问题描述
最近在使用一个内部的RPC框架时,发现如果使用Object类型,实际类型为BigDecimal的时候,作为传输对象的时候,会出现丢失精度的问题;比如在序列化前为金额1.00,反序列化之后为1.0,本身值可能没有影响,但是在有些强依赖金额的地方,会出现问题;
问题分析
查看源码发现RPC框架默认使用的序列化框架为Jackson,那简单,看一下本地是否可以重现问题;
1.准备数据传输bean
public class Bean1 {
private String p1;
private BigDecimal p2;
...省略get/set...
}
public class Bean2 {
private String p1;
private Object p2;
...省略get/set...
}
为了更好的看出问题,分别准备了2个bean;
2.准备测试类
public class JKTest {
public static void main(String[] args) throws IOException {
ObjectMapper mapper = new ObjectMapper();
Bean1 bean1 = new Bean1("haha1", new BigDecimal("1.00"));
Bean2 bean2 = new Bean2("haha2", new BigDecimal("2.00"));
String bs1 = mapper.writeValueAsString(bean1);
String bs2 = mapper.writeValueAsString(bean2);
System.out.println(bs1);
System.out.println(bs2);
Bean1 b1 = mapper.readValue(bs1, Bean1.class);
System.out.println(b1.toString());
Bean2 b22 = mapper.readValue(bs2, Bean2.class);
System.out.println(b22.toString());
}
}
分别对Bean1和Bean2进行序列化和反序列化操作,然后查看结果;
3.显示结果
{"p1":"haha1","p2":1.00}
{"p1":"haha2","p2":2.00}
Bean1 [p1=haha1, p2=1.00]
Bean2 [p1=haha2, p2=2.0]
4.结果分析
结果可以发现两个问题:
1.在序列化的时候2个bean都没有问题;
2.重现了问题,Bean2在反序列化时,p2出现了精度丢失的问题;
5.源码分析
通过一步一步查看Jackson源码,最终定位到UntypedObjectDeserializer的Vanilla内部类中,反序列方法如下:
public Object deserialize(JsonParser p, DeserializationContext ctxt) throws IOException
{
switch (p.getCurrentTokenId()) {
case JsonTokenId.ID_START_OBJECT:
{
JsonToken t = p.nextToken();
if (t == JsonToken.END_OBJECT) {
return new LinkedHashMap<String,Object>(2);
}
}
case JsonTokenId.ID_FIELD_NAME:
return mapObject(p, ctxt);
case JsonTokenId.ID_START_ARRAY:
{
JsonToken t = p.nextToken();
if (t == JsonToken.END_ARRAY) { // and empty one too
if (ctxt.isEnabled(DeserializationFeature.USE_JAVA_ARRAY_FOR_JSON_ARRAY)) {
return NO_OBJECTS;
}
return new ArrayList<Object>(2);
}
}
if (ctxt.isEnabled(DeserializationFeature.USE_JAVA_ARRAY_FOR_JSON_ARRAY)) {
return mapArrayToArray(p, ctxt);
}
return mapArray(p, ctxt);
case JsonTokenId.ID_EMBEDDED_OBJECT:
return p.getEmbeddedObject();
case JsonTokenId.ID_STRING:
return p.getText();
case JsonTokenId.ID_NUMBER_INT:
if (ctxt.hasSomeOfFeatures(F_MASK_INT_COERCIONS)) {
return _coerceIntegral(p, ctxt);
}
return p.getNumberValue(); // should be optimal, whatever it is
case JsonTokenId.ID_NUMBER_FLOAT:
if (ctxt.isEnabled(DeserializationFeature.USE_BIG_DECIMAL_FOR_FLOATS)) {
return p.getDecimalValue();
}
return p.getNumberValue();
case JsonTokenId.ID_TRUE:
return Boolean.TRUE;
case JsonTokenId.ID_FALSE:
return Boolean.FALSE;
case JsonTokenId.ID_END_OBJECT:
// 28-Oct-2015, tatu: [databind#989] We may also be given END_OBJECT (similar to FIELD_NAME),
// if caller has advanced to the first token of Object, but for empty Object
return new LinkedHashMap<String,Object>(2);
case JsonTokenId.ID_NULL: // 08-Nov-2016, tatu: yes, occurs
return null;
//case JsonTokenId.ID_END_ARRAY: // invalid
default:
}
return ctxt.handleUnexpectedToken(Object.class, p);
}
