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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* 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/. */
#ifndef ds_OrderedHashTable_h
#define ds_OrderedHashTable_h
/*
* Define two collection templates, js::OrderedHashMap and js::OrderedHashSet.
* They are like js::HashMap and js::HashSet except that:
*
* - Iterating over an Ordered hash table visits the entries in the order in
* which they were inserted. This means that unlike a HashMap, the behavior
* of an OrderedHashMap is deterministic (as long as the HashPolicy methods
* are effect-free and consistent); the hashing is a pure performance
* optimization.
*
* - Range objects over Ordered tables remain valid even when entries are
* added or removed or the table is resized. (However in the case of
* removing entries, note the warning on class Range below.)
*
* - The API is a little different, so it's not a drop-in replacement.
* In particular, the hash policy is a little different.
* Also, the Ordered templates lack the Ptr and AddPtr types.
*
* Hash policies
*
* See the comment about "Hash policy" in HashTable.h for general features that
* hash policy classes must provide. Hash policies for OrderedHashMaps and Sets
* differ in that the hash() method takes an extra argument:
* static js::HashNumber hash(Lookup, const HashCodeScrambler&);
* They must additionally provide a distinguished "empty" key value and the
* following static member functions:
* bool isEmpty(const Key&);
* void makeEmpty(Key*);
*/
#include "mozilla/HashFunctions.h"
#include "mozilla/Move.h"
using mozilla::Forward;
using mozilla::Move;
namespace js {
namespace detail {
/*
* detail::OrderedHashTable is the underlying data structure used to implement both
* OrderedHashMap and OrderedHashSet. Programs should use one of those two
* templates rather than OrderedHashTable.
*/
template <class T, class Ops, class AllocPolicy>
class OrderedHashTable
{
public:
typedef typename Ops::KeyType Key;
typedef typename Ops::Lookup Lookup;
struct Data
{
T element;
Data* chain;
Data(const T& e, Data* c) : element(e), chain(c) {}
Data(T&& e, Data* c) : element(Move(e)), chain(c) {}
};
class Range;
friend class Range;
private:
Data** hashTable; // hash table (has hashBuckets() elements)
Data* data; // data vector, an array of Data objects
// data[0:dataLength] are constructed
uint32_t dataLength; // number of constructed elements in data
uint32_t dataCapacity; // size of data, in elements
uint32_t liveCount; // dataLength less empty (removed) entries
uint32_t hashShift; // multiplicative hash shift
Range* ranges; // list of all live Ranges on this table
AllocPolicy alloc;
mozilla::HashCodeScrambler hcs; // don't reveal pointer hash codes
public:
OrderedHashTable(AllocPolicy& ap, mozilla::HashCodeScrambler hcs)
: hashTable(nullptr), data(nullptr), dataLength(0), ranges(nullptr), alloc(ap), hcs(hcs) {}
MOZ_MUST_USE bool init() {
MOZ_ASSERT(!hashTable, "init must be called at most once");
uint32_t buckets = initialBuckets();
Data** tableAlloc = alloc.template pod_malloc<Data*>(buckets);
if (!tableAlloc)
return false;
for (uint32_t i = 0; i < buckets; i++)
tableAlloc[i] = nullptr;
uint32_t capacity = uint32_t(buckets * fillFactor());
Data* dataAlloc = alloc.template pod_malloc<Data>(capacity);
if (!dataAlloc) {
alloc.free_(tableAlloc);
return false;
}
// clear() requires that members are assigned only after all allocation
// has succeeded, and that this->ranges is left untouched.
hashTable = tableAlloc;
data = dataAlloc;
dataLength = 0;
dataCapacity = capacity;
liveCount = 0;
hashShift = HashNumberSizeBits - initialBucketsLog2();
MOZ_ASSERT(hashBuckets() == buckets);
return true;
}
~OrderedHashTable() {
for (Range* r = ranges; r; ) {
Range* next = r->next;
r->onTableDestroyed();
r = next;
}
alloc.free_(hashTable);
freeData(data, dataLength);
}
/* Return the number of elements in the table. */
uint32_t count() const { return liveCount; }
/* True if any element matches l. */
bool has(const Lookup& l) const {
return lookup(l) != nullptr;
}
/* Return a pointer to the element, if any, that matches l, or nullptr. */
T* get(const Lookup& l) {
Data* e = lookup(l, prepareHash(l));
return e ? &e->element : nullptr;
}
/* Return a pointer to the element, if any, that matches l, or nullptr. */
const T* get(const Lookup& l) const {
return const_cast<OrderedHashTable*>(this)->get(l);
}
/*
* If the table already contains an entry that matches |element|,
* replace that entry with |element|. Otherwise add a new entry.
