前言
DSL 全称为 domain-specific language(领域特定语言),本系列应当会很长,其中包含些许不成熟的想法,欢迎私信指正。
1. DSL 简述
我理解的 DSL 的主要职能是对领域的描述,他存在于领域服务之上,如下图所示:
其实,我们也可以认为 DomainService 是 AggregateRoot 的 DSL,区别是 DomainService 表达的是更原子化的描述,下图是我理解的更通俗的层次关系:
一句话总结:DSL 应当如同代码的组装说明书,他描述了各个子域的关系及其表达流程。
2. 扩展点论述
扩展点,顾名思义其核心在于扩展二字,如果你的领域只表达一种形态,那没必要关注他。但假设你的领域存在不同维度或者多种形式的表达,那扩展点极具价值,如下图所示:
此时代码中的各个子域都成为了各种类型的标准件,而扩展点可以看做领域的骨架,由他限定整个域的职责(比如规定这个工厂只能生产汽车),然后由 DSL 去描述该职责有哪些表达(比如生产哪种型号的车)。
3. 扩展点的实现方案
3.1 效果预期
在实现功能之前,我简单写了以下伪代码:
接口:
public interface Engine {
void launch();
}
实例 A:
@Service
public class AEngine implements Engine {
@Override
public void launch() {
System.out.println("aengine launched");
}
}
实例 B:
@Service
public class BEngine_1 implements Engine {
@Override
public void launch() {
System.out.print("union 1 + ");
}
}
@Service
public class BEngine_2 implements Engine {
@Override
public void launch() {
System.out.print("union 2 +");
}
}
@Service
public class BEngine_3 implements Engine {
@Override
public void launch() {
System.out.print("union 3");
System.out.println("bengine launched");
}
}
测试:
public class DefaultTest {
@Autowired
private Engine engine;
@Test
public void testA() {
// set dsl a
engine.launch();
}
@Test
public void testB() {
// set dsl b
engine.launch();
}
}
我期待的结果是当 testA 执行时输出:aengine launched
,当 testB 执行时输出:union 1 + union 2 + union 3 bengine launched
3.2 实现接口到实例的一对多路由
一对一的路由就是依赖注入,Spring 已经帮我们实现了,那怎样实现一对多?我的想法是仿照 @Autowired ,匹配实例的那部分代码使用 jdk 代理进行重写, 示例如下:
注解:
@Retention(RetentionPolicy.RUNTIME)
@Target(ElementType.FIELD)
public @interface ExtensionNode {
}
Processor:
@Configuration
public class ETPostProcessor extends InstantiationAwareBeanPostProcessorAdapter
implements MergedBeanDefinitionPostProcessor, BeanFactoryAware {
private final Log logger = LogFactory.getLog(getClass());
private final Map, Constructor>[]> candidateConstructorsCache = new ConcurrentHashMap<>(256);
private final Map injectionMetadataCache = new ConcurrentHashMap<>(256);
private NodeProxy nodeProxy;
@Override
public void setBeanFactory(BeanFactory beanFactory) {
if (!(beanFactory instanceof ConfigurableListableBeanFactory)) {
throw new IllegalArgumentException(
"ETPostProcessor requires a ConfigurableListableBeanFactory: " + beanFactory);
}
this.nodeProxy = new NodeProxy((ConfigurableListableBeanFactory) beanFactory);
}
@Override
public void postProcessMergedBeanDefinition(RootBeanDefinition beanDefinition, Class> beanType, String beanName) {
InjectionMetadata metadata = findAutowiringMetadata(beanName, beanType, null);
metadata.checkConfigMembers(beanDefinition);
}
@Override
public void resetBeanDefinition(String beanName) {
this.injectionMetadataCache.remove(beanName);
}
@Override
@Nullable
public Constructor>[] determineCandidateConstructors(Class> beanClass, final String beanName)
throws BeanCreationException {
// Quick check on the concurrent map first, with minimal locking.
Constructor>[] candidateConstructors = this.candidateConstructorsCache.get(beanClass);
if (candidateConstructors == null) {
// Fully synchronized resolution now...
synchronized (this.candidateConstructorsCache) {
candidateConstructors = this.candidateConstructorsCache.get(beanClass);
if (candidateConstructors == null) {
Constructor>[] rawCandidates;
try {
rawCandidates = beanClass.getDeclaredConstructors();
} catch (Throwable ex) {
throw new BeanCreationException(beanName,
"Resolution of declared constructors on bean Class [" + beanClass.getName() +
"] from ClassLoader [" + beanClass.getClassLoader() + "] failed", ex);
}
List> candidates = new ArrayList<>(rawCandidates.length);
Constructor> requiredConstructor = null;
Constructor> defaultConstructor = null;
Constructor> primaryConstructor = BeanUtils.findPrimaryConstructor(beanClass);
int nonSyntheticConstructors = 0;
for (Constructor> candidate : rawCandidates) {
if (!candidate.isSynthetic()) {
nonSyntheticConstructors++;
} else if (primaryConstructor != null) {
continue;
}
AnnotationAttributes ann = findETAnnotation(candidate);
if (ann == null) {
Class> userClass = ClassUtils.getUserClass(beanClass);
if (userClass != beanClass) {
try {
Constructor> superCtor =
userClass.getDeclaredConstructor(candidate.getParameterTypes());
ann = findETAnnotation(superCtor);
} catch (NoSuchMethodException ignore) {
}
}
}
if (ann != null) {
if (requiredConstructor != null) {
throw new BeanCreationException(beanName,
"Invalid autowire-marked constructor: " + candidate +
". Found constructor with 'required' ET annotation already: " +
requiredConstructor);
}
requiredConstructor = candidate;
candidates.add(candidate);
} else if (candidate.getParameterCount() == 0) {
defaultConstructor = candidate;
}
}
if (!candidates.isEmpty()) {
// Add default constructor to list of optional constructors, as fallback.
