src/v8/src/compiler/persistent-map.h - cobalt - Git at Google

 // Copyright 2017 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_COMPILER_PERSISTENT_MAP_H_
 #define V8_COMPILER_PERSISTENT_MAP_H_

 #include <array>
 #include <tuple>

 #include "src/base/functional.h"
 #include "src/zone/zone-containers.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 // PersistentMap is a persistent map datastructure based on hash trees (a binary
 // tree using the bits of a hash value as addresses). The map is a conceptually
 // infinite: All keys are initially mapped to a default value, values are
 // deleted by overwriting them with the default value. The iterators produce
 // exactly the keys that are not the default value. The hash values should have
 // high variance in their high bits, so dense integers are a bad choice.
 // Complexity:
 // - Copy and assignment: O(1)
 // - access: O(log n)
 // - update: O(log n) time and space
 // - iteration: amortized O(1) per step
 // - Zip: O(n)
 // - equality check: O(n)
 // TODO(tebbi): Cache map transitions to avoid re-allocation of the same map.
 // TODO(tebbi): Implement an O(1) equality check based on hash consing or
 //              something similar.
 template <class Key, class Value, class Hasher = base::hash<Key>>
 class PersistentMap {
  public:
   using key_type = Key;
   using mapped_type = Value;
   using value_type = std::pair<Key, Value>;

  private:
   static constexpr size_t kHashBits = 32;
   enum Bit : int { kLeft = 0, kRight = 1 };

   // Access hash bits starting from the high bits and compare them according to
   // their unsigned value. This way, the order in the hash tree is compatible
   // with numeric hash comparisons.
   class HashValue;

   struct KeyValue : std::pair<Key, Value> {
     const Key& key() const { return this->first; }
     const Value& value() const { return this->second; }
     using std::pair<Key, Value>::pair;
   };

   struct FocusedTree;

  public:
   // Depth of the last added element. This is a cheap estimate for the size of
   // the hash tree.
   size_t last_depth() const {
     if (tree_) {
       return tree_->length;
     } else {
       return 0;
     }
   }

   const Value& Get(const Key& key) const {
     HashValue key_hash = HashValue(Hasher()(key));
     const FocusedTree* tree = FindHash(key_hash);
     return GetFocusedValue(tree, key);
   }

   // Add or overwrite an existing key-value pair.
   void Set(Key key, Value value);

   bool operator==(const PersistentMap& other) const {
     if (tree_ == other.tree_) return true;
     if (def_value_ != other.def_value_) return false;
     for (const std::tuple<Key, Value, Value>& triple : Zip(other)) {
       if (std::get<1>(triple) != std::get<2>(triple)) return false;
     }
     return true;
   }

   bool operator!=(const PersistentMap& other) const {
     return !(*this == other);
   }

   // The iterator produces key-value pairs in the lexicographical order of
   // hash value and key. It produces exactly the key-value pairs where the value
   // is not the default value.
   class iterator;

   iterator begin() const {
     if (!tree_) return end();
     return iterator::begin(tree_, def_value_);
   }
   iterator end() const { return iterator::end(def_value_); }

   // Iterator to traverse two maps in lockstep, producing matching value pairs
   // for each key where at least one value is different from the respective
   // default.
   class double_iterator;

   // An iterable to iterate over the two maps in lockstep.
   struct ZipIterable {
     PersistentMap a;
     PersistentMap b;
     double_iterator begin() { return double_iterator(a.begin(), b.begin()); }
     double_iterator end() { return double_iterator(a.end(), b.end()); }
   };

   ZipIterable Zip(const PersistentMap& other) const { return {*this, other}; }

   explicit PersistentMap(Zone* zone, Value def_value = Value())
       : PersistentMap(nullptr, zone, def_value) {}

  private:
   // Find the {FocusedTree} that contains a key-value pair with key hash {hash}.
   const FocusedTree* FindHash(HashValue hash) const;

   // Find the {FocusedTree} that contains a key-value pair with key hash {hash}.
   // Output the path to this {FocusedTree} and its length. If no such
   // {FocusedTree} exists, return {nullptr} and output the path to the last node
   // with a matching hash prefix. Note that {length} is the length of the found
   // path and may be less than the length of the found {FocusedTree}.
   const FocusedTree* FindHash(HashValue hash,
                               std::array<const FocusedTree*, kHashBits>* path,
                               int* length) const;

