src/third_party/v8/src/utils/identity-map.cc - cobalt - Git at Google

 // Copyright 2015 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.

 #include "src/utils/identity-map.h"

 #include "src/base/functional.h"
 #include "src/base/logging.h"
 #include "src/heap/heap.h"
 #include "src/roots/roots-inl.h"

 namespace v8 {
 namespace internal {

 static const int kInitialIdentityMapSize = 4;
 static const int kResizeFactor = 2;

 IdentityMapBase::~IdentityMapBase() {
   // Clear must be called by the subclass to avoid calling the virtual
   // DeleteArray function from the destructor.
   DCHECK_NULL(keys_);
 }

 void IdentityMapBase::Clear() {
   if (keys_) {
     DCHECK(!is_iterable());
     DCHECK_NOT_NULL(strong_roots_entry_);
     heap_->UnregisterStrongRoots(strong_roots_entry_);
     DeletePointerArray(reinterpret_cast<uintptr_t*>(keys_), capacity_);
     DeletePointerArray(values_, capacity_);
     keys_ = nullptr;
     strong_roots_entry_ = nullptr;
     values_ = nullptr;
     size_ = 0;
     capacity_ = 0;
     mask_ = 0;
   }
 }

 void IdentityMapBase::EnableIteration() {
   CHECK(!is_iterable());
   is_iterable_ = true;
 }

 void IdentityMapBase::DisableIteration() {
   CHECK(is_iterable());
   is_iterable_ = false;
 }

 int IdentityMapBase::ScanKeysFor(Address address, uint32_t hash) const {
   int start = hash & mask_;
   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
   for (int index = start; index < capacity_; index++) {
     if (keys_[index] == address) return index;  // Found.
     if (keys_[index] == not_mapped) return -1;  // Not found.
   }
   for (int index = 0; index < start; index++) {
     if (keys_[index] == address) return index;  // Found.
     if (keys_[index] == not_mapped) return -1;  // Not found.
   }
   return -1;
 }

 std::pair<int, bool> IdentityMapBase::InsertKey(Address address,
                                                 uint32_t hash) {
   DCHECK_EQ(gc_counter_, heap_->gc_count());

   // Grow the map if we reached >= 80% occupancy.
   if (size_ + size_ / 4 >= capacity_) {
     Resize(capacity_ * kResizeFactor);
   }

   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();

   int start = hash & mask_;
   // Guaranteed to terminate since size_ < capacity_, there must be at least
   // one empty slot.
   int index = start;
   while (true) {
     if (keys_[index] == address) return {index, true};  // Found.
     if (keys_[index] == not_mapped) {                   // Free entry.
       size_++;
       DCHECK_LE(size_, capacity_);
       keys_[index] = address;
       return {index, false};
     }
     index = (index + 1) & mask_;
     // We should never loop back to the start.
     DCHECK_NE(index, start);
   }
 }

 bool IdentityMapBase::DeleteIndex(int index, uintptr_t* deleted_value) {
   if (deleted_value != nullptr) *deleted_value = values_[index];
   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
   DCHECK_NE(keys_[index], not_mapped);
   keys_[index] = not_mapped;
   values_[index] = 0;
   size_--;
   DCHECK_GE(size_, 0);

   if (capacity_ > kInitialIdentityMapSize &&
       size_ * kResizeFactor < capacity_ / kResizeFactor) {
     Resize(capacity_ / kResizeFactor);
     return true;  // No need to fix collisions as resize reinserts keys.
   }

   // Move any collisions to their new correct location.
   int next_index = index;
   for (;;) {
     next_index = (next_index + 1) & mask_;
     Address key = keys_[next_index];
     if (key == not_mapped) break;

     int expected_index = Hash(key) & mask_;
     if (index < next_index) {
       if (index < expected_index && expected_index <= next_index) continue;
     } else {
       DCHECK_GT(index, next_index);
       if (index < expected_index || expected_index <= next_index) continue;
     }

