def loop_main(temp): temp = re.sub('#.*', "", temp) temp = re.sub('//.*', "", temp) if len(temp) == 0: return flds = temp.replace("\"","").replace("[","").replace("]","").rstrip() ope_t = OperateTreeNode() codec = Codec2() if len(flds) > 0: root = codec.deserialize(flds) # root = ope_t.createTreeNode(flds) else: root = None print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) time0 = time.time() root = codec.deserialize(flds) result = codec.serialize(root) time1 = time.time() print("result = [{0}]".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): temp = re.sub('#.*', "", temp) temp = re.sub('//.*', "", temp) if len(temp) == 0: return flds = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip().split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) k = int(flds[1]) print("k = {0:d}".format(k)) sl = Solution() time0 = time.time() result = sl.kthSmallest(root, k) time1 = time.time() print("result = {0:d}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"","").replace("[","").replace("]","").rstrip() n = int(flds) print("n = {0:d}".format(n)) sl = Solution() time0 = time.time() result = sl.allPossibleFBT(n) time1 = time.time() cd = Codec() print("result = [") for i, node in enumerate(result): if i == 0: print(" [{0}]".format(cd.serialize(node))) else: print(",[{0}]".format(cd.serialize(node))) print("]") ope_t = OperateTreeNode() for i, node in enumerate(result): print("result[{0:d}] = \n{1}".format(i, ope_t.treeToStaircaseString(node))) print() for i, node in enumerate(result): print("result[{0:d}] = {1}".format(i, ope_t.tree2str(node))) print() print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[", "").replace("]", "").rstrip() nums = [int(n) for n in flds.split(",")] print("nums = {0}".format(nums)) sl = Solution() time0 = time.time() result = sl.sortedArrayToBST(nums) time1 = time.time() ope_t = OperateTreeNode() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"","").replace("[","").replace("]","").rstrip() ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) sl = Solution() time0 = time.time() result = sl.diameterOfBinaryTree(root) time1 = time.time() print("result = {0}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): n = int(temp.replace("[", "").replace("]", "").rstrip()) print("num = {0:d}".format(n)) sl = Solution() time0 = time.time() result = sl.generateTrees(n) time1 = time.time() ope_t = OperateTreeNode() for i, res in enumerate(result): print("result[{0:d}] = \n{1}".format( i, ope_t.treeToStaircaseString(result[i]))) print("result[{0:d}] = {1}".format(i, ope_t.tree2str(result[i]))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[", "").replace("]", "").rstrip() preorder = [int(fld) for fld in flds.split(",")] print("preorder = {0}".format(preorder)) sl = Solution() time0 = time.time() result = sl.bstFromPreorder(preorder) time1 = time.time() ope_t = OperateTreeNode() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip().split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) target = int(flds[1]) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) print("target = {0:d}\n".format(target)) sl = Solution() time0 = time.time() result = sl.removeLeafNodes(root, target) time1 = time.time() cd = Codec() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("result = [{0}]".format(cd.serialize(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip().split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) L = int(flds[1]) R = int(flds[2]) print("L = {0:d}, R = {1:d}".format(L, R)) sl = Solution() time0 = time.time() result = sl.trimBST(root, L, R) time1 = time.time() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip().split("],[") preorder = [int(n) for n in flds[0].split(",")] inorder = [int(n) for n in flds[1].split(",")] print("preorder = {0}, inorder = {1}".format(preorder, inorder)) sl = Solution() time0 = time.time() result = sl.buildTree(preorder, inorder) time1 = time.time() ope_t = OperateTreeNode() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): temp = re.sub('#.*', "", temp) temp = re.sub('//.