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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
// The methods 'AvlTreeImpl::insert_worker' and 'AvlTreeImpl::delete_worker',
// and all supporting methods reachable from them, are derived from a public
// domain implementation by Georg Kraml. The public domain implementation in
// C was translated into Rust and the Rust translation was later translated
// into this C++ implementation.
//
// Unfortunately the relevant web site for the original C version is long
// gone, and can only be found on the Wayback Machine:
//
//
//
//
// The intermediate Rust translation can be found at
//
//
// For relicensing clearances, see Mozilla bugs 1620332 and 1769261:
//
//
// All other code in this file originates from Mozilla.
#ifndef ds_AvlTree_h
#define ds_AvlTree_h
#include "mozilla/Attributes.h"
#include "mozilla/Likely.h"
#include "mozilla/MathAlgorithms.h"
#include "mozilla/Maybe.h"
#include "ds/LifoAlloc.h"
namespace js {
////////////////////////////////////////////////////////////////////////
// //
// AvlTree implementation. For interface see `class AvlTree` below. //
// //
////////////////////////////////////////////////////////////////////////
// An AVL tree class, with private allocator and node-recycling. `T` is the
// class of elements in the tree. `C` must provide a method
//
// static int compare(const T&, const T&)
//
// to provide a total ordering on values `T` that are put into the tree,
// returning -1 for less-than, 0 for equal, and 1 for greater-than.
//
// `C::compare` does not have to be a total ordering for *all* values of `T`,
// but it must be so for the `T` values in the tree. Requests to insert
// duplicate `T` values, as determined equal by `C::compare`, are valid but
// will be ignored in this implementation class: the stored data is unchanged.
// The interface class `AvlTree` however will MOZ_CRASH() on such requests.
//
// `T` values stored in the tree will not be explicitly freed or destroyed.
//
// For best cache-friendlyness, try to put the fields of `T` that are read by
// your compare function at the end of `T`. See comment on `struct Node`
// below.
//
// Some operations require (internally) building a stack of tree nodes from
// the root to some leaf. The maximum stack size, and hence the maximum tree
// depth, is currently bounded at 48. The max depth of an AVL tree is roughly
// 1.44 * log2(# nodes), so providing the tree-balancing machinery works
// correctly, the max number of nodes is at least 2^(48 / 1.44), somewhat over
// 2^33 (= 8 G). On a 32-bit target we'll run out of address space long
// before reaching that. On a 64-bit target, the minimum imaginable
// sizeof(Node) is 16 (for the two pointers), so a tree with 2^33 nodes would
// occupy at least 2^37 bytes, viz, around 137GB. So this seems unlikely to
// be a limitation.
//
// All stack-pushing operations are release-asserted to not overflow the stack.
template <class T, class C>
class AvlTreeImpl {
// This is the implementation of AVL trees. If you want to know how to use
// them in your code, don't read this; instead look below at the public
// interface, that is, `class AvlTree`.
//
// All of `AvlTreeImpl`, apart from the iterator code at the bottom, is
// protected. Public facilities are provided by child class `AvlTree`.
protected:
// Tree node tags.
enum class Tag {
Free, // Node not in use -- is on the freelist.
None, // Node in use. Neither subtree is deeper.
Left, // Node in use. The left subtree is deeper.
Right, // Node in use. The right subtree is deeper.
Count, // Not used as an actual tag - should remain last in this list
};
// Tree nodes. The tag is stored in the lower bits of the right Node pointer
// rather than as a separate field. For types T with alignment no more than
// twice the size of a pointer (ie, most types), this reduces the size of Node
// and enables them to pack more tightly, reducing memory requirements and
// improving cache behavior. (See bug 1847616.)
struct Node {
T item;
Node* left;
// This is the mask to use to extract the tag from `rightAndTag`.
