drgn/libdrgn/splay_tree.c

// Copyright (c) Facebook, Inc. and its affiliates.
// SPDX-License-Identifier: GPL-3.0+

#include "binary_search_tree.h"

/*
 * Binary search tree splay operation based on the original paper [1]. Rotations
 * are inlined to avoid redundant pointer assignments. We still do redundant
 * assignments to great_grandparent->{left,right} and node->{left,right}; this
 * was faster in microbenchmarks than doing the extra tracking to avoid the
 * reassignments.
 *
 * This assumes that the node is not already the root.
 *
 * 1: "Self-Adjusting Binary Search Trees" (Sleator & Tarjan, 1985):
 * http://www.cs.cmu.edu/~sleator/papers/self-adjusting.pdf
 */
void splay_tree_splay(struct binary_tree_node **root,
		      struct binary_tree_node *node,
		      struct binary_tree_node *parent)
{
	for (;;) {
		struct binary_tree_node *grandparent, *great_grandparent;

		grandparent = parent->parent;
		if (node == parent->left) {
			if (!grandparent) {
				/*
				 * Zig step: rotate_right(parent). The node
				 * takes the place of its parent, which is the
				 * root.
				 */
				parent->left = node->right;
				node->right = parent;

				if (parent->left)
					parent->left->parent = parent;
				parent->parent = node;
				break;
			} else {
				great_grandparent = grandparent->parent;
				if (parent == grandparent->left) {
					/*
					 * Zig-zig step:
					 * rotate_right(grandparent),
					 * rotate_right(parent).
					 */
					grandparent->left = parent->right;
					parent->left = node->right;
					parent->right = grandparent;
					node->right = parent;

					if (grandparent->left)
						grandparent->left->parent = grandparent;
					grandparent->parent = parent;
					if (parent->left)
						parent->left->parent = parent;
					parent->parent = node;
				} else {
					/*
					 * Zig-zag step: rotate_right(parent),
					 * rotate_left(grandparent).
					 */
					grandparent->right = node->left;
					parent->left = node->right;
					node->left = grandparent;
					node->right = parent;

					if (grandparent->right)
						grandparent->right->parent = grandparent;
					if (parent->left)
						parent->left->parent = parent;
					grandparent->parent = node;
					parent->parent = node;
				}
			}
		} else {
			if (!grandparent) {
				/*
				 * Zig step: rotate_left(parent). The node
				 * takes the place of its parent, which is the
				 * root.
				 */
				parent->right = node->left;
				node->left = parent;

				if (parent->right)
					parent->right->parent = parent;
				parent->parent = node;
				break;
			} else {
				great_grandparent = grandparent->parent;
				if (parent == grandparent->right) {
					/*
					 * Zig-zig step:
					 * rotate_left(grandparent),
					 * rotate_left(parent).
					 */
					grandparent->right = parent->left;
					parent->right = node->left;
					parent->left = grandparent;
					node->left = parent;

					if (grandparent->right)
						grandparent->right->parent = grandparent;
					grandparent->parent = parent;
					if (parent->right)
						parent->right->parent = parent;
					parent->parent = node;
				} else {
					/*
					 * Zig-zag step: rotate_left(parent),
					 * rotate_right(grandparent).
					 */
					grandparent->left = node->right;
					parent->right = node->left;
					node->right = grandparent;
					node->left = parent;

					if (grandparent->left)
						grandparent->left->parent = grandparent;
					if (parent->right)
						parent->right->parent = parent;
					grandparent->parent = node;
					parent->parent = node;
				}
			}
		}
		/*
		 * Common code for zig-zig and zig-zag steps, both left and
		 * right. The node took the place of its grandparent, which may
		 * have been the root. We don't need to update the node's parent
		 * pointer because it is always NULL in the end.
		 */
		if (!great_grandparent)
			break;
		if (grandparent == great_grandparent->left)
			great_grandparent->left = node;
		else
			great_grandparent->right = node;
		parent = great_grandparent;
	}

	/* The node reached the root. */
	*root = node;
	node->parent = NULL;
}

static inline void transplant(struct binary_tree_node **root,
			      struct binary_tree_node *old,
			      struct binary_tree_node *new)
{
	if (!old->parent)
		*root = new;
	else if (old == old->parent->left)
		old->parent->left = new;
	else
		old->parent->right = new;
	if (new)
		new->parent = old->parent;
}

void splay_tree_delete(struct binary_tree_node **root,
		       struct binary_tree_node *node)
{
	if (node->left == NULL) {
		transplant(root, node, node->right);
	} else if (node->right == NULL) {
		transplant(root, node, node->left);
	} else {
		struct binary_tree_node *successor;

		successor = node->right;
		if (successor->left) {
			do {
				successor = successor->left;
			} while (successor->left);
			transplant(root, successor, successor->right);
			successor->right = node->right;
			successor->right->parent = successor;
		}
		transplant(root, node, successor);
		successor->left = node->left;
		successor->left->parent = successor;
	}
	if (node->parent && node->parent->parent)
		splay_tree_splay(root, node->parent, node->parent->parent);
}
Update copyright headers to Facebook and add missing headers drgn was originally my side project, but for awhile now it's also been my work project. Update the copyright headers to reflect this, and add a copyright header to various files that were missing it. 2020-05-15 23:13:02 +01:00			`// Copyright (c) Facebook, Inc. and its affiliates.`
libdrgn: add splay tree implementation This will be used to track memory segments instead of the array we currently use. The API is based on the hash table API; it can support alternative implementations in the future, like red-black trees. 2019-05-23 21:12:31 +01:00			`// SPDX-License-Identifier: GPL-3.0+`

