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转载:http://www.jdon.com/concurrent/serialization.html
这里比较Java对象序列化 XML JSON Kryo POF等序列化性能比较。
很多人以为JDK的Java序列化肯定是将Java对象转换成二进制序列化最快的方式,JDK7出来以后,我们发现实际上每次新的JDK比旧版本快。
我们通常以为将Java对象序列化成二进制比序列化成XML或Json更快,其实是错误的,如果你关心性能,建议避免Java序列化。
Java序列化有很多的要求,最主要的一个是包含能够序列化任何东西(或至少任何实现Serializable接口)。这样才能进入其他JVM之中,这很重要,所以有时性能不是主要的要求,标准的格式才最重要。
我们经常看到CPU花费很多时间内进行Java序列化,下面我们研究一下,假设一定Order,虽然只有几个字节,但是序列化以后不是几十个字节,而是600多个字节:
Ordr代码:
public class Order implements Serializable { private long id; private String description; private BigDecimal totalCost = BigDecimal.valueOf(0); private List orderLines = new ArrayList(); private Customer customer; ... }
序列化输出:
----sr--model.Order----h#-----J--idL--customert--Lmodel/Customer;L--descriptiont--Ljava/lang/String;L--orderLinest--Ljava/util/List;L--totalCostt--Ljava/math/BigDecimal;xp--------ppsr--java.util.ArrayListx-----a----I--sizexp----w-----sr--model.OrderLine--&-1-S----I--lineNumberL--costq-~--L--descriptionq-~--L--ordert--Lmodel/Order;xp----sr--java.math.BigDecimalT--W--(O---I--scaleL--intValt--Ljava/math/BigInteger;xr--java.lang.Number-----------xp----sr--java.math.BigInteger-----;-----I--bitCountI--bitLengthI--firstNonzeroByteNumI--lowestSetBitI--signum[--magnitudet--[Bxq-~----------------------ur--[B------T----xp----xxpq-~--xq-~--
正如你可能已经注意到,Java序列化写入不仅是完整的类名,也包含整个类的定义,包含所有被引用的类。类定义可以是相当大的,也许构成了性能和效率的问题,当然这是编写一个单一的对象。如果您正在编写了大量相同的类的对象,这时类定义的开销通常不是一个大问题。另一件事情是,如果你的对象有一类的引用(如元数据对象),那么Java序列化将写入整个类的定义,不只是类的名称,因此,使用Java序列化写出元数据(meta-data)是非常昂贵的。
通过实现Externalizable接口,这是可能优化Java序列化的。实现此接口,避免写出整个类定义,只是类名被写入。它需要你实施readExternal和writeExternal方法方法的,所以需要做一些工作,但相比仅仅是实现Serializable更快,更高效。
Externalizable对小数目对象有效的多。但是对大量对象,或者重复对象,则效率低。
public class Order implements Externalizable { private long id; private String description; private BigDecimal totalCost = BigDecimal.valueOf(0); private List orderLines = new ArrayList(); private Customer customer; public Order() { } public void readExternal(ObjectInput stream) throws IOException, ClassNotFoundException { this.id = stream.readLong(); this.description = (String)stream.readObject(); this.totalCost = (BigDecimal)stream.readObject(); this.customer = (Customer)stream.readObject(); this.orderLines = (List)stream.readObject(); } public void writeExternal(ObjectOutput stream) throws IOException { stream.writeLong(this.id); stream.writeObject(this.description); stream.writeObject(this.totalCost); stream.writeObject(this.customer); stream.writeObject(this.orderLines); } }
序列化输出:
----sr--model.Order---*3--^---xpw---------psr--java.math.BigDecimalT--W--(O---I--scaleL--intValt--Ljava/math/BigInteger;xr--java.lang.Number-----------xp----sr--java.math.BigInteger-----;-----I--bitCountI--bitLengthI--firstNonzeroByteNumI--lowestSetBitI--signum[--magnitudet--[Bxq-~----------------------ur--[B------T----xp----xxpsr--java.util.ArrayListx-----a----I--sizexp----w-----sr--model.OrderLine-!!|---S---xpw-----pq-~--q-~--xxx
序列化成XML或JSON可以允许其他语言访问,可以实现REST服务等。缺点是文本格式的效率比优化的二进制格式低一些,使用JAXB,你需要使用JAXB注释类,或提供一个XML配置文件。使用@XmlIDREF处理循环。
@XmlRootElement public class Order { @XmlID @XmlAttribute private long id; @XmlAttribute private String description; @XmlAttribute private BigDecimal totalCost = BigDecimal.valueOf(0); private List orderLines = new ArrayList(); private Customer customer; } public class OrderLine { @XmlIDREF private Order order; @XmlAttribute private int lineNumber; @XmlAttribute private String description; @XmlAttribute private BigDecimal cost = BigDecimal.valueOf(0); }
