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Нигде не могу найти нормальной реализации или хоть псевдокода Tango Tree, нашел одну более менее понятную реализацию, но она содержит ошибку в поиске. Например, при последовательности поиска 7, 5, 1, 10, 7 в дереве с ключами [1...15] получаю ошибку, что происходит обращение к объекту типа None. Еще бывали ошибки, что на последовательности ключей [0...15] после какой-то последовательности поиска, я входил в бесконечный цикл по разрезанию(cut) и склеиванию вершины 13. Если кто-то заметит ошибку - подскажите где, или где можно посмотреть правильную реализацию.

    def search(self, key):
    """
    Search for key in the tree.

    The search is only defined for accesses, i.e. keys that are actually
    in the tree.

    Returns:
        The reference p of a node with p.key == key.
    """

    # Start at the root.
    p = self.root

    # We do a normal BST walk.
    while True:
        if p.key < key:
            p = p.right
        elif p.key > key:
            p = p.left
        else:
            break #<------------------------------------------------------------------------------------------------------------
        #endif

        # If we visit a marked node we have to modifiy the preferred paths
        # 1 Cut auxiliary tree containing the parent of p at p.min_depth-1.
        #       into a top and a bottom path.
        # 2 Join the top path with auxiliary tree rooted at p.
        if p.is_root:
            depth = p.min_depth - 1
            p = p.parent

            p = self._cut(p, depth)

            # p is now the root of the top path.
            # Go down to the bottom path to join again.
            p = self._aux_search(key, p)
            # We are now at a leaf of the top path so go down one more.
            if p.key < key:
                p = p.right
            elif p.key > key:
                p = p.left
            else:
                raise Exception("??")
            #endif

            p = self._join(p)
        #endif
    #endwhile

    # The while loop has terminated so p.key == key.
    # If the searched node was a root we are now at the root again
    # so we make sure that p.key = key again
    # TODO Test if this breaks something again.
    # if p.key != key:
    #     p = self._aux_search(key, p)

    # Finally set the preferred child of the access p to left.
    # 1 cut its auxiliary tree at depth p.depth
    # 2 join with preceding marked node
    print("final cut&join")
    p = self._cut(p, p.depth)

    # Go down to node again.
    p = self._aux_search(key, p)

    # The paper says: "join the resulting top path with the auxiliary tree
    # rooted at the preceding marked node"
    #
    # So we try to find the predecessor of p.
    # Case 1: The predecessor is an ancestor of p, i.e. p has no
    #         left child (and we would go up).
    #   Then this predecessor is already included in the auxiliary tree,
    #   i.e. (*)
    #       - the preferred child of p in P is already set to left or
    #       - p has no children in P and the predecessor of p in P is also
    #         above
    # Case 2: p has a left child
    #   Find the first root on the way to predecessor.
    #   Case 2.1 if you find a root: join it
    #   Case 2.2 if not: (*)

    if p.left is None:
        # Case 1
        pass
    else:
        p = p.left

        # Go to predecessor but stop at a root.
        while not p.is_root and p.right is not None:
            p = p.right

        # The loop exited because:
        if p.is_root:
            # Case 2.1: p.is_root: join it.
            p = self._join(p)
        else:
            # Case 2.2: p.right is None: predecessor is already included.
            pass
        #endif
    #endif

    # Search for p again to return pointer/data
    p = self._aux_go_to_root(p)
    p = self._aux_search(key, p)
    print("Search: Found", p.key)
    return p
#end_search

def _aux_search(self, key, root):
    """
    Search key in the auxiliary tree with the given root.

    Returns:
        Either the node with the given key or
        the leaf where the search ends.
    """
    # Do an ordinary search until the next node would be a root or None.
    p = root
    while p.key != key:
        if p.key < key:
            if not is_root_or_None(p.right):
                p = p.right
            else:
                # print("\taux_search of {} in {} ended in leaf {}".format(
                #     key, root.key, p.key))
                # self.view(highlight_nodes=[p])
                return p
            #endif
        elif p.key > key:
            if not is_root_or_None(p.left):
                p = p.left
            else:
                # print("\taux_search of {} in {} ended in leaf {}".format(
                #     key, root.key, p.key))
                # self.view(highlight_nodes=[p])
                return p
            #endif
        #endif
    #endwhile
    # print("\taux_search of {} in {} successful".format(
    #     key, root.key))
    # self.view(highlight_nodes=[p])
    return p
#end_aux_search

def _aux_go_to_root(self, p):
    """
    Returns the root of the auxiliary tree containing p.
    """
    if p is None:
        return None

    while not p.is_root:
        p = p.parent
    # print("\tgoing up to", p.key)
    # self.view(highlight_nodes=[p])
    return p
#end_aux_go_to_root

def _aux_concatenate(self, p):
    """
    p is the root of a subtree t where both childs are roots of
    red-black trees:
        p
       / \
      T1 T2
    Modify t such that t is a red-black tree by doing
    concatenate(T1, p, T2).

