e5951d46fc
Motivation: HTTP is a plaintext protocol which means that someone may be able to eavesdrop the data. To prevent this, HTTPS should be used whenever possible. However, maintaining using https:// in all URLs may be difficult. The nohttp tool can help here. The tool scans all the files in a repository and reports where http:// is used. Modifications: - Added nohttp (via checkstyle) into the build process. - Suppressed findings for the websites that don't support HTTPS or that are not reachable Result: - Prevent using HTTP in the future. - Encourage users to use HTTPS when they follow the links they found in the code.
145 lines
5.3 KiB
Java
145 lines
5.3 KiB
Java
/*
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* Copyright 2017 The Netty Project
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*
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* The Netty Project licenses this file to you under the Apache License,
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* version 2.0 (the "License"); you may not use this file except in compliance
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* with the License. You may obtain a copy of the License at:
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*
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* https://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
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* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
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* License for the specific language governing permissions and limitations
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* under the License.
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*/
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package io.netty.buffer;
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import io.netty.util.internal.PlatformDependent;
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import org.junit.Test;
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import static org.junit.Assert.assertEquals;
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import static org.junit.Assert.assertTrue;
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import static org.junit.Assert.fail;
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public abstract class AbstractByteBufAllocatorTest<T extends AbstractByteBufAllocator> extends ByteBufAllocatorTest {
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@Override
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protected abstract T newAllocator(boolean preferDirect);
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protected abstract T newUnpooledAllocator();
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@Override
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protected boolean isDirectExpected(boolean preferDirect) {
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return preferDirect && PlatformDependent.hasUnsafe();
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}
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@Override
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protected final int defaultMaxCapacity() {
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return AbstractByteBufAllocator.DEFAULT_MAX_CAPACITY;
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}
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@Override
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protected final int defaultMaxComponents() {
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return AbstractByteBufAllocator.DEFAULT_MAX_COMPONENTS;
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}
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@Test
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public void testCalculateNewCapacity() {
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testCalculateNewCapacity(true);
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testCalculateNewCapacity(false);
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}
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private void testCalculateNewCapacity(boolean preferDirect) {
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T allocator = newAllocator(preferDirect);
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assertEquals(8, allocator.calculateNewCapacity(1, 8));
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assertEquals(7, allocator.calculateNewCapacity(1, 7));
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assertEquals(64, allocator.calculateNewCapacity(1, 129));
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assertEquals(AbstractByteBufAllocator.CALCULATE_THRESHOLD,
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allocator.calculateNewCapacity(AbstractByteBufAllocator.CALCULATE_THRESHOLD,
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AbstractByteBufAllocator.CALCULATE_THRESHOLD + 1));
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assertEquals(AbstractByteBufAllocator.CALCULATE_THRESHOLD * 2,
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allocator.calculateNewCapacity(AbstractByteBufAllocator.CALCULATE_THRESHOLD + 1,
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AbstractByteBufAllocator.CALCULATE_THRESHOLD * 4));
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try {
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allocator.calculateNewCapacity(8, 7);
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fail();
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} catch (IllegalArgumentException e) {
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// expected
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}
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try {
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allocator.calculateNewCapacity(-1, 8);
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fail();
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} catch (IllegalArgumentException e) {
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// expected
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}
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}
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@Test
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public void testUnsafeHeapBufferAndUnsafeDirectBuffer() {
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T allocator = newUnpooledAllocator();
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ByteBuf directBuffer = allocator.directBuffer();
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assertInstanceOf(directBuffer,
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PlatformDependent.hasUnsafe() ? UnpooledUnsafeDirectByteBuf.class : UnpooledDirectByteBuf.class);
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directBuffer.release();
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ByteBuf heapBuffer = allocator.heapBuffer();
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assertInstanceOf(heapBuffer,
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PlatformDependent.hasUnsafe() ? UnpooledUnsafeHeapByteBuf.class : UnpooledHeapByteBuf.class);
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heapBuffer.release();
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}
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protected static void assertInstanceOf(ByteBuf buffer, Class<? extends ByteBuf> clazz) {
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// Unwrap if needed
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assertTrue(clazz.isInstance(buffer instanceof SimpleLeakAwareByteBuf ? buffer.unwrap() : buffer));
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}
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@SuppressWarnings("unchecked")
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@Test
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public void testUsedDirectMemory() {
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T allocator = newAllocator(true);
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ByteBufAllocatorMetric metric = ((ByteBufAllocatorMetricProvider) allocator).metric();
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assertEquals(0, metric.usedDirectMemory());
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ByteBuf buffer = allocator.directBuffer(1024, 4096);
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int capacity = buffer.capacity();
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assertEquals(expectedUsedMemory(allocator, capacity), metric.usedDirectMemory());
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// Double the size of the buffer
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buffer.capacity(capacity << 1);
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capacity = buffer.capacity();
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assertEquals(buffer.toString(), expectedUsedMemory(allocator, capacity), metric.usedDirectMemory());
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buffer.release();
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assertEquals(expectedUsedMemoryAfterRelease(allocator, capacity), metric.usedDirectMemory());
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}
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@SuppressWarnings("unchecked")
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@Test
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public void testUsedHeapMemory() {
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T allocator = newAllocator(true);
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ByteBufAllocatorMetric metric = ((ByteBufAllocatorMetricProvider) allocator).metric();
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assertEquals(0, metric.usedHeapMemory());
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ByteBuf buffer = allocator.heapBuffer(1024, 4096);
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int capacity = buffer.capacity();
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assertEquals(expectedUsedMemory(allocator, capacity), metric.usedHeapMemory());
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// Double the size of the buffer
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buffer.capacity(capacity << 1);
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capacity = buffer.capacity();
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assertEquals(expectedUsedMemory(allocator, capacity), metric.usedHeapMemory());
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buffer.release();
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assertEquals(expectedUsedMemoryAfterRelease(allocator, capacity), metric.usedHeapMemory());
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}
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protected long expectedUsedMemory(T allocator, int capacity) {
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return capacity;
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}
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protected long expectedUsedMemoryAfterRelease(T allocator, int capacity) {
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return 0;
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}
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}
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