TestNG源代码分析:依赖管理的实现
2018-03-19
1 背景
当case之间有依赖关系,有依赖关系的case,它们的执行顺序是有限制的。TestNG提供了依赖管理功能
2 基础理论
这个执行顺序可以用拓扑排序算法实现。
只要是有向无环图就能被拓扑排序,拓扑排序维基典型实现算法:
L ← Empty list that will contain the sorted elements S ← Set of all nodes with no incoming edges while S is non-empty do remove a node n from S insert n into L foreach node m with an edge e from n to m do remove edge e from thegraph if m has no other incoming edges then insert m into S if graph has edges then return error (graph has at least one cycle) else return L (a topologically sorted order)
TestNG依赖管理功能
- dependsOnMethods
@Test public void serverStartedOk(){} @Test(dependsOnMethods={ "serverStartedOk" }) public void method1() {}
- dependsOnGroups
@Test(groups = { "init" })
public void serverStartedOk(){}
@Test(groups = { "init" })
public void initEnvironment(){}
@Test(dependsOnGroups = { "init.*})
public void method1() {}
3 TestNG依赖管理源代码
如何找到依赖原理源代码?
通过报错,即即故意制造一个循环依赖,然后看stack trace:
错误代码如下:
@Test(dependsOnMethods={"MethodA"})
public void MethodA(){}
Stack Trace
at org.testng.internal.Graph.topologicalSort(Graph.java:143)
at org.testng.internal.MethodHelper.topologicalSort(MethodHelper.java:231)
org.testng.TestNGException: The following methods have cyclic dependencies: Sample.MethodA()[pri:0, instance:Demo.Sample@50c87b21] at org.testng.internal.Graph.topologicalSort(Graph.java:143) at org.testng.internal.MethodHelper.topologicalSort(MethodHelper.java:231) at org.testng.internal.MethodHelper.sortMethods(MethodHelper.java:287) at org.testng.internal.MethodHelper.collectAndOrderMethods(MethodHelper.java:60) at org.testng.TestRunner.initMethods(TestRunner.java:464) at org.testng.TestRunner.init(TestRunner.java:247) at org.testng.TestRunner.init(TestRunner.java:217) at org.testng.TestRunner.<init>(TestRunner.java:169) at org.testng.remote.support.RemoteTestNG6_9_10$1.newTestRunner(RemoteTestNG6_9_10.java:28) at org.testng.remote.support.RemoteTestNG6_9_10$DelegatingTestRunnerFactory.newTestRunner(RemoteTestNG6_9_10.java:61) at org.testng.SuiteRunner$ProxyTestRunnerFactory.newTestRunner(SuiteRunner.java:594) at org.testng.SuiteRunner.init(SuiteRunner.java:168) at org.testng.SuiteRunner.<init>(SuiteRunner.java:117) at org.testng.TestNG.createSuiteRunner(TestNG.java:1339) at org.testng.TestNG.createSuiteRunners(TestNG.java:1326) at org.testng.TestNG.runSuitesLocally(TestNG.java:1180) at org.testng.TestNG.runSuites(TestNG.java:1104) at org.testng.TestNG.run(TestNG.java:1076) at org.testng.remote.AbstractRemoteTestNG.run(AbstractRemoteTestNG.java:126) at org.testng.remote.RemoteTestNG.initAndRun(RemoteTestNG.java:152) at org.testng.remote.RemoteTestNG.main(RemoteTestNG.java:57)
4 源代码分析
//MethodHelper.topologicalSort private static Graph<ITestNGMethod> topologicalSort(ITestNGMethod[] methods, List<ITestNGMethod> sequentialList, List<ITestNGMethod> parallelList) //Graph.topologicalSort public void topologicalSort()
注意:
- methods变量包括所有的要跑的用例和用例依赖的用例(依赖用例依赖的用例也包括)
- 依赖管理代码在Graph类中实现,MethodHelper.topologicalSort方法会调用Graph类中的方法
Graph类有三个变量
//m_nodes:放的是所有的节点的引用 private Map<T, Node<T>> m_nodes = Maps.newLinkedHashMap(); //m_independentNodes:所有独立节点的引用,这样的节点(用例)可并发运行 private List<T> m_strictlySortedNodes = null; //m_strictlySortedNodes:经过严格排序的非独立节点 private Map<T, Node<T>> m_independentNodes = null;
Graph.topologicalSort方法实现依赖节点的拓扑排序
