test/torque/test-torque.tq - v8/v8.git - Git at Google

 // 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): 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);
   }

   @export
   macro TestConstexpr1() {
     check(FromConstexpr<bool>(IsFastElementsKind(PACKED_SMI_ELEMENTS)));
   }

   @export
   macro TestConstexprIf() {
     check(ElementsKindTestHelper1(UINT8_ELEMENTS));
     check(ElementsKindTestHelper1(UINT16_ELEMENTS));
     check(!ElementsKindTestHelper1(UINT32_ELEMENTS));
   }

   @export
   macro TestConstexprReturn() {
     check(FromConstexpr<bool>(ElementsKindTestHelper2(UINT8_ELEMENTS)));
     check(FromConstexpr<bool>(ElementsKindTestHelper2(UINT16_ELEMENTS)));
     check(!FromConstexpr<bool>(ElementsKindTestHelper2(UINT32_ELEMENTS)));
     check(FromConstexpr<bool>(!ElementsKindTestHelper2(UINT32_ELEMENTS)));
   }

   @export
   macro TestGotoLabel(): Boolean {
     try {
       LabelTestHelper1() otherwise Label1;
     }
     label Label1 {
       return True;
     }
   }

   @export
   macro TestGotoLabelWithOneParameter(): Boolean {
     try {
       LabelTestHelper2() otherwise Label2;
     }
     label Label2(smi: Smi) {
       check(smi == 42);
       return True;
     }
   }

   @export
   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): JSAny {
     return Null;
   }

   GenericBuiltinTest<JSAny>(_c: Context, param: JSAny): JSAny {
     return param;
   }

   @export
   macro TestBuiltinSpecialization(c: Context) {
     check(GenericBuiltinTest<Smi>(c, 0) == Null);
     check(GenericBuiltinTest<Smi>(c, 1) == Null);
     check(GenericBuiltinTest<JSAny>(c, Undefined) == Undefined);
     check(GenericBuiltinTest<JSAny>(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;
     }
   }

   @export
   macro TestPartiallyUnusedLabel(): Boolean {
     const r1: bool = CallLabelTestHelper4(true);
     const 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;
   }

   @export
   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;
   }

   @export
   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;
   }

   @export
   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;
   }

   @export
   macro TestTernaryOperator(x: Smi): Smi {
     const b: bool = x < 0 ? true : false;
     return b ? x - 10 : x + 100;
   }

   @export
   macro TestFunctionPointerToGeneric(c: Context) {
     const fptr1: builtin(Context, Smi) => JSAny = GenericBuiltinTest<Smi>;
     const fptr2: builtin(Context, JSAny) => JSAny = GenericBuiltinTest<JSAny>;

     check(fptr1(c, 0) == Null);
     check(fptr1(c, 1) == Null);
     check(fptr2(c, Undefined) == Undefined);
     check(fptr2(c, Undefined) == Undefined);
   }

   type ObjectToObject = builtin(Context, JSAny) => JSAny;
   @export
   macro TestTypeAlias(x: ObjectToObject): BuiltinPtr {
     return x;
   }

   @export
   macro TestUnsafeCast(implicit context: Context)(n: Number): Boolean {
     if (TaggedIsSmi(n)) {
       const m: Smi = UnsafeCast<Smi>(n);

       check(TestHelperPlus1(context, m) == 11);
       return True;
     }
     return False;
   }

   @export
   macro TestHexLiteral() {
     check(Convert<intptr>(0xffff) + 1 == 0x10000);
     check(Convert<intptr>(-0xffff) == -65535);
   }

   @export
   macro TestLargeIntegerLiterals(implicit c: Context)() {
     let _x: int32 = 0x40000000;
     let _y: int32 = 0x7fffffff;
   }

   @export
   macro TestMultilineAssert() {
     const someVeryLongVariableNameThatWillCauseLineBreaks: Smi = 5;
     check(
         someVeryLongVariableNameThatWillCauseLineBreaks > 0 &&
         someVeryLongVariableNameThatWillCauseLineBreaks < 10);
   }

   @export
   macro TestNewlineInString() {
     Print('Hello, World!\n');
   }

   const kConstexprConst: constexpr int31 = 5;
   const kIntptrConst: intptr = 4;
   const kSmiConst: Smi = 3;

