// Copyright (C) 2010 Internet Systems Consortium, Inc. ("ISC") // // Permission to use, copy, modify, and/or distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice appear in all copies. // // THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES WITH // REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY // AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR ANY SPECIAL, DIRECT, // INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM // LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE // OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR // PERFORMANCE OF THIS SOFTWARE. #include #include #include #include #include #include #include #include #include using namespace std; using namespace isc; using namespace isc::dns; using isc::UnitTestUtil; using namespace isc::datasrc; // XXX: some compilers cannot find class static constants used in // EXPECT_xxx macros, for which we need an explicit empty definition. const size_t Name::MAX_LABELS; /* The initial structure of rbtree * * b * / \ * a d.e.f * / | \ * c | g.h * | | * w.y i * / | \ * x | z * | | * p j * / \ * o q */ namespace { class RBTreeTest : public::testing::Test { protected: RBTreeTest() : rbtree_expose_empty_node(true), crbtnode(NULL) { const char* const domain_names[] = { "c", "b", "a", "x.d.e.f", "z.d.e.f", "g.h", "i.g.h", "o.w.y.d.e.f", "j.z.d.e.f", "p.w.y.d.e.f", "q.w.y.d.e.f"}; int name_count = sizeof(domain_names) / sizeof(domain_names[0]); for (int i = 0; i < name_count; ++i) { rbtree.insert(Name(domain_names[i]), &rbtnode); rbtnode->setData(RBNode::NodeDataPtr(new int(i + 1))); rbtree_expose_empty_node.insert(Name(domain_names[i]), &rbtnode); rbtnode->setData(RBNode::NodeDataPtr(new int(i + 1))); } } RBTree rbtree; RBTree rbtree_expose_empty_node; RBNode* rbtnode; const RBNode* crbtnode; }; TEST_F(RBTreeTest, getNodeCount) { EXPECT_EQ(13, rbtree.getNodeCount()); } TEST_F(RBTreeTest, setGetData) { rbtnode->setData(RBNode::NodeDataPtr(new int(11))); EXPECT_EQ(11, *(rbtnode->getData())); } TEST_F(RBTreeTest, insertNames) { EXPECT_EQ(RBTree::ALREADYEXISTS, rbtree.insert(Name("d.e.f"), &rbtnode)); EXPECT_EQ(Name("d.e.f"), rbtnode->getName()); EXPECT_EQ(13, rbtree.getNodeCount()); //insert not exist node EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("."), &rbtnode)); EXPECT_EQ(Name("."), rbtnode->getName()); EXPECT_EQ(14, rbtree.getNodeCount()); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("example.com"), &rbtnode)); EXPECT_EQ(15, rbtree.getNodeCount()); rbtnode->setData(RBNode::NodeDataPtr(new int(12))); // return ALREADYEXISTS, since node "example.com" already has been explicitly inserted EXPECT_EQ(RBTree::ALREADYEXISTS, rbtree.insert(Name("example.com"), &rbtnode)); EXPECT_EQ(15, rbtree.getNodeCount()); // split the node "d.e.f" EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("k.e.f"), &rbtnode)); EXPECT_EQ(Name("k"), rbtnode->getName()); EXPECT_EQ(17, rbtree.getNodeCount()); // split the node "g.h" EXPECT_EQ(RBTree::ALREADYEXISTS, rbtree.insert(Name("h"), &rbtnode)); EXPECT_EQ(Name("h"), rbtnode->getName()); EXPECT_EQ(18, rbtree.getNodeCount()); // add child domain EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("m.p.w.y.d.e.f"), &rbtnode)); EXPECT_EQ(Name("m"), rbtnode->getName()); EXPECT_EQ(19, rbtree.getNodeCount()); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("n.p.w.y.d.e.f"), &rbtnode)); EXPECT_EQ(Name("n"), rbtnode->getName()); EXPECT_EQ(20, rbtree.getNodeCount()); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("l.a"), &rbtnode)); EXPECT_EQ(Name("l"), rbtnode->getName()); EXPECT_EQ(21, rbtree.getNodeCount()); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("r.d.e.f"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("s.d.e.f"), &rbtnode)); EXPECT_EQ(23, rbtree.getNodeCount()); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("h.w.y.d.e.f"), &rbtnode)); // add