// Copyright 2015 The Bazel Authors. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package com.google.devtools.build.lib.actions; import static com.google.common.truth.Truth.assertThat; import static org.junit.Assert.assertEquals; import static org.junit.Assert.assertFalse; import static org.junit.Assert.assertTrue; import static org.junit.Assert.fail; import com.google.common.collect.ImmutableSet; import com.google.common.eventbus.EventBus; import com.google.devtools.build.lib.actions.ResourceManager.ResourceHandle; import com.google.devtools.build.lib.testutil.TestThread; import com.google.devtools.build.lib.testutil.TestUtils; import java.util.concurrent.CyclicBarrier; import java.util.concurrent.TimeUnit; import java.util.concurrent.atomic.AtomicInteger; import javax.annotation.Nullable; import org.junit.Before; import org.junit.Test; import org.junit.runner.RunWith; import org.junit.runners.JUnit4; /** * * Tests for @{link ResourceManager}. */ @RunWith(JUnit4.class) public class ResourceManagerTest { private final ActionExecutionMetadata resourceOwner = new ResourceOwnerStub(); private final ResourceManager rm = ResourceManager.instanceForTestingOnly(); private AtomicInteger counter; CyclicBarrier sync; CyclicBarrier sync2; @Before public final void configureResourceManager() throws Exception { rm.setRamUtilizationPercentage(100); rm.setAvailableResources( ResourceSet.create(/*memoryMb=*/1000.0, /*cpuUsage=*/1.0, /*ioUsage=*/1.0, /*testCount=*/2)); rm.setEventBus(new EventBus()); counter = new AtomicInteger(0); sync = new CyclicBarrier(2); sync2 = new CyclicBarrier(2); rm.resetResourceUsage(); } private void acquire(double ram, double cpu, double io, int tests) throws InterruptedException { rm.acquireResources(resourceOwner, ResourceSet.create(ram, cpu, io, tests)); } private ResourceHandle acquireNonblocking(double ram, double cpu, double io, int tests) { return rm.tryAcquire(resourceOwner, ResourceSet.create(ram, cpu, io, tests)); } private void release(double ram, double cpu, double io, int tests) { rm.releaseResources(resourceOwner, ResourceSet.create(ram, cpu, io, tests)); } private void validate(int count) { assertEquals(count, counter.incrementAndGet()); } @Test public void testOverBudgetRequests() throws Exception { assertFalse(rm.inUse()); // When nothing is consuming RAM, // Then Resource Manager will successfully acquire an over-budget request for RAM: double bigRam = 10000.0; acquire(bigRam, 0, 0, 0); // When RAM is consumed, // Then Resource Manager will be "in use": assertTrue(rm.inUse()); release(bigRam, 0, 0, 0); // When that RAM is released, // Then Resource Manager will not be "in use": assertFalse(rm.inUse()); // Ditto, for CPU: double bigCpu = 10.0; acquire(0, bigCpu, 0, 0); assertTrue(rm.inUse()); release(0, bigCpu, 0, 0); assertFalse(rm.inUse()); // Ditto, for IO: double bigIo = 10.0; acquire(0, 0, bigIo, 0); assertTrue(rm.inUse()); release(0, 0, bigIo, 0); assertFalse(rm.inUse()); // Ditto, for tests: int bigTests = 10; acquire(0, 0, 0, bigTests); assertTrue(rm.inUse()); release(0, 0, 0, bigTests); assertFalse(rm.inUse()); } @Test public void testThatCpuCanBeOverallocated() throws Exception { assertFalse(rm.inUse()); // Given CPU is partially acquired: acquire(0, 0.5, 0, 0); // When a request for CPU is made that would slightly overallocate CPU, // Then the request succeeds: TestThread thread1 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(0, 0.6, 0, 0)).isNotNull(); } }; thread1.start(); thread1.joinAndAssertState(10000); } @Test public void testThatCpuAllocationIsNoncommutative() throws Exception { assertFalse(rm.inUse()); // Given that CPU has a small initial allocation: acquire(0, 0.099, 0, 0); // When a request for a large CPU allocation is made, // Then the request succeeds: TestThread thread1 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(0, 0.99, 0, 0)).isNotNull(); // Cleanup release(0, 0.99, 0, 0); } }; thread1.start(); thread1.joinAndAssertState(10000); // Cleanup release(0, 0.099, 0, 0); assertFalse(rm.inUse()); // Given that CPU has a large initial allocation: acquire(0, 0.99, 0, 0); // When a request for a small CPU allocation is made, // Then the request fails: TestThread thread2 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(0, 0.099, 0, 0)).isNull(); } }; thread2.start(); thread2.joinAndAssertState(10000); // Note that this behavior is surprising and probably