     DCHECK_EQ(not_mapped, keys_[index]);
     DCHECK_EQ(values_[index], 0);
     std::swap(keys_[index], keys_[next_index]);
     std::swap(values_[index], values_[next_index]);
     index = next_index;
   }

   return true;
 }

 int IdentityMapBase::Lookup(Address key) const {
   uint32_t hash = Hash(key);
   int index = ScanKeysFor(key, hash);
   if (index < 0 && gc_counter_ != heap_->gc_count()) {
     // Miss; rehash if there was a GC, then lookup again.
     const_cast<IdentityMapBase*>(this)->Rehash();
     index = ScanKeysFor(key, hash);
   }
   return index;
 }

 std::pair<int, bool> IdentityMapBase::LookupOrInsert(Address key) {
   uint32_t hash = Hash(key);
   // Perform an optimistic lookup.
   int index = ScanKeysFor(key, hash);
   bool already_exists;
   if (index < 0) {
     // Miss; rehash if there was a GC, then insert.
     if (gc_counter_ != heap_->gc_count()) Rehash();
     std::tie(index, already_exists) = InsertKey(key, hash);
   } else {
     already_exists = true;
   }
   DCHECK_GE(index, 0);
   return {index, already_exists};
 }

 uint32_t IdentityMapBase::Hash(Address address) const {
   CHECK_NE(address, ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
   return static_cast<uint32_t>(hasher_(address));
 }

 // Searches this map for the given key using the object's address
 // as the identity, returning:
 //    found => a pointer to the storage location for the value, true
 //    not found => a pointer to a new storage location for the value, false
 IdentityMapFindResult<uintptr_t> IdentityMapBase::FindOrInsertEntry(
     Address key) {
   CHECK(!is_iterable());  // Don't allow insertion while iterable.
   if (capacity_ == 0) {
     return {InsertEntry(key), false};
   }
   auto lookup_result = LookupOrInsert(key);
   return {&values_[lookup_result.first], lookup_result.second};
 }

 // Searches this map for the given key using the object's address
 // as the identity, returning:
 //    found => a pointer to the storage location for the value
 //    not found => {nullptr}
 IdentityMapBase::RawEntry IdentityMapBase::FindEntry(Address key) const {
   // Don't allow find by key while iterable (might rehash).
   CHECK(!is_iterable());
   if (size_ == 0) return nullptr;
   int index = Lookup(key);
   return index >= 0 ? &values_[index] : nullptr;
 }

 // Inserts the given key using the object's address as the identity, returning
 // a pointer to the new storage location for the value.
 IdentityMapBase::RawEntry IdentityMapBase::InsertEntry(Address key) {
   // Don't allow find by key while iterable (might rehash).
   CHECK(!is_iterable());
   if (capacity_ == 0) {
     // Allocate the initial storage for keys and values.
     capacity_ = kInitialIdentityMapSize;
     mask_ = kInitialIdentityMapSize - 1;
     gc_counter_ = heap_->gc_count();

     keys_ = reinterpret_cast<Address*>(NewPointerArray(capacity_));
     Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
     for (int i = 0; i < capacity_; i++) keys_[i] = not_mapped;
     values_ = NewPointerArray(capacity_);
     memset(values_, 0, sizeof(uintptr_t) * capacity_);

     strong_roots_entry_ = heap_->RegisterStrongRoots(
         FullObjectSlot(keys_), FullObjectSlot(keys_ + capacity_));
   } else {
     // Rehash if there was a GC, then insert.
     if (gc_counter_ != heap_->gc_count()) Rehash();
   }

   int index;
   bool already_exists;
   std::tie(index, already_exists) = InsertKey(key, Hash(key));
   DCHECK(!already_exists);
   return &values_[index];
 }

 // Deletes the given key from the map using the object's address as the
 // identity, returning true iff the key was found (in which case, the value
 // argument will be set to the deleted entry's value).
 bool IdentityMapBase::DeleteEntry(Address key, uintptr_t* deleted_value) {
   CHECK(!is_iterable());  // Don't allow deletion by key while iterable.
   if (size_ == 0) return false;
   int index = Lookup(key);
   if (index < 0) return false;  // No entry found.
   return DeleteIndex(index, deleted_value);
 }

