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datatypes: add a binary search tree implementation (#13453)

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Vincenzo Palazzo 2022-02-22 09:28:01 +01:00 committed by GitHub
parent 4a765bc33b
commit 7bd8503170
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3 changed files with 460 additions and 0 deletions

28
examples/bst_map.v Normal file
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import datatypes
struct KeyVal {
mut:
key int
val int
}
fn (a KeyVal) == (b KeyVal) bool {
return a.key == b.key
}
fn (a KeyVal) < (b KeyVal) bool {
return a.key < b.key
}
fn main() {
mut bst := datatypes.BSTree<KeyVal>{}
bst.insert(KeyVal{ key: 1, val: 12 })
println(bst.in_order_traversal())
bst.insert(KeyVal{ key: 2, val: 34 })
bst.insert(KeyVal{ key: -2, val: 203 })
for elem in bst.in_order_traversal() {
println(elem.val)
}
}

296
vlib/datatypes/bstree.v Normal file
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module datatypes
/// Internal rapresentation of the tree node
[heap]
struct BSTreeNode<T> {
mut:
// Mark a node as initialized
is_init bool
// Value of the node
value T
// The parent of the node
parent &BSTreeNode<T> = 0
// The left side with value less than the
// value of this node
left &BSTreeNode<T> = 0
// The right side with value grater than the
// value of thiss node
right &BSTreeNode<T> = 0
}
// Create new root bst node
fn new_root_node<T>(value T) &BSTreeNode<T> {
return &BSTreeNode<T>{
is_init: true
value: value
parent: new_none_node<T>(true)
left: new_none_node<T>(false)
right: new_none_node<T>(false)
}
}
// new_node creates a new bst node with a parent reference.
fn new_node<T>(parent &BSTreeNode<T>, value T) &BSTreeNode<T> {
return &BSTreeNode<T>{
is_init: true
value: value
parent: parent
}
}
// new_none_node creates a dummy node.
fn new_none_node<T>(init bool) &BSTreeNode<T> {
return &BSTreeNode<T>{
is_init: false
}
}
// bind to an actual instance of a node.
fn (mut node BSTreeNode<T>) bind(mut to_bind BSTreeNode<T>, left bool) {
node.left = to_bind.left
node.right = to_bind.right
node.value = to_bind.value
node.is_init = to_bind.is_init
to_bind = new_none_node<T>(false)
}
// Pure Binary Seach Tree implementation
//
// Pure V implementation of the Binary Search Tree
// Time complexity of main operation O(log N)
// Space complexity O(N)
pub struct BSTree<T> {
mut:
root &BSTreeNode<T> = 0
}
// insert give the possibility to insert an element in the BST.
pub fn (mut bst BSTree<T>) insert(value T) bool {
if bst.is_empty() {
bst.root = new_root_node(value)
return true
}
return bst.insert_helper(mut bst.root, value)
}
// insert_helper walks the tree and inserts the given node.
fn (mut bst BSTree<T>) insert_helper(mut node BSTreeNode<T>, value T) bool {
if node.value < value {
if node.right != 0 && node.right.is_init {
return bst.insert_helper(mut node.right, value)
}
node.right = new_node(node, value)
return true
} else if node.value > value {
if node.left != 0 && node.left.is_init {
return bst.insert_helper(mut node.left, value)
}
node.left = new_node(node, value)
return true
}
return false
}
// contains checks if an element with a given `value` is inside the BST.
pub fn (bst &BSTree<T>) contains(value T) bool {
return bst.contains_helper(bst.root, value)
}
// contains_helper is a helper function to walk the tree, and return
// the absence or presence of the `value`.
fn (bst &BSTree<T>) contains_helper(node &BSTreeNode<T>, value T) bool {
if node == 0 || !node.is_init {
return false
}
if node.value < value {
return bst.contains_helper(node.right, value)
} else if node.value > value {
return bst.contains_helper(node.left, value)
}
assert node.value == value
return true
}
// remove removes an element with `value` from the BST.