   @export
   macro TestModuleConstBindings() {
     check(kConstexprConst == Int32Constant(5));
     check(kIntptrConst == 4);
     check(kSmiConst == 3);
   }

   @export
   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;
   }

   @export
   macro TestStruct1(i: TestStructA): Smi {
     return i.i;
   }

   @export
   macro TestStruct2(implicit context: Context)(): TestStructA {
     return TestStructA{
       indexes: UnsafeCast<FixedArray>(kEmptyFixedArray),
       i: 27,
       k: 31
     };
   }

   @export
   macro TestStruct3(implicit context: Context)(): TestStructA {
     let a: TestStructA =
     TestStructA{indexes: UnsafeCast<FixedArray>(kEmptyFixedArray), i: 13, k: 5};
     let _b: TestStructA = a;
     const 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;
   }

   @export
   macro TestStruct4(implicit context: Context)(): TestStructC {
     return TestStructC{x: TestStruct2(), y: TestStruct2()};
   }

   macro TestStructInLabel(implicit context: Context)(): never labels
   Foo(TestStructA) {
     goto Foo(TestStruct2());
   }
   @export  // Silence unused warning.
   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.
   @export
   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) {
     }
   }

   @export
   macro TestSubtyping(x: Smi) {
     const _foo: JSAny = 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;
   }

   @export
   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);
   }

   @export
   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;
   }

   @export
   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);
   }

   @export
   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);
   }

   @export
   macro TestOrAnd(x: bool, y: bool, z: bool): bool {
     return x || y && z ? true : false;
   }

   @export
   macro TestAndOr(x: bool, y: bool, z: bool): bool {
     return x && y || z ? true : false;
   }

   @export
   macro TestLogicalOperators() {
     check(TestAndOr(true, true, true));
     check(TestAndOr(true, true, false));
     check(TestAndOr(true, false, true));
     check(!TestAndOr(true, false, false));
     check(TestAndOr(false, true, true));
     check(!TestAndOr(false, true, false));
     check(TestAndOr(false, false, true));
     check(!TestAndOr(false, false, false));
     check(TestOrAnd(true, true, true));
     check(TestOrAnd(true, true, false));
     check(TestOrAnd(true, false, true));
     check(TestOrAnd(true, false, false));
     check(TestOrAnd(false, true, true));
     check(!TestOrAnd(false, true, false));
     check(!TestOrAnd(false, false, true));
     check(!TestOrAnd(false, false, false));
   }

   @export
   macro TestCall(i: Smi): Smi labels A {
     if (i < 5) return i;
     goto A;
   }

   @export
   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);
   }

   @export
   macro TestOtherwiseWithCode2() {
     let s: Smi = 0;
     for (let i: Smi = 0; i < 10; ++i) {
       TestCall(i) otherwise break;
       ++s;
     }
     assert(s == 5);
   }

   @export
   macro TestOtherwiseWithCode3() {
     let s: Smi = 0;
     for (let i: Smi = 0; i < 10; ++i) {
       s += TestCall(i) otherwise break;
     }
     assert(s == 10);
   }

   @export
   macro TestForwardLabel() {
     try {
       goto A;
     }
     label A {
       goto B(5);
     }
     label B(b: Smi) {
       assert(b == 5);
     }
   }

   @export
   macro TestQualifiedAccess(implicit context: Context)() {
     const s: Smi = 0;
     check(!Is<JSArray>(s));
   }

   @export
   macro TestCatch1(implicit context: Context)(): Smi {
     let r: Smi = 0;
     try {
       ThrowTypeError(kInvalidArrayLength);
     } catch (_e) {
       r = 1;
       return r;
     }
   }

   @export
   macro TestCatch2Wrapper(implicit context: Context)(): never {
     ThrowTypeError(kInvalidArrayLength);
   }

   @export
   macro TestCatch2(implicit context: Context)(): Smi {
     let r: Smi = 0;
     try {
       TestCatch2Wrapper();
     } catch (_e) {
       r = 2;
       return r;
     }
   }

   @export
   macro TestCatch3WrapperWithLabel(implicit context: Context)():
       never labels _Abort {
     ThrowTypeError(kInvalidArrayLength);
   }

