btree: add basic in memory b-tree with integers

2019-07-30 17:26:36 +02:00 · 2019-07-30 17:26:36 +02:00 · 33657122f9
commit 33657122f9
parent 4f361f7d55
4 changed files with 670 additions and 0 deletions
--- a/.drone.yml
+++ b/.drone.yml
@ -0,0 +1,13 @@
 pipeline:
    build:
        image: golang:1.12
        group: build
        commands:
            - go get -v -d ./...
            - go build .
    test:
        image: golang:1.12
        group: test
        commands:
            - go get -v -d ./...
            - go test -v ./...
--- a/btree/btree.go
+++ b/btree/btree.go
@ -0,0 +1,498 @@
 package btree
 import (
 	"fmt"
 )
 // Tree is the tree itself
 type Tree struct {
 	root *Node // Pointer to the Node root
 	t    int   // Minimum degree
 }
 // Node is a Node of a Btree
 type Node struct {
 	numberOfKeys int // The number of keys really stored
 	t            int // The value of t dependes upon disk blok size
 	isLeaf       bool
 	keys         []int
 	children     []*Node
 }
 // Constructors
 // NewBtree creates a new btree
 func NewBtree(t int) *Tree {
 	return &Tree{
 		root: nil,
 		t:    t,
 	}
 }
 func newNode(t int, isLeaf bool) *Node {
 	return &Node{
 		numberOfKeys: 0,
 		t:            t,
 		isLeaf:       isLeaf,
 		keys:         make([]int, 2*t-1),
 		children:     make([]*Node, 2*t),
 	}
 }
 // Tree methods
 // Traverse the tree
 func (t *Tree) Traverse() {
 	if t.root != nil {
 		t.root.traverse()
 	}
 }
 // Search k in the tree
 func (t *Tree) Search(k int) *Node {
 	if t.root == nil {
 		return nil
 	}
 	return t.root.search(k)
 }
 // Remove k in the tree
 func (t *Tree) Remove(k int) error {
 	if t.root == nil {
 		return fmt.Errorf("The tree is empty")
 	}
 	err := t.root.remove(k)
 	// If the root node has 0 keys, makes its first child as the new root
 	// If it has no child, set root as nil
 	if t.root.numberOfKeys == 0 {
 		if t.root.isLeaf {
 			t.root = nil
 			return err
 		}
 		t.root = t.root.children[0]
 	}
 	return err
 }
 // Insert k in the tree
 func (t *Tree) Insert(k int) {
 	// If the tree is empty
 	if t.root == nil {
 		t.root = newNode(t.t, true)
 		t.root.keys[0] = k
 		t.root.numberOfKeys = 1
 		return
 	}
 	// If the tree is not empty
 	if !t.root.isFull() {
 		// If root is not full, insert in non full root
 		t.root.insertNonFull(k)
 		return
 	}
 	// If the root is full, then the tree grows in height
 	s := newNode(t.t, false)
 	// Make the old root as a child of the new root
 	s.children[0] = t.root
 	// Split the old root and move 1 key to the new root
 	s.splitChild(0, t.root)
 	// The new root has two children now.
 	// We decide which of the two children is going to have the new key
 	i := 0
 	if s.keys[0] < k {
 		i++
 	}
 	s.children[i].insertNonFull(k)
 	// Change root
 	t.root = s
 }
 // Node methods
 // traverse all nodes in a subtree rooted with this node
 func (n *Node) traverse() {
 	// There are n entries and n+1 children, treverse trough n keys and n first children
 	for i := 0; i < n.numberOfKeys; i++ {
 		// If this is not a leaf, then traverse the subtree before printing the key
 		if !n.isLeaf {
 			n.children[i].traverse()
 		}
 		fmt.Printf(" %d", n.keys[i])
 	}
 	// Print the subtree rooted with the last child
 	if !n.isLeaf {
 		n.children[n.numberOfKeys].traverse()
 	}
 }
 // search k in the subtree rooted with this node
 func (n *Node) search(k int) *Node {
 	// Find the first entry greater than or equal to k