XML输出:
<order id="0" totalCost="0"> <orderLines lineNumber="1" cost="0"> <order>0</order ></orderLines ></order>
JSOn输出:
{"order":{"id":0,"totalCost":0,"orderLines":[{"lineNumber":1,"cost":0,"order":0}]}}
Kryo 是一种快速,高效的序列化的Java框架。 KRYO是新的BSD许可下一个开源项目提供。这是一个很小的项目,只有3名成员,它首先在2009年出品。
工作原理类似于Java序列化KRYO,尊重瞬态字段,但不要求一类是可序列化的。KRYO有一定的局限性,比如需要有一个默认的构造函数的类,在序列化将java.sql.Time java.sql.Date java.sql.Timestamp类会遇到一些问题。
order序列化结果:
------java-util-ArrayLis-----model-OrderLin----java-math-BigDecima---------model-Orde-----
Oracle Coherence 产品提供其自己优化的二进制格式,称为POF (可移植对象格式) 。 Oracle Coherence的是一个内存中的数据网格解决方案(分布式缓存) 。是一个商业产品,并需要许可证。
POF提供了一个序列化框架,并可以独立使用。 POF要求类实现一个PortableObject接口和读/写方法。您还可以实现一个单独的序列化类,或使用最新版本的序列化的注解。 POF要求每个类都被提前分配一个固定ID,所以你需要通过某种方式确定这个ID 。 POF格式是二进制格式,非常紧凑,高效,快速的,但确实需要你付出一些工作。
POF的总字节数为一个单一的订单/订单行对象为32个字节, 1593字节100 OrderLines的。我不会放弃的结果, POF是一个商业许可产品的一部分,但是是非常快的。
public class Order implements PortableObject { private long id; private String description; private BigDecimal totalCost = BigDecimal.valueOf(0); private List orderLines = new ArrayList(); private Customer customer; public Order() { } public void readExternal(PofReader in) throws IOException { this.id = in.readLong(0); this.description = in.readString(1); this.totalCost = in.readBigDecimal(2); this.customer = (Customer)in.readObject(3); this.orderLines = (List)in.readCollection(4, new ArrayList()); } public void writeExternal(PofWriter out) throws IOException { out.writeLong(0, this.id); out.writeString(1, this.description); out.writeBigDecimal(2, this.totalCost); out.writeObject(3, this.customer); out.writeCollection(4, this.orderLines); } }
序列化结果:
-----B--G---d-U------A--G-------
一个订单包含一个Oderline
Serializer | Size (bytes) | Serialize (operations/second) | Deserialize (operations/second) | % Difference (from Java serialize) | % Difference (deserialize) |
---|---|---|---|---|---|
Java Serializable | 636 | 128,634 | 19,180 | 0% | 0% |
Java Externalizable | 435 | 160,549 | 26,678 | 24% | 39% |
EclipseLink MOXy XML | 101 | 348,056 | 47,334 | 170% | 146% |
Kryo | 90 | 359,368 | 346,984 | 179% | 1709% |
一个订单100个oderlines:
Serializer | Size (bytes) | Serialize (operations/second) | Deserialize (operations/second) | % Difference (from Java serialize) | % Difference (deserialize) |
---|---|---|---|---|---|
Java Serializable | 2,715 | 16,470 | 10,215 | 0% | 0% |
Java Externalizable | 2,811 | 16,206 | 11,483 | -1% | 12% |
EclipseLink MOXy XML | 6,628 | 7,304 | 2,731 | -55% | -73% |
Kryo | 1216 | 22,862 | 31,499 | 38% | 208% |
要获得象C那样的序列化性能,直接自己编写。
三者性能测试代码:
package com.ifenglian.test.safe; import sun.misc.Unsafe; import java.io.ByteArrayInputStream; import java.io.ByteArrayOutputStream; import java.io.ObjectInputStream; import java.io.ObjectOutputStream; import java.io.Serializable; import java.lang.reflect.Field; import java.nio.ByteBuffer; import java.util.Arrays; public final class TestSerialisationPerf { public static final int REPETITIONS = 1 * 1000 * 1000; private static ObjectToBeSerialised ITEM = new ObjectToBeSerialised(1010L, true, 777, 99, new double[] { 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0 }, new long[] { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 }); public static void main(final String[] arg) throws Exception { for (final PerformanceTestCase testCase : testCases) { for (int i = 0; i < 5; i++) { testCase.performTest(); System.out.format("%d %s\twrite=%,dns