在Bean2中的p2是一个Object类型,所以Jackson中给定的反序列化类为UntypedObjectDeserializer,这个比较容易理解;然后根据具体的数据类型,调用不用的读取方法;因为json这种序列化方式,除了数据,本身并没有存放具体的数据类型,所有这里Jackson认定2.00为一个ID_NUMBER_FLOAT类型,在这个case下面有2个选择,默认是直接调用getNumberValue()方法,这种情况会丢失精度,返回结果为2.0;或者开启使用USE_BIG_DECIMAL_FOR_FLOATS特性,问题解决也很简单,使用此特性即可;
6.使用USE_BIG_DECIMAL_FOR_FLOATS特性
ObjectMapper mapper = new ObjectMapper();
mapper.enable(DeserializationFeature.USE_BIG_DECIMAL_FOR_FLOATS);
再次测试,可以发现结果如下:
{"p1":"haha1","p2":1.00}
{"p1":"haha2","p2":2.00}
Bean1 [p1=haha1, p2=1.00]
Bean2 [p1=haha2, p2=2.00]
7.反序列扩展
Jackson本身提供了对序列化和反序列扩展的功能,对应特殊的Bean可以自己定义反序列类,比如针对Bean2,可以实现Bean2Deserializer,然后在ObjectMapper进行注册
ObjectMapper mapper = new ObjectMapper();
SimpleModule desModule = new SimpleModule("testModule");
desModule.addDeserializer(Bean2.class, new Bean2Deserializer(Bean2.class));
mapper.registerModule(desModule);
扩展
Json本身并没有存放数据类型,只有数据本身,那应该类Json的序列化方式应该都存在此问题;
1.FastJson分析
准备测试代码如下:
public class FJTest {
public static void main(String[] args) {
Bean1 bean1 = new Bean1("haha1", new BigDecimal("1.00"));
Bean2 bean2 = new Bean2("haha2", new BigDecimal("2.00"));
String jsonString1 = JSON.toJSONString(bean1);
String jsonString2 = JSON.toJSONString(bean2);
System.out.println(jsonString1);
System.out.println(jsonString2);
Bean1 bean11 = JSON.parseObject(jsonString1, Bean1.class);
Bean2 bean22 = JSON.parseObject(jsonString2, Bean2.class);
System.out.println(bean11.toString());
System.out.println(bean22.toString());
}
}
结果如下:
{"p1":"haha1","p2":1.00}
{"p1":"haha2","p2":2.00}
Bean1 [p1=haha1, p2=1.00]
Bean2 [p1=haha2, p2=2.00]
可以发现FastJson并不存在此问题,查看源码,定位到DefaultJSONParser的parse方法,部分代码如下:
public Object parse(Object fieldName) {
final JSONLexer lexer = this.lexer;
switch (lexer.token()) {
case SET:
lexer.nextToken();
HashSet<Object> set = new HashSet<Object>();
parseArray(set, fieldName);
return set;
case TREE_SET:
lexer.nextToken();
TreeSet<Object> treeSet = new TreeSet<Object>();
parseArray(treeSet, fieldName);
return treeSet;
case LBRACKET:
JSONArray array = new JSONArray();
parseArray(array, fieldName);
if (lexer.isEnabled(Feature.UseObjectArray)) {
return array.toArray();
}
return array;
case LBRACE:
JSONObject object = new JSONObject(lexer.isEnabled(Feature.OrderedField));
return parseObject(object, fieldName);
case LITERAL_INT:
Number intValue = lexer.integerValue();
lexer.nextToken();
return intValue;
case LITERAL_FLOAT:
Object value = lexer.decimalValue(lexer.isEnabled(Feature.UseBigDecimal));
lexer.nextToken();
return value;
case LITERAL_STRING:
String stringLiteral = lexer.stringVal();
lexer.nextToken(JSONToken.COMMA);
if (lexer.isEnabled(Feature.AllowISO8601DateFormat)) {
JSONScanner iso8601Lexer = new JSONScanner(stringLiteral);
try {
if (iso8601Lexer.scanISO8601DateIfMatch()) {
return iso8601Lexer.getCalendar().getTime();
}
} finally {
iso8601Lexer.close();
}
}
return stringLiteral;
case NULL:
lexer.nextToken();
return null;
case UNDEFINED:
lexer.nextToken();
return null;
case TRUE:
lexer.nextToken();
return Boolean.TRUE;
case FALSE:
lexer.nextToken();
return Boolean.FALSE;
...省略...