//m_nodes:放的是所有的节点(用例)的引用 //m_independentNodes:所有独立节点的引用 //m_strictlySortedNodes:经过严格排序的非独立节点 public void topologicalSort() { ppp("================ SORTING"); //m_strictlySortedNodes集合: 最后的结果放到这个集合中 m_strictlySortedNodes=Lists.newArrayList(); initializeIndependentNodes(); //nodes2集合: 非独立的节点 List<Node<T>>nodes2 =Lists.newArrayList(); //1 创建非独立节点集合,即存在依赖关系的方法的集合 for (Node<T> n :getNodes()) { //getNodes()返回m_nodes if (!isIndependent(n.getObject())){// 判断该节点是否独立,如果不独立的话,添加到nodes2中 ppp("ADDING FOR SORT: " +n.getObject()); nodes2.add(n.clone()); //使用的是clone方法来进行对象的复制,一般不推荐使用clone方法,参见Effective Java Item 11 } else { ppp("SKIPPING INDEPENDENT NODE" + n); } } //2 将非独立的节点集合排序,为了让属于同类中的方法在集合中的位置近一些,从而在调用的顺序上能够相邻一些 Collections.sort(nodes2); //3 进行拓扑排序,如果发现有循环依赖,马上抛出异常 while (!nodes2.isEmpty()) { Node<T> node =findNodeWithNoPredecessors(nodes2); // 从nodes2集合中找到没有前驱节点的节点 if (null == node) { // 如果没有找到节点,那么创建一个Tarjan对象来得到一个cycle List<T> cycle =newTarjan<T>(this,nodes2.get(0).getObject()).getCycle(); // 这里实现了Tarjan算法,用来得到环的路径信息 StringBuffer sb = new StringBuffer(); //在非并发环境中应该尽量使用StringBuilder sb.append("The following methodshave cyclic dependencies: "); for (T m : cycle) { sb.append(m).append(" "); } throw newTestNGException(sb.toString()); } else { //如果找到了,将这个没有任何前驱节点的节点放到结果结合中,然后从nodes2集合中删除该节点 m_strictlySortedNodes.add(node.getObject()); removeFromNodes(nodes2, node); } } ppp("===============DONESORTING"); if (m_verbose) { dumpSortedNodes(); } }
调用方法
private void initializeIndependentNodes() { if (null == m_independentNodes) { List<Node<T>> list = Lists.newArrayList(m_nodes.values()); Collections.sort(list); m_independentNodes = Maps.newLinkedHashMap(); for (Node<T> node : list) { m_independentNodes.put(node.getObject(), node); } } } private Collection<Node<T>> getNodes() { return m_nodes.values(); }
MethodHelper.topologicalSort方法,调用Graph方法区分独立节点和依赖节点,并调用toplogicalSort进行依赖节点拓扑排序
private static Graph<ITestNGMethod> topologicalSort(ITestNGMethod[] methods, List<ITestNGMethod> sequentialList, List<ITestNGMethod> parallelList) { Graph<ITestNGMethod> result = new Graph<>(); if (methods.length == 0) { return result; //如果传入的methods数组长度为0,直接返回了空的graph } // 区分出要顺序执行的用例(依赖用例)和可并行的用例(独立用例) for (ITestNGMethod m : methods) { result.addNode(m); //对于每个方法instance,添加到graph中 List<ITestNGMethod> predecessors = Lists.newArrayList(); //获得该方法依赖的方法 String[] methodsDependedUpon = m.getMethodsDependedUpon(); String[] groupsDependedUpon = m.getGroupsDependedUpon(); if (methodsDependedUpon.length > 0) { ITestNGMethod[] methodsNamed = MethodHelper.findDependedUponMethods(m, methods); for (ITestNGMethod pred : methodsNamed) { predecessors.add(pred); } } if (groupsDependedUpon.length > 0) { for (String group : groupsDependedUpon) { ITestNGMethod[] methodsThatBelongToGroup = MethodGroupsHelper.findMethodsThatBelongToGroup(m, methods, group); for (ITestNGMethod pred : methodsThatBelongToGroup) { predecessors.add(pred); } } } for (ITestNGMethod predecessor : predecessor s) { result.addPredecessor(m, predecessor); //将依赖方法加入graph中 } } result.topologicalSort(); sequentialList.addAll(result.getStrictlySortedNodes()); parallelList.addAll(result.getIndependentNodes()); return result; }
调用方法
public void addNode(T tm) { ppp("ADDING NODE " + tm + " " + tm.hashCode()); m_nodes.put(tm, new Node<>(tm)); // Initially, all the nodes are put in the independent list as well } public void addPredecessor(T tm, T predecessor) { Node<T> node = findNode(tm); if (null == node) { throw new TestNGException("Non-existing node: " + tm); } else { node.addPredecessor(predecessor); addNeighbor(tm, predecessor); // Remove these two nodes from the independent list initializeIndependentNodes(); m_independentNodes.remove(predecessor); m_independentNodes.remove(tm); ppp(" REMOVED " + predecessor + " FROM INDEPENDENT OBJECTS"); } } public Set<T> getIndependentNodes() { return m_independentNodes.keySet(); } public List<T> getStrictlySortedNodes() { return m_strictlySortedNodes; }