read=%,dns total=%,dns\n", i, testCase.getName(), testCase.getWriteTimeNanos(), testCase.getReadTimeNanos(), testCase.getWriteTimeNanos() + testCase.getReadTimeNanos()); if (!ITEM.equals(testCase.getTestOutput())) { throw new IllegalStateException("Objects do not match"); } System.gc(); Thread.sleep(3000); } } } private static final PerformanceTestCase[] testCases = { new PerformanceTestCase("Serialisation", REPETITIONS, ITEM) { ByteArrayOutputStream baos = new ByteArrayOutputStream(); public void testWrite(ObjectToBeSerialised item) throws Exception { for (int i = 0; i < REPETITIONS; i++) { baos.reset(); ObjectOutputStream oos = new ObjectOutputStream(baos); oos.writeObject(item); oos.close(); } } public ObjectToBeSerialised testRead() throws Exception { ObjectToBeSerialised object = null; for (int i = 0; i < REPETITIONS; i++) { ByteArrayInputStream bais = new ByteArrayInputStream(baos.toByteArray()); ObjectInputStream ois = new ObjectInputStream(bais); object = (ObjectToBeSerialised) ois.readObject(); } return object; } }, new PerformanceTestCase("ByteBuffer", REPETITIONS, ITEM) { ByteBuffer byteBuffer = ByteBuffer.allocate(1024); public void testWrite(ObjectToBeSerialised item) throws Exception { for (int i = 0; i < REPETITIONS; i++) { byteBuffer.clear(); item.write(byteBuffer); } } public ObjectToBeSerialised testRead() throws Exception { ObjectToBeSerialised object = null; for (int i = 0; i < REPETITIONS; i++) { byteBuffer.flip(); object = ObjectToBeSerialised.read(byteBuffer); } return object; } }, new PerformanceTestCase("UnsafeMemory", REPETITIONS, ITEM) { UnsafeMemory buffer = new UnsafeMemory(new byte[1024]); public void testWrite(ObjectToBeSerialised item) throws Exception { for (int i = 0; i < REPETITIONS; i++) { buffer.reset(); item.write(buffer); } } public ObjectToBeSerialised testRead() throws Exception { ObjectToBeSerialised object = null; for (int i = 0; i < REPETITIONS; i++) { buffer.reset(); object = ObjectToBeSerialised.read(buffer); } return object; } }, }; } abstract class PerformanceTestCase { private final String name; private final int repetitions; private final ObjectToBeSerialised testInput; private ObjectToBeSerialised testOutput; private long writeTimeNanos; private long readTimeNanos; public PerformanceTestCase(final String name, final int repetitions, final ObjectToBeSerialised testInput) { this.name = name; this.repetitions = repetitions; this.testInput = testInput; } public String getName() { return name; } public ObjectToBeSerialised getTestOutput() { return testOutput; } public long getWriteTimeNanos() { return writeTimeNanos; } public long getReadTimeNanos() { return readTimeNanos; } public void performTest() throws Exception { final long startWriteNanos = System.nanoTime(); testWrite(testInput); writeTimeNanos = (System.nanoTime() - startWriteNanos) / repetitions; final long startReadNanos = System.nanoTime(); testOutput = testRead(); readTimeNanos = (System.nanoTime() - startReadNanos) / repetitions; } public abstract void testWrite(ObjectToBeSerialised item) throws Exception; public abstract ObjectToBeSerialised testRead() throws Exception; } class ObjectToBeSerialised implements Serializable { private static final long serialVersionUID = 10275539472837495L; private final long sourceId; private final boolean special; private final int orderCode; private final int priority; private final double[] prices; private final long[] quantities; public ObjectToBeSerialised(final long sourceId, final boolean special, final int orderCode, final int priority, final double[] prices, final long[] quantities) { this.sourceId = sourceId; this.special = special; this.orderCode = orderCode; this.priority = priority; this.prices = prices; this.quantities = quantities; } public void write(final ByteBuffer byteBuffer) { byteBuffer.putLong(sourceId); byteBuffer.put((byte) (special ? 