*', "", temp) if len(temp) == 0: return flds = temp.replace("\"", "").replace("[", "").replace("]", "").rstrip() ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) sl = Solution() time0 = time.time() result = sl.postorderTraversal(root) time1 = time.time() print("result = {0}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[", "").replace("]", "").rstrip() ope_t = OperateTreeNode() if len(flds) > 0: root = ope_t.createTreeNode(flds) else: root = None print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) sl = Solution() time0 = time.time() result = sl.levelOrderBottom(root) time1 = time.time() print("result = {0}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace(", ", ",").rstrip().split("],[[[") cmds = flds[0].replace("[[", "").split(",") node_flds = (flds[1].split("]],["))[0] ope_t = OperateTreeNode() if len(node_flds) > 0: mynode = ope_t.createTreeNode(node_flds) else: mynode = None print("mynode = \n[{0}]".format(ope_t.treeToStaircaseString(mynode))) sl = Solution() time0 = time.time() sl.main(cmds, mynode) time1 = time.time() print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): str_args = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip() flds = str_args.split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) sum = int(flds[1].replace("sum = ", "")) print("sum = {0:d}".format(sum)) sl = Solution() time0 = time.time() result = sl.pathSum(root, sum) print("result = {0:d}".format(result)) time1 = time.time() print("result = {0:d}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): str_args = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip() flds = str_args.split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) p = set_target_node(root, int(flds[1])) q = set_target_node(root, int(flds[2])) print("p = {0}, q = {1}".format(ope_t.tree2str(p), ope_t.tree2str(q))) sl = Solution() time0 = time.time() result = sl.lowestCommonAncestor(root, p, q) time1 = time.time() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}\n".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): str_args = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip() flds = str_args.split("],[") ope_t = OperateTreeNode() t1 = ope_t.createTreeNode(flds[0]) t2 = ope_t.createTreeNode(flds[1]) print("t1 = \n{0}".format(ope_t.treeToStaircaseString(t1))) print("t1 = {0}".format(ope_t.tree2str(t1))) print("t2 = \n{0}".format(ope_t.treeToStaircaseString(t2))) print("t2 = {0}".format(ope_t.tree2str(t2))) sl = Solution() time0 = time.time() result = sl.mergeTrees(t1, t2) time1 = time.time() print("result = \n{0}".format(ope_t.treeToStaircaseString(result))) print("result = {0}".format(ope_t.tree2str(result))) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"","").replace("[","").replace("]","").rstrip() ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds) print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) sl = Solution() time0 = time.time() result = sl.findDuplicateSubtrees(root) time1 = time.time() ope_t = OperateTreeNode() print("result = [", end = "") for i, node in enumerate(result): if i == 0: print(" [{0}]".format(ope_t.tree2str(node)), end = "") else: print(" ,[{0}]".format(ope_t.tree2str(node)), end = "") print(" ]") print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): str_args = temp.replace("\"","").replace("[[","").replace("]]","").rstrip() flds = str_args.split("],[") ope_t = OperateTreeNode() s = ope_t.createTreeNode(flds[0]) print("s = \n{0}".format(ope_t.treeToStaircaseString(s))) print("s = {0}".format(ope_t.tree2str(s))) t = ope_t.createTreeNode(flds[1]) print("t = \n{0}".format(ope_t.treeToStaircaseString(t))) print("t = {0}".format(ope_t.tree2str(t))) sl = Solution() time0 = time.time() result = sl.isSubtree(s, t) time1 = time.time() print("result = {0}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"","").replace("[[","").replace("]]","").rstrip().split("],[") ope_t = OperateTreeNode() root1 = ope_t.createTreeNode(flds[0]) print("root1 = \n{0}".format(ope_t.treeToStaircaseString(root1))) print("root1 = {0}".format(ope_t.tree2str(root1))) root2 = ope_t.createTreeNode(flds[1]) print("root2 = \n{0}".format(ope_t.treeToStaircaseString(root2))) print("root2 = {0}".format(ope_t.tree2str(root2))) sl = Solution() time0 = time.time() result = sl.leafSimilar(root1, root2) time1 = time.time() print("result = {0}".format(result)) print("Execute time ... : {0:f}[s]\n".format(time1 - time0))
def loop_main(temp): flds = temp.replace("\"", "").replace("[[", "").replace("]]", "").rstrip().split("],[") ope_t = OperateTreeNode() root = ope_t.createTreeNode(flds[0]) to_delete = [int(n) for n in flds[1].split(",")] print("root = \n{0}".format(ope_t.treeToStaircaseString(root))) print("root = {0}".format(ope_t.tree2str(root))) print("to_detele = {0}\n".format(to_delete)) sl = Solution() time0 = time.time() result = sl.delNodes(root, to_delete) time1 = time.time() cd = Codec() for i, node in enumerate(result): if i == 0: print("result = [[{0}]".format(cd.serialize(node)), end="") else: print(",[{0}]".format(cd.serialize(node)), end="") print("]\n") for i, node in enumerate(result): print("result[{0:d}] = \n{1}".format( i, ope_t.treeToStaircaseString(node))) print() for i, node in enumerate(result): print("result[{0:d}] = {1}".format(i, ope_t.tree2str(node))) print() print("Execute time ... : {0:f}[s]\n".format(time1 - time0))