   // Load value from the leaf node on the focused path of {tree}.
   const Value& GetFocusedValue(const FocusedTree* tree, const Key& key) const;

   // Return the {FocusedTree} representing the left (bit==kLeft) or right
   // (bit==kRight) child of the node on the path of {tree} at tree level
   // {level}.
   static const FocusedTree* GetChild(const FocusedTree* tree, int level,
                                      Bit bit);

   // Find the leftmost path in the tree, starting at the node at tree level
   // {level} on the path of {start}. Output the level of the leaf to {level} and
   // the path to {path}.
   static const FocusedTree* FindLeftmost(
       const FocusedTree* start, int* level,
       std::array<const FocusedTree*, kHashBits>* path);

   PersistentMap(const FocusedTree* tree, Zone* zone, Value def_value)
       : tree_(tree), def_value_(def_value), zone_(zone) {}

   const FocusedTree* tree_;
   Value def_value_;
   Zone* zone_;
 };

 // This structure represents a hash tree with one focused path to a specific
 // leaf. For the focused leaf, it stores key, value and key hash. The path is
 // defined by the hash bits of the focused leaf. In a traditional tree
 // datastructure, the nodes of a path form a linked list with the values being
 // the pointers outside of this path. Instead of storing all of these nodes,
 // we store an array of the pointers pointing outside of the path. This is
 // similar to the stack used when doing DFS traversal of a tree. The hash of
 // the leaf is used to know if the pointers point to the left or the
 // right of the path. As there is no explicit representation of a tree node,
 // this structure also represents all the nodes on its path. The intended node
 // depends on the tree depth, which is always clear from the referencing
 // context. So the pointer to a {FocusedTree} stored in the
 // {PersistentMap.tree_} always references the root, while a pointer from a
 // focused node of another {FocusedTree} always references to one tree level
 // lower than before.
 template <class Key, class Value, class Hasher>
 struct PersistentMap<Key, Value, Hasher>::FocusedTree {
   KeyValue key_value;
   // The depth of the focused path, that is, the number of pointers stored in
   // this structure.
   int8_t length;
   HashValue key_hash;
   // Out-of-line storage for hash collisions.
   const ZoneMap<Key, Value>* more;
   using more_iterator = typename ZoneMap<Key, Value>::const_iterator;
   // {path_array} has to be the last member: To store an array inline, we
   // over-allocate memory for this structure and access memory beyond
   // {path_array}. This corresponds to a flexible array member as defined in
   // C99.
   const FocusedTree* path_array[1];
   const FocusedTree*& path(int i) {
     DCHECK(i < length);
     return reinterpret_cast<const FocusedTree**>(
         reinterpret_cast<byte*>(this) + offsetof(FocusedTree, path_array))[i];
   }
   const FocusedTree* path(int i) const {
     DCHECK(i < length);
     return reinterpret_cast<const FocusedTree* const*>(
         reinterpret_cast<const byte*>(this) +
         offsetof(FocusedTree, path_array))[i];
   }
 };

 template <class Key, class Value, class Hasher>
 class PersistentMap<Key, Value, Hasher>::HashValue {
  public:
   explicit HashValue(size_t hash) : bits_(static_cast<uint32_t>(hash)) {}

   Bit operator[](int pos) const {
     DCHECK_LT(pos, kHashBits);
     return bits_ & (static_cast<decltype(bits_)>(1) << (kHashBits - pos - 1))
                ? kRight
                : kLeft;
   }

   bool operator<(HashValue other) const { return bits_ < other.bits_; }
   bool operator==(HashValue other) const { return bits_ == other.bits_; }
   bool operator!=(HashValue other) const { return bits_ != other.bits_; }
   HashValue operator^(HashValue other) const {
     return HashValue(bits_ ^ other.bits_);
   }

  private:
   static_assert(sizeof(uint32_t) * 8 == kHashBits, "wrong type for bits_");
   uint32_t bits_;
 };

 template <class Key, class Value, class Hasher>
 class PersistentMap<Key, Value, Hasher>::iterator {
  public:
   const value_type operator*() const {
     if (current_->more) {
       return *more_iter_;
     } else {
       return current_->key_value;
     }
   }