static constexpr uintptr_t kTagMask = 3;
static_assert(mozilla::IsPowerOfTwo(kTagMask + 1),
"kTagMask must only have a consecutive sequence of its "
"lowest bits set");
static_assert(
kTagMask >= static_cast<uintptr_t>(Tag::Count) - 1,
"kTagMask must be sufficient to cover largest value in 'Tag'");
private:
uintptr_t rightAndTag;
public:
explicit Node(const T& item)
: item(item),
left(nullptr),
rightAndTag(static_cast<uintptr_t>(Tag::None)) {}
[[nodiscard]] Node* getRight() const {
return reinterpret_cast<Node*>(rightAndTag & ~kTagMask);
}
[[nodiscard]] Tag getTag() const {
return static_cast<Tag>(rightAndTag & kTagMask);
}
void setRight(Node* right) {
rightAndTag =
reinterpret_cast<uintptr_t>(right) | static_cast<uintptr_t>(getTag());
}
void setTag(const Tag tag) {
rightAndTag = (rightAndTag & ~kTagMask) | static_cast<uintptr_t>(tag);
}
void setRightAndTag(Node* right, const Tag tag) {
const uintptr_t rightAsUint = reinterpret_cast<uintptr_t>(right);
rightAndTag = rightAsUint | static_cast<uintptr_t>(tag);
}
};
// Ensure that we can use the needed lower bits of a Node pointer to store the
// tag.
static_assert(alignof(Node) >= Node::kTagMask + 1);
// Once-per-tree components.
Node* root_;
Node* freeList_;
LifoAlloc* alloc_;
// As a modest but easy optimisation, ::allocateNode will allocate one node
// at the first call that sees an empty `freeList_`, two on the next such
// call and four on subsequent such calls. This has the effect of reducing
// the number of calls to the underlying allocator `alloc_` by a factor of 4
// for all but the smallest trees. It also helps pack more nodes into each
// cache line. The limit of 4 exists for three reasons:
//
// (1) It gains the majority (75%) of the available benefit from reducing
// the number of calls to `alloc_`, as the allocation size tends to
// infinity.
//
// (2) Similarly, 4 `struct Node`s will surely be greater than 128 bytes,
// hence there is minimal chance to use even fewer cache lines by increasing
// the group size further. In any case most machines have cache lines of
// size 64 bytes, not 128.
//
// (3) Most importantly, it limits the maximum potentially wasted space,
// which is the case where a request causes an allocation of N nodes, of
// which one is used immediately and the N-1 are put on the freelist, but
// then -- because the tree never grows larger -- are never used. Given
// that N=4 here, the worst case lossage is 3 nodes, which seems tolerable.
uint32_t nextAllocSize_; // 1, 2 or 4 only
// The expected maximum tree depth. See comments above.
static const size_t MAX_TREE_DEPTH = 48;
AvlTreeImpl(const AvlTreeImpl&) = delete;
AvlTreeImpl& operator=(const AvlTreeImpl&) = delete;
// ---- Preliminaries --------------------------------------- //
explicit AvlTreeImpl(LifoAlloc* alloc = nullptr)
: root_(nullptr), freeList_(nullptr), alloc_(alloc), nextAllocSize_(1) {}
void setAllocator(LifoAlloc* alloc) { alloc_ = alloc; }
// Put `node` onto the free list, for possible later reuse.
inline void addToFreeList(Node* node) {
node->left = freeList_;
node->setRightAndTag(nullptr, Tag::Free); // for safety
freeList_ = node;
}
// A safer version of `addToFreeList`.
inline void freeNode(Node* node) {
MOZ_ASSERT(node->getTag() != Tag::Free);
addToFreeList(node);
}
// This is the slow path for ::allocateNode below. Allocate 1, 2 or 4 nodes
// as a block, return the first one properly initialised, and put the rest
// on the freelist, in increasing order of address.
MOZ_NEVER_INLINE Node* allocateNodeOOL(const T& v) {
switch (nextAllocSize_) {
case 1: {
nextAllocSize_ = 2;
Node* node = alloc_->new_<Node>(v);
// `node` is either fully initialized, or nullptr on OOM.
return node;
}
case 2: {
nextAllocSize_ = 4;
Node* nodes = alloc_->newArrayUninitialized<Node>(2);
if (!nodes) {
return nullptr;
}
Node* node0 = &nodes[0];
addToFreeList(&nodes[1]);
new (node0) Node(v);
return node0;
}
case 4: {
Node* nodes = alloc_->newArrayUninitialized<Node>(4);
if (!nodes) {
return nullptr;
}
Node* node0 = &nodes[0];
addToFreeList(&nodes[3]);
addToFreeList(&nodes[2]);
addToFreeList(&nodes[1]);
new (node0) Node(v);
return node0;
}
default: {
MOZ_CRASH();
}
}
}
// Allocate a Node holding `v`, or return nullptr on OOM. All of the fields
// are initialized.