*
* On success, return true, whether there was already a matching element or
* not. On allocation failure, return false. If this returns false, it
* means the element was not added to the table.
*/
template <typename ElementInput>
MOZ_MUST_USE bool put(ElementInput&& element) {
HashNumber h = prepareHash(Ops::getKey(element));
if (Data* e = lookup(Ops::getKey(element), h)) {
e->element = Forward<ElementInput>(element);
return true;
}
if (dataLength == dataCapacity) {
// If the hashTable is more than 1/4 deleted data, simply rehash in
// place to free up some space. Otherwise, grow the table.
uint32_t newHashShift = liveCount >= dataCapacity * 0.75 ? hashShift - 1 : hashShift;
if (!rehash(newHashShift))
return false;
}
h >>= hashShift;
liveCount++;
Data* e = &data[dataLength++];
new (e) Data(Forward<ElementInput>(element), hashTable[h]);
hashTable[h] = e;
return true;
}
/*
* If the table contains an element matching l, remove it and set *foundp
* to true. Otherwise set *foundp to false.
*
* Return true on success, false if we tried to shrink the table and hit an
* allocation failure. Even if this returns false, *foundp is set correctly
* and the matching element was removed. Shrinking is an optimization and
* it's OK for it to fail.
*/
bool remove(const Lookup& l, bool* foundp) {
// Note: This could be optimized so that removing the last entry,
// data[dataLength - 1], decrements dataLength. LIFO use cases would
// benefit.
// If a matching entry exists, empty it.
Data* e = lookup(l, prepareHash(l));
if (e == nullptr) {
*foundp = false;
return true;
}
*foundp = true;
liveCount--;
Ops::makeEmpty(&e->element);
// Update active Ranges.
uint32_t pos = e - data;
for (Range* r = ranges; r; r = r->next)
r->onRemove(pos);
// If many entries have been removed, try to shrink the table.
if (hashBuckets() > initialBuckets() && liveCount < dataLength * minDataFill()) {
if (!rehash(hashShift + 1))
return false;
}
return true;
}
/*
* Remove all entries.
*
* Returns false on OOM, leaving the OrderedHashTable and any live Ranges
* in the old state.
*
* The effect on live Ranges is the same as removing all entries; in
* particular, those Ranges are still live and will see any entries added
* after a successful clear().
*/
MOZ_MUST_USE bool clear() {
if (dataLength != 0) {
Data** oldHashTable = hashTable;
Data* oldData = data;
uint32_t oldDataLength = dataLength;
hashTable = nullptr;
if (!init()) {
// init() only mutates members on success; see comment above.
hashTable = oldHashTable;
return false;
}
alloc.free_(oldHashTable);
freeData(oldData, oldDataLength);
for (Range* r = ranges; r; r = r->next)
r->onClear();
}
MOZ_ASSERT(hashTable);
MOZ_ASSERT(data);
MOZ_ASSERT(dataLength == 0);
MOZ_ASSERT(liveCount == 0);
return true;
}
/*
* Ranges are used to iterate over OrderedHashTables.
*
* Suppose 'Map' is some instance of OrderedHashMap, and 'map' is a Map.
* Then you can walk all the key-value pairs like this:
*
* for (Map::Range r = map.all(); !r.empty(); r.popFront()) {
* Map::Entry& pair = r.front();
* ... do something with pair ...
* }
*
* Ranges remain valid for the lifetime of the OrderedHashTable, even if
* entries are added or removed or the table is resized. Don't do anything
* to a Range, except destroy it, after the OrderedHashTable has been
* destroyed. (We support destroying the two objects in either order to
* humor the GC, bless its nondeterministic heart.)