 Address IdentityMapBase::KeyAtIndex(int index) const {
   DCHECK_LE(0, index);
   DCHECK_LT(index, capacity_);
   DCHECK_NE(keys_[index], ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
   CHECK(is_iterable());  // Must be iterable to access by index;
   return keys_[index];
 }

 IdentityMapBase::RawEntry IdentityMapBase::EntryAtIndex(int index) const {
   DCHECK_LE(0, index);
   DCHECK_LT(index, capacity_);
   DCHECK_NE(keys_[index], ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
   CHECK(is_iterable());  // Must be iterable to access by index;
   return &values_[index];
 }

 int IdentityMapBase::NextIndex(int index) const {
   DCHECK_LE(-1, index);
   DCHECK_LE(index, capacity_);
   CHECK(is_iterable());  // Must be iterable to access by index;
   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
   for (++index; index < capacity_; ++index) {
     if (keys_[index] != not_mapped) {
       return index;
     }
   }
   return capacity_;
 }

 void IdentityMapBase::Rehash() {
   CHECK(!is_iterable());  // Can't rehash while iterating.
   // Record the current GC counter.
   gc_counter_ = heap_->gc_count();
   // Assume that most objects won't be moved.
   std::vector<std::pair<Address, uintptr_t>> reinsert;
   // Search the table looking for keys that wouldn't be found with their
   // current hashcode and evacuate them.
   int last_empty = -1;
   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
   for (int i = 0; i < capacity_; i++) {
     if (keys_[i] == not_mapped) {
       last_empty = i;
     } else {
       int pos = Hash(keys_[i]) & mask_;
       if (pos <= last_empty || pos > i) {
         // Evacuate an entry that is in the wrong place.
         reinsert.push_back(std::pair<Address, uintptr_t>(keys_[i], values_[i]));
         keys_[i] = not_mapped;
         values_[i] = 0;
         last_empty = i;
         size_--;
       }
     }
   }
   // Reinsert all the key/value pairs that were in the wrong place.
   for (auto pair : reinsert) {
     int index = InsertKey(pair.first, Hash(pair.first)).first;
     DCHECK_GE(index, 0);
     values_[index] = pair.second;
   }
 }

 void IdentityMapBase::Resize(int new_capacity) {
   CHECK(!is_iterable());  // Can't resize while iterating.
   // Resize the internal storage and reinsert all the key/value pairs.
   DCHECK_GT(new_capacity, size_);
   int old_capacity = capacity_;
   Address* old_keys = keys_;
   uintptr_t* old_values = values_;

   capacity_ = new_capacity;
   mask_ = capacity_ - 1;
   gc_counter_ = heap_->gc_count();
   size_ = 0;

   keys_ = reinterpret_cast<Address*>(NewPointerArray(capacity_));
   Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
   for (int i = 0; i < capacity_; i++) keys_[i] = not_mapped;
   values_ = NewPointerArray(capacity_);
   memset(values_, 0, sizeof(uintptr_t) * capacity_);

   for (int i = 0; i < old_capacity; i++) {
     if (old_keys[i] == not_mapped) continue;
     int index = InsertKey(old_keys[i], Hash(old_keys[i])).first;
     DCHECK_GE(index, 0);
     values_[index] = old_values[i];
   }

   // Unregister old keys and register new keys.
   DCHECK_NOT_NULL(strong_roots_entry_);
   heap_->UpdateStrongRoots(strong_roots_entry_, FullObjectSlot(keys_),
                            FullObjectSlot(keys_ + capacity_));

   // Delete old storage;
   DeletePointerArray(reinterpret_cast<uintptr_t*>(old_keys), old_capacity);
   DeletePointerArray(old_values, old_capacity);
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2015 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.