inline Node* allocateNode(const T& v) {
Node* node = freeList_;
if (MOZ_LIKELY(node)) {
MOZ_ASSERT(node->getTag() == Tag::Free);
freeList_ = node->left;
new (node) Node(v);
return node;
}
return allocateNodeOOL(v);
}
// These exist only transiently, to aid rebalancing. They indicate whether
// an insertion/deletion succeeded, whether subsequent rebalancing is
// needed.
enum class Result { Error, OK, Balance };
using NodeAndResult = std::pair<Node*, Result>;
// Standard AVL single-rotate-left
Node* rotate_left(Node* old_root) {
Node* new_root = old_root->getRight();
old_root->setRight(new_root->left);
new_root->left = old_root;
return new_root;
}
// Standard AVL single-rotate-right
Node* rotate_right(Node* old_root) {
Node* new_root = old_root->left;
old_root->left = new_root->getRight();
new_root->setRight(old_root);
return new_root;
}
// ---- Helpers for insertion ------------------------------- //
// `leftgrown`: a helper function for `insert_worker`
//
// Parameters:
//
// root Root of a tree. This node's left subtree has just grown due to
// item insertion; its "tag" flag needs adjustment, and the local
// tree (the subtree of which this node is the root node) may have
// become unbalanced.
//
// Return values:
//
// The new root of the subtree, plus either:
//
// OK The local tree could be rebalanced or was balanced from the
// start. The caller, insert_worker, may assume the entire tree
// is valid.
// or
// Balance The local tree was balanced, but has grown in height.
// Do not assume the entire tree is valid.
//
// This function has been split into two pieces: `leftgrown`, which is small
// and hot, and is marked always-inline, and `leftgrown_left`, which handles
// a more complex and less frequent case, and is marked never-inline. The
// intent is to have the common case always inlined without having to deal
// with the extra register pressure from inlining the less frequent code.
// The dual function `rightgrown` is split similarly.
MOZ_NEVER_INLINE Node* leftgrown_left(Node* root) {
if (root->left->getTag() == Tag::Left) {
root->setTag(Tag::None);
root->left->setTag(Tag::None);
root = rotate_right(root);
} else {
switch (root->left->getRight()->getTag()) {
case Tag::Left:
root->setTag(Tag::Right);
root->left->setTag(Tag::None);
break;
case Tag::Right:
root->setTag(Tag::None);
root->left->setTag(Tag::Left);
break;
case Tag::None:
root->setTag(Tag::None);
root->left->setTag(Tag::None);
break;
case Tag::Free:
default:
MOZ_CRASH();
}
root->left->getRight()->setTag(Tag::None);
root->left = rotate_left(root->left);
root = rotate_right(root);
}
return root;
}
inline NodeAndResult leftgrown(Node* root) {
switch (root->getTag()) {
case Tag::Left:
return NodeAndResult(leftgrown_left(root), Result::OK);
case Tag::Right:
root->setTag(Tag::None);
return NodeAndResult(root, Result::OK);
case Tag::None:
root->setTag(Tag::Left);
return NodeAndResult(root, Result::Balance);
case Tag::Free:
default:
break;
}
MOZ_CRASH();
}
// `rightgrown`: a helper function for `insert_worker`. See `leftgrown` for
// details.