candidateConstructors = candidates.toArray(new Constructor>[0]);
} else if (rawCandidates.length == 1 && rawCandidates[0].getParameterCount() > 0) {
candidateConstructors = new Constructor>[]{rawCandidates[0]};
} else if (nonSyntheticConstructors == 2 && primaryConstructor != null &&
defaultConstructor != null && !primaryConstructor.equals(defaultConstructor)) {
candidateConstructors = new Constructor>[]{primaryConstructor, defaultConstructor};
} else if (nonSyntheticConstructors == 1 && primaryConstructor != null) {
candidateConstructors = new Constructor>[]{primaryConstructor};
} else {
candidateConstructors = new Constructor>[0];
}
this.candidateConstructorsCache.put(beanClass, candidateConstructors);
}
}
}
return (candidateConstructors.length > 0 ? candidateConstructors : null);
}
@Override
public PropertyValues postProcessProperties(PropertyValues pvs, Object bean, String beanName) {
InjectionMetadata metadata = findAutowiringMetadata(beanName, bean.getClass(), pvs);
try {
metadata.inject(bean, beanName, pvs);
} catch (BeanCreationException ex) {
throw ex;
} catch (Throwable ex) {
throw new BeanCreationException(beanName, "Injection of ET dependencies failed", ex);
}
return pvs;
}
private InjectionMetadata findAutowiringMetadata(String beanName, Class> clazz, @Nullable PropertyValues pvs) {
// Fall back to class name as cache key, for backwards compatibility with custom callers.
String cacheKey = (StringUtils.hasLength(beanName) ? beanName : clazz.getName());
// Quick check on the concurrent map first, with minimal locking.
InjectionMetadata metadata = this.injectionMetadataCache.get(cacheKey);
if (InjectionMetadata.needsRefresh(metadata, clazz)) {
synchronized (this.injectionMetadataCache) {
metadata = this.injectionMetadataCache.get(cacheKey);
if (InjectionMetadata.needsRefresh(metadata, clazz)) {
if (metadata != null) {
metadata.clear(pvs);
}
metadata = buildAutowiringMetadata(clazz);
this.injectionMetadataCache.put(cacheKey, metadata);
}
}
}
return metadata;
}
private InjectionMetadata buildAutowiringMetadata(final Class> clazz) {
List elements = new ArrayList<>();
Class> targetClass = clazz;
do {
final List currElements = new ArrayList<>();
ReflectionUtils.doWithLocalFields(targetClass, field -> {
AnnotationAttributes ann = findETAnnotation(field);
if (ann != null) {
if (Modifier.isStatic(field.getModifiers())) {
if (logger.isInfoEnabled()) {
logger.info("ET annotation is not supported on static fields: " + field);
}
return;
}
currElements.add(new ETPostProcessor.ETFieldElement(field));
}
});
elements.addAll(0, currElements);
targetClass = targetClass.getSuperclass();
}
while (targetClass != null && targetClass != Object.class);
return new InjectionMetadata(clazz, elements);
}
@Nullable
private AnnotationAttributes findETAnnotation(AccessibleObject ao) {
if (ao.getAnnotations().length > 0) {
AnnotationAttributes attributes = AnnotatedElementUtils.getMergedAnnotationAttributes(ao, ExtensionNode.class);
if (attributes != null) {
return attributes;
}
}
return null;
}
private class ETFieldElement extends InjectionMetadata.InjectedElement {
ETFieldElement(Field field) {
super(field, null);
}
@Override
protected void inject(Object bean, @Nullable String beanName, @Nullable PropertyValues pvs) throws Throwable {
Field field = (Field) this.member;
Object value = nodeProxy.getProxy(field.getType());
if (value != null) {
ReflectionUtils.makeAccessible(field);
field.set(bean, value);
}
}
}
}
代理:
@Configuration
public class NodeProxy implements InvocationHandler {
private final ConfigurableListableBeanFactory beanFactory;
public NodeProxy(ConfigurableListableBeanFactory beanFactory) {
this.beanFactory = beanFactory;
}
public Object getProxy(Class> clazz) {
ClassLoader classLoader = ClassUtils.getDefaultClassLoader();
return Proxy.newProxyInstance(classLoader, new Class[]{clazz}, this);
}
@Override
public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
List
此时我们跑一下单元测试,得到:
一对多实例路由完美实现。
3.3 添加 DSL 描述
零件有了,骨架有了,最后就是怎样给他加一张图纸,让扩展点按需表达,伪代码如下:
public class DslUtils {
private static final ThreadLocal
修改代理:
@Override
public Object invoke(Object proxy, Method method, Object[] args) throws Throwable {
List
修改测试:
@ExtensionNode
private Engine engine;
@Test
public void testA() {
DslUtils.setDslA();
engine.launch();
}
@Test
public void testB() {
DslUtils.setDslB();
engine.launch();
}
再跑一次单元测试可完美实现预期效果(温馨提示:因时间关系伪代码写的很糙,此处有极大的设计和发挥空间,后续系列中逐步展开探讨)。
结语
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