   @export
   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.
   @export
   macro TestIterator(implicit context: Context)(o: JSReceiver, map: Map) {
     try {
       const t1: JSAny = iterator::GetIteratorMethod(o);
       const t2: iterator::IteratorRecord = iterator::GetIterator(o);

       const _t3: JSAny = iterator::IteratorStep(t2) otherwise Fail;
       const _t4: JSAny = iterator::IteratorStep(t2, map) otherwise Fail;

       const t5: JSAny = iterator::IteratorValue(o);
       const _t6: JSAny = iterator::IteratorValue(o, map);

       const _t7: JSArray = iterator::IterableToList(t1, t1);

       iterator::IteratorCloseOnException(t2, t5);
     }
     label Fail {}
   }

   @export
   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): {
       }
     }
   }

   @export
   macro TestNew(implicit context: Context)() {
     const f: JSArray = NewJSArray();
     check(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;
   }

   @export
   macro TestStructConstructor(implicit context: Context)() {
     // Test default constructor
     let a: TestOuter = TestOuter{a: 5, b: TestInner{x: 6, y: 7}, c: 8};
     check(a.a == 5);
     check(a.b.x == 6);
     check(a.b.y == 7);
     check(a.c == 8);
     a.b.x = 1;
     check(a.b.x == 1);
     a.b.SetX(2);
     check(a.b.x == 2);
     check(a.b.GetX() == 2);
   }

   class InternalClass extends Struct {
     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};
   }

   @export
   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;
   }

   @export
   macro TestConstInStructs() {
     const x = StructWithConst{a: Null, b: 1};
     let y = StructWithConst{a: Null, b: 1};
     y.a = Undefined;
     const _copy = x;

     check(x.TestMethod1() == 1);
     check(x.TestMethod2() == Null);
   }

   struct TestIterator {
     Next(): Object labels NoMore {
       if (this.count-- == 0) goto NoMore;
       return TheHole;
     }
     count: Smi;
   }

   @export
   macro TestNewFixedArrayFromSpread(implicit context: Context)(): Object {
     let i = TestIterator{count: 5};
     return new FixedArray{map: kFixedArrayMap, length: 5, objects: ...i};
   }

   class SmiPair extends Struct {
     GetA():&Smi {
       return & this.a;
     }
     a: Smi;
     b: Smi;
   }

   macro Swap<T: type>(a:&T, b:&T) {
     const tmp = * a;
     * a = * b;
     * b = tmp;
   }

   @export
   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);
   }

   @export
   macro TestSlices() {
     const it = TestIterator{count: 3};
     const a = new FixedArray{map: kFixedArrayMap, length: 3, objects: ...it};
     check(a.length == 3);

     const oneTwoThree = Convert<Smi>(123);
     a.objects[0] = oneTwoThree;
     const firstRef:&Object = & a.objects[0];
     check(TaggedEqual(* firstRef, oneTwoThree));

     const slice: torque_internal::Slice<Object> = & a.objects;
     const firstRefAgain:&Object = slice.TryAtIndex(0) otherwise unreachable;
     check(TaggedEqual(* firstRefAgain, oneTwoThree));

     const threeTwoOne = Convert<Smi>(321);
     * firstRefAgain = threeTwoOne;
     check(TaggedEqual(a.objects[0], threeTwoOne));

     // *slice;             // error, not allowed
     // a.objects;          // error, not allowed
     // a.objects = slice;  // error, not allowed

     // TODO(gsps): Currently errors, but should be allowed:
     // const _sameSlice: torque_internal::Slice<Object> = &(*slice);
     // (*slice)[0] : Smi
   }

   @export
   macro TestSliceEnumeration(implicit context: Context)(): Undefined {
     const fixedArray: FixedArray = AllocateZeroedFixedArray(3);
     for (let i: intptr = 0; i < 3; i++) {
       check(UnsafeCast<Smi>(fixedArray.objects[i]) == 0);
       fixedArray.objects[i] = Convert<Smi>(i) + 3;
     }

     let slice = & fixedArray.objects;
     for (let i: intptr = 0; i < slice.length; i++) {
       let ref = slice.TryAtIndex(i) otherwise unreachable;
       const value = UnsafeCast<Smi>(* ref);
       check(value == Convert<Smi>(i) + 3);
       * ref = value + 4;
     }

     let it = slice.Iterator();
     let count: Smi = 0;
     while (true) {
       let ref = it.Next() otherwise break;
       const value = UnsafeCast<Smi>(* ref);
       check(value == count + 7);
       count++;
     }
     check(count == 3);
     check(it.Empty());

     return Undefined;
   }

   @export
   macro TestStaticAssert() {
     StaticAssert(1 + 2 == 3);
   }

   class SmiBox extends Struct {
     value: Smi;
     unrelated: Smi;
   }

   builtin NewSmiBox(implicit context: Context)(value: Smi): SmiBox {
     return new SmiBox{value, unrelated: 0};
   }

