Consider a binary search tree, where all keys are unique. Nodes haven't parent pointers.
We have up to n/2 marked nodes.
I can delete all of them at O(n^2) time ( using postorder traversal and when encounter a marked node delete each at O(n)). But it is inappropriate.
I need an algorithm to delete all marked nodes at O(n) time.
Thanks.
EDIT After deletion i need to have nodes order unchanged.
EDIT2 So it should look like I have deleted each marked node using the typical deletion (finding the rightmost node at the left subtree and exchanging it with the node to delete).



There are many ways, but here is one that should be easy to get right, and give you a perfectly balanced tree as a side effect. It requires linear extra space, however.
Update: forgot to say skipping the marked elements, but that was obvious, right? ;) 


I have found how to do it!



I don't see why a postorder traversal would be O(n^{2}). The reason that deleting a single node is O(n) is that you need to traverse the tree to find the node, which is an O(n) operation. But once you find a node, it can be deleted in O(1) time.^{*} Thus, you can delete all O(n) marked nodes in a single traversal in O(n) time. ^{*} Unless you need to maintain a balanced tree. However, you don't list that as a requirement. EDIT As @njlarsson correctly points out in his comment, a delete operation is not normally O(1) even after the node is found. However, since the left and right subtrees are being traversed before visiting a node to be deleted, the minimum (or maximum) elements of the subtrees can be obtained at no additional cost during the subtree traversals. This enables an O(1) deletion. 