 	i := 0
 	for i < n.numberOfKeys && k > n.keys[i] {
 		i++
 	}
 	// If theh found key is equal to  k, return this node
 	if n.keys[i] == k {
 		return n
 	}
 	// If the key is not found here and this is a leaf node
 	if n.isLeaf {
 		return nil
 	}
 	// Go to the approipriate child
 	return n.children[i].search(k)
 }
 func (n *Node) isFull() bool {
 	return n.numberOfKeys == 2*n.t-1
 }
 func (n *Node) insertNonFull(k int) {
 	// Initialize the index as the index of the rightmost element
 	i := n.numberOfKeys - 1
 	// If this is a leaf node
 	if n.isLeaf {
 		// Finds the location of the new key to be inserted
 		// Moves all greater keys to one place ahead
 		for i >= 0 && n.keys[i] > k {
 			n.keys[i+1] = n.keys[i]
 			i--
 		}
 		// Insert the new key at the found location
 		n.keys[i+1] = k
 		n.numberOfKeys++
 		return
 	}
 	// If this is not a leaf
 	// Finds the child wich is going to have the new key
 	for i >= 0 && n.keys[i] > k {
 		i--
 	}
 	// Check if the found chird is full
 	if n.children[i+1].isFull() {
 		// If the child is full, then split it
 		n.splitChild(i+1, n.children[i+1])
 		// After the split, the middle key of children[i] goes up and
 		// children[i] is splitted into two
 		// See which of those two is going to have the new key
 		if n.keys[i+1] < k {
 			i++
 		}
 	}
 	n.children[i+1].insertNonFull(k)
 }
 func (n *Node) splitChild(i int, y *Node) {
 	// Create a new node that will store (t-1) keys of y
 	z := newNode(y.t, y.isLeaf)
 	z.numberOfKeys = n.t - 1
 	// TODO: make optimisations
 	// Copy the last (t-1) keys of y to z
 	for j := 0; j < n.t-1; j++ {
 		z.keys[j] = y.keys[j+n.t]
 	}
 	// Copy the last t children of y to z
 	if !y.isLeaf {
 		for j := 0; j < n.t; j++ {
 			z.children[j] = y.children[j+n.t]
 		}
 	}
 	// Reduce the number of keys in y
 	y.numberOfKeys = n.t - 1
 	// Since this node is going to have a new child, create space for it
 	for j := n.numberOfKeys; j >= i+1; j-- {
 		n.children[j+1] = n.children[j]
 	}
 	// Link the new child to this node
 	n.children[i+1] = z
 	// A key of y will move to this node
 	// Find the location of the new key and move all greater keys ahead
 	for j := n.numberOfKeys - 1; j >= i; j-- {
 		n.keys[j+1] = n.keys[j]
 	}
 	// Copy the middle key of y to this node
 	n.keys[i] = y.keys[n.t-1]
 	// Increment the count of keys in this node
 	n.numberOfKeys++
 }
 // findKey returns the index of the first key that is greater than or equal to k
 func (n *Node) findKey(k int) int {
 	index := 0
 	for index < n.numberOfKeys && n.keys[index] < k {
 		index++
 	}
 	return index
 }
 // remove the key k from the sub-tree rooted with this node
 func (n *Node) remove(k int) error {
 	index := n.findKey(k)
 	// The key to be removed is in this node
 	if index < n.numberOfKeys && n.keys[index] == k {
 		if n.isLeaf {
 			return n.removeFromLeaf(index)
 		}
 		return n.removeFromNonLeaf(index)
 	}
 	// If this is a leaf, the key is not in the tree
 	if n.isLeaf {
 		return fmt.Errorf("The key %d does not exist in the tree", k)
 	}
 	isInLastChild := false
 	if index == n.numberOfKeys {
 		isInLastChild = true
 	}
 	// If the child where is the key has less than t keys, wi fill it
 	if n.children[index].numberOfKeys < n.t {
 		n.fill(index)
 	}
 	// If the last child has been merged, it must be merged with the previous
 	// child and so we recurse on the (index-1)th child.