   iterator& operator++() {
     do {
       if (!current_) {
         // Iterator is past the end.
         return *this;
       }
       if (current_->more) {
         DCHECK(more_iter_ != current_->more->end());
         ++more_iter_;
         if (more_iter_ != current_->more->end()) return *this;
       }
       if (level_ == 0) {
         *this = end(def_value_);
         return *this;
       }
       --level_;
       while (current_->key_hash[level_] == kRight || path_[level_] == nullptr) {
         if (level_ == 0) {
           *this = end(def_value_);
           return *this;
         }
         --level_;
       }
       const FocusedTree* first_right_alternative = path_[level_];
       level_++;
       current_ = FindLeftmost(first_right_alternative, &level_, &path_);
       if (current_->more) {
         more_iter_ = current_->more->begin();
       }
     } while (!((**this).second != def_value()));
     return *this;
   }

   bool operator==(const iterator& other) const {
     if (is_end()) return other.is_end();
     if (other.is_end()) return false;
     if (current_->key_hash != other.current_->key_hash) {
       return false;
     } else {
       return (**this).first == (*other).first;
     }
   }
   bool operator!=(const iterator& other) const { return !(*this == other); }

   bool operator<(const iterator& other) const {
     if (is_end()) return false;
     if (other.is_end()) return true;
     if (current_->key_hash == other.current_->key_hash) {
       return (**this).first < (*other).first;
     } else {
       return current_->key_hash < other.current_->key_hash;
     }
   }

   bool is_end() const { return current_ == nullptr; }

   const Value& def_value() { return def_value_; }

   static iterator begin(const FocusedTree* tree, Value def_value) {
     iterator i(def_value);
     i.current_ = FindLeftmost(tree, &i.level_, &i.path_);
     if (i.current_->more) {
       i.more_iter_ = i.current_->more->begin();
     }
     // Skip entries with default value. PersistentMap iterators must never point
     // to a default value.
     while (!i.is_end() && !((*i).second != def_value)) ++i;
     return i;
   }

   static iterator end(Value def_value) { return iterator(def_value); }

  private:
   int level_;
   typename FocusedTree::more_iterator more_iter_;
   const FocusedTree* current_;
   std::array<const FocusedTree*, kHashBits> path_;
   Value def_value_;

   explicit iterator(Value def_value)
       : level_(0), current_(nullptr), def_value_(def_value) {}
 };

 template <class Key, class Value, class Hasher>
 class PersistentMap<Key, Value, Hasher>::double_iterator {
  public:
   std::tuple<Key, Value, Value> operator*() {
     if (first_current_) {
       auto pair = *first_;
       return std::make_tuple(
           pair.first, pair.second,
           second_current_ ? (*second_).second : second_.def_value());
     } else {
       DCHECK(second_current_);
       auto pair = *second_;
       return std::make_tuple(pair.first, first_.def_value(), pair.second);
     }
   }

   double_iterator& operator++() {
 #ifdef DEBUG
     iterator old_first = first_;
     iterator old_second = second_;
 #endif
     if (first_current_) {
       ++first_;
       DCHECK(old_first < first_);
     }
     if (second_current_) {
       ++second_;
       DCHECK(old_second < second_);
     }
     return *this = double_iterator(first_, second_);
   }

   double_iterator(iterator first, iterator second)
       : first_(first), second_(second) {
     if (first_ == second_) {
       first_current_ = second_current_ = true;
     } else if (first_ < second_) {
       first_current_ = true;
       second_current_ = false;
     } else {
       DCHECK(second_ < first_);
       first_current_ = false;
       second_current_ = true;
     }
   }

   bool operator!=(const double_iterator& other) {
     return first_ != other.first_ || second_ != other.second_;
   }

   bool is_end() const { return first_.is_end() && second_.is_end(); }

  private:
   iterator first_;
   iterator second_;
   bool first_current_;
   bool second_current_;
 };