   @export
   macro TestLoadEliminationFixed(implicit context: Context)() {
     const box = NewSmiBox(123);
     const v1 = box.value;
     box.unrelated = 999;
     const v2 = (box.unrelated == 0) ? box.value : box.value;
     StaticAssert(TaggedEqual(v1, v2));

     box.value = 11;
     const v3 = box.value;
     const eleven: Smi = 11;
     StaticAssert(TaggedEqual(v3, eleven));
   }

   @export
   macro TestLoadEliminationVariable(implicit context: Context)() {
     const a = UnsafeCast<FixedArray>(kEmptyFixedArray);
     const box = NewSmiBox(1);
     const v1 = a.objects[box.value];
     const u1 = a.objects[box.value + 2];
     const v2 = a.objects[box.value];
     const u2 = a.objects[box.value + 2];
     StaticAssert(TaggedEqual(v1, v2));
     StaticAssert(TaggedEqual(u1, u2));
   }

   @export
   macro TestRedundantArrayElementCheck(implicit context: Context)(): Smi {
     const a = kEmptyFixedArray;
     for (let i: Smi = 0; i < a.length; i++) {
       if (a.objects[i] == TheHole) {
         if (a.objects[i] == TheHole) {
           return -1;
         } else {
           StaticAssert(false);
         }
       }
     }
     return 1;
   }

   @export
   macro TestRedundantSmiCheck(implicit context: Context)(): Smi {
     const a = kEmptyFixedArray;
     const x = a.objects[1];
     typeswitch (x) {
       case (Smi): {
         Cast<Smi>(x) otherwise VerifiedUnreachable();
         return -1;
       }
       case (Object): {
       }
     }
     return 1;
   }

   struct SBox<T: type> {
     value: T;
   }

   @export
   macro TestGenericStruct1(): intptr {
     const i: intptr = 123;
     let box = SBox{value: i};
     let boxbox: SBox<SBox<intptr>> = SBox{value: box};
     check(box.value == 123);
     boxbox.value.value *= 2;
     check(boxbox.value.value == 246);
     return boxbox.value.value;
   }

   struct TestTuple<T1: type, T2: type> {
     const fst: T1;
     const snd: T2;
   }

   macro TupleSwap<T1: type, T2: type>(tuple: TestTuple<T1, T2>):
       TestTuple<T2, T1> {
     return TestTuple{fst: tuple.snd, snd: tuple.fst};
   }

   @export
   macro TestGenericStruct2():
       TestTuple<TestTuple<intptr, Smi>, TestTuple<Smi, intptr>> {
     const intptrAndSmi = TestTuple<intptr, Smi>{fst: 1, snd: 2};
     const smiAndIntptr = TupleSwap(intptrAndSmi);
     check(intptrAndSmi.fst == smiAndIntptr.snd);
     check(intptrAndSmi.snd == smiAndIntptr.fst);
     const tupleTuple =
         TestTuple<TestTuple<intptr, Smi>>{fst: intptrAndSmi, snd: smiAndIntptr};
     return tupleTuple;
   }

   macro BranchAndWriteResult(x: Smi, box: SmiBox): bool {
     if (x > 5 || x < 0) {
       box.value = 1;
       return true;
     } else {
       box.value = 2;
       return false;
     }
   }

   @export
   macro TestBranchOnBoolOptimization(implicit context: Context)(input: Smi) {
     const box = NewSmiBox(1);
     // If the two branches get combined into one, we should be able to determine
     // the value of {box} statically.
     if (BranchAndWriteResult(input, box)) {
       StaticAssert(box.value == 1);
     } else {
       StaticAssert(box.value == 2);
     }
   }