1 : 0)); byteBuffer.putInt(orderCode); byteBuffer.putInt(priority); byteBuffer.putInt(prices.length); for (final double price : prices) { byteBuffer.putDouble(price); } byteBuffer.putInt(quantities.length); for (final long quantity : quantities) { byteBuffer.putLong(quantity); } } public static ObjectToBeSerialised read(final ByteBuffer byteBuffer) { final long sourceId = byteBuffer.getLong(); final boolean special = 0 != byteBuffer.get(); final int orderCode = byteBuffer.getInt(); final int priority = byteBuffer.getInt(); final int pricesSize = byteBuffer.getInt(); final double[] prices = new double[pricesSize]; for (int i = 0; i < pricesSize; i++) { prices[i] = byteBuffer.getDouble(); } final int quantitiesSize = byteBuffer.getInt(); final long[] quantities = new long[quantitiesSize]; for (int i = 0; i < quantitiesSize; i++) { quantities[i] = byteBuffer.getLong(); } return new ObjectToBeSerialised(sourceId, special, orderCode, priority, prices, quantities); } public void write(final UnsafeMemory buffer) { buffer.putLong(sourceId); buffer.putBoolean(special); buffer.putInt(orderCode); buffer.putInt(priority); buffer.putDoubleArray(prices); buffer.putLongArray(quantities); } public static ObjectToBeSerialised read(final UnsafeMemory buffer) { final long sourceId = buffer.getLong(); final boolean special = buffer.getBoolean(); final int orderCode = buffer.getInt(); final int priority = buffer.getInt(); final double[] prices = buffer.getDoubleArray(); final long[] quantities = buffer.getLongArray(); return new ObjectToBeSerialised(sourceId, special, orderCode, priority, prices, quantities); } @Override public boolean equals(final Object o) { if (this == o) { return true; } if (o == null || getClass() != o.getClass()) { return false; } final ObjectToBeSerialised that = (ObjectToBeSerialised) o; if (orderCode != that.orderCode) { return false; } if (priority != that.priority) { return false; } if (sourceId != that.sourceId) { return false; } if (special != that.special) { return false; } if (!Arrays.equals(prices, that.prices)) { return false; } if (!Arrays.equals(quantities, that.quantities)) { return false; } return true; } } class UnsafeMemory { private static final Unsafe unsafe; static { try { Field field = Unsafe.class.getDeclaredField("theUnsafe"); field.setAccessible(true); unsafe = (Unsafe) field.get(null); } catch (Exception e) { throw new RuntimeException(e); } } private static final long byteArrayOffset = unsafe.arrayBaseOffset(byte[].class); private static final long longArrayOffset = unsafe.arrayBaseOffset(long[].class); private static final long doubleArrayOffset = unsafe.arrayBaseOffset(double[].class); private static final int SIZE_OF_BOOLEAN = 1; private static final int SIZE_OF_INT = 4; private static final int SIZE_OF_LONG = 8; private int pos = 0; private final byte[] buffer; public UnsafeMemory(final byte[] buffer) { if (null == buffer) { throw new NullPointerException("buffer cannot be null"); } this.buffer = buffer; } public void reset() { this.pos = 0; } public void putBoolean(final boolean