	#include "src/utils/identity-map.h"

	#include "src/base/functional.h"
	#include "src/base/logging.h"
	#include "src/heap/heap.h"
	#include "src/roots/roots-inl.h"

	namespace v8 {
	namespace internal {

	static const int kInitialIdentityMapSize = 4;
	static const int kResizeFactor = 2;

	IdentityMapBase::~IdentityMapBase() {
	// Clear must be called by the subclass to avoid calling the virtual
	// DeleteArray function from the destructor.
	DCHECK_NULL(keys_);
	}

	void IdentityMapBase::Clear() {
	if (keys_) {
	DCHECK(!is_iterable());
	DCHECK_NOT_NULL(strong_roots_entry_);
	heap_->UnregisterStrongRoots(strong_roots_entry_);
	DeletePointerArray(reinterpret_cast<uintptr_t*>(keys_), capacity_);
	DeletePointerArray(values_, capacity_);
	keys_ = nullptr;
	strong_roots_entry_ = nullptr;
	values_ = nullptr;
	size_ = 0;
	capacity_ = 0;
	mask_ = 0;
	}
	}

	void IdentityMapBase::EnableIteration() {
	CHECK(!is_iterable());
	is_iterable_ = true;
	}

	void IdentityMapBase::DisableIteration() {
	CHECK(is_iterable());
	is_iterable_ = false;
	}

	int IdentityMapBase::ScanKeysFor(Address address, uint32_t hash) const {
	int start = hash & mask_;
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	for (int index = start; index < capacity_; index++) {
	if (keys_[index] == address) return index; // Found.
	if (keys_[index] == not_mapped) return -1; // Not found.
	}
	for (int index = 0; index < start; index++) {
	if (keys_[index] == address) return index; // Found.
	if (keys_[index] == not_mapped) return -1; // Not found.
	}
	return -1;
	}

	std::pair<int, bool> IdentityMapBase::InsertKey(Address address,
	uint32_t hash) {
	DCHECK_EQ(gc_counter_, heap_->gc_count());

	// Grow the map if we reached >= 80% occupancy.
	if (size_ + size_ / 4 >= capacity_) {
	Resize(capacity_ * kResizeFactor);
	}

	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();

	int start = hash & mask_;
	// Guaranteed to terminate since size_ < capacity_, there must be at least
	// one empty slot.
	int index = start;
	while (true) {
	if (keys_[index] == address) return {index, true}; // Found.
	if (keys_[index] == not_mapped) { // Free entry.
	size_++;
	DCHECK_LE(size_, capacity_);
	keys_[index] = address;
	return {index, false};
	}
	index = (index + 1) & mask_;
	// We should never loop back to the start.
	DCHECK_NE(index, start);
	}
	}

	bool IdentityMapBase::DeleteIndex(int index, uintptr_t* deleted_value) {
	if (deleted_value != nullptr) *deleted_value = values_[index];
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	DCHECK_NE(keys_[index], not_mapped);
	keys_[index] = not_mapped;
	values_[index] = 0;
	size_--;
	DCHECK_GE(size_, 0);

	if (capacity_ > kInitialIdentityMapSize &&
	size_ * kResizeFactor < capacity_ / kResizeFactor) {
	Resize(capacity_ / kResizeFactor);
	return true; // No need to fix collisions as resize reinserts keys.
	}

	// Move any collisions to their new correct location.
	int next_index = index;
	for (;;) {
	next_index = (next_index + 1) & mask_;
	Address key = keys_[next_index];
	if (key == not_mapped) break;

	int expected_index = Hash(key) & mask_;
	if (index < next_index) {
	if (index < expected_index && expected_index <= next_index) continue;
	} else {
	DCHECK_GT(index, next_index);
	if (index < expected_index \|\| expected_index <= next_index) continue;
	}