more nodes one by one to cover leftRotate and rightRotate EXPECT_EQ(RBTree::ALREADYEXISTS, rbtree.insert(Name("f"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("m"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("nm"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("om"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("k"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("l"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("fe"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("ge"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("i"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("ae"), &rbtnode)); EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("n"), &rbtnode)); } TEST_F(RBTreeTest, findName) { // find const rbtnode // exact match EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("a"), &crbtnode)); EXPECT_EQ(Name("a"), crbtnode->getName()); // not found EXPECT_EQ(RBTree::NOTFOUND, rbtree.find(Name("d.e.f"), &crbtnode)); EXPECT_EQ(RBTree::NOTFOUND, rbtree.find(Name("y.d.e.f"), &crbtnode)); EXPECT_EQ(RBTree::NOTFOUND, rbtree.find(Name("x"), &crbtnode)); EXPECT_EQ(RBTree::NOTFOUND, rbtree.find(Name("m.n"), &crbtnode)); // if we expose empty node, we can get the empty node created during insert EXPECT_EQ(RBTree::EXACTMATCH, rbtree_expose_empty_node.find(Name("d.e.f"), &crbtnode)); EXPECT_EQ(RBTree::EXACTMATCH, rbtree_expose_empty_node.find(Name("w.y.d.e.f"), &crbtnode)); // partial match EXPECT_EQ(RBTree::PARTIALMATCH, rbtree.find(Name("m.b"), &crbtnode)); EXPECT_EQ(Name("b"), crbtnode->getName()); EXPECT_EQ(RBTree::PARTIALMATCH, rbtree_expose_empty_node.find(Name("m.d.e.f"), &crbtnode)); // find rbtnode EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("q.w.y.d.e.f"), &rbtnode)); EXPECT_EQ(Name("q"), rbtnode->getName()); } TEST_F(RBTreeTest, findError) { // For the version that takes a node chain, the chain must be empty. RBTreeNodeChain chain; EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("a"), &crbtnode, chain, NULL, NULL)); // trying to reuse the same chain. it should result in an exception. EXPECT_THROW(rbtree.find(Name("a"), &crbtnode, chain, NULL, NULL), BadValue); } TEST_F(RBTreeTest, flags) { EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("flags.example"), &rbtnode)); // by default, flags are all off EXPECT_FALSE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // set operation, by default it enables the flag rbtnode->setFlag(RBNode::FLAG_CALLBACK); EXPECT_TRUE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // try disable the flag explicitly rbtnode->setFlag(RBNode::FLAG_CALLBACK, false); EXPECT_FALSE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // try enable the flag explicitly rbtnode->setFlag(RBNode::FLAG_CALLBACK, true); EXPECT_TRUE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // setting an unknown flag will trigger an exception EXPECT_THROW(rbtnode->setFlag(static_cast::Flags>(2), true), isc::InvalidParameter); } bool testCallback(const RBNode&, bool* callack_checker) { *callack_checker = true; return (false); } TEST_F(RBTreeTest, callback) { // by default callback isn't enabled EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("callback.example"), &rbtnode)); rbtnode->setData(RBNode::NodeDataPtr(new int(1))); EXPECT_FALSE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // enable/re-disable callback rbtnode->setFlag(RBNode::FLAG_CALLBACK); EXPECT_TRUE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); rbtnode->setFlag(RBNode::FLAG_CALLBACK, false); EXPECT_FALSE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); // enable