 }
	// 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): 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);
	}

	@export
	macro TestConstexpr1() {
	check(FromConstexpr<bool>(IsFastElementsKind(PACKED_SMI_ELEMENTS)));
	}

	@export
	macro TestConstexprIf() {
	check(ElementsKindTestHelper1(UINT8_ELEMENTS));
	check(ElementsKindTestHelper1(UINT16_ELEMENTS));
	check(!ElementsKindTestHelper1(UINT32_ELEMENTS));
	}

	@export
	macro TestConstexprReturn() {
	check(FromConstexpr<bool>(ElementsKindTestHelper2(UINT8_ELEMENTS)));
	check(FromConstexpr<bool>(ElementsKindTestHelper2(UINT16_ELEMENTS)));
	check(!FromConstexpr<bool>(ElementsKindTestHelper2(UINT32_ELEMENTS)));
	check(FromConstexpr<bool>(!ElementsKindTestHelper2(UINT32_ELEMENTS)));
	}

	@export
	macro TestGotoLabel(): Boolean {
	try {
	LabelTestHelper1() otherwise Label1;
	}
	label Label1 {
	return True;
	}
	}

	@export
	macro TestGotoLabelWithOneParameter(): Boolean {
	try {
	LabelTestHelper2() otherwise Label2;
	}
	label Label2(smi: Smi) {
	check(smi == 42);
	return True;
	}
	}

	@export
	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): JSAny {
	return Null;
	}

	GenericBuiltinTest<JSAny>(_c: Context, param: JSAny): JSAny {
	return param;
	}

	@export
	macro TestBuiltinSpecialization(c: Context) {
	check(GenericBuiltinTest<Smi>(c, 0) == Null);
	check(GenericBuiltinTest<Smi>(c, 1) == Null);
	check(GenericBuiltinTest<JSAny>(c, Undefined) == Undefined);
	check(GenericBuiltinTest<JSAny>(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;
	}
	}

	@export
	macro TestPartiallyUnusedLabel(): Boolean {
	const r1: bool = CallLabelTestHelper4(true);
	const 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;
	}

	@export
	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;
	}

	@export
	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;
	}

	@export
	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;
	}

	@export
	macro TestTernaryOperator(x: Smi): Smi {
	const b: bool = x < 0 ? true : false;
	return b ? x - 10 : x + 100;
	}

	@export
	macro TestFunctionPointerToGeneric(c: Context) {
	const fptr1: builtin(Context, Smi) => JSAny = GenericBuiltinTest<Smi>;
	const fptr2: builtin(Context, JSAny) => JSAny = GenericBuiltinTest<JSAny>;

	check(fptr1(c, 0) == Null);
	check(fptr1(c, 1) == Null);
	check(fptr2(c, Undefined) == Undefined);
	check(fptr2(c, Undefined) == Undefined);
	}

	type ObjectToObject = builtin(Context, JSAny) => JSAny;
	@export
	macro TestTypeAlias(x: ObjectToObject): BuiltinPtr {
	return x;
	}

	@export
	macro TestUnsafeCast(implicit context: Context)(n: Number): Boolean {
	if (TaggedIsSmi(n)) {
	const m: Smi = UnsafeCast<Smi>(n);

	check(TestHelperPlus1(context, m) == 11);
	return True;
	}
	return False;
	}

	@export
	macro TestHexLiteral() {
	check(Convert<intptr>(0xffff) + 1 == 0x10000);
	check(Convert<intptr>(-0xffff) == -65535);
	}

	@export
	macro TestLargeIntegerLiterals(implicit c: Context)() {
	let _x: int32 = 0x40000000;
	let _y: int32 = 0x7fffffff;
	}

	@export
	macro TestMultilineAssert() {
	const someVeryLongVariableNameThatWillCauseLineBreaks: Smi = 5;
	check(
	someVeryLongVariableNameThatWillCauseLineBreaks > 0 &&
	someVeryLongVariableNameThatWillCauseLineBreaks < 10);
	}

	@export
	macro TestNewlineInString() {
	Print('Hello, World!\n');
	}

	const kConstexprConst: constexpr int31 = 5;
	const kIntptrConst: intptr = 4;
	const kSmiConst: Smi = 3;