			`#include "binary_search_tree.h"`

			`/*`
			`* Binary search tree splay operation based on the original paper [1]. Rotations`
			`* are inlined to avoid redundant pointer assignments. We still do redundant`
			`* assignments to great_grandparent->{left,right} and node->{left,right}; this`
			`* was faster in microbenchmarks than doing the extra tracking to avoid the`
			`* reassignments.`
			`*`
			`* This assumes that the node is not already the root.`
			`*`
			`* 1: "Self-Adjusting Binary Search Trees" (Sleator & Tarjan, 1985):`
			`* http://www.cs.cmu.edu/~sleator/papers/self-adjusting.pdf`
			`*/`
			`void splay_tree_splay(struct binary_tree_node **root,`
			`struct binary_tree_node *node,`
			`struct binary_tree_node *parent)`
			`{`
			`for (;;) {`
			`struct binary_tree_node grandparent, great_grandparent;`

			`grandparent = parent->parent;`
			`if (node == parent->left) {`
			`if (!grandparent) {`
			`/*`
			`* Zig step: rotate_right(parent). The node`
			`* takes the place of its parent, which is the`
			`* root.`
			`*/`
			`parent->left = node->right;`
			`node->right = parent;`

			`if (parent->left)`
			`parent->left->parent = parent;`
			`parent->parent = node;`
			`break;`
			`} else {`
			`great_grandparent = grandparent->parent;`
			`if (parent == grandparent->left) {`
			`/*`
			`* Zig-zig step:`
			`* rotate_right(grandparent),`
			`* rotate_right(parent).`
			`*/`
			`grandparent->left = parent->right;`
			`parent->left = node->right;`
			`parent->right = grandparent;`
			`node->right = parent;`

			`if (grandparent->left)`
			`grandparent->left->parent = grandparent;`
			`grandparent->parent = parent;`
			`if (parent->left)`
			`parent->left->parent = parent;`
			`parent->parent = node;`
			`} else {`
			`/*`
			`* Zig-zag step: rotate_right(parent),`
			`* rotate_left(grandparent).`
			`*/`
			`grandparent->right = node->left;`
			`parent->left = node->right;`
			`node->left = grandparent;`
			`node->right = parent;`

			`if (grandparent->right)`
			`grandparent->right->parent = grandparent;`
			`if (parent->left)`
			`parent->left->parent = parent;`
			`grandparent->parent = node;`
			`parent->parent = node;`
			`}`
			`}`
			`} else {`
			`if (!grandparent) {`
			`/*`
			`* Zig step: rotate_left(parent). The node`
			`* takes the place of its parent, which is the`
			`* root.`
			`*/`
			`parent->right = node->left;`
			`node->left = parent;`

			`if (parent->right)`
			`parent->right->parent = parent;`
			`parent->parent = node;`
			`break;`
			`} else {`
			`great_grandparent = grandparent->parent;`
			`if (parent == grandparent->right) {`
			`/*`
			`* Zig-zig step:`
			`* rotate_left(grandparent),`
			`* rotate_left(parent).`
			`*/`
			`grandparent->right = parent->left;`
			`parent->right = node->left;`
			`parent->left = grandparent;`
			`node->left = parent;`

			`if (grandparent->right)`
			`grandparent->right->parent = grandparent;`
			`grandparent->parent = parent;`
			`if (parent->right)`
			`parent->right->parent = parent;`
			`parent->parent = node;`
			`} else {`
			`/*`
			`* Zig-zag step: rotate_left(parent),`
			`* rotate_right(grandparent).`
			`*/`
			`grandparent->left = node->right;`
			`parent->right = node->left;`
			`node->right = grandparent;`
			`node->left = parent;`

			`if (grandparent->left)`
			`grandparent->left->parent = grandparent;`
			`if (parent->right)`
			`parent->right->parent = parent;`
			`grandparent->parent = node;`
			`parent->parent = node;`
			`}`
			`}`
			`}`
			`/*`
			`* Common code for zig-zig and zig-zag steps, both left and`
			`* right. The node took the place of its grandparent, which may`
			`* have been the root. We don't need to update the node's parent`
			`* pointer because it is always NULL in the end.`
			`*/`
			`if (!great_grandparent)`
			`break;`
			`if (grandparent == great_grandparent->left)`
			`great_grandparent->left = node;`
			`else`
			`great_grandparent->right = node;`
			`parent = great_grandparent;`
			`}`

			`/* The node reached the root. */`
			`*root = node;`
			`node->parent = NULL;`
			`}`

			`static inline void transplant(struct binary_tree_node **root,`
			`struct binary_tree_node *old,`
			`struct binary_tree_node *new)`
			`{`
			`if (!old->parent)`
			`*root = new;`
			`else if (old == old->parent->left)`
			`old->parent->left = new;`
			`else`
			`old->parent->right = new;`
			`if (new)`
			`new->parent = old->parent;`
			`}`

			`void splay_tree_delete(struct binary_tree_node **root,`
			`struct binary_tree_node *node)`
			`{`
			`if (node->left == NULL) {`
			`transplant(root, node, node->right);`
			`} else if (node->right == NULL) {`
			`transplant(root, node, node->left);`
			`} else {`
			`struct binary_tree_node *successor;`

			`successor = node->right;`
			`if (successor->left) {`
			`do {`
			`successor = successor->left;`
			`} while (successor->left);`
			`transplant(root, successor, successor->right);`
			`successor->right = node->right;`
			`successor->right->parent = successor;`
			`}`
			`transplant(root, node, successor);`
			`successor->left = node->left;`
			`successor->left->parent = successor;`
			`}`
			`if (node->parent && node->parent->parent)`
			`splay_tree_splay(root, node->parent, node->parent->parent);`
			`}`