gods/trees/btree/iterator.go

// Copyright (c) 2015, Emir Pasic. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

package btree

import "github.com/emirpasic/gods/containers"

func assertIteratorImplementation() {
	var _ containers.ReverseIteratorWithKey = (*Iterator)(nil)
}

// Iterator holding the iterator's state
type Iterator struct {
	tree     *Tree
	node     *Node
	entry    *Entry
	position position
}

type position byte

const (
	begin, between, end position = 0, 1, 2
)

// Iterator returns a stateful iterator whose elements are key/value pairs.
func (tree *Tree) Iterator() Iterator {
	return Iterator{tree: tree, node: nil, position: begin}
}

// Next moves the iterator to the next element and returns true if there was a next element in the container.
// If Next() returns true, then next element's key and value can be retrieved by Key() and Value().
// If Next() was called for the first time, then it will point the iterator to the first element if it exists.
// Modifies the state of the iterator.
func (iterator *Iterator) Next() bool {
	// If already at end, go to end
	if iterator.position == end {
		goto end
	}
	// If at beginning, get the left-most entry in the tree
	if iterator.position == begin {
		left := iterator.tree.Left()
		if left == nil {
			goto end
		}
		iterator.node = left
		iterator.entry = left.Entries[0]
		goto between
	}
	{
		// Find current entry position in current node
		e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)
		// Try to go down to the child right of the current entry
		if e+1 < len(iterator.node.Children) {
			iterator.node = iterator.node.Children[e+1]
			// Try to go down to the child left of the current node
			for len(iterator.node.Children) > 0 {
				iterator.node = iterator.node.Children[0]
			}
			// Return the left-most entry
			iterator.entry = iterator.node.Entries[0]
			goto between
		}
		// Above assures that we have reached a leaf node, so return the next entry in current node (if any)
		if e+1 < len(iterator.node.Entries) {
			iterator.entry = iterator.node.Entries[e+1]
			goto between
		}
	}
	// Reached leaf node and there are no entries to the right of the current entry, so go up to the parent
	for iterator.node.Parent != nil {
		iterator.node = iterator.node.Parent
		// Find next entry position in current node (note: search returns the first equal or bigger than entry)
		e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)
		// Check that there is a next entry position in current node
		if e < len(iterator.node.Entries) {
			iterator.entry = iterator.node.Entries[e]
			goto between
		}
	}

end:
	iterator.End()
	return false

between:
	iterator.position = between
	return true
}

// Prev moves the iterator to the previous element and returns true if there was a previous element in the container.
// If Prev() returns true, then previous element's key and value can be retrieved by Key() and Value().
// Modifies the state of the iterator.
func (iterator *Iterator) Prev() bool {
	// If already at beginning, go to begin
	if iterator.position == begin {
		goto begin
	}
	// If at end, get the right-most entry in the tree
	if iterator.position == end {
		right := iterator.tree.Right()
		if right == nil {
			goto begin
		}
		iterator.node = right
		iterator.entry = right.Entries[len(right.Entries)-1]
		goto between
	}
	{
		// Find current entry position in current node
		e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)
		// Try to go down to the child left of the current entry
		if e < len(iterator.node.Children) {
			iterator.node = iterator.node.Children[e]
			// Try to go down to the child right of the current node
			for len(iterator.node.Children) > 0 {
				iterator.node = iterator.node.Children[len(iterator.node.Children)-1]
			}
			// Return the right-most entry
			iterator.entry = iterator.node.Entries[len(iterator.node.Entries)-1]
			goto between
		}
		// Above assures that we have reached a leaf node, so return the previous entry in current node (if any)
		if e-1 >= 0 {
			iterator.entry = iterator.node.Entries[e-1]
			goto between
		}
	}
	// Reached leaf node and there are no entries to the left of the current entry, so go up to the parent
	for iterator.node.Parent != nil {
		iterator.node = iterator.node.Parent
		// Find previous entry position in current node (note: search returns the first equal or bigger than entry)
		e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)
		// Check that there is a previous entry position in current node
		if e-1 >= 0 {
			iterator.entry = iterator.node.Entries[e-1]
			goto between
		}
	}

begin:
	iterator.Begin()
	return false

between:
	iterator.position = between
	return true
}

// Value returns the current element's value.
// Does not modify the state of the iterator.
func (iterator *Iterator) Value() interface{} {
	return iterator.entry.Value
}