pub fn (mut bst BSTree<T>) remove(value T) bool {
if bst.root == 0 {
return false
}
return bst.remove_helper(mut bst.root, value, false)
}
fn (mut bst BSTree<T>) remove_helper(mut node BSTreeNode<T>, value T, left bool) bool {
if !node.is_init {
return false
}
if node.value == value {
if node.left != 0 && node.left.is_init {
// In order to remove the element we need to bring up as parent the max of the
// left sub-tree.
mut max_node := bst.get_max_from_right(node.left)
node.bind(mut max_node, true)
} else if node.right != 0 && node.right.is_init {
// Bring up the element with the minimum value in the right sub-tree.
mut min_node := bst.get_min_from_left(node.right)
node.bind(mut min_node, false)
} else {
mut parent := node.parent
if left {
parent.left = new_none_node<T>(false)
} else {
parent.right = new_none_node<T>(false)
}
node = new_none_node<T>(false)
}
return true
}
if node.value < value {
return bst.remove_helper(mut node.right, value, false)
}
return bst.remove_helper(mut node.left, value, true)
}
// get_max_from_right returns the max element of the BST following the right branch.
fn (bst &BSTree<T>) get_max_from_right(node &BSTreeNode<T>) &BSTreeNode<T> {
right_node := node.right
if right_node == 0 || !right_node.is_init {
return node
}
return bst.get_max_from_right(right_node)
}
// get_min_from_left returns the min element of the BST by following the left branch.
fn (bst &BSTree<T>) get_min_from_left(node &BSTreeNode<T>) &BSTreeNode<T> {
left_node := node.left
if left_node == 0 || !left_node.is_init {
return node
}
return bst.get_min_from_left(left_node)
}
// is_empty checks if the BST is empty
pub fn (bst &BSTree<T>) is_empty() bool {
return bst.root == 0
}
// in_order_traversal traverses the BST in order, and returns the result as an array.
pub fn (bst &BSTree<T>) in_order_traversal() []T {
mut result := []T{}
bst.in_order_traversal_helper(bst.root, mut result)
return result
}
// in_order_traversal_helper helps traverse the BST, and accumulates the result in the `result` array.
fn (bst &BSTree<T>) in_order_traversal_helper(node &BSTreeNode<T>, mut result []T) {
if node == 0 || !node.is_init {
return
}
bst.in_order_traversal_helper(node.left, mut result)
result << node.value
bst.in_order_traversal_helper(node.right, mut result)
}
// post_order_traversal traverses the BST in post order, and returns the result in an array.
pub fn (bst &BSTree<T>) post_order_traversal() []T {
mut result := []T{}
bst.post_order_traversal_helper(bst.root, mut result)
return result
}
// post_order_traversal_helper is a helper function that traverses the BST in post order,
// accumulating the result in an array.
fn (bst &BSTree<T>) post_order_traversal_helper(node &BSTreeNode<T>, mut result []T) {
if node == 0 || !node.is_init {
return
}
bst.post_order_traversal_helper(node.left, mut result)
bst.post_order_traversal_helper(node.right, mut result)
result << node.value
}
// pre_order_traversal traverses the BST in pre order, and returns the result as an array.
pub fn (bst &BSTree<T>) pre_order_traversal() []T {
mut result := []T{}
bst.pre_order_traversal_helper(bst.root, mut result)
return result
}
// pre_order_traversal_helper is a helper function to traverse the BST
// in pre order and accumulates the results in an array.
fn (bst &BSTree<T>) pre_order_traversal_helper(node &BSTreeNode<T>, mut result []T) {
if node == 0 || !node.is_init {
return
}
result << node.value
bst.pre_order_traversal_helper(node.left, mut result)
bst.pre_order_traversal_helper(node.right, mut result)
}
// get_node is a helper method to ge the internal rapresentation of the node with the `value`.
fn (bst &BSTree<T>) get_node(node &BSTreeNode<T>, value T) &BSTreeNode<T> {
if node == 0 || !node.is_init {
return new_none_node<T>(false)
}
if node.value == value {
return node
}
if node.value < value {
return bst.get_node(node.right, value)
}
return bst.get_node(node.left, value)
}
// to_left returns the value of the node to the left of the node with `value` specified if it exists,
// otherwise the a false value is returned.