    Returns:
        The (new) root of the concatenated tree.
    """
    # See also RBTree._concatenate().

    t1 = p.left     # just an alias for readability
    if t1 and t1.color == RED:
        t1.color = BLACK
        t1.bh += 1
    t2 = p.right    # just an alias for readability
    if t2 and t2.color == RED:
        t2.color = BLACK
        t2.bh += 1

    # To return the root after concatenation we want to save its parent's
    # key so we can go up to it after the rotations and the rb_fixup().
    parent_key = p.parent.key if p.parent else None

    # There are 4 cases: t1 and t2 can both exist or not.

    # Case 1: both subtrees are empty
    if is_root_or_None(t1) and is_root_or_None(t2):
        # There is nothing to do. Just restore the RB properties.
        root_key = p.key

        p.color = BLACK
        p.bh = 1

    # Case 2: t1 is empty (and t2 not)
    # p         t2
    #  \  -->  /_\
    #  t2     p
    elif is_root_or_None(t1):
        # Insert p into t2.
        # This can also be done simply by rotating it down.
        root_key = p.right.key

        while not is_root_or_None(p.right):
            p.right.rotate()

        # We set the color of p to RED as if it was inserted and invoke
        # insert_fixup() later.
        p.color = RED
        p.bh = 0

    # Case 3: t2 is empty (and t1 not) - symmetric to case 2
    #   p      t1
    #  /  ->  /_\
    # t1         p
    elif is_root_or_None(t2):
        root_key = p.left.key

        while not is_root_or_None(p.left):
            p.left.rotate()

        p.color = RED
        p.bh = 0

    # Case 4: t1 and t2 are present
        #   p
        #  / \
        # t1 t2
    # Case 4.1: t1 and t2 have equal black-height
    elif t1.bh == t2.bh:
        root_key = p.key

        p.color = BLACK
        p.bh = t1.bh + 1

    # Case 4.2: t1 has larger black-height
    elif t1.bh > t2.bh:
        # Make t2 part of t1
        # Rotate down the right path of t1 to search for the node
        # with equal blackheight as t2 (and maximum depth).
        # p.right is always t2.
        #   /\
        #  /  t (red)
        # /__/_\
        root_key = p.left.key

        p.color = RED
        p.bh = t2.bh
        while p.left.bh > t2.bh or p.left.color == RED:
            p.left.rotate()

    # Case 4.3: t2 has larger black-height - symmetric to case 4.2
    else:
        # symmetric to Case 4.2
        root_key = p.right.key

        p.color = RED
        p.bh = t1.bh
        while p.right.bh > t1.bh or p.right.color == RED:
            p.right.rotate()

    # fix RB properties
    if p.color == RED:
        p = TangoTree._insert_fixup(p)
        # p moves only up as it does if we go to root.

    # go up to (new) root
    if parent_key == None:
        # go to real root
        while p.parent:
            p = p.parent
    else:
        while p.parent.key != parent_key:
            p = p.parent

    # print("\tconcatenated")
    # self.view(highlight_nodes=[p])
    return p

def _insert_fixup(p):
    """
    Fix RB properties.