// Key returns the current element's key.
// Does not modify the state of the iterator.
func (iterator *Iterator) Key() interface{} {
	return iterator.entry.Key
}

// Begin resets the iterator to its initial state (one-before-first)
// Call Next() to fetch the first element if any.
func (iterator *Iterator) Begin() {
	iterator.node = nil
	iterator.position = begin
	iterator.entry = nil
}

// End moves the iterator past the last element (one-past-the-end).
// Call Prev() to fetch the last element if any.
func (iterator *Iterator) End() {
	iterator.node = nil
	iterator.position = end
	iterator.entry = nil
}

// First moves the iterator to the first element and returns true if there was a first element in the container.
// If First() returns true, then first element's key and value can be retrieved by Key() and Value().
// Modifies the state of the iterator
func (iterator *Iterator) First() bool {
	iterator.Begin()
	return iterator.Next()
}

// Last moves the iterator to the last element and returns true if there was a last element in the container.
// If Last() returns true, then last element's key and value can be retrieved by Key() and Value().
// Modifies the state of the iterator.
func (iterator *Iterator) Last() bool {
	iterator.End()
	return iterator.Prev()
}
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`// Copyright (c) 2015, Emir Pasic. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package btree`

			`import "github.com/emirpasic/gods/containers"`

			`func assertIteratorImplementation() {`
			`var _ containers.ReverseIteratorWithKey = (*Iterator)(nil)`
			`}`

			`// Iterator holding the iterator's state`
			`type Iterator struct {`
			`tree *Tree`
			`node *Node`
			`entry *Entry`
			`position position`
			`}`

			`type position byte`

			`const (`
			`begin, between, end position = 0, 1, 2`
			`)`

			`// Iterator returns a stateful iterator whose elements are key/value pairs.`
- revert some of changes coming from avl tree merge 2017-03-05 19:48:18 +00:00			`func (tree *Tree) Iterator() Iterator {`
			`return Iterator{tree: tree, node: nil, position: begin}`
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`}`

			`// Next moves the iterator to the next element and returns true if there was a next element in the container.`
			`// If Next() returns true, then next element's key and value can be retrieved by Key() and Value().`
			`// If Next() was called for the first time, then it will point the iterator to the first element if it exists.`
			`// Modifies the state of the iterator.`
			`func (iterator *Iterator) Next() bool {`
			`// If already at end, go to end`
			`if iterator.position == end {`
			`goto end`
			`}`
			`// If at beginning, get the left-most entry in the tree`
			`if iterator.position == begin {`
			`left := iterator.tree.Left()`
			`if left == nil {`
			`goto end`
			`}`
			`iterator.node = left`
			`iterator.entry = left.Entries[0]`
			`goto between`
			`}`
			`{`
			`// Find current entry position in current node`
			`e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)`
			`// Try to go down to the child right of the current entry`
			`if e+1 < len(iterator.node.Children) {`
			`iterator.node = iterator.node.Children[e+1]`
			`// Try to go down to the child left of the current node`
			`for len(iterator.node.Children) > 0 {`
			`iterator.node = iterator.node.Children[0]`
			`}`
			`// Return the left-most entry`
			`iterator.entry = iterator.node.Entries[0]`
			`goto between`
			`}`
			`// Above assures that we have reached a leaf node, so return the next entry in current node (if any)`
			`if e+1 < len(iterator.node.Entries) {`
			`iterator.entry = iterator.node.Entries[e+1]`
			`goto between`
			`}`
			`}`
			`// Reached leaf node and there are no entries to the right of the current entry, so go up to the parent`
			`for iterator.node.Parent != nil {`
			`iterator.node = iterator.node.Parent`
			`// Find next entry position in current node (note: search returns the first equal or bigger than entry)`
			`e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)`
			`// Check that there is a next entry position in current node`
			`if e < len(iterator.node.Entries) {`
			`iterator.entry = iterator.node.Entries[e]`
			`goto between`
			`}`
			`}`