 	if isInLastChild && index > n.numberOfKeys {
 		return n.children[index-1].remove(k)
 	}
 	// We recurse on the (index)th child which now has at least t keys
 	return n.children[index].remove(k)
 }
 // removeFromLeaf the index-th key from this node which is a leaf node
 func (n *Node) removeFromLeaf(index int) error {
 	// Move all the keys after the index-th position one place backward
 	for i := index + 1; i < n.numberOfKeys; i++ {
 		n.keys[i-1] = n.keys[i]
 	}
 	n.numberOfKeys--
 	return nil
 }
 // removeFromNonLeaf the index-th key from this node which is not a leaf node
 func (n *Node) removeFromNonLeaf(index int) error {
 	k := n.keys[index]
 	// If the child that precedes k has at least t keys,
 	// find the predecessor of k in the subtree and replace k with it
 	// Recursively delete the predecessor in the child
 	if n.children[index].numberOfKeys >= n.t {
 		pred := n.getPred(index)
 		n.keys[index] = pred
 		return n.children[index].remove(pred)
 	}
 	// If the child has less than t keys, examine children[index+1]
 	// If it has at least t keys, find the successor of k in this subtree
 	// Replace k by its successor and recursively delete the successor in the subtree
 	if n.children[index+1].numberOfKeys >= n.t {
 		succ := n.getSucc(index)
 		n.keys[index] = succ
 		return n.children[index+1].remove(succ)
 	}
 	// Merge k and all of children[index+1] int children[index]
 	// Free children[index+1] and recursively delete k from children[index]
 	n.merge(index)
 	return n.children[index].remove(k)
 }
 // getPred returns the predecessor of keys[index]
 func (n *Node) getPred(index int) int {
 	// Keep moving to the rightmost node until we reach a leaf
 	current := n.children[index]
 	for !current.isLeaf {
 		current = current.children[current.numberOfKeys]
 	}
 	// Return the last key of the leaf
 	return current.keys[current.numberOfKeys-1]
 }
 // getSucc returns the successor of keys[index]
 func (n *Node) getSucc(index int) int {
 	// Keep moving to the leftmost node starting from children[index+1] until we reach a leaf
 	current := n.children[index+1]
 	for !current.isLeaf {
 		current = current.children[0]
 	}
 	// Return the first key of the leaf
 	return current.keys[0]
 }
 // fill child children[index] which has less than t-1 keys
 func (n *Node) fill(index int) {
 	// If the previous child has more than t-1 keys, borrow a key from that child
 	if index != 0 && n.children[index-1].numberOfKeys >= n.t {
 		n.borrowFromPrev(index)
 		return
 	}
 	// If the next child has more than t-1 keys, borrow a key from that child
 	if index != n.numberOfKeys && n.children[index+1].numberOfKeys >= n.t {
 		n.borrowFromNext(index)
 		return
 	}
 	// Merge children[index] with its sibling
 	if index != n.numberOfKeys {
 		n.merge(index)
 		return
 	}
 	// If this is the last child, merge with the previous sibling
 	n.merge(index - 1)
 }
 // borrowFromPrev takes a key from children[index+1] and insert it in children[index]
 func (n *Node) borrowFromPrev(index int) {
 	child := n.children[index]
 	sibling := n.children[index-1]
 	// Moves all keys in children[index] one step ahead
 	for i := child.numberOfKeys - 1; i >= 0; i-- {
 		child.keys[i+1] = child.keys[i]
 	}
 	// If the child is not a leaf, move all its child pointers one step ahead
 	if !child.isLeaf {
 		for i := child.numberOfKeys; i >= 0; i-- {
 			child.children[i+1] = child.children[i]
 		}
 	}
 	// Sets child's first key equal to keys[index-1] from the current node
 	child.keys[0] = n.keys[index-1]
 	// Moves sibling's last child as children[index]'s first child
 	if !child.isLeaf {
 		child.children[0] = sibling.children[sibling.numberOfKeys]
 	}
 	// Moves the key from the sibling to the parent
 	n.keys[index-1] = sibling.keys[sibling.numberOfKeys-1]
 	child.numberOfKeys++
 	sibling.numberOfKeys--
 }
 // borrowFromNext takes a key from children[index+1] and insert it in children[index]
 func (n *Node) borrowFromNext(index int) {
 	child := n.children[index]
 	sibling := n.children[index+1]
 	// keys[index] is inserted as the last key in children[index]
 	child.keys[child.numberOfKeys] = n.keys[index]
 	// Sibling's first child is inserted as the last child into children[index]
 	if !child.isLeaf {
 		child.children[child.numberOfKeys+1] = sibling.children[0]
 	}
 	// The first key from sibling is inserted into keys[index]
 	n.keys[index] = sibling.keys[0]
 	// TODO: optimize loops here
 	// Moving all keys in sibling one step behind
 	for i := 1; i < sibling.numberOfKeys; i++ {