 template <class Key, class Value, class Hasher>
 void PersistentMap<Key, Value, Hasher>::Set(Key key, Value value) {
   HashValue key_hash = HashValue(Hasher()(key));
   std::array<const FocusedTree*, kHashBits> path;
   int length = 0;
   const FocusedTree* old = FindHash(key_hash, &path, &length);
   ZoneMap<Key, Value>* more = nullptr;
   if (!(GetFocusedValue(old, key) != value)) return;
   if (old && !(old->more == nullptr && old->key_value.key() == key)) {
     more = new (zone_->New(sizeof(*more))) ZoneMap<Key, Value>(zone_);
     if (old->more) {
       *more = *old->more;
     } else {
       (*more)[old->key_value.key()] = old->key_value.value();
     }
     (*more)[key] = value;
   }
   FocusedTree* tree =
       new (zone_->New(sizeof(FocusedTree) +
                       std::max(0, length - 1) * sizeof(const FocusedTree*)))
           FocusedTree{KeyValue(std::move(key), std::move(value)),
                       static_cast<int8_t>(length),
                       key_hash,
                       more,
                       {}};
   for (int i = 0; i < length; ++i) {
     tree->path(i) = path[i];
   }
   *this = PersistentMap(tree, zone_, def_value_);
 }

 template <class Key, class Value, class Hasher>
 const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
 PersistentMap<Key, Value, Hasher>::FindHash(HashValue hash) const {
   const FocusedTree* tree = tree_;
   int level = 0;
   while (tree && hash != tree->key_hash) {
     while ((hash ^ tree->key_hash)[level] == 0) {
       ++level;
     }
     tree = level < tree->length ? tree->path(level) : nullptr;
     ++level;
   }
   return tree;
 }

 template <class Key, class Value, class Hasher>
 const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
 PersistentMap<Key, Value, Hasher>::FindHash(
     HashValue hash, std::array<const FocusedTree*, kHashBits>* path,
     int* length) const {
   const FocusedTree* tree = tree_;
   int level = 0;
   while (tree && hash != tree->key_hash) {
     int map_length = tree->length;
     while ((hash ^ tree->key_hash)[level] == 0) {
       (*path)[level] = level < map_length ? tree->path(level) : nullptr;
       ++level;
     }
     (*path)[level] = tree;
     tree = level < tree->length ? tree->path(level) : nullptr;
     ++level;
   }
   if (tree) {
     while (level < tree->length) {
       (*path)[level] = tree->path(level);
       ++level;
     }
   }
   *length = level;
   return tree;
 }

 template <class Key, class Value, class Hasher>
 const Value& PersistentMap<Key, Value, Hasher>::GetFocusedValue(
     const FocusedTree* tree, const Key& key) const {
   if (!tree) {
     return def_value_;
   }
   if (tree->more) {
     auto it = tree->more->find(key);
     if (it == tree->more->end())
       return def_value_;
     else
       return it->second;
   } else {
     if (key == tree->key_value.key()) {
       return tree->key_value.value();
     } else {
       return def_value_;
     }
   }
 }

 template <class Key, class Value, class Hasher>
 const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
 PersistentMap<Key, Value, Hasher>::GetChild(const FocusedTree* tree, int level,
                                             Bit bit) {
   if (tree->key_hash[level] == bit) {
     return tree;
   } else if (level < tree->length) {
     return tree->path(level);
   } else {
     return nullptr;
   }
 }

 template <class Key, class Value, class Hasher>
 const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
 PersistentMap<Key, Value, Hasher>::FindLeftmost(
     const FocusedTree* start, int* level,
     std::array<const FocusedTree*, kHashBits>* path) {
   const FocusedTree* current = start;
   while (*level < current->length) {
     if (const FocusedTree* child = GetChild(current, *level, kLeft)) {
       (*path)[*level] = GetChild(current, *level, kRight);
       current = child;
       ++*level;
     } else if (const FocusedTree* child = GetChild(current, *level, kRight)) {
       (*path)[*level] = GetChild(current, *level, kLeft);
       current = child;
       ++*level;
     } else {
       UNREACHABLE();
     }
   }
   return current;
 }

 template <class Key, class Value, class Hasher>
 std::ostream& operator<<(std::ostream& os,
                          const PersistentMap<Key, Value, Hasher>& map) {
   os << "{";
   bool first = true;
   for (auto pair : map) {
     if (!first) os << ", ";
     first = false;
     os << pair.first << ": " << pair.second;
   }
   return os << "}";
 }