not intended. } @Test public void testThatRamCannotBeOverallocated() throws Exception { assertFalse(rm.inUse()); // Given RAM is partially acquired: acquire(500, 0, 0, 0); // When a request for RAM is made that would slightly overallocate RAM, // Then the request fails: TestThread thread1 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(600, 0, 0, 0)).isNull(); } }; thread1.start(); thread1.joinAndAssertState(10000); } @Test public void testThatIOCannotBeOverallocated() throws Exception { assertFalse(rm.inUse()); // Given IO is partially acquired: acquire(0, 0, 0.5, 0); // When a request for IO is made that would slightly overallocate IO, // Then the request fails: TestThread thread1 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(0, 0, 0.6, 0)).isNull(); } }; thread1.start(); thread1.joinAndAssertState(10000); } @Test public void testThatTestsCannotBeOverallocated() throws Exception { assertFalse(rm.inUse()); // Given test count is partially acquired: acquire(0, 0, 0, 1); // When a request for tests is made that would slightly overallocate tests, // Then the request fails: TestThread thread1 = new TestThread() { @Override public void runTest() throws Exception { assertThat(acquireNonblocking(0, 0, 0, 2)).isNull(); } }; thread1.start(); thread1.joinAndAssertState(10000); } @Test public void testHasResources() throws Exception { assertFalse(rm.inUse()); assertFalse(rm.threadHasResources()); acquire(1.0, 0.1, 0.1, 1); assertTrue(rm.threadHasResources()); // We have resources in this thread - make sure other threads // are not affected. TestThread thread1 = new TestThread () { @Override public void runTest() throws Exception { assertFalse(rm.threadHasResources()); acquire(1.0, 0, 0, 0); assertTrue(rm.threadHasResources()); release(1.0, 0, 0, 0); assertFalse(rm.threadHasResources()); acquire(0, 0.1, 0, 0); assertTrue(rm.threadHasResources()); release(0, 0.1, 0, 0); assertFalse(rm.threadHasResources()); acquire(0, 0, 0.1, 0); assertTrue(rm.threadHasResources()); release(0, 0, 0.1, 0); assertFalse(rm.threadHasResources()); acquire(0, 0, 0, 1); assertTrue(rm.threadHasResources()); release(0, 0, 0, 1); assertFalse(rm.threadHasResources()); } }; thread1.start(); thread1.joinAndAssertState(10000); release(1.0, 0.1, 0.1, 1); assertFalse(rm.threadHasResources()); assertFalse(rm.inUse()); } @Test public void testConcurrentLargeRequests() throws Exception { assertFalse(rm.inUse()); TestThread thread1 = new TestThread () { @Override public void runTest() throws Exception { acquire(2000, 2, 0, 0); sync.await(); validate(1); sync.await(); // Wait till other thread will be locked. while (rm.getWaitCount() == 0) { Thread.yield(); } release(2000, 2, 0, 0); assertEquals(0, rm.getWaitCount()); acquire(2000, 2, 0, 0); // Will be blocked by the thread2. validate(3); release(2000, 2, 0, 0); } }; TestThread thread2 = new TestThread () { @Override public void runTest() throws Exception { sync2.await(); assertFalse(rm.isAvailable(2000, 2, 0, 0)); acquire(2000, 2, 0, 0); // Will be blocked by the thread1. validate(2); sync2.await(); // Wait till other thread will be locked. while (rm.getWaitCount() == 0) { Thread.yield(); } release(2000, 2, 0, 0); } }; thread1.start(); thread2.start(); sync.await(1, TimeUnit.SECONDS); assertTrue(rm.inUse()); assertEquals(0, rm.getWaitCount()); sync2.await(1, TimeUnit.SECONDS); sync.await(1, TimeUnit.SECONDS); sync2.await(1, TimeUnit.SECONDS); thread1.joinAndAssertState(1000); thread2.joinAndAssertState(1000); assertFalse(rm.inUse()); } @Test public void testInterruptedAcquisitionClearsResources() throws Exception { assertFalse(rm.inUse()); // Acquire a small amount of resources so that future requests can block (the initial request // always succeeds even if it's for too much). TestThread smallThread = new TestThread() { @Override public void runTest() throws InterruptedException { acquire(1, 0, 0, 0); } }; smallThread.start(); smallThread.joinAndAssertState(TestUtils.WAIT_TIMEOUT_MILLISECONDS); TestThread thread1 = new TestThread() { @Override public void runTest() { Thread.currentThread().interrupt(); try { acquire(1999, 0, 0, 0); fail("Didn't throw interrupted exception"); } catch (InterruptedException e) { // Expected. } } }; thread1.start(); thread1.joinAndAssertState(TestUtils.WAIT_TIMEOUT_MILLISECONDS); // This should process the queue. If the request from above is still present, it will take all // the