 		sibling.keys[i-1] = sibling.keys[i]
 	}
 	// Moving the child pointers one step behind
 	if !sibling.isLeaf {
 		for i := 1; i <= sibling.numberOfKeys; i++ {
 			sibling.children[i-1] = sibling.children[i]
 		}
 	}
 	child.numberOfKeys++
 	sibling.numberOfKeys--
 }
 // merge children[index] with children[index+1]
 func (n *Node) merge(index int) {
 	child := n.children[index]
 	sibling := n.children[index+1]
 	// Pulls a key from the current node ande insert it into the (t-1)th position
 	child.keys[n.t-1] = n.keys[index]
 	// Copies the keys from children[index+1] to children[index] at the end
 	for i := 0; i < sibling.numberOfKeys; i++ {
 		child.keys[i+n.t] = sibling.keys[i]
 	}
 	// Copies the child pointers from C[index+1] to children[index]
 	if !child.isLeaf {
 		for i := 0; i <= sibling.numberOfKeys; i++ {
 			child.children[i+n.t] = sibling.children[i]
 		}
 	}
 	// Moves all keys after index in the current node one step before
 	// to fill the gap created by moving keys[index] to children[index]
 	for i := index + 1; i < n.numberOfKeys; i++ {
 		n.keys[i-1] = n.keys[i]
 	}
 	// Moves the child pointer after (index+1) in the current node one step before
 	// This action marks sibling for deletion by the GC
 	for i := index + 2; i <= n.numberOfKeys; i++ {
 		n.children[i-1] = n.children[i]
 	}
 	// Updates the key count of child and the current node
 	child.numberOfKeys += sibling.numberOfKeys + 1
 	n.numberOfKeys--
 }
--- a/btree/btree_test.go
+++ b/btree/btree_test.go
@ -0,0 +1,123 @@
 package btree
 import (
 	"fmt"
 	"testing"
 )
 func TestTree_Search(t *testing.T) {
 	tree := NewBtree(3)
 	tree.Insert(6)
 	k := 6
 	if tree.Search(k) == nil {
 		t.Errorf("Not present %d", k)
 	}
 	k = 15
 	if tree.Search(k) != nil {
 		t.Errorf("Present %d", k)
 	}
 }
 func TestTree_Remove(t *testing.T) {
 	tree := NewBtree(3)
 	toInsert := []int{10, 20, 5, 6, 12, 30, 7, 17}
 	for _, k := range toInsert {
 		tree.Insert(k)
 	}
 	tree.Remove(toInsert[0])
 	for _, k := range toInsert[1:] {
 		if tree.Search(k) == nil {
 			t.Errorf("Not present %d", k)
 		}
 	}
 	if tree.Search(toInsert[0]) != nil {
 		t.Errorf("Present %d", toInsert[0])
 	}
 }
 func TestTree_Insert(t *testing.T) {
 	tree := NewBtree(3)
 	toInsert := []int{10, 20, 5, 6, 12, 30, 7, 17}
 	// Test before insertion
 	for _, k := range toInsert {
 		if tree.Search(k) != nil {
 			t.Errorf("Present %d", k)
 		}
 	}
 	for _, k := range toInsert {
 		tree.Insert(k)
 	}
 	// Test after insertion
 	for _, k := range toInsert {
 		if tree.Search(k) == nil {
 			t.Errorf("Not present %d", k)
 		}
 	}
 }
 /*
 func TestTree_Traverse(t *testing.T) {
 	tree := NewBtree(3)
 	toInsert := []int{1, 3, 7, 10, 11, 13, 14, 15, 18, 16, 19, 24, 25, 26, 21, 4, 5, 20, 22, 2, 17, 12, 6}
 	for _, k := range toInsert {
 		tree.Insert(k)
 	}
 	tree.Traverse()
 	fmt.Println("\n 1 2 3 4 5 6 7 10 11 12 13 14 15 16 17 18 19 20 21 22 24 25 26")
 }
 */
 func ExampleTree_Traverse() {
 	tree := NewBtree(3)
 	toInsert := []int{1, 3, 7, 10, 11, 13, 14, 15, 18, 16, 19, 24, 25, 26, 21, 4, 5, 20, 22, 2, 17, 12, 6}
 	for _, k := range toInsert {
 		tree.Insert(k)
 	}
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(6)
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(13)
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(7)
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(4)
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(2)
 	tree.Traverse()
 	fmt.Println("")
 	tree.Remove(16)
 	tree.Traverse()
 	// Output:
 	// 1 2 3 4 5 6 7 10 11 12 13 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 2 3 4 5 7 10 11 12 13 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 2 3 4 5 7 10 11 12 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 2 3 4 5 10 11 12 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 2 3 5 10 11 12 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 3 5 10 11 12 14 15 16 17 18 19 20 21 22 24 25 26
 	//  1 3 5 10 11 12 14 15 17 18 19 20 21 22 24 25 26
 }
--- a/main.go
+++ b/main.go
@ -0,0 +1,36 @@
 package main
 import (
 	"fmt"
 	"git.klmp200.net/klmp200/kvs/btree"
 )
 func main() {
 	t := btree.NewBtree(3)
 	t.Insert(10)
 	t.Insert(20)
 	t.Insert(5)
 	t.Insert(6)
 	t.Insert(12)
 	t.Insert(30)
 	t.Insert(7)
 	t.Insert(17)
 	fmt.Print("Traversal of the constructed tree is")
 	t.Traverse()
 	k := 6
 	if t.Search(k) != nil {
 		fmt.Print("\nPresent")
 	} else {
 		fmt.Print("\nNot Present")
 	}
 	k = 15
 	if t.Search(k) != nil {
 		fmt.Print("\nPresent")
 	} else {
 		fmt.Print("\nNot Present")
 	}
 }