//
// An example of usage can be the following one
//```v
// left_value, exist := bst.to_left(10)
//```
pub fn (bst &BSTree<T>) to_left(value T) ?T {
node := bst.get_node(bst.root, value)
if !node.is_init {
return none
}
left_node := node.left
return left_node.value
}
// to_right return the value of the element to the right of the node with `value` specified, if exist
// otherwise, the boolean value is false
// An example of usage can be the following one
//
//```v
// left_value, exist := bst.to_right(10)
//```
pub fn (bst &BSTree<T>) to_right(value T) ?T {
node := bst.get_node(bst.root, value)
if !node.is_init {
return none
}
right_node := node.right
return right_node.value
}
// max return the max element inside the BST.
// Time complexity O(N) if the BST is not balanced
pub fn (bst &BSTree<T>) max() ?T {
max := bst.get_max_from_right(bst.root)
if !max.is_init {
return none
}
return max.value
}
// min return the minimum element in the BST.
// Time complexity O(N) if the BST is not balanced.
pub fn (bst &BSTree<T>) min() ?T {
min := bst.get_min_from_left(bst.root)
if !min.is_init {
return none
}
return min.value
}

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module datatypes
// Make an insert of one element and check if
// the bst is able to fin it.
fn test_insert_into_bst_one() {
mut bst := BSTree<int>{}
assert bst.insert(10) == true
assert bst.contains(10) == true
assert bst.contains(20) == false
}
// Make the insert of more element inside the BST
// and check if the BST is able to find all the values
fn test_insert_into_bst_two() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(9)
assert bst.contains(9)
assert bst.contains(10)
assert bst.contains(20)
assert bst.contains(11) == false
}
// Test if the in_order_traversals list return the correct
// result array
fn test_in_order_bst_visit_one() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
assert bst.in_order_traversal() == [1, 10, 20, 21]
}
// Test if the post_order_bst_visit return the correct
// result array
fn test_post_order_bst_visit_one() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
assert bst.post_order_traversal() == [1, 21, 20, 10]
}
// Test if the pre_order_traversal return the correct result array
fn test_pre_order_bst_visit_one() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
assert bst.pre_order_traversal() == [10, 1, 20, 21]
}
// After many insert check if we are abe to get the correct
// right and left value of the root.
fn test_get_left_root() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
left_val := bst.to_left(10) or { -1 }
assert left_val == 1
right_val := bst.to_right(10) or { -1 }
assert right_val == 20
}
// Check if BST panic if we call some operation on an empty BST.
fn test_get_left_on_empty_bst() {
mut bst := BSTree<int>{}
left_val := bst.to_left(10) or { -1 }
assert left_val == -1
right_val := bst.to_right(10) or { -1 }
assert right_val == -1
}
// Check the remove operation if it is able to remove
// all elements required, and mantains the BST propriety.
fn test_remove_from_bst_one() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
assert bst.in_order_traversal() == [1, 10, 20, 21]
assert bst.remove(21)
assert bst.in_order_traversal() == [1, 10, 20]
}
// Another test n the remove BST, this remove an intermidia node
// that it is a triky operation.
fn test_remove_from_bst_two() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
assert bst.in_order_traversal() == [1, 10, 20, 21]
assert bst.remove(20)
assert bst.in_order_traversal() == [1, 10, 21]
}
// check if we are able to get the max from the BST.
fn test_get_max_in_bst() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
max := bst.max() or { -1 }
assert max == 21
}
// check if we are able to get the min from the BST.
fn test_get_min_in_bst() {
mut bst := BSTree<int>{}
assert bst.insert(10)
assert bst.insert(20)
assert bst.insert(21)
assert bst.insert(1)
min := bst.min() or { -1 }
assert min == 1
}