	DCHECK_EQ(not_mapped, keys_[index]);
	DCHECK_EQ(values_[index], 0);
	std::swap(keys_[index], keys_[next_index]);
	std::swap(values_[index], values_[next_index]);
	index = next_index;
	}

	return true;
	}

	int IdentityMapBase::Lookup(Address key) const {
	uint32_t hash = Hash(key);
	int index = ScanKeysFor(key, hash);
	if (index < 0 && gc_counter_ != heap_->gc_count()) {
	// Miss; rehash if there was a GC, then lookup again.
	const_cast<IdentityMapBase*>(this)->Rehash();
	index = ScanKeysFor(key, hash);
	}
	return index;
	}

	std::pair<int, bool> IdentityMapBase::LookupOrInsert(Address key) {
	uint32_t hash = Hash(key);
	// Perform an optimistic lookup.
	int index = ScanKeysFor(key, hash);
	bool already_exists;
	if (index < 0) {
	// Miss; rehash if there was a GC, then insert.
	if (gc_counter_ != heap_->gc_count()) Rehash();
	std::tie(index, already_exists) = InsertKey(key, hash);
	} else {
	already_exists = true;
	}
	DCHECK_GE(index, 0);
	return {index, already_exists};
	}

	uint32_t IdentityMapBase::Hash(Address address) const {
	CHECK_NE(address, ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
	return static_cast<uint32_t>(hasher_(address));
	}

	// Searches this map for the given key using the object's address
	// as the identity, returning:
	// found => a pointer to the storage location for the value, true
	// not found => a pointer to a new storage location for the value, false
	IdentityMapFindResult<uintptr_t> IdentityMapBase::FindOrInsertEntry(
	Address key) {
	CHECK(!is_iterable()); // Don't allow insertion while iterable.
	if (capacity_ == 0) {
	return {InsertEntry(key), false};
	}
	auto lookup_result = LookupOrInsert(key);
	return {&values_[lookup_result.first], lookup_result.second};
	}

	// Searches this map for the given key using the object's address
	// as the identity, returning:
	// found => a pointer to the storage location for the value
	// not found => {nullptr}
	IdentityMapBase::RawEntry IdentityMapBase::FindEntry(Address key) const {
	// Don't allow find by key while iterable (might rehash).
	CHECK(!is_iterable());
	if (size_ == 0) return nullptr;
	int index = Lookup(key);
	return index >= 0 ? &values_[index] : nullptr;
	}

	// Inserts the given key using the object's address as the identity, returning
	// a pointer to the new storage location for the value.
	IdentityMapBase::RawEntry IdentityMapBase::InsertEntry(Address key) {
	// Don't allow find by key while iterable (might rehash).
	CHECK(!is_iterable());
	if (capacity_ == 0) {
	// Allocate the initial storage for keys and values.
	capacity_ = kInitialIdentityMapSize;
	mask_ = kInitialIdentityMapSize - 1;
	gc_counter_ = heap_->gc_count();

	keys_ = reinterpret_cast<Address*>(NewPointerArray(capacity_));
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	for (int i = 0; i < capacity_; i++) keys_[i] = not_mapped;
	values_ = NewPointerArray(capacity_);
	memset(values_, 0, sizeof(uintptr_t) * capacity_);

	strong_roots_entry_ = heap_->RegisterStrongRoots(
	FullObjectSlot(keys_), FullObjectSlot(keys_ + capacity_));
	} else {
	// Rehash if there was a GC, then insert.
	if (gc_counter_ != heap_->gc_count()) Rehash();
	}

	int index;
	bool already_exists;
	std::tie(index, already_exists) = InsertKey(key, Hash(key));
	DCHECK(!already_exists);
	return &values_[index];
	}

	// Deletes the given key from the map using the object's address as the
	// identity, returning true iff the key was found (in which case, the value
	// argument will be set to the deleted entry's value).
	bool IdentityMapBase::DeleteEntry(Address key, uintptr_t* deleted_value) {
	CHECK(!is_iterable()); // Don't allow deletion by key while iterable.
	if (size_ == 0) return false;
	int index = Lookup(key);
	if (index < 0) return false; // No entry found.
	return DeleteIndex(index, deleted_value);
	}