available memory. But it shouldn't. rm.setAvailableResources( ResourceSet.create( /*memoryMb=*/ 2000.0, /*cpuUsage=*/ 1.0, /*ioUsage=*/ 1.0, /*testCount=*/ 2)); TestThread thread2 = new TestThread() { @Override public void runTest() throws InterruptedException { acquire(1999, 0, 0, 0); release(1999, 0, 0, 0); } }; thread2.start(); thread2.joinAndAssertState(TestUtils.WAIT_TIMEOUT_MILLISECONDS); } @Test public void testOutOfOrderAllocation() throws Exception { final CyclicBarrier sync3 = new CyclicBarrier(2); final CyclicBarrier sync4 = new CyclicBarrier(2); assertFalse(rm.inUse()); TestThread thread1 = new TestThread () { @Override public void runTest() throws Exception { sync.await(); acquire(900, 0.5, 0, 0); // Will be blocked by the main thread. validate(5); release(900, 0.5, 0, 0); sync.await(); } }; TestThread thread2 = new TestThread() { @Override public void runTest() throws Exception { // Wait till other thread will be locked while (rm.getWaitCount() == 0) { Thread.yield(); } acquire(100, 0.1, 0, 0); validate(2); release(100, 0.1, 0, 0); sync2.await(); acquire(200, 0.5, 0, 0); validate(4); sync2.await(); release(200, 0.5, 0, 0); } }; TestThread thread3 = new TestThread() { @Override public void runTest() throws Exception { acquire(100, 0.4, 0, 0); sync3.await(); sync3.await(); release(100, 0.4, 0, 0); } }; TestThread thread4 = new TestThread() { @Override public void runTest() throws Exception { acquire(750, 0.3, 0, 0); sync4.await(); sync4.await(); release(750, 0.3, 0, 0); } }; // Lock 900 MB, 0.9 CPU in total (spread over three threads so that we can individually release // parts of it). acquire(50, 0.2, 0, 0); thread3.start(); thread4.start(); sync3.await(1, TimeUnit.SECONDS); sync4.await(1, TimeUnit.SECONDS); validate(1); // Start thread1, which will try to acquire 900 MB, 0.5 CPU, but can't, so it has to wait. thread1.start(); sync.await(1, TimeUnit.SECONDS); // Start thread2, which will successfully acquire and release 100 MB, 0.1 CPU. thread2.start(); // Signal thread2 to acquire 200 MB and 0.5 CPU, which will block. sync2.await(1, TimeUnit.SECONDS); // Waiting till both threads are locked. while (rm.getWaitCount() < 2) { Thread.yield(); } validate(3); // Thread1 is now first in the queue and Thread2 is second. // Release 100 MB, 0.4 CPU. This allows Thread2 to continue out of order. sync3.await(1, TimeUnit.SECONDS); sync2.await(1, TimeUnit.SECONDS); // Release 750 MB, 0.3 CPU. At this point thread1 will finally acquire resources. sync4.await(1, TimeUnit.SECONDS); sync.await(1, TimeUnit.SECONDS); // Release all remaining resources. release(50, 0.2, 0, 0); thread1.join(); thread2.join(); thread3.join(); thread4.join(); assertFalse(rm.inUse()); } private static class ResourceOwnerStub implements ActionExecutionMetadata { @Override @Nullable public String getProgressMessage() { throw new IllegalStateException(); } @Override public ActionOwner getOwner() { throw new IllegalStateException(); } @Override public String prettyPrint() { throw new IllegalStateException(); } @Override public String getMnemonic() { throw new IllegalStateException(); } @Override public boolean inputsKnown() { throw new IllegalStateException(); } @Override public boolean discoversInputs() { throw new IllegalStateException(); } @Override public Iterable getTools() { throw new IllegalStateException(); } @Override public Iterable getInputs() { throw new IllegalStateException(); } @Override public Iterable getClientEnvironmentVariables() { throw new IllegalStateException(); } @Override public RunfilesSupplier getRunfilesSupplier() { throw new IllegalStateException(); } @Override public ImmutableSet getOutputs() { throw new IllegalStateException(); } @Override public Artifact getPrimaryInput() { throw new IllegalStateException(); } @Override public Artifact getPrimaryOutput() { throw new IllegalStateException(); } @Override public Iterable getMandatoryInputs() { throw new IllegalStateException(); } @Override public String getKey() { throw new IllegalStateException(); } @Override @Nullable public String describeKey() { throw new IllegalStateException(); } @Override public ImmutableSet getMandatoryOutputs() { return ImmutableSet.of(); } @Override public boolean shouldReportPathPrefixConflict(ActionAnalysisMetadata action) { throw new IllegalStateException(); } @Override public MiddlemanType getActionType() { throw new IllegalStateException(); } } }