again for subsequent tests rbtnode->setFlag(RBNode::FLAG_CALLBACK); // add more levels below and above the callback node for partial match. RBNode* subrbtnode; EXPECT_EQ(RBTree::SUCCESS, rbtree.insert(Name("sub.callback.example"), &subrbtnode)); subrbtnode->setData(RBNode::NodeDataPtr(new int(2))); RBNode* parentrbtnode; EXPECT_EQ(RBTree::ALREADYEXISTS, rbtree.insert(Name("example"), &parentrbtnode)); // the chilld/parent nodes shouldn't "inherit" the callback flag. // "rbtnode" may be invalid due to the insertion, so we need to re-find // it. EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("callback.example"), &rbtnode)); EXPECT_TRUE(rbtnode->getFlag(RBNode::FLAG_CALLBACK)); EXPECT_FALSE(subrbtnode->getFlag(RBNode::FLAG_CALLBACK)); EXPECT_FALSE(parentrbtnode->getFlag(RBNode::FLAG_CALLBACK)); // check if the callback is called from find() RBTreeNodeChain node_path1; bool callback_called = false; EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("sub.callback.example"), &crbtnode, node_path1, testCallback, &callback_called)); EXPECT_TRUE(callback_called); // enable callback at the parent node, but it doesn't have data so // the callback shouldn't be called. RBTreeNodeChain node_path2; parentrbtnode->setFlag(RBNode::FLAG_CALLBACK); callback_called = false; EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name("callback.example"), &crbtnode, node_path2, testCallback, &callback_called)); EXPECT_FALSE(callback_called); } TEST_F(RBTreeTest, chainLevel) { RBTreeNodeChain chain; // by default there should be no level in the chain. EXPECT_EQ(0, chain.getLevelCount()); // insert one node to the tree and find it. there should be exactly // one level in the chain. RBTree tree(true); Name node_name(Name::ROOT_NAME()); EXPECT_EQ(RBTree::SUCCESS, tree.insert(node_name, &rbtnode)); EXPECT_EQ(RBTree::EXACTMATCH, tree.find(node_name, &crbtnode, chain, NULL, NULL)); EXPECT_EQ(1, chain.getLevelCount()); /* * Now creating a possibly deepest tree with MAX_LABELS levels. * it should look like: * (.) * | * a * | * a * : (MAX_LABELS - 1) "a"'s * * then confirm that find() for the deepest name succeeds without any * disruption, and the resulting chain has the expected level. * Note that the root name (".") solely belongs to a single level, * so the levels begin with 2. */ for (unsigned int i = 2; i <= Name::MAX_LABELS; ++i) { node_name = Name("a.").concatenate(node_name); EXPECT_EQ(RBTree::SUCCESS, tree.insert(node_name, &rbtnode)); RBTreeNodeChain found_chain; EXPECT_EQ(RBTree::EXACTMATCH, tree.find(node_name, &crbtnode, found_chain, NULL, NULL)); EXPECT_EQ(i, found_chain.getLevelCount()); } // Confirm the last inserted name has the possible maximum length with // maximum label count. This confirms the rbtree and chain level cannot // be larger. EXPECT_EQ(Name::MAX_LABELS, node_name.getLabelCount()); EXPECT_THROW(node_name.concatenate(Name("a.")), TooLongName); } TEST_F(RBTreeTest, getAbsoluteNameError) { // an empty chain isn't allowed. RBTreeNodeChain chain; EXPECT_THROW(chain.getAbsoluteName(), BadValue); } /* *the domain order should be: * a, b, c, d.e.f, x.d.e.f, w.y.d.e.f, o.w.y.d.e.f, p.w.y.d.e.f, q.w.y.d.e.f, * z.d.e.f, j.z.d.e.f, g.h, i.g.h * b * / \ * a d.e.f * / | \ * c | g.h * | | * w.y i * / | \ * x | z * | | * p j * / \ * o q */ TEST_F(RBTreeTest, nextNode) { const char* const names[] = { "a", "b", "c", "d.e.f", "x.d.e.f", "w.y.d.e.f", "o.w.y.d.e.f", "p.w.y.d.e.f", "q.w.y.d.e.f", "z.d.e.f", "j.z.d.e.f", "g.h", "i.g.h"}; const int name_count = sizeof(names) / sizeof(names[0]); RBTreeNodeChain node_path; const RBNode* node = NULL; EXPECT_EQ(RBTree::EXACTMATCH, rbtree.find(Name(names[0]), &node, node_path, NULL, NULL)); for (int i = 0; i < name_count; ++i) { EXPECT_NE(static_cast(NULL), node); EXPECT_EQ(Name(names[i]), node_path.getAbsoluteName()); node = rbtree.nextNode(node_path); } // We should have reached the end of the tree. EXPECT_EQ(static_cast(NULL), node); } TEST_F(RBTreeTest, nextNodeError) { // Empty chain for nextNode() is invalid. RBTreeNodeChain chain; EXPECT_THROW(rbtree.nextNode(chain), BadValue); } // A helper function for getLastComparedNode() below. void comparisonChecks(const RBTreeNodeChain& chain, int expected_order, int expected_common_labels, NameComparisonResult::NameRelation expected_reln) { if (expected_order > 0) { EXPECT_LT(0, chain.getLastComparisonResult().getOrder()); } else if (expected_order < 0) { EXPECT_GT(0, chain.getLastComparisonResult().getOrder()); } else { EXPECT_EQ(0, chain.getLastComparisonResult().getOrder()); } EXPECT_EQ(expected_common_labels, chain.getLastComparisonResult().getCommonLabels()); EXPECT_EQ(expected_reln, chain.getLastComparisonResult().getRelation()); } TEST_F(RBTreeTest, getLastComparedNode) { RBTree& tree = rbtree_expose_empty_node; // use the "empty OK" mode RBTreeNodeChain chain; // initially there should be no 'last compared'. EXPECT_EQ(static_cast(NULL), chain.getLastComparedNode()); // A search for an empty tree should result in no 'last compared', too. RBTree empty_tree; EXPECT_EQ(RBTree::NOTFOUND, empty_tree.find(Name("a"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(static_cast(NULL), chain.getLastComparedNode()); chain.clear(); const RBNode* expected_node = NULL; // Exact match case. The returned node should be last compared. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("x.d.e.f"), &expected_node, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // 2 = # labels of "x." comparisonChecks(chain, 0, 2, NameComparisonResult::EQUAL); chain.clear(); // Partial match, search stopped at the matching node, which should be // the last compared node. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("i.g.h"), &expected_node)); EXPECT_EQ(RBTree::PARTIALMATCH, tree.find(Name("x.i.g.h"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // i.g.h < x.i.g.h, 2 = # labels of "i." comparisonChecks(chain, 1, 2, NameComparisonResult::SUBDOMAIN); chain.clear(); // Partial match, search stopped in the subtree below the matching node // after following a left branch. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("x.d.e.f"), &expected_node)); EXPECT_EQ(RBTree::PARTIALMATCH, tree.find(Name("a.d.e.f"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // a < x, 1 = # labels of "." (trailing dot) comparisonChecks(chain, -1, 1, NameComparisonResult::COMMONANCESTOR); chain.clear(); // Partial match, search stopped in the subtree below the matching node // after following a right branch. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("z.d.e.f"), &expected_node)); EXPECT_EQ(RBTree::PARTIALMATCH, tree.find(Name("zz.d.e.f"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // zz > z, 1 = # labels of "." (trailing dot) comparisonChecks(chain, 1, 1, NameComparisonResult::COMMONANCESTOR); chain.clear(); // Partial match, search stopped at a node for a super domain of the // search name in the subtree below the matching node. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("w.y.d.e.f"), &expected_node)); EXPECT_EQ(RBTree::PARTIALMATCH, tree.find(Name("y.d.e.f"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // y < w.y, 2 = # labels of "y." comparisonChecks(chain, -1, 2, NameComparisonResult::SUPERDOMAIN); chain.clear(); // Partial match, search stopped at a node that share a common ancestor // with the search name in the subtree below the matching node. // (the expected node is the same as the previous case) EXPECT_EQ(RBTree::PARTIALMATCH, tree.find(Name("z.y.d.e.f"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // z.y > w.y, 2 = # labels of "y." comparisonChecks(chain, 1, 2, NameComparisonResult::COMMONANCESTOR); chain.clear(); // Search stops in the highest level after following a left branch. EXPECT_EQ(RBTree::EXACTMATCH, tree.find(Name("c"), &expected_node)); EXPECT_EQ(RBTree::NOTFOUND, tree.find(Name("bb"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // bb < c, 1 = # labels of "." (trailing dot) comparisonChecks(chain, -1, 1, NameComparisonResult::COMMONANCESTOR); chain.clear(); // Search stops in the highest level after following a right branch. // (the expected node is the same as the previous case) EXPECT_EQ(RBTree::NOTFOUND, tree.find(Name("d"), &crbtnode, chain, NULL, NULL)); EXPECT_EQ(expected_node, chain.getLastComparedNode()); // d > c, 1 = # labels of "." (trailing dot) comparisonChecks(chain, 1, 1, NameComparisonResult::COMMONANCESTOR); chain.clear(); } TEST_F(RBTreeTest, dumpTree) { std::ostringstream str; std::ostringstream str2; rbtree.dumpTree(str); str2 << "tree has 13 node(s)\nb. (black)\n a. (black)\n NULL\n NULL\n d.e.f. (black)[invisible] \n begin down from d.e.f.\n w.y. (black)[invisible] \n begin down from w.y.\n p. (black)\n o. (red)\n NULL\n NULL\n q. (red)\n NULL\n NULL\n end down from w.y.\n x. (red)\n NULL\n NULL\n z. (red)\n begin down from z.\n j. (black)\n NULL\n NULL\n end down from z.\n NULL\n NULL\n end down from d.e.f.\n c. (red)\n NULL\n NULL\n g.h. (red)\n begin down from g.h.\n i. (black)\n NULL\n NULL\n end down from g.h.\n NULL\n NULL\n"; EXPECT_EQ(str.str(), str2.str()); } TEST_F(RBTreeTest, swap) { // Store info about the first tree std::ostringstream str1; rbtree.dumpTree(str1); size_t count1(rbtree.getNodeCount()); // Create second one and store state RBTree tree2; RBNode* node; tree2.insert(Name("second"), &node); std::ostringstream str2; tree2.dumpTree(str2); // Swap them ASSERT_NO_THROW(tree2.swap(rbtree)); // Check their sizes ASSERT_EQ(1, rbtree.getNodeCount()); ASSERT_EQ(count1, tree2.getNodeCount()); // And content std::ostringstream out; rbtree.dumpTree(out); ASSERT_EQ(str2.str(), out.str()); out.str(""); tree2.dumpTree(out); ASSERT_EQ(str1.str(), out.str()); } // Matching in the "root zone" may be special (e.g. there's no parent, // any domain names should be considered a subdomain of it), so it makes // sense to test cases with the root zone explicitly. TEST_F(RBTreeTest, root) { RBTree root; root.insert(Name::ROOT_NAME(), &rbtnode); rbtnode->setData(RBNode::NodeDataPtr(new int(1))); EXPECT_EQ(RBTree::EXACTMATCH, root.find(Name::ROOT_NAME(), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); EXPECT_EQ(RBTree::PARTIALMATCH, root.find(Name("example.com"), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); // Insert a new name that better matches the query name. find() should // find the better one. root.insert(Name("com"), &rbtnode); rbtnode->setData(RBNode::NodeDataPtr(new int(2))); EXPECT_EQ(RBTree::PARTIALMATCH, root.find(Name("example.com"), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); // Perform the same tests for the tree that allows matching against empty // nodes. RBTree root_emptyok(true); root_emptyok.insert(Name::ROOT_NAME(), &rbtnode); EXPECT_EQ(RBTree::EXACTMATCH, root_emptyok.find(Name::ROOT_NAME(), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); EXPECT_EQ(RBTree::PARTIALMATCH, root_emptyok.find(Name("example.com"), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); root.insert(Name("com"), &rbtnode); EXPECT_EQ(RBTree::PARTIALMATCH, root.find(Name("example.com"), &crbtnode)); EXPECT_EQ(rbtnode, crbtnode); } }