value) { unsafe.putBoolean(buffer, byteArrayOffset + pos, value); pos += SIZE_OF_BOOLEAN; } public boolean getBoolean() { boolean value = unsafe.getBoolean(buffer, byteArrayOffset + pos); pos += SIZE_OF_BOOLEAN; return value; } public void putInt(final int value) { unsafe.putInt(buffer, byteArrayOffset + pos, value); pos += SIZE_OF_INT; } public int getInt() { int value = unsafe.getInt(buffer, byteArrayOffset + pos); pos += SIZE_OF_INT; return value; } public void putLong(final long value) { unsafe.putLong(buffer, byteArrayOffset + pos, value); pos += SIZE_OF_LONG; } public long getLong() { long value = unsafe.getLong(buffer, byteArrayOffset + pos); pos += SIZE_OF_LONG; return value; } public void putLongArray(final long[] values) { putInt(values.length); long bytesToCopy = values.length << 3; unsafe.copyMemory(values, longArrayOffset, buffer, byteArrayOffset + pos, bytesToCopy); pos += bytesToCopy; } public long[] getLongArray() { int arraySize = getInt(); long[] values = new long[arraySize]; long bytesToCopy = values.length << 3; unsafe.copyMemory(buffer, byteArrayOffset + pos, values, longArrayOffset, bytesToCopy); pos += bytesToCopy; return values; } public void putDoubleArray(final double[] values) { putInt(values.length); long bytesToCopy = values.length << 3; unsafe.copyMemory(values, doubleArrayOffset, buffer, byteArrayOffset + pos, bytesToCopy); pos += bytesToCopy; } public double[] getDoubleArray() { int arraySize = getInt(); double[] values = new double[arraySize]; long bytesToCopy = values.length << 3; unsafe.copyMemory(buffer, byteArrayOffset + pos, values, doubleArrayOffset, bytesToCopy); pos += bytesToCopy; return values; } }
测试结果:
2.8GHz Nehalem - Java 1.7.0_04
==============================
0 Serialisation write=2,517ns read=11,570ns total=14,087ns
1 Serialisation write=2,198ns read=11,122ns total=13,320ns
2 Serialisation write=2,190ns read=11,011ns total=13,201ns
3 Serialisation write=2,221ns read=10,972ns total=13,193ns
4 Serialisation write=2,187ns read=10,817ns total=13,004ns
0 ByteBuffer write=264ns read=273ns total=537ns
1 ByteBuffer write=248ns read=243ns total=491ns
2 ByteBuffer write=262ns read=243ns total=505ns
3 ByteBuffer write=300ns read=240ns total=540ns
4 ByteBuffer write=247ns read=243ns total=490ns
0 UnsafeMemory write=99ns read=84ns total=183ns
1 UnsafeMemory write=53ns read=82ns total=135ns
2 UnsafeMemory write=63ns read=66ns total=129ns
3 UnsafeMemory write=46ns read=63ns total=109ns
4 UnsafeMemory write=48ns read=58ns total=106ns
2.4GHz Sandy Bridge - Java 1.7.0_04
===================================
0 Serialisation write=1,940ns read=9,006ns total=10,946ns
1 Serialisation write=1,674ns read=8,567ns total=10,241ns
2 Serialisation write=1,666ns read=8,680ns total=10,346ns
3 Serialisation write=1,666ns read=8,623ns total=10,289ns
4 Serialisation write=1,715ns read=8,586ns total=10,301ns
0 ByteBuffer write=199ns read=198ns total=397ns
1 ByteBuffer write=176ns read=178ns total=354ns
2 ByteBuffer write=174ns read=174ns total=348ns
3 ByteBuffer write=172ns read=183ns total=355ns
4 ByteBuffer write=174ns read=180ns total=354ns
0 UnsafeMemory write=38ns read=75ns total=113ns
1 UnsafeMemory write=26ns read=52ns total=78ns
2 UnsafeMemory write=26ns read=51ns total=77ns
3 UnsafeMemory write=25ns read=51ns total=76ns
4 UnsafeMemory write=27ns read=50ns total=77ns
很显然允许自己内存操作的 Unsafe性能是最快的。
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原文地址:http://www.cnblogs.com/shixm/p/5933648.html