MOZ_NEVER_INLINE Node* rightgrown_right(Node* root) {
if (root->getRight()->getTag() == Tag::Right) {
root->setTag(Tag::None);
root->getRight()->setTag(Tag::None);
root = rotate_left(root);
} else {
switch (root->getRight()->left->getTag()) {
case Tag::Right:
root->setTag(Tag::Left);
root->getRight()->setTag(Tag::None);
break;
case Tag::Left:
root->setTag(Tag::None);
root->getRight()->setTag(Tag::Right);
break;
case Tag::None:
root->setTag(Tag::None);
root->getRight()->setTag(Tag::None);
break;
case Tag::Free:
default:
MOZ_CRASH();
}
root->getRight()->left->setTag(Tag::None);
root->setRight(rotate_right(root->getRight()));
root = rotate_left(root);
}
return root;
}
inline NodeAndResult rightgrown(Node* root) {
switch (root->getTag()) {
case Tag::Left:
root->setTag(Tag::None);
return NodeAndResult(root, Result::OK);
case Tag::Right:
return NodeAndResult(rightgrown_right(root), Result::OK);
case Tag::None:
root->setTag(Tag::Right);
return NodeAndResult(root, Result::Balance);
case Tag::Free:
default:
break;
}
MOZ_CRASH();
}
// ---- Insertion ------------------------------------------- //
// Worker for insertion. Allocates a node for `v` and inserts it into the
// tree. Returns: nullptr for OOM; (Node*)1 if `v` is a duplicate (per
// `C::compare`), in which case the tree is unchanged; otherwise (successful
// insertion) the new root. In the latter case, the new `item` field is
// initialised from `v`.
Node* insert_worker(const T& v) {
// Insertion is a two pass process. In the first pass, we descend from
// the root, looking for the place in the tree where the new node will go,
// and at the same time storing the sequence of visited nodes in a stack.
// In the second phase we re-ascend the tree, as guided by the stack,
// rebalancing as we go.
//
// Note, we start from `root_`, but that isn't updated at the end. Instead
// the new value is returned to the caller, which has to do the update.
Node* stack[MAX_TREE_DEPTH];
size_t stackPtr = 0; // points to next available slot
#define STACK_ENTRY_SET_IS_LEFT(_nodePtr) \
((Node*)(uintptr_t(_nodePtr) | uintptr_t(1)))
#define STACK_ENTRY_GET_IS_LEFT(_ent) ((bool)(uintptr_t(_ent) & uintptr_t(1)))
#define STACK_ENTRY_GET_NODE(_ent) ((Node*)(uintptr_t(_ent) & ~uintptr_t(1)))
// In the first phase, walk down the tree to find the place where the new
// node should be inserted, recording our path in `stack`. This loop has
// a factor-of-2 unrolling (the loop body contains two logical iterations)
// in order to reduce the overall cost of the stack-overflow check at the
// bottom.
Node* node = root_;
while (true) {
// First logical iteration
if (!node) {
break;
}
int cmpRes1 = C::compare(v, node->item);
if (cmpRes1 < 0) {
stack[stackPtr++] = STACK_ENTRY_SET_IS_LEFT(node);
node = node->left;
} else if (cmpRes1 > 0) {
stack[stackPtr++] = node;
node = node->getRight();
} else {
// `v` is already in the tree. Inform the caller, and don't change
// the tree.
return (Node*)(uintptr_t(1));
}
// Second logical iteration
if (!node) {
break;
}
int cmpRes2 = C::compare(v, node->item);
if (cmpRes2 < 0) {
stack[stackPtr++] = STACK_ENTRY_SET_IS_LEFT(node);
node = node->left;
} else if (cmpRes2 > 0) {
stack[stackPtr++] = node;
node = node->getRight();
} else {
return (Node*)(uintptr_t(1));
}
// We're going around again. Ensure there are at least two available
// stack slots.
MOZ_RELEASE_ASSERT(stackPtr < MAX_TREE_DEPTH - 2);
}
MOZ_ASSERT(!node);
// Now allocate the new node.
Node* new_node = allocateNode(v);
if (!new_node) {
return nullptr; // OOM
}
// And unwind the stack, back to the root, rebalancing as we go. Once get
// to a place where the new subtree doesn't need to be rebalanced, we can
// stop this upward scan, because no nodes above it will need to be
// rebalanced either.