}
类似jackson的方式,根据不同的类型做不同的数据处理,同样2.00也被认为是float类型,同样需要检测是否开启Feature.UseBigDecimal特性,只不过FastJson默认开启了此功能;
2.Protostuff分析
下面再来看一个非Json类序列化方式,看protostuff是如果处理此种问题的;
准备测试代码如下:
@SuppressWarnings("unchecked")
public class PBTest {
public static void main(String[] args) {
Bean1 bean1 = new Bean1("haha1", new BigDecimal("1.00"));
Bean2 bean2 = new Bean2("haha2", new BigDecimal("2.00"));
LinkedBuffer buffer1 = LinkedBuffer.allocate(LinkedBuffer.DEFAULT_BUFFER_SIZE);
Schema schema1 = RuntimeSchema.createFrom(bean1.getClass());
byte[] bytes1 = ProtostuffIOUtil.toByteArray(bean1, schema1, buffer1);
Bean1 bean11 = new Bean1();
ProtostuffIOUtil.mergeFrom(bytes1, bean11, schema1);
System.out.println(bean11.toString());
LinkedBuffer buffer2 = LinkedBuffer.allocate(LinkedBuffer.DEFAULT_BUFFER_SIZE);
Schema schema2 = RuntimeSchema.createFrom(bean2.getClass());
byte[] bytes2 = ProtostuffIOUtil.toByteArray(bean2, schema2, buffer2);
Bean2 bean22 = new Bean2();
ProtostuffIOUtil.mergeFrom(bytes2, bean22, schema2);
System.out.println(bean22.toString());
}
}
结果如下:
Bean1 [p1=haha1, p2=1.00]
Bean2 [p1=haha2, p2=2.00]
可以发现Protostuff也不存在此问题,原因是因为Protostuff在序列化的时候就将类型等信息存放在二进制中,不同的类型给定了不同的标识,RuntimeFieldFactory列出了所有标识:
public abstract class RuntimeFieldFactory<V> implements Delegate<V>
{
static final int ID_BOOL = 1, ID_BYTE = 2, ID_CHAR = 3, ID_SHORT = 4,
ID_INT32 = 5, ID_INT64 = 6, ID_FLOAT = 7,
ID_DOUBLE = 8,
ID_STRING = 9,
ID_BYTES = 10,
ID_BYTE_ARRAY = 11,
ID_BIGDECIMAL = 12,
ID_BIGINTEGER = 13,
ID_DATE = 14,
ID_ARRAY = 15, // 1-15 is encoded as 1 byte on protobuf and
// protostuff format
ID_OBJECT = 16, ID_ARRAY_MAPPED = 17, ID_CLASS = 18,
ID_CLASS_MAPPED = 19, ID_CLASS_ARRAY = 20,
ID_CLASS_ARRAY_MAPPED = 21,
ID_ENUM_SET = 22, ID_ENUM_MAP = 23, ID_ENUM = 24,
ID_COLLECTION = 25, ID_MAP = 26,
ID_POLYMORPHIC_COLLECTION = 28, ID_POLYMORPHIC_MAP = 29,
ID_DELEGATE = 30,
ID_ARRAY_DELEGATE = 32, ID_ARRAY_SCALAR = 33, ID_ARRAY_ENUM = 34,
ID_ARRAY_POJO = 35,
ID_THROWABLE = 52,
// pojo fields limited to 126 if not explicitly using @Tag
// annotations
ID_POJO = 127;
......
}
序列化的时候是已如下格式来存储数据的,如下图所示:
tag里面包含了字段的位置标识,比如第一个字段,第二个字段…,以及类型信息,可以看一下两个bean序列化之后的二进制信息:
10 5 104 97 104 97 49 18 4 49 46 48 48
10 5 104 97 104 97 50 19 98 4 50 46 48 48 20
104 97 104 97 49和104 97 104 97 50分别是:haha1和haha2;49 46 48 48和50 46 48 48分别是1.00和2.00;
Bean2存储的数据量明细比Bean1大,因为Bean2中的p2作为Object存储,需要存储Object的起始标识和结束标识,还需要保存具体的类型信息;
更多可以参考:https://my.oschina.net/OutOfM...
总结
类Json序列化方式本身没有保存数据的类型,所以在反序列时有些类型不能区分,只能通过设置特性的方式来解决,但是json格式有更好的可读性;直接序列化为二进制的方式可读性差点,但是可以将很多信息保存进去,更加完善;
示例代码地址
https://github.com/ksfzhaohui...
https://gitee.com/OutOfMemory...
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