	@export
	macro TestModuleConstBindings() {
	check(kConstexprConst == Int32Constant(5));
	check(kIntptrConst == 4);
	check(kSmiConst == 3);
	}

	@export
	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;
	}

	@export
	macro TestStruct1(i: TestStructA): Smi {
	return i.i;
	}

	@export
	macro TestStruct2(implicit context: Context)(): TestStructA {
	return TestStructA{
	indexes: UnsafeCast<FixedArray>(kEmptyFixedArray),
	i: 27,
	k: 31
	};
	}

	@export
	macro TestStruct3(implicit context: Context)(): TestStructA {
	let a: TestStructA =
	TestStructA{indexes: UnsafeCast<FixedArray>(kEmptyFixedArray), i: 13, k: 5};
	let _b: TestStructA = a;
	const 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;
	}

	@export
	macro TestStruct4(implicit context: Context)(): TestStructC {
	return TestStructC{x: TestStruct2(), y: TestStruct2()};
	}

	macro TestStructInLabel(implicit context: Context)(): never labels
	Foo(TestStructA) {
	goto Foo(TestStruct2());
	}
	@export // Silence unused warning.
	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.
	@export
	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) {
	}
	}

	@export
	macro TestSubtyping(x: Smi) {
	const _foo: JSAny = 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;
	}

	@export
	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);
	}

	@export
	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;
	}

	@export
	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);
	}

	@export
	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);
	}

	@export
	macro TestOrAnd(x: bool, y: bool, z: bool): bool {
	return x \|\| y && z ? true : false;
	}

	@export
	macro TestAndOr(x: bool, y: bool, z: bool): bool {
	return x && y \|\| z ? true : false;
	}

	@export
	macro TestLogicalOperators() {
	check(TestAndOr(true, true, true));
	check(TestAndOr(true, true, false));
	check(TestAndOr(true, false, true));
	check(!TestAndOr(true, false, false));
	check(TestAndOr(false, true, true));
	check(!TestAndOr(false, true, false));
	check(TestAndOr(false, false, true));
	check(!TestAndOr(false, false, false));
	check(TestOrAnd(true, true, true));
	check(TestOrAnd(true, true, false));
	check(TestOrAnd(true, false, true));
	check(TestOrAnd(true, false, false));
	check(TestOrAnd(false, true, true));
	check(!TestOrAnd(false, true, false));
	check(!TestOrAnd(false, false, true));
	check(!TestOrAnd(false, false, false));
	}

	@export
	macro TestCall(i: Smi): Smi labels A {
	if (i < 5) return i;
	goto A;
	}

	@export
	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);
	}

	@export
	macro TestOtherwiseWithCode2() {
	let s: Smi = 0;
	for (let i: Smi = 0; i < 10; ++i) {
	TestCall(i) otherwise break;
	++s;
	}
	assert(s == 5);
	}

	@export
	macro TestOtherwiseWithCode3() {
	let s: Smi = 0;
	for (let i: Smi = 0; i < 10; ++i) {
	s += TestCall(i) otherwise break;
	}
	assert(s == 10);
	}

	@export
	macro TestForwardLabel() {
	try {
	goto A;
	}
	label A {
	goto B(5);
	}
	label B(b: Smi) {
	assert(b == 5);
	}
	}

	@export
	macro TestQualifiedAccess(implicit context: Context)() {
	const s: Smi = 0;
	check(!Is<JSArray>(s));
	}

	@export
	macro TestCatch1(implicit context: Context)(): Smi {
	let r: Smi = 0;
	try {
	ThrowTypeError(kInvalidArrayLength);
	} catch (_e) {
	r = 1;
	return r;
	}
	}

	@export
	macro TestCatch2Wrapper(implicit context: Context)(): never {
	ThrowTypeError(kInvalidArrayLength);
	}

	@export
	macro TestCatch2(implicit context: Context)(): Smi {
	let r: Smi = 0;
	try {
	TestCatch2Wrapper();
	} catch (_e) {
	r = 2;
	return r;
	}
	}

	@export
	macro TestCatch3WrapperWithLabel(implicit context: Context)():
	never labels _Abort {
	ThrowTypeError(kInvalidArrayLength);
	}