Node* curr_node = new_node;
Result curr_node_action = Result::Balance;
while (stackPtr > 0) {
Node* parent_node_tagged = stack[--stackPtr];
Node* parent_node = STACK_ENTRY_GET_NODE(parent_node_tagged);
if (STACK_ENTRY_GET_IS_LEFT(parent_node_tagged)) {
parent_node->left = curr_node;
if (curr_node_action == Result::Balance) {
auto pair = leftgrown(parent_node);
curr_node = pair.first;
curr_node_action = pair.second;
} else {
curr_node = parent_node;
break;
}
} else {
parent_node->setRight(curr_node);
if (curr_node_action == Result::Balance) {
auto pair = rightgrown(parent_node);
curr_node = pair.first;
curr_node_action = pair.second;
} else {
curr_node = parent_node;
break;
}
}
}
if (stackPtr > 0) {
curr_node = STACK_ENTRY_GET_NODE(stack[0]);
}
MOZ_ASSERT(curr_node);
#undef STACK_ENTRY_SET_IS_LEFT
#undef STACK_ENTRY_GET_IS_LEFT
#undef STACK_ENTRY_GET_NODE
return curr_node;
}
// ---- Helpers for deletion -------------------------------- //
// `leftshrunk`: a helper function for `delete_worker` and `findlowest`
//
// Parameters:
//
// n Pointer to a node. The node's left subtree has just shrunk due to
// item removal; its "skew" flag needs adjustment, and the local tree
// (the subtree of which this node is the root node) may have become
// unbalanced.
//
// Return values:
//
// (jseward: apparently some node, but what is it?), plus either:
//
// OK The parent activation of the delete activation that called
// this function may assume the entire tree is valid.
//
// Balance Do not assume the entire tree is valid.
NodeAndResult leftshrunk(Node* n) {
switch (n->getTag()) {
case Tag::Left: {
n->setTag(Tag::None);
return NodeAndResult(n, Result::Balance);
}
case Tag::Right: {
if (n->getRight()->getTag() == Tag::Right) {
n->setTag(Tag::None);
n->getRight()->setTag(Tag::None);
n = rotate_left(n);
return NodeAndResult(n, Result::Balance);
} else if (n->getRight()->getTag() == Tag::None) {
n->setTag(Tag::Right);
n->getRight()->setTag(Tag::Left);
n = rotate_left(n);
return NodeAndResult(n, Result::OK);
} else {
switch (n->getRight()->left->getTag()) {
case Tag::Left:
n->setTag(Tag::None);
n->getRight()->setTag(Tag::Right);
break;
case Tag::Right:
n->setTag(Tag::Left);
n->getRight()->setTag(Tag::None);
break;
case Tag::None:
n->setTag(Tag::None);
n->getRight()->setTag(Tag::None);
break;
case Tag::Free:
default:
MOZ_CRASH();
}
n->getRight()->left->setTag(Tag::None);
n->setRight(rotate_right(n->getRight()));
;
n = rotate_left(n);
return NodeAndResult(n, Result::Balance);
}
/*NOTREACHED*/ MOZ_CRASH();
}
case Tag::None: {
n->setTag(Tag::Right);
return NodeAndResult(n, Result::OK);
}
case Tag::Free:
default: {
MOZ_CRASH();
}
}
MOZ_CRASH();
}
// rightshrunk: a helper function for `delete` and `findhighest`. See
// `leftshrunk` for details.
NodeAndResult rightshrunk(Node* n) {
switch (n->getTag()) {
case Tag::Right: {
n->setTag(Tag::None);
return NodeAndResult(n, Result::Balance);
}
case Tag::Left: {
if (n->left->getTag() == Tag::Left) {
n->setTag(Tag::None);
n->left->setTag(Tag::None);
n = rotate_right(n);
return NodeAndResult(n, Result::Balance);
} else if (n->left->getTag() == Tag::None) {
n->setTag(Tag::Left);
n->left->setTag(Tag::Right);
n = rotate_right(n);
return NodeAndResult(n, Result::OK);
} else {
switch (n->left->getRight()->getTag()) {
case Tag::Left:
n->setTag(Tag::Right);
n->left->setTag(Tag::None);
break;
case Tag::Right:
n->setTag(Tag::None);
n->left->setTag(Tag::Left);
break;
case Tag::None:
n->setTag(Tag::None);
n->left->setTag(Tag::None);
break;
case Tag::Free:
default:
MOZ_CRASH();
}
n->left->getRight()->setTag(Tag::None);
n->left = rotate_left(n->left);
n = rotate_right(n);
return NodeAndResult(n, Result::Balance);
}
/*NOTREACHED*/ MOZ_CRASH();
}
case Tag::None: {
n->setTag(Tag::Left);
return NodeAndResult(n, Result::OK);
}
case Tag::Free:
default: {
MOZ_CRASH();
}
}
MOZ_CRASH();
}
// `findhighest`: helper function for `delete_worker`. It replaces a node
// with a subtree's greatest (per C::compare) item.