    Returns:
        The node where fixup stops.
    """
    while not p.is_root and p.parent.color == RED:
        # p.parent.parent exists because p.parent.color == RED
        if p.parent == p.parent.parent.left:
            y = p.parent.parent.right       # NOTE: y is just an alias
            if y and y.color == RED:
                #   gB           p=gR
                #  / \            / \
                # qR  yR  -->    qB  yB
                #  \              \
                # ..pR           ..R
                p.parent.color = BLACK
                p.parent.bh += 1
                y.color = BLACK
                y.bh += 1
                p.parent.parent.color = RED
                p = p.parent.parent
            else:
                #   gB             gB          pB
                #  / \            / \         / \
                # qR  yB  -->    pR  yB -->  qR  gR
                #  \            /                 \
                # ..pR         qR                  y
                if p == p.parent.right:
                    p.rotate()
                    p = p.left
                p.parent.color = BLACK
                p.parent.bh += 1
                p.parent.parent.color = RED
                p.parent.parent.bh -= 1
                p.parent.rotate()
        else:
            # analog left <-> right
            y = p.parent.parent.left
            if y and y.color == RED:
                p.parent.color = BLACK
                p.parent.bh += 1
                y.color = BLACK
                y.bh += 1
                p.parent.parent.color = RED
                p = p.parent.parent
            else:
                if p == p.parent.left:
                    p.rotate()
                    p = p.right
                p.parent.color = BLACK
                p.parent.bh += 1
                p.parent.parent.color = RED
                p.parent.parent.bh -= 1
                p.parent.rotate()

    # if not p.parent and p.color == RED:
    if p.is_root and p.color == RED:
        p.color = BLACK
        p.bh += 1

    return p

def _aux_split(self, p, root_key=None):
    """
    Reorder the auxiliary tree containing p such that p is at the root.

    You can also specify a root_key to mark the root of a subtree which is
    a red-black tree but not a auxiliary tree.

    Note: The resulting tree is not a red-black tree any more but
          p's children are.

    Note: The runtime is logarithmic (the runtimes of the concatenates
          add up nicely).

    Returns:
        The root p.
    """
    # See also RBTree.split()

    found_root_key = False
    if root_key is not None and p.key == root_key:
        return p

    while not p.is_root and not found_root_key:
        if root_key and p.parent.key == root_key:
            found_root_key = True

        if p == p.parent.left:
            #     pp           p
            #    /  \         / \
            #   p    R'  ->  L   pp
            #  / \              / \
            # L   R            R   R'
            p.rotate()
            p = self._aux_concatenate(p.right)
        else:
            p.rotate()
            p = self._aux_concatenate(p.left)

        p = p.parent

    # print("\tsplit")
    # self.view(highlight_nodes=[p])
    return p

def _cut(self, p, d):
    """
    Cut the auxiliary tree containing p into two auxiliary trees, one
    containing all nodes with depth <= d and one with depths > d.

    Returns:
        The root of the top path.
    """
    # TODO explain cutting
    print("Cut at", p.key, "depth", d)
    p = self._aux_go_to_root(p)

    # l .. smalles node with depth > d
    #      found by walking left while max_depth > d
    # r .. biggest node with depth > d
    #      found by walking right while max_depth > d
    # l_pre .. predecessor of l
    # r_suc .. successor of r

    if p.max_depth <= d:
        # There is no l and no r, i.e. the interval is empty
        # we can return
        return p

    # Find l.
    #  - if there is a left child and its max_depth is > d:
    #       go left
    #  - if there is no left child and the current node has depth > d:
    #       return this node
    #  - if there is no left child and the current node has depth <= d:
    #       go right (this right child has to have max_depth > d)
    while True:
        if not is_root_or_None(p.left) and p.left.max_depth > d:
            # we can go left
            p = p.left

        # The following two cases can be combined when the case above is
        # already covered:
        # elif is_root_or_None(p.left) and p.depth > d:
            # can not go left and node has desired depth -> found it
        # elif (not is_root_or_None(p.left) and p.left.max_depth <= d
        #       and p.depth > d):
            # this is the minimal node with depth > d,
            # all smaller nodes have depth <= d

        # The minimal node is found.
        elif p.depth > d:
            break

        # We may have to go right if p.depth <= d and left is nothing.
        elif p.depth <= d and (
                (not is_root_or_None(p.left) and p.left.max_depth <= d) or
                is_root_or_None(p.left)):
            p = p.right
        else:
            raise Exception('ERROR: Case not covered')

    # Find predecessor of l.
    p, l_pre_exists = self._find_predecessor(p)

    # To find the node where to concatenate we also save the key.
    l_pre_key = p.key if l_pre_exists else None

    # Split if predecessor exists.
    if l_pre_exists:
        # Do splitting. Result:
        p = self._aux_split(p)
        subtree_root_key = p.right.key if p.right else None
        # Result:
        #   l_pre = p
        #    / \
        #   /   *.key == subtree_root_key
        #  /\   /\
        # /B \ /C \  <-  r may be in C.
        # ---- ----
    else:
        # Go back to root.
        p = self._aux_go_to_root(p)
        subtree_root_key = p.key
        # Result:
        #   p.key = subtree_root_key
        #  / \
        # / C \  <-  r may be in C.
        # -----