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_COMPILER_PERSISTENT_MAP_H_
	// Copyright 2017 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_COMPILER_PERSISTENT_MAP_H_
	#define V8_COMPILER_PERSISTENT_MAP_H_

	#include <array>
	#include <tuple>

	#include "src/base/functional.h"
	#include "src/zone/zone-containers.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	// PersistentMap is a persistent map datastructure based on hash trees (a binary
	// tree using the bits of a hash value as addresses). The map is a conceptually
	// infinite: All keys are initially mapped to a default value, values are
	// deleted by overwriting them with the default value. The iterators produce
	// exactly the keys that are not the default value. The hash values should have
	// high variance in their high bits, so dense integers are a bad choice.
	// Complexity:
	// - Copy and assignment: O(1)
	// - access: O(log n)
	// - update: O(log n) time and space
	// - iteration: amortized O(1) per step
	// - Zip: O(n)
	// - equality check: O(n)
	// TODO(tebbi): Cache map transitions to avoid re-allocation of the same map.
	// TODO(tebbi): Implement an O(1) equality check based on hash consing or
	// something similar.
	template <class Key, class Value, class Hasher = base::hash<Key>>
	class PersistentMap {
	public:
	using key_type = Key;
	using mapped_type = Value;
	using value_type = std::pair<Key, Value>;

	private:
	static constexpr size_t kHashBits = 32;
	enum Bit : int { kLeft = 0, kRight = 1 };

	// Access hash bits starting from the high bits and compare them according to
	// their unsigned value. This way, the order in the hash tree is compatible
	// with numeric hash comparisons.
	class HashValue;

	struct KeyValue : std::pair<Key, Value> {
	const Key& key() const { return this->first; }
	const Value& value() const { return this->second; }
	using std::pair<Key, Value>::pair;
	};

	struct FocusedTree;

	public:
	// Depth of the last added element. This is a cheap estimate for the size of
	// the hash tree.
	size_t last_depth() const {
	if (tree_) {
	return tree_->length;
	} else {
	return 0;
	}
	}

	const Value& Get(const Key& key) const {
	HashValue key_hash = HashValue(Hasher()(key));
	const FocusedTree* tree = FindHash(key_hash);
	return GetFocusedValue(tree, key);
	}

	// Add or overwrite an existing key-value pair.
	void Set(Key key, Value value);

	bool operator==(const PersistentMap& other) const {
	if (tree_ == other.tree_) return true;
	if (def_value_ != other.def_value_) return false;
	for (const std::tuple<Key, Value, Value>& triple : Zip(other)) {
	if (std::get<1>(triple) != std::get<2>(triple)) return false;
	}
	return true;
	}

	bool operator!=(const PersistentMap& other) const {
	return !(*this == other);
	}

	// The iterator produces key-value pairs in the lexicographical order of
	// hash value and key. It produces exactly the key-value pairs where the value
	// is not the default value.
	class iterator;

	iterator begin() const {
	if (!tree_) return end();
	return iterator::begin(tree_, def_value_);
	}
	iterator end() const { return iterator::end(def_value_); }

	// Iterator to traverse two maps in lockstep, producing matching value pairs
	// for each key where at least one value is different from the respective
	// default.
	class double_iterator;

	// An iterable to iterate over the two maps in lockstep.
	struct ZipIterable {
	PersistentMap a;
	PersistentMap b;
	double_iterator begin() { return double_iterator(a.begin(), b.begin()); }
	double_iterator end() { return double_iterator(a.end(), b.end()); }
	};

	ZipIterable Zip(const PersistentMap& other) const { return {*this, other}; }

	explicit PersistentMap(Zone* zone, Value def_value = Value())
	: PersistentMap(nullptr, zone, def_value) {}

	private:
	// Find the {FocusedTree} that contains a key-value pair with key hash {hash}.
	const FocusedTree* FindHash(HashValue hash) const;

	// Find the {FocusedTree} that contains a key-value pair with key hash {hash}.
	// Output the path to this {FocusedTree} and its length. If no such
	// {FocusedTree} exists, return {nullptr} and output the path to the last node
	// with a matching hash prefix. Note that {length} is the length of the found
	// path and may be less than the length of the found {FocusedTree}.
	const FocusedTree* FindHash(HashValue hash,
	std::array<const FocusedTree, kHashBits> path,
	int* length) const;