- go fmt/vet 2017-03-05 19:50:19 +00:00			`end:`
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`iterator.End()`
			`return false`

- go fmt/vet 2017-03-05 19:50:19 +00:00			`between:`
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`iterator.position = between`
			`return true`
			`}`

			`// Prev moves the iterator to the previous element and returns true if there was a previous element in the container.`
			`// If Prev() returns true, then previous element's key and value can be retrieved by Key() and Value().`
			`// Modifies the state of the iterator.`
			`func (iterator *Iterator) Prev() bool {`
			`// If already at beginning, go to begin`
			`if iterator.position == begin {`
			`goto begin`
			`}`
			`// If at end, get the right-most entry in the tree`
			`if iterator.position == end {`
			`right := iterator.tree.Right()`
			`if right == nil {`
			`goto begin`
			`}`
			`iterator.node = right`
			`iterator.entry = right.Entries[len(right.Entries)-1]`
			`goto between`
			`}`
			`{`
			`// Find current entry position in current node`
			`e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)`
			`// Try to go down to the child left of the current entry`
			`if e < len(iterator.node.Children) {`
			`iterator.node = iterator.node.Children[e]`
			`// Try to go down to the child right of the current node`
			`for len(iterator.node.Children) > 0 {`
			`iterator.node = iterator.node.Children[len(iterator.node.Children)-1]`
			`}`
			`// Return the right-most entry`
			`iterator.entry = iterator.node.Entries[len(iterator.node.Entries)-1]`
			`goto between`
			`}`
			`// Above assures that we have reached a leaf node, so return the previous entry in current node (if any)`
			`if e-1 >= 0 {`
			`iterator.entry = iterator.node.Entries[e-1]`
			`goto between`
			`}`
			`}`
			`// Reached leaf node and there are no entries to the left of the current entry, so go up to the parent`
			`for iterator.node.Parent != nil {`
			`iterator.node = iterator.node.Parent`
			`// Find previous entry position in current node (note: search returns the first equal or bigger than entry)`
			`e, _ := iterator.tree.search(iterator.node, iterator.entry.Key)`
			`// Check that there is a previous entry position in current node`
			`if e-1 >= 0 {`
			`iterator.entry = iterator.node.Entries[e-1]`
			`goto between`
			`}`
			`}`

- go fmt/vet 2017-03-05 19:50:19 +00:00			`begin:`
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`iterator.Begin()`
			`return false`

- go fmt/vet 2017-03-05 19:50:19 +00:00			`between:`
- btree iterator implemented with tests 2016-07-12 00:53:48 +00:00			`iterator.position = between`
			`return true`
			`}`

			`// Value returns the current element's value.`
			`// Does not modify the state of the iterator.`
			`func (iterator *Iterator) Value() interface{} {`
			`return iterator.entry.Value`
			`}`

			`// Key returns the current element's key.`
			`// Does not modify the state of the iterator.`
			`func (iterator *Iterator) Key() interface{} {`
			`return iterator.entry.Key`
			`}`

			`// Begin resets the iterator to its initial state (one-before-first)`
			`// Call Next() to fetch the first element if any.`
			`func (iterator *Iterator) Begin() {`
			`iterator.node = nil`
			`iterator.position = begin`
			`iterator.entry = nil`
			`}`

			`// End moves the iterator past the last element (one-past-the-end).`
			`// Call Prev() to fetch the last element if any.`
			`func (iterator *Iterator) End() {`
			`iterator.node = nil`
			`iterator.position = end`
			`iterator.entry = nil`
			`}`

			`// First moves the iterator to the first element and returns true if there was a first element in the container.`
			`// If First() returns true, then first element's key and value can be retrieved by Key() and Value().`
			`// Modifies the state of the iterator`
			`func (iterator *Iterator) First() bool {`
			`iterator.Begin()`
			`return iterator.Next()`
			`}`

			`// Last moves the iterator to the last element and returns true if there was a last element in the container.`
			`// If Last() returns true, then last element's key and value can be retrieved by Key() and Value().`
			`// Modifies the state of the iterator.`
			`func (iterator *Iterator) Last() bool {`
			`iterator.End()`
			`return iterator.Prev()`
			`}`