    # Find r (symmetric to finding l).
    while True:
        if not is_root_or_None(p.right) and p.right.max_depth > d:
            p = p.right

        # The minimal node is found.
        elif p.depth > d:
            break

        # We may have to go left if p.depth <= d and right is nothing.
        elif p.depth <= d and (
                (not is_root_or_None(p.right) and p.right.max_depth <= d) or
                is_root_or_None(p.right)):
            p = p.left
        else:
            raise Exception('ERROR: Case not covered')

    # Find successor of r.
    p, r_suc_exists = self._find_successor(p)

    # Split if Successor exists.
    if r_suc_exists:
        p = self._aux_split(p, subtree_root_key)

        # Result
        #       l_pre
        #      / \
        #     /   r_suc = p
        #    /\    /  \
        #   /B \  /\  /\
        #   ---- /D \/E \
        #        --------
        p = p.left

    # else:
    # l_pre
    #   \
    #   /\
    #  /D \
    #  ----

    # Mark root of D as new auxiliary tree.
    self._aux_set_root_mark(p, True)

    if r_suc_exists:
        p = p.parent
        p = self._aux_concatenate(p)

    if l_pre_exists:
        # Go back up to node with key l_pre_key.
        while p.key != l_pre_key:
            p = p.parent
        p = self._aux_concatenate(p)

    print("\tCut end.")
    self.view(highlight_nodes=[p])

    return p

def _aux_split_l(self, p, l_pre):
    """
    Split at l_pre if present where l_pre is either p or None

    Case 1: l_pre is not None
        Do splitting. Result:

            l_pre = p
             / \
            /   *.key == subtree_root_key
           /\   /\
          /B \ /Cr\
          ---- ----

    Case 2: l_pre is None
        No splitting.

            p.key = subtree_root_key
           / \
          /Cr \
          -----

    Returns:
        p, subtree_root_key
    """
    if l_pre is not None:
        p = self._aux_split(l_pre)
        print("Split l")
        self.view(highlight_nodes=[p])
        # we need to mark the right child as root since we want to
        # use split later
        #
        # TODO how to use split on right subtree properly
        #   1 specify pseudo root
        #   2 temporary mark right child as root

        # proper splitting
        subtree_root_key = p.right.key if p.right else None
    else:
        p = self._aux_go_to_root(p)
        print("l_pre is None: no left split")
        self.view(highlight_nodes=[p])
        subtree_root_key = p.key
    return (p, subtree_root_key)

def _aux_split_r(self, p, r_suc, subtree_root_key):
    """
    TODO ? Split at r_suc where r_suc is either p or None.

    Returns:
        p
    """
    if r_suc is not None:
        p = self._aux_split(r_suc, subtree_root_key)
        print("Split r")
        self.view(highlight_nodes=[p])
        # Result
        #       l_pre
        #      / \
        #     /   r_suc = p
        #    /\    /  \
        #   /B \  /\  /\
        #   ---- /D \/E \
        #        --------
        p = p.left      # TODO check None
        print("Interval splitted")
        self.view(highlight_nodes=[p])
        return p
    else:
        # l_pre
        #   \
        #   /\
        #  /D \
        #  ----
        p = p.right
        print("Interval splitted (else)")
        #self.view(highlight_nodes=[p])#??????????????????????????????????????????????????????????????????????????????????????
        return p

def _join(self, p):
    """
    Join the auxiliary tree t containing p with the auxiliary tree
    containing the parent of the root of t.

    Returns:
        The root of the joined auxiliary tree.
    """

    print("Join at", p.key)
    #self.view(highlight_nodes=[p])#???????????????????????????????????????????????????????????????????????????????????????????