	// Load value from the leaf node on the focused path of {tree}.
	const Value& GetFocusedValue(const FocusedTree* tree, const Key& key) const;

	// Return the {FocusedTree} representing the left (bit==kLeft) or right
	// (bit==kRight) child of the node on the path of {tree} at tree level
	// {level}.
	static const FocusedTree* GetChild(const FocusedTree* tree, int level,
	Bit bit);

	// Find the leftmost path in the tree, starting at the node at tree level
	// {level} on the path of {start}. Output the level of the leaf to {level} and
	// the path to {path}.
	static const FocusedTree* FindLeftmost(
	const FocusedTree* start, int* level,
	std::array<const FocusedTree, kHashBits> path);

	PersistentMap(const FocusedTree* tree, Zone* zone, Value def_value)
	: tree_(tree), def_value_(def_value), zone_(zone) {}

	const FocusedTree* tree_;
	Value def_value_;
	Zone* zone_;
	};

	// This structure represents a hash tree with one focused path to a specific
	// leaf. For the focused leaf, it stores key, value and key hash. The path is
	// defined by the hash bits of the focused leaf. In a traditional tree
	// datastructure, the nodes of a path form a linked list with the values being
	// the pointers outside of this path. Instead of storing all of these nodes,
	// we store an array of the pointers pointing outside of the path. This is
	// similar to the stack used when doing DFS traversal of a tree. The hash of
	// the leaf is used to know if the pointers point to the left or the
	// right of the path. As there is no explicit representation of a tree node,
	// this structure also represents all the nodes on its path. The intended node
	// depends on the tree depth, which is always clear from the referencing
	// context. So the pointer to a {FocusedTree} stored in the
	// {PersistentMap.tree_} always references the root, while a pointer from a
	// focused node of another {FocusedTree} always references to one tree level
	// lower than before.
	template <class Key, class Value, class Hasher>
	struct PersistentMap<Key, Value, Hasher>::FocusedTree {
	KeyValue key_value;
	// The depth of the focused path, that is, the number of pointers stored in
	// this structure.
	int8_t length;
	HashValue key_hash;
	// Out-of-line storage for hash collisions.
	const ZoneMap<Key, Value>* more;
	using more_iterator = typename ZoneMap<Key, Value>::const_iterator;
	// {path_array} has to be the last member: To store an array inline, we
	// over-allocate memory for this structure and access memory beyond
	// {path_array}. This corresponds to a flexible array member as defined in
	// C99.
	const FocusedTree* path_array[1];
	const FocusedTree*& path(int i) {
	DCHECK(i < length);
	return reinterpret_cast<const FocusedTree**>(
	reinterpret_cast<byte*>(this) + offsetof(FocusedTree, path_array))[i];
	}
	const FocusedTree* path(int i) const {
	DCHECK(i < length);
	return reinterpret_cast<const FocusedTree* const*>(
	reinterpret_cast<const byte*>(this) +
	offsetof(FocusedTree, path_array))[i];
	}
	};

	template <class Key, class Value, class Hasher>
	class PersistentMap<Key, Value, Hasher>::HashValue {
	public:
	explicit HashValue(size_t hash) : bits_(static_cast<uint32_t>(hash)) {}

	Bit operator[](int pos) const {
	DCHECK_LT(pos, kHashBits);
	return bits_ & (static_cast<decltype(bits_)>(1) << (kHashBits - pos - 1))
	? kRight
	: kLeft;
	}

	bool operator<(HashValue other) const { return bits_ < other.bits_; }
	bool operator==(HashValue other) const { return bits_ == other.bits_; }
	bool operator!=(HashValue other) const { return bits_ != other.bits_; }
	HashValue operator^(HashValue other) const {
	return HashValue(bits_ ^ other.bits_);
	}

	private:
	static_assert(sizeof(uint32_t) * 8 == kHashBits, "wrong type for bits_");
	uint32_t bits_;
	};

	template <class Key, class Value, class Hasher>
	class PersistentMap<Key, Value, Hasher>::iterator {
	public:
	const value_type operator*() const {
	if (current_->more) {
	return *more_iter_;
	} else {
	return current_->key_value;
	}
	}