//
// Parameters:
//
// target Pointer to node to be replaced.
//
// n Address of pointer to subtree.
//
// Return value:
//
// Nothing The target node could not be replaced because the subtree
// provided was empty.
//
// Some(Node*,Result) jseward: it's pretty unclear, but I *think* it
// is a pair that has the same meaning as the
// pair returned by `leftgrown`, as described above.
mozilla::Maybe<NodeAndResult> findhighest(Node* target, Node* n) {
if (n == nullptr) {
return mozilla::Nothing();
}
auto res = Result::Balance;
if (n->getRight() != nullptr) {
auto fhi = findhighest(target, n->getRight());
if (fhi.isSome()) {
n->setRight(fhi.value().first);
res = fhi.value().second;
if (res == Result::Balance) {
auto pair = rightshrunk(n);
n = pair.first;
res = pair.second;
}
return mozilla::Some(NodeAndResult(n, res));
} else {
return mozilla::Nothing();
}
}
target->item = n->item;
Node* tmp = n;
n = n->left;
freeNode(tmp);
return mozilla::Some(NodeAndResult(n, res));
}
// `findhighest`: helper function for `delete_worker`. It replaces a node
// with a subtree's greatest (per C::compare) item. See `findhighest` for
// details.
mozilla::Maybe<NodeAndResult> findlowest(Node* target, Node* n) {
if (n == nullptr) {
return mozilla::Nothing();
}
Result res = Result::Balance;
if (n->left != nullptr) {
auto flo = findlowest(target, n->left);
if (flo.isSome()) {
n->left = flo.value().first;
res = flo.value().second;
if (res == Result::Balance) {
auto pair = leftshrunk(n);
n = pair.first;
res = pair.second;
}
return mozilla::Some(NodeAndResult(n, res));
} else {
return mozilla::Nothing();
}
}
target->item = n->item;
Node* tmp = n;
n = n->getRight();
freeNode(tmp);
return mozilla::Some(NodeAndResult(n, res));
}
// ---- Deletion -------------------------------------------- //
// Deletes the node matching `item` from an arbitrary subtree rooted at
// `node`. Returns the root of the new subtree (if any), a `Result` that
// indicates that either, the tree containing `node` does or does not need
// rebalancing (::Balance, ::OK) or that the item was not found (::Error).
NodeAndResult delete_worker(Node* node, const T& item) {
Result tmp = Result::Balance;
if (node == nullptr) {
return NodeAndResult(node, Result::Error);
}
int cmp_res = C::compare(item, node->item);
if (cmp_res < 0) {
auto pair1 = delete_worker(node->left, item);
node->left = pair1.first;
tmp = pair1.second;
if (tmp == Result::Balance) {
auto pair2 = leftshrunk(node);
node = pair2.first;
tmp = pair2.second;
}
return NodeAndResult(node, tmp);
} else if (cmp_res > 0) {
auto pair1 = delete_worker(node->getRight(), item);
node->setRight(pair1.first);
tmp = pair1.second;
if (tmp == Result::Balance) {
auto pair2 = rightshrunk(node);
node = pair2.first;
tmp = pair2.second;
}
return NodeAndResult(node, tmp);
} else {
if (node->left != nullptr) {
auto fhi = findhighest(node, node->left);
if (fhi.isSome()) {
node->left = fhi.value().first;
tmp = fhi.value().second;
if (tmp == Result::Balance) {
auto pair = leftshrunk(node);
node = pair.first;
tmp = pair.second;
}
}
return NodeAndResult(node, tmp);
}
if (node->getRight() != nullptr) {
auto flo = findlowest(node, node->getRight());
if (flo.isSome()) {
node->setRight(flo.value().first);
tmp = flo.value().second;
if (tmp == Result::Balance) {
auto pair = rightshrunk(node);
node = pair.first;
tmp = pair.second;
}
}
return NodeAndResult(node, tmp);
}
freeNode(node);
return NodeAndResult(nullptr, Result::Balance);
}
}
// ---- Lookup ---------------------------------------------- //
// Find the node matching `v`, or return nullptr if not found.
