mirror of
https://github.com/dart-lang/sdk
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f2fd150ea0
BUG= R=johnmccutchan@google.com Review-Url: https://codereview.chromium.org/2666133002 .
250 lines
9.5 KiB
C++
250 lines
9.5 KiB
C++
// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
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// for details. All rights reserved. Use of this source code is governed by a
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// BSD-style license that can be found in the LICENSE file.
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#include "include/dart_api.h"
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#include "platform/assert.h"
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#include "vm/globals.h"
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#include "vm/isolate.h"
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#include "vm/lockers.h"
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#include "vm/thread_barrier.h"
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#include "vm/thread_pool.h"
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#include "vm/unit_test.h"
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namespace dart {
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VM_UNIT_TEST_CASE(IsolateCurrent) {
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Dart_Isolate isolate = Dart_CreateIsolate(
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NULL, NULL, bin::core_isolate_snapshot_data,
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bin::core_isolate_snapshot_instructions, NULL, NULL, NULL);
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EXPECT_EQ(isolate, Dart_CurrentIsolate());
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Dart_ShutdownIsolate();
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EXPECT_EQ(reinterpret_cast<Dart_Isolate>(NULL), Dart_CurrentIsolate());
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}
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// Test to ensure that an exception is thrown if no isolate creation
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// callback has been set by the embedder when an isolate is spawned.
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TEST_CASE(IsolateSpawn) {
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const char* kScriptChars =
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"import 'dart:isolate';\n"
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// Ignores printed lines.
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"var _nullPrintClosure = (String line) {};\n"
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"void entry(message) {}\n"
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"int testMain() {\n"
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" Isolate.spawn(entry, null);\n"
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// TODO(floitsch): the following code is only to bump the event loop
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// so it executes asynchronous microtasks.
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" var rp = new RawReceivePort();\n"
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" rp.sendPort.send(null);\n"
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" rp.handler = (_) { rp.close(); };\n"
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"}\n";
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Dart_Handle test_lib = TestCase::LoadTestScript(kScriptChars, NULL);
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// Setup the internal library's 'internalPrint' function.
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// Necessary because asynchronous errors use "print" to print their
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// stack trace.
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Dart_Handle url = NewString("dart:_internal");
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DART_CHECK_VALID(url);
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Dart_Handle internal_lib = Dart_LookupLibrary(url);
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DART_CHECK_VALID(internal_lib);
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Dart_Handle print = Dart_GetField(test_lib, NewString("_nullPrintClosure"));
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Dart_Handle result =
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Dart_SetField(internal_lib, NewString("_printClosure"), print);
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DART_CHECK_VALID(result);
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// Setup the 'scheduleImmediate' closure.
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url = NewString("dart:isolate");
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DART_CHECK_VALID(url);
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Dart_Handle isolate_lib = Dart_LookupLibrary(url);
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DART_CHECK_VALID(isolate_lib);
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Dart_Handle schedule_immediate_closure = Dart_Invoke(
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isolate_lib, NewString("_getIsolateScheduleImmediateClosure"), 0, NULL);
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Dart_Handle args[1];
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args[0] = schedule_immediate_closure;
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url = NewString("dart:async");
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DART_CHECK_VALID(url);
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Dart_Handle async_lib = Dart_LookupLibrary(url);
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DART_CHECK_VALID(async_lib);
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DART_CHECK_VALID(Dart_Invoke(
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async_lib, NewString("_setScheduleImmediateClosure"), 1, args));
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result = Dart_Invoke(test_lib, NewString("testMain"), 0, NULL);
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EXPECT_VALID(result);
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// Run until all ports to isolate are closed.
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result = Dart_RunLoop();
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EXPECT_ERROR(result, "Unsupported operation: Isolate.spawn");
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EXPECT(Dart_ErrorHasException(result));
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Dart_Handle exception_result = Dart_ErrorGetException(result);
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EXPECT_VALID(exception_result);
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}
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class InterruptChecker : public ThreadPool::Task {
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public:
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static const intptr_t kTaskCount;
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static const intptr_t kIterations;
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InterruptChecker(Thread* thread, ThreadBarrier* barrier)
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: thread_(thread), barrier_(barrier) {}
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virtual void Run() {
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Thread::EnterIsolateAsHelper(thread_->isolate(), Thread::kUnknownTask);
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// Tell main thread that we are ready.
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barrier_->Sync();
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for (intptr_t i = 0; i < kIterations; ++i) {
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// Busy wait for interrupts.
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uword limit = 0;
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do {
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limit = AtomicOperations::LoadRelaxed(
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reinterpret_cast<uword*>(thread_->stack_limit_address()));
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} while (
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(limit == thread_->saved_stack_limit_) ||
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(((limit & Thread::kInterruptsMask) & Thread::kVMInterrupt) == 0));
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// Tell main thread that we observed the interrupt.