	iterator& operator++() {
	do {
	if (!current_) {
	// Iterator is past the end.
	return *this;
	}
	if (current_->more) {
	DCHECK(more_iter_ != current_->more->end());
	++more_iter_;
	if (more_iter_ != current_->more->end()) return *this;
	}
	if (level_ == 0) {
	*this = end(def_value_);
	return *this;
	}
	--level_;
	while (current_->key_hash[level_] == kRight \|\| path_[level_] == nullptr) {
	if (level_ == 0) {
	*this = end(def_value_);
	return *this;
	}
	--level_;
	}
	const FocusedTree* first_right_alternative = path_[level_];
	level_++;
	current_ = FindLeftmost(first_right_alternative, &level_, &path_);
	if (current_->more) {
	more_iter_ = current_->more->begin();
	}
	} while (!((**this).second != def_value()));
	return *this;
	}

	bool operator==(const iterator& other) const {
	if (is_end()) return other.is_end();
	if (other.is_end()) return false;
	if (current_->key_hash != other.current_->key_hash) {
	return false;
	} else {
	return (*this).first == (other).first;
	}
	}
	bool operator!=(const iterator& other) const { return !(*this == other); }

	bool operator<(const iterator& other) const {
	if (is_end()) return false;
	if (other.is_end()) return true;
	if (current_->key_hash == other.current_->key_hash) {
	return (*this).first < (other).first;
	} else {
	return current_->key_hash < other.current_->key_hash;
	}
	}

	bool is_end() const { return current_ == nullptr; }

	const Value& def_value() { return def_value_; }

	static iterator begin(const FocusedTree* tree, Value def_value) {
	iterator i(def_value);
	i.current_ = FindLeftmost(tree, &i.level_, &i.path_);
	if (i.current_->more) {
	i.more_iter_ = i.current_->more->begin();
	}
	// Skip entries with default value. PersistentMap iterators must never point
	// to a default value.
	while (!i.is_end() && !((*i).second != def_value)) ++i;
	return i;
	}

	static iterator end(Value def_value) { return iterator(def_value); }

	private:
	int level_;
	typename FocusedTree::more_iterator more_iter_;
	const FocusedTree* current_;
	std::array<const FocusedTree*, kHashBits> path_;
	Value def_value_;

	explicit iterator(Value def_value)
	: level_(0), current_(nullptr), def_value_(def_value) {}
	};

	template <class Key, class Value, class Hasher>
	class PersistentMap<Key, Value, Hasher>::double_iterator {
	public:
	std::tuple<Key, Value, Value> operator*() {
	if (first_current_) {
	auto pair = *first_;
	return std::make_tuple(
	pair.first, pair.second,
	second_current_ ? (*second_).second : second_.def_value());
	} else {
	DCHECK(second_current_);
	auto pair = *second_;
	return std::make_tuple(pair.first, first_.def_value(), pair.second);
	}
	}

	double_iterator& operator++() {
	#ifdef DEBUG
	iterator old_first = first_;
	iterator old_second = second_;
	#endif
	if (first_current_) {
	++first_;
	DCHECK(old_first < first_);
	}
	if (second_current_) {
	++second_;
	DCHECK(old_second < second_);
	}
	return *this = double_iterator(first_, second_);
	}

	double_iterator(iterator first, iterator second)
	: first_(first), second_(second) {
	if (first_ == second_) {
	first_current_ = second_current_ = true;
	} else if (first_ < second_) {
	first_current_ = true;
	second_current_ = false;
	} else {
	DCHECK(second_ < first_);
	first_current_ = false;
	second_current_ = true;
	}
	}

	bool operator!=(const double_iterator& other) {
	return first_ != other.first_ \|\| second_ != other.second_;
	}

	bool is_end() const { return first_.is_end() && second_.is_end(); }

	private:
	iterator first_;
	iterator second_;
	bool first_current_;
	bool second_current_;
	};