Node* find_worker(const T& v) const {
Node* node = root_;
while (node) {
int cmpRes = C::compare(v, node->item);
if (cmpRes < 0) {
node = node->left;
} else if (cmpRes > 0) {
node = node->getRight();
} else {
return node;
}
}
return nullptr;
}
// ---- Iteration ------------------------------------------- //
public:
// This provides iteration forwards over the tree. You can either iterate
// over the whole tree or specify a start point. To iterate over the whole
// tree:
//
// AvlTree<MyT,MyC> tree;
// .. put stuff into `tree` ..
//
// AvlTree<MyT,MyC>::Iter iter(&tree);
// while (iter.hasMore) {
// MyT item = iter.next();
// }
//
// Alternatively you can initialize the iterator with some value `startAt`,
// so that the first value you get is greater than or equal to `startAt`,
// per `MyC::compare`:
//
// AvlTree<MyT,MyC>::Iter iter(&tree, startAt);
//
// Starting the iterator at a particular value requires finding the value in
// the tree and recording the path to it. So it's nearly as cheap as a call
// to `AvlTree::contains` and you can use it as a plausible substitute for
// `::contains` if you want.
//
// Note that `class Iter` is quite large -- around 50 machine words -- so
// you might want to think twice before allocating instances on the heap.
class Iter {
const AvlTreeImpl<T, C>* tree_;
Node* stack_[MAX_TREE_DEPTH];
size_t stackPtr_;
// This sets up the iterator stack so that the first value it produces
// will be the smallest value that is greater than or equal to `v`. Note
// the structural similarity to ::find_worker above.
//
// The logic for pushing nodes on the stack looks strange at first. Once
// set up, the stack contains a root-to-some-node path, and the
// top-of-stack value is the next value the iterator will emit. If the
// stack becomes empty then the iteration is complete.
//
// It's not quite accurate to say that the stack contains a complete
// root-to-some-node path. Rather, the stack contains such a path, except
// it omits nodes at which the path goes to the right child. Eg:
//
// 5
// 3 8
// 1 4 7 9
//
// If the next item to be emitted is 4, then the stack will be [5, 4] and
// not [5, 3, 4], because at 3 we go right. This explains why the
// `cmpRes > 0` case in `setupIteratorStack` doesn't push an item on the
// stack. It also explains why the single-argument `Iter::Iter` below,
// which sets up for iteration starting at the lowest element, simply
// calls `visitLeftChildren` to do its work.
void setupIteratorStack(Node* node, const T& v) {
// Ensure stackPtr_ is cached in a register, since this function can be
// hot.
MOZ_ASSERT(stackPtr_ == 0);
size_t stackPtr = 0;
while (node) {
int cmpRes = C::compare(v, node->item);
if (cmpRes < 0) {
stack_[stackPtr++] = node;
MOZ_RELEASE_ASSERT(stackPtr < MAX_TREE_DEPTH);
node = node->left;
} else if (cmpRes > 0) {
node = node->getRight();
} else {
stack_[stackPtr++] = node;
MOZ_RELEASE_ASSERT(stackPtr < MAX_TREE_DEPTH);
break;
}
}
stackPtr_ = stackPtr;
}
void visitLeftChildren(Node* node) {
while (true) {
Node* left = node->left;
if (left == nullptr) {
break;
}
stack_[stackPtr_++] = left;
MOZ_RELEASE_ASSERT(stackPtr_ < MAX_TREE_DEPTH);
node = left;
}
}
public:
explicit Iter(const AvlTreeImpl<T, C>* tree) {
tree_ = tree;
stackPtr_ = 0;
if (tree->root_ != nullptr) {
stack_[stackPtr_++] = tree->root_;
MOZ_RELEASE_ASSERT(stackPtr_ < MAX_TREE_DEPTH);
visitLeftChildren(tree->root_);
}
}
Iter(const AvlTreeImpl<T, C>* tree, const T& startAt) {
tree_ = tree;
stackPtr_ = 0;
setupIteratorStack(tree_->root_, startAt);
}
bool hasMore() const { return stackPtr_ > 0; }
T next() {
MOZ_RELEASE_ASSERT(stackPtr_ > 0);
Node* ret = stack_[--stackPtr_];
Node* right = ret->getRight();
if (right != nullptr) {
stack_[stackPtr_++] = right;
MOZ_RELEASE_ASSERT(stackPtr_ < MAX_TREE_DEPTH);
visitLeftChildren(right);
}
return ret->item;
}
};
};
////////////////////////////////////////////////////////////////////////
// //
// AvlTree public interface, for SpiderMonkey. //
// //
////////////////////////////////////////////////////////////////////////
// This public interface is fairly limited and restrictive. If you need to
// add more functionality, consider copying code from `class AvlTreeTestIF` in
// js/src/jsapi-tests/testAvlTree.cpp rather than rolling your own. See
// comments there.