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barrier_->Sync();
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}
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Thread::ExitIsolateAsHelper();
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barrier_->Exit();
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}
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private:
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Thread* thread_;
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ThreadBarrier* barrier_;
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};
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const intptr_t InterruptChecker::kTaskCount = 5;
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const intptr_t InterruptChecker::kIterations = 10;
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// Test and document usage of Isolate::HasInterruptsScheduled.
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//
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// Go through a number of rounds of scheduling interrupts and waiting until all
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// unsynchronized busy-waiting tasks observe it (in the current implementation,
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// the exact latency depends on cache coherence). Synchronization is then used
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// to ensure that the response to the interrupt, i.e., starting a new round,
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// happens *after* the interrupt is observed. Without this synchronization, the
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// compiler and/or CPU could reorder operations to make the tasks observe the
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// round update *before* the interrupt is set.
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TEST_CASE(StackLimitInterrupts) {
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Isolate* isolate = thread->isolate();
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ThreadBarrier barrier(InterruptChecker::kTaskCount + 1,
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isolate->heap()->barrier(),
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isolate->heap()->barrier_done());
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// Start all tasks. They will busy-wait until interrupted in the first round.
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for (intptr_t task = 0; task < InterruptChecker::kTaskCount; task++) {
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Dart::thread_pool()->Run(new InterruptChecker(thread, &barrier));
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}
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// Wait for all tasks to get ready for the first round.
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barrier.Sync();
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for (intptr_t i = 0; i < InterruptChecker::kIterations; ++i) {
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thread->ScheduleInterrupts(Thread::kVMInterrupt);
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// Wait for all tasks to observe the interrupt.
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barrier.Sync();
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// Continue with next round.
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uword interrupts = thread->GetAndClearInterrupts();
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EXPECT((interrupts & Thread::kVMInterrupt) != 0);
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}
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barrier.Exit();
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}
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class IsolateTestHelper {
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public:
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static uword GetStackLimit(Thread* thread) { return thread->stack_limit_; }
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static uword GetSavedStackLimit(Thread* thread) {
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return thread->saved_stack_limit_;
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}
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static uword GetDeferredInterruptsMask(Thread* thread) {
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return thread->deferred_interrupts_mask_;
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}
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static uword GetDeferredInterrupts(Thread* thread) {
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return thread->deferred_interrupts_;
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}
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};
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TEST_CASE(NoOOBMessageScope) {
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// EXPECT_EQ is picky about type agreement for its arguments.
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const uword kZero = 0;
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const uword kMessageInterrupt = Thread::kMessageInterrupt;
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const uword kVMInterrupt = Thread::kVMInterrupt;
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uword stack_limit;
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uword interrupt_bits;
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// Initially no interrupts are scheduled or deferred.
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterrupts(thread));
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{
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// Defer message interrupts.
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NoOOBMessageScope no_msg_scope(thread);
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterrupts(thread));
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// Schedule a message, it is deferred.
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thread->ScheduleInterrupts(Thread::kMessageInterrupt);
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterrupts(thread));
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// Schedule a vm interrupt, it is not deferred.
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thread->ScheduleInterrupts(Thread::kVMInterrupt);
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stack_limit = IsolateTestHelper::GetStackLimit(thread);
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EXPECT_NE(stack_limit, IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT((stack_limit & Thread::kVMInterrupt) != 0);
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterrupts(thread));
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// Clear the vm interrupt. Message is still deferred.
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interrupt_bits = thread->GetAndClearInterrupts();
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EXPECT_EQ(kVMInterrupt, interrupt_bits);
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterrupts(thread));
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}
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// Restore message interrupts. Message is now pending.
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stack_limit = IsolateTestHelper::GetStackLimit(thread);
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EXPECT_NE(stack_limit, IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT((stack_limit & Thread::kMessageInterrupt) != 0);
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterrupts(thread));
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{
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// Defer message interrupts, again. The pending interrupt is deferred.
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NoOOBMessageScope no_msg_scope(thread);
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kMessageInterrupt,
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IsolateTestHelper::GetDeferredInterrupts(thread));
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}
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// Restore, then clear interrupts. The world is as it was.
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interrupt_bits = thread->GetAndClearInterrupts();
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EXPECT_EQ(kMessageInterrupt, interrupt_bits);
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EXPECT_EQ(IsolateTestHelper::GetStackLimit(thread),
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IsolateTestHelper::GetSavedStackLimit(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterruptsMask(thread));
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EXPECT_EQ(kZero, IsolateTestHelper::GetDeferredInterrupts(thread));
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}
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} // namespace dart
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