	template <class Key, class Value, class Hasher>
	void PersistentMap<Key, Value, Hasher>::Set(Key key, Value value) {
	HashValue key_hash = HashValue(Hasher()(key));
	std::array<const FocusedTree*, kHashBits> path;
	int length = 0;
	const FocusedTree* old = FindHash(key_hash, &path, &length);
	ZoneMap<Key, Value>* more = nullptr;
	if (!(GetFocusedValue(old, key) != value)) return;
	if (old && !(old->more == nullptr && old->key_value.key() == key)) {
	more = new (zone_->New(sizeof(*more))) ZoneMap<Key, Value>(zone_);
	if (old->more) {
	more = old->more;
	} else {
	(*more)[old->key_value.key()] = old->key_value.value();
	}
	(*more)[key] = value;
	}
	FocusedTree* tree =
	new (zone_->New(sizeof(FocusedTree) +
	std::max(0, length - 1) * sizeof(const FocusedTree*)))
	FocusedTree{KeyValue(std::move(key), std::move(value)),
	static_cast<int8_t>(length),
	key_hash,
	more,
	{}};
	for (int i = 0; i < length; ++i) {
	tree->path(i) = path[i];
	}
	*this = PersistentMap(tree, zone_, def_value_);
	}

	template <class Key, class Value, class Hasher>
	const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
	PersistentMap<Key, Value, Hasher>::FindHash(HashValue hash) const {
	const FocusedTree* tree = tree_;
	int level = 0;
	while (tree && hash != tree->key_hash) {
	while ((hash ^ tree->key_hash)[level] == 0) {
	++level;
	}
	tree = level < tree->length ? tree->path(level) : nullptr;
	++level;
	}
	return tree;
	}

	template <class Key, class Value, class Hasher>
	const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
	PersistentMap<Key, Value, Hasher>::FindHash(
	HashValue hash, std::array<const FocusedTree, kHashBits> path,
	int* length) const {
	const FocusedTree* tree = tree_;
	int level = 0;
	while (tree && hash != tree->key_hash) {
	int map_length = tree->length;
	while ((hash ^ tree->key_hash)[level] == 0) {
	(*path)[level] = level < map_length ? tree->path(level) : nullptr;
	++level;
	}
	(*path)[level] = tree;
	tree = level < tree->length ? tree->path(level) : nullptr;
	++level;
	}
	if (tree) {
	while (level < tree->length) {
	(*path)[level] = tree->path(level);
	++level;
	}
	}
	*length = level;
	return tree;
	}

	template <class Key, class Value, class Hasher>
	const Value& PersistentMap<Key, Value, Hasher>::GetFocusedValue(
	const FocusedTree* tree, const Key& key) const {
	if (!tree) {
	return def_value_;
	}
	if (tree->more) {
	auto it = tree->more->find(key);
	if (it == tree->more->end())
	return def_value_;
	else
	return it->second;
	} else {
	if (key == tree->key_value.key()) {
	return tree->key_value.value();
	} else {
	return def_value_;
	}
	}
	}

	template <class Key, class Value, class Hasher>
	const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
	PersistentMap<Key, Value, Hasher>::GetChild(const FocusedTree* tree, int level,
	Bit bit) {
	if (tree->key_hash[level] == bit) {
	return tree;
	} else if (level < tree->length) {
	return tree->path(level);
	} else {
	return nullptr;
	}
	}

	template <class Key, class Value, class Hasher>
	const typename PersistentMap<Key, Value, Hasher>::FocusedTree*
	PersistentMap<Key, Value, Hasher>::FindLeftmost(
	const FocusedTree* start, int* level,
	std::array<const FocusedTree, kHashBits> path) {
	const FocusedTree* current = start;
	while (*level < current->length) {
	if (const FocusedTree* child = GetChild(current, *level, kLeft)) {
	(path)[level] = GetChild(current, *level, kRight);
	current = child;
	++*level;
	} else if (const FocusedTree* child = GetChild(current, *level, kRight)) {
	(path)[level] = GetChild(current, *level, kLeft);
	current = child;
	++*level;
	} else {
	UNREACHABLE();
	}
	}
	return current;
	}

	template <class Key, class Value, class Hasher>
	std::ostream& operator<<(std::ostream& os,
	const PersistentMap<Key, Value, Hasher>& map) {
	os << "{";
	bool first = true;
	for (auto pair : map) {
	if (!first) os << ", ";
	first = false;
	os << pair.first << ": " << pair.second;
	}
	return os << "}";
	}

	} // namespace compiler
	} // namespace internal
	} // namespace v8

	#endif // V8_COMPILER_PERSISTENT_MAP_H_