	@export
	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.
	@export
	macro TestIterator(implicit context: Context)(o: JSReceiver, map: Map) {
	try {
	const t1: JSAny = iterator::GetIteratorMethod(o);
	const t2: iterator::IteratorRecord = iterator::GetIterator(o);

	const _t3: JSAny = iterator::IteratorStep(t2) otherwise Fail;
	const _t4: JSAny = iterator::IteratorStep(t2, map) otherwise Fail;

	const t5: JSAny = iterator::IteratorValue(o);
	const _t6: JSAny = iterator::IteratorValue(o, map);

	const _t7: JSArray = iterator::IterableToList(t1, t1);

	iterator::IteratorCloseOnException(t2, t5);
	}
	label Fail {}
	}

	@export
	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): {
	}
	}
	}

	@export
	macro TestNew(implicit context: Context)() {
	const f: JSArray = NewJSArray();
	check(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;
	}

	@export
	macro TestStructConstructor(implicit context: Context)() {
	// Test default constructor
	let a: TestOuter = TestOuter{a: 5, b: TestInner{x: 6, y: 7}, c: 8};
	check(a.a == 5);
	check(a.b.x == 6);
	check(a.b.y == 7);
	check(a.c == 8);
	a.b.x = 1;
	check(a.b.x == 1);
	a.b.SetX(2);
	check(a.b.x == 2);
	check(a.b.GetX() == 2);
	}

	class InternalClass extends Struct {
	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};
	}

	@export
	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;
	}

	@export
	macro TestConstInStructs() {
	const x = StructWithConst{a: Null, b: 1};
	let y = StructWithConst{a: Null, b: 1};
	y.a = Undefined;
	const _copy = x;

	check(x.TestMethod1() == 1);
	check(x.TestMethod2() == Null);
	}

	struct TestIterator {
	Next(): Object labels NoMore {
	if (this.count-- == 0) goto NoMore;
	return TheHole;
	}
	count: Smi;
	}

	@export
	macro TestNewFixedArrayFromSpread(implicit context: Context)(): Object {
	let i = TestIterator{count: 5};
	return new FixedArray{map: kFixedArrayMap, length: 5, objects: ...i};
	}

	class SmiPair extends Struct {
	GetA():&Smi {
	return & this.a;
	}
	a: Smi;
	b: Smi;
	}

	macro Swap<T: type>(a:&T, b:&T) {
	const tmp = * a;
	* a = * b;
	* b = tmp;
	}

	@export
	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);
	}

	@export
	macro TestSlices() {
	const it = TestIterator{count: 3};
	const a = new FixedArray{map: kFixedArrayMap, length: 3, objects: ...it};
	check(a.length == 3);

	const oneTwoThree = Convert<Smi>(123);
	a.objects[0] = oneTwoThree;
	const firstRef:&Object = & a.objects[0];
	check(TaggedEqual(* firstRef, oneTwoThree));

	const slice: torque_internal::Slice<Object> = & a.objects;
	const firstRefAgain:&Object = slice.TryAtIndex(0) otherwise unreachable;
	check(TaggedEqual(* firstRefAgain, oneTwoThree));

	const threeTwoOne = Convert<Smi>(321);
	* firstRefAgain = threeTwoOne;
	check(TaggedEqual(a.objects[0], threeTwoOne));

	// *slice; // error, not allowed
	// a.objects; // error, not allowed
	// a.objects = slice; // error, not allowed

	// TODO(gsps): Currently errors, but should be allowed:
	// const _sameSlice: torque_internal::Slice<Object> = &(*slice);
	// (*slice)[0] : Smi
	}

	@export
	macro TestSliceEnumeration(implicit context: Context)(): Undefined {
	const fixedArray: FixedArray = AllocateZeroedFixedArray(3);
	for (let i: intptr = 0; i < 3; i++) {
	check(UnsafeCast<Smi>(fixedArray.objects[i]) == 0);
	fixedArray.objects[i] = Convert<Smi>(i) + 3;
	}

	let slice = & fixedArray.objects;
	for (let i: intptr = 0; i < slice.length; i++) {
	let ref = slice.TryAtIndex(i) otherwise unreachable;
	const value = UnsafeCast<Smi>(* ref);
	check(value == Convert<Smi>(i) + 3);
	* ref = value + 4;
	}

	let it = slice.Iterator();
	let count: Smi = 0;
	while (true) {
	let ref = it.Next() otherwise break;
	const value = UnsafeCast<Smi>(* ref);
	check(value == count + 7);
	count++;
	}
	check(count == 3);
	check(it.Empty());

	return Undefined;
	}

	@export
	macro TestStaticAssert() {
	StaticAssert(1 + 2 == 3);
	}

	class SmiBox extends Struct {
	value: Smi;
	unrelated: Smi;
	}

	builtin NewSmiBox(implicit context: Context)(value: Smi): SmiBox {
	return new SmiBox{value, unrelated: 0};
	}