template <class T, class C>
class AvlTree : public AvlTreeImpl<T, C> {
// Shorthands for names in the implementation (parent) class.
using Impl = AvlTreeImpl<T, C>;
using ImplNode = typename AvlTreeImpl<T, C>::Node;
using ImplResult = typename AvlTreeImpl<T, C>::Result;
using ImplNodeAndResult = typename AvlTreeImpl<T, C>::NodeAndResult;
public:
explicit AvlTree(LifoAlloc* alloc = nullptr) : Impl(alloc) {}
// You'll need to tell the tree how to allocate nodes, either here or in
// `AvlTree::AvlTree`.
void setAllocator(LifoAlloc* alloc) { Impl::setAllocator(alloc); }
// Is the tree empty?
bool empty() const { return Impl::root_ == nullptr; }
// Insert `v` in the tree. Returns false to indicate OOM. `v` may not be
// equal to any existing value in the tree, per `C::compare`; if it is, this
// routine will MOZ_CRASH(). It would be trivial to change this to replace
// an existing value instead, if needed.
[[nodiscard]] bool insert(const T& v) {
ImplNode* new_root = Impl::insert_worker(v);
// Take out both unlikely cases with a single comparison.
if (MOZ_UNLIKELY(uintptr_t(new_root) <= uintptr_t(1))) {
// OOM (new_root == 0) or duplicate (new_root == 1)
if (!new_root) {
// OOM
return false;
}
// Duplicate; tree is unchanged.
MOZ_CRASH();
}
Impl::root_ = new_root;
return true;
}
// Remove `v` from the tree. `v` must actually be in the tree, per
// `C::compare`. If it is not, this routine will MOZ_CRASH().
// Superficially it looks like we could change it to return without doing
// anything in that case, if needed, except we'd need to first verify that
// `delete_worker` doesn't change the tree in that case.
void remove(const T& v) {
ImplNodeAndResult pair = Impl::delete_worker(Impl::root_, v);
ImplNode* new_root = pair.first;
ImplResult res = pair.second;
if (MOZ_UNLIKELY(res == ImplResult::Error)) {
// `v` isn't in the tree.
MOZ_CRASH();
} else {
Impl::root_ = new_root;
}
}
// Determine whether the tree contains `v` and if so return, in `res`, a
// copy of the stored version. Note that the determination is done using
// `C::compare` and you should consider carefully the consequences of
// passing in `v` for which `C::compare` indicates "equal" for more than one
// value in the tree. This is not invalid, but it does mean that you may be
// returned, via `res`, *any* of the values in the tree that `compare` deems
// equal to `v`, and which you get is arbitrary -- it depends on which is
// closest to the root.
bool contains(const T& v, T* res) const {
ImplNode* node = Impl::find_worker(v);
if (node) {
*res = node->item;
return true;
}
return false;
}
// Determine whether the tree contains `v` and if so return the address of
// the stored version. The comments on `::contains` about the meaning of
// `C::compare` apply here too.
T* maybeLookup(const T& v) {
ImplNode* node = Impl::find_worker(v);
if (node) {
return &(node->item);
}
return nullptr;
}
// AvlTree::Iter is also public; it's just pass-through from AvlTreeImpl.
// See documentation above on AvlTree::Iter on how to use it.
};
} /* namespace js */
#endif /* ds_AvlTree_h */