	Address IdentityMapBase::KeyAtIndex(int index) const {
	DCHECK_LE(0, index);
	DCHECK_LT(index, capacity_);
	DCHECK_NE(keys_[index], ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
	CHECK(is_iterable()); // Must be iterable to access by index;
	return keys_[index];
	}

	IdentityMapBase::RawEntry IdentityMapBase::EntryAtIndex(int index) const {
	DCHECK_LE(0, index);
	DCHECK_LT(index, capacity_);
	DCHECK_NE(keys_[index], ReadOnlyRoots(heap_).not_mapped_symbol().ptr());
	CHECK(is_iterable()); // Must be iterable to access by index;
	return &values_[index];
	}

	int IdentityMapBase::NextIndex(int index) const {
	DCHECK_LE(-1, index);
	DCHECK_LE(index, capacity_);
	CHECK(is_iterable()); // Must be iterable to access by index;
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	for (++index; index < capacity_; ++index) {
	if (keys_[index] != not_mapped) {
	return index;
	}
	}
	return capacity_;
	}

	void IdentityMapBase::Rehash() {
	CHECK(!is_iterable()); // Can't rehash while iterating.
	// Record the current GC counter.
	gc_counter_ = heap_->gc_count();
	// Assume that most objects won't be moved.
	std::vector<std::pair<Address, uintptr_t>> reinsert;
	// Search the table looking for keys that wouldn't be found with their
	// current hashcode and evacuate them.
	int last_empty = -1;
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	for (int i = 0; i < capacity_; i++) {
	if (keys_[i] == not_mapped) {
	last_empty = i;
	} else {
	int pos = Hash(keys_[i]) & mask_;
	if (pos <= last_empty \|\| pos > i) {
	// Evacuate an entry that is in the wrong place.
	reinsert.push_back(std::pair<Address, uintptr_t>(keys_[i], values_[i]));
	keys_[i] = not_mapped;
	values_[i] = 0;
	last_empty = i;
	size_--;
	}
	}
	}
	// Reinsert all the key/value pairs that were in the wrong place.
	for (auto pair : reinsert) {
	int index = InsertKey(pair.first, Hash(pair.first)).first;
	DCHECK_GE(index, 0);
	values_[index] = pair.second;
	}
	}

	void IdentityMapBase::Resize(int new_capacity) {
	CHECK(!is_iterable()); // Can't resize while iterating.
	// Resize the internal storage and reinsert all the key/value pairs.
	DCHECK_GT(new_capacity, size_);
	int old_capacity = capacity_;
	Address* old_keys = keys_;
	uintptr_t* old_values = values_;

	capacity_ = new_capacity;
	mask_ = capacity_ - 1;
	gc_counter_ = heap_->gc_count();
	size_ = 0;

	keys_ = reinterpret_cast<Address*>(NewPointerArray(capacity_));
	Address not_mapped = ReadOnlyRoots(heap_).not_mapped_symbol().ptr();
	for (int i = 0; i < capacity_; i++) keys_[i] = not_mapped;
	values_ = NewPointerArray(capacity_);
	memset(values_, 0, sizeof(uintptr_t) * capacity_);

	for (int i = 0; i < old_capacity; i++) {
	if (old_keys[i] == not_mapped) continue;
	int index = InsertKey(old_keys[i], Hash(old_keys[i])).first;
	DCHECK_GE(index, 0);
	values_[index] = old_values[i];
	}

	// Unregister old keys and register new keys.
	DCHECK_NOT_NULL(strong_roots_entry_);
	heap_->UpdateStrongRoots(strong_roots_entry_, FullObjectSlot(keys_),
	FullObjectSlot(keys_ + capacity_));

	// Delete old storage;
	DeletePointerArray(reinterpret_cast<uintptr_t*>(old_keys), old_capacity);
	DeletePointerArray(old_values, old_capacity);
	}

	} // namespace internal
	} // namespace v8