	@export
	macro TestLoadEliminationFixed(implicit context: Context)() {
	const box = NewSmiBox(123);
	const v1 = box.value;
	box.unrelated = 999;
	const v2 = (box.unrelated == 0) ? box.value : box.value;
	StaticAssert(TaggedEqual(v1, v2));

	box.value = 11;
	const v3 = box.value;
	const eleven: Smi = 11;
	StaticAssert(TaggedEqual(v3, eleven));
	}

	@export
	macro TestLoadEliminationVariable(implicit context: Context)() {
	const a = UnsafeCast<FixedArray>(kEmptyFixedArray);
	const box = NewSmiBox(1);
	const v1 = a.objects[box.value];
	const u1 = a.objects[box.value + 2];
	const v2 = a.objects[box.value];
	const u2 = a.objects[box.value + 2];
	StaticAssert(TaggedEqual(v1, v2));
	StaticAssert(TaggedEqual(u1, u2));
	}

	@export
	macro TestRedundantArrayElementCheck(implicit context: Context)(): Smi {
	const a = kEmptyFixedArray;
	for (let i: Smi = 0; i < a.length; i++) {
	if (a.objects[i] == TheHole) {
	if (a.objects[i] == TheHole) {
	return -1;
	} else {
	StaticAssert(false);
	}
	}
	}
	return 1;
	}

	@export
	macro TestRedundantSmiCheck(implicit context: Context)(): Smi {
	const a = kEmptyFixedArray;
	const x = a.objects[1];
	typeswitch (x) {
	case (Smi): {
	Cast<Smi>(x) otherwise VerifiedUnreachable();
	return -1;
	}
	case (Object): {
	}
	}
	return 1;
	}

	struct SBox<T: type> {
	value: T;
	}

	@export
	macro TestGenericStruct1(): intptr {
	const i: intptr = 123;
	let box = SBox{value: i};
	let boxbox: SBox<SBox<intptr>> = SBox{value: box};
	check(box.value == 123);
	boxbox.value.value *= 2;
	check(boxbox.value.value == 246);
	return boxbox.value.value;
	}

	struct TestTuple<T1: type, T2: type> {
	const fst: T1;
	const snd: T2;
	}

	macro TupleSwap<T1: type, T2: type>(tuple: TestTuple<T1, T2>):
	TestTuple<T2, T1> {
	return TestTuple{fst: tuple.snd, snd: tuple.fst};
	}

	@export
	macro TestGenericStruct2():
	TestTuple<TestTuple<intptr, Smi>, TestTuple<Smi, intptr>> {
	const intptrAndSmi = TestTuple<intptr, Smi>{fst: 1, snd: 2};
	const smiAndIntptr = TupleSwap(intptrAndSmi);
	check(intptrAndSmi.fst == smiAndIntptr.snd);
	check(intptrAndSmi.snd == smiAndIntptr.fst);
	const tupleTuple =
	TestTuple<TestTuple<intptr, Smi>>{fst: intptrAndSmi, snd: smiAndIntptr};
	return tupleTuple;
	}

	macro BranchAndWriteResult(x: Smi, box: SmiBox): bool {
	if (x > 5 \|\| x < 0) {
	box.value = 1;
	return true;
	} else {
	box.value = 2;
	return false;
	}
	}

	@export
	macro TestBranchOnBoolOptimization(implicit context: Context)(input: Smi) {
	const box = NewSmiBox(1);
	// If the two branches get combined into one, we should be able to determine
	// the value of {box} statically.
	if (BranchAndWriteResult(input, box)) {
	StaticAssert(box.value == 1);
	} else {
	StaticAssert(box.value == 2);
	}
	}

	}