    # Normalize p. We are now at the root of an bottom path.
    p = self._aux_go_to_root(p)

    # Save the root of the bottom to find its predecessor/successor
    # in top path.
    root_key = p.key

    # Go up to the top path.
    p = p.parent

    # If we search this auxiliary tree for root_key we find
    # l_pre < root_key < r_suc (l_pre or r_suc may be None).

    # Case 1: Found l_pre.
    #  p = l_pre
    #   \
    #   root
    if p.key < root_key:
        l_pre_key = p.key

        p = self._aux_split(p)
        subtree_root_key = p.right.key if p.right else None

        p, r_suc_exists = self._find_successor(p)

        if r_suc_exists:
            p = self._aux_split(p, subtree_root_key)
            p = p.left
        else:
            p = p.right

        # Unmark instead of mark as in split.
        p = self._aux_set_root_mark(p, False)

        # Concatenate right if present.
        if r_suc_exists:
            p = p.parent
            p = self._aux_concatenate(p)

        # Concatenate left.
        while p.key != l_pre_key:
            p = p.parent
        p = self._aux_concatenate(p)

    # Case 2: Found r_suc (symmetric to case 1).
    #   p = r_suc
    #  /
    # root
    else:
        r_suc_key = p.key

        p = self._aux_split(p)
        subtree_root_key = p.left.key if p.left else None

        p, l_pre_exists = self._find_predecessor(p)

        if l_pre_exists:
            p = self._aux_split(p, subtree_root_key)
            p = p.right
        else:
            p = p.left

        # Unmark instead of mark as in split.
        p = self._aux_set_root_mark(p, False)

        # Concatenate left if present.
        if l_pre_exists:
            p = p.parent
            p = self._aux_concatenate(p)

        # Concatenate right.
        while p.key != r_suc_key:
            p = p.parent
        p = self._aux_concatenate(p)

    print("\tJoin end.")
    self.view(highlight_nodes=[p])

    return p

def _aux_set_root_mark(self, p, mark):
    """
    Set p.is_root to mark and updates min_depth and max_depth of ancestors.

    Returns:
        p
    """
    p.is_root = mark
    # This adds or removes nodes from the subtree p.parents auxiliary tree
    # so we have to update all recursively defined attributes.
    if p.parent:
        # save the key to go back to it
        p_key = p.key

        # update the depths
        p = p.parent
        p = self._aux_update_depths(p)

        # go back
        if p.key > p_key:
            p = p.left
        else:
            p = p.right


    print("\tSet root to", mark)
    self.view(highlight_nodes=[p])

    return p

def _aux_update_depths(self, p):
    """
    Update the min_depth and max_depth of p and its ancestors in auxiliary
    tree.

    This is be needed if you mark or unmark a node thus changing an
    auxiliary tree.

    Returns:
        The argument p.
    """
    p._update_depths()
    p_key = p.key

    while not p.is_root:
        p = p.parent
        p._update_depths()

    # go down to the saved key again
    p = self._aux_search(p_key, p)

    return p

# The methods _find_predecessor(self, p) and _find_successor(self, p)
# do not return p.
def _find_predecessor(self, p):
    """
    Returns the predecessor of a node in an auxiliary tree if it exists,
    otherwise p itself.

    Returns:
        (pred, True) if pred is the predecessor of p, otherwise
        (p, False) if there is no predecessor.
    """
    # Case 1: left subtree is not empty
    #   the maximum node of the left subtree is the predecessor
    if not is_root_or_None(p.left):
        # if left child exists go left and then all the way right
        p = p.left
        while not is_root_or_None(p.right):
            p = p.right
        return p, True

    # Case 2: left subtree is empty
    #   go up until we come from a right child
    #   this parent is the predecessor
    # Case 3: no parent (and left subtree) exists
    #   there is no predecessor
    p_key = p.key
    while True:
        if p.is_root:
            # Case 3: no predecessor
            # We have to go back to p
            p = self._aux_search(p_key, p)
            return p, False
        if p == p.parent.right:
            return p.parent, True
        else:
            p = p.parent    # go up

def _find_successor(self, p):
    """
    Returns the successor of a node in an auxiliary tree if it exists,
    otherwise p itself.

    Returns:
        (succ, True) if succ is the successor of p, otherwise
        (p, False) if there is no successor.
    """
    # This is symmetric with _find_predecessor swapping left and right.

    # Case 1: right subtree is not empty
    #   the maximum node of the right subtree is the successor
    if not is_root_or_None(p.right):
        # if right child exists go right and then all the way left
        p = p.right
        while not is_root_or_None(p.left):
            p = p.left
        return p, True

    # Case 2: right subtree is empty
    #   go up until we come from a left child
    #   this parent is the successor
    # Case 3: no parent (and right subtree) exists
    #   there is no successor
    p_key = p.key
    while True:
        if p.is_root:
            # Case 3: no successor
            # We have to go back to p
            p = self._aux_search(p_key, p)
            return p, False
        if p == p.parent.left:
            return p.parent, True
        else:
            p = p.parent    # go up

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