*
* Warning: The behavior when the current front() entry is removed from the
* table is subtly different from js::HashTable<>::Enum::removeFront()!
* HashTable::Enum doesn't skip any entries when you removeFront() and then
* popFront(). OrderedHashTable::Range does! (This is useful for using a
* Range to implement JS Map.prototype.iterator.)
*
* The workaround is to call popFront() as soon as possible,
* before there's any possibility of modifying the table:
*
* for (Map::Range r = map.all(); !r.empty(); ) {
* Key key = r.front().key; // this won't modify map
* Value val = r.front().value; // this won't modify map
* r.popFront();
* // ...do things that might modify map...
* }
*/
class Range
{
friend class OrderedHashTable;
// Cannot be a reference since we need to be able to do
// |offsetof(Range, ht)|.
OrderedHashTable* ht;
/* The index of front() within ht->data. */
uint32_t i;
/*
* The number of nonempty entries in ht->data to the left of front().
* This is used when the table is resized or compacted.
*/
uint32_t count;
/*
* Links in the doubly-linked list of active Ranges on ht.
*
* prevp points to the previous Range's .next field;
* or to ht->ranges if this is the first Range in the list.
* next points to the next Range;
* or nullptr if this is the last Range in the list.
*
* Invariant: *prevp == this.
*/
Range** prevp;
Range* next;
/*
* Create a Range over all the entries in ht.
* (This is private on purpose. End users must use ht->all().)
*/
explicit Range(OrderedHashTable* ht) : ht(ht), i(0), count(0), prevp(&ht->ranges), next(ht->ranges) {
*prevp = this;
if (next)
next->prevp = &next;
seek();
}
public:
Range(const Range& other)
: ht(other.ht), i(other.i), count(other.count), prevp(&ht->ranges), next(ht->ranges)
{
*prevp = this;
if (next)
next->prevp = &next;
}
~Range() {
*prevp = next;
if (next)
next->prevp = prevp;
}
private:
// Prohibit copy assignment.
Range& operator=(const Range& other) = delete;
void seek() {
while (i < ht->dataLength && Ops::isEmpty(Ops::getKey(ht->data[i].element)))
i++;
}
/*
* The hash table calls this when an entry is removed.
* j is the index of the removed entry.
*/
void onRemove(uint32_t j) {
MOZ_ASSERT(valid());
if (j < i)
count--;
if (j == i)
seek();
}
/*
* The hash table calls this when the table is resized or compacted.
* Since |count| is the number of nonempty entries to the left of
* front(), discarding the empty entries will not affect count, and it
* will make i and count equal.
*/
void onCompact() {
MOZ_ASSERT(valid());
i = count;
}
/* The hash table calls this when cleared. */
void onClear() {
MOZ_ASSERT(valid());
i = count = 0;
}
bool valid() const {
return next != this;
}
void onTableDestroyed() {
MOZ_ASSERT(valid());
prevp = &next;
next = this;
}
public:
bool empty() const {
MOZ_ASSERT(valid());
return i >= ht->dataLength;
}
/*
* Return the first element in the range. This must not be called if
* this->empty().
*
* Warning: Removing an entry from the table also removes it from any
* live Ranges, and a Range can become empty that way, rendering
* front() invalid. If in doubt, check empty() before calling front().
*/
T& front() {
MOZ_ASSERT(valid());
MOZ_ASSERT(!empty());
return ht->data[i].element;
}
/*
* Remove the first element from this range.
* This must not be called if this->empty().
*
* Warning: Removing an entry from the table also removes it from any
* live Ranges, and a Range can become empty that way, rendering
* popFront() invalid. If in doubt, check empty() before calling
* popFront().
*/
void popFront() {
MOZ_ASSERT(valid());
MOZ_ASSERT(!empty());
MOZ_ASSERT(!Ops::isEmpty(Ops::getKey(ht->data[i].element)));
count++;
i++;
seek();
}
/*
* Change the key of the front entry.
*
* This calls Ops::hash on both the current key and the new key.
* Ops::hash on the current key must return the same hash code as
* when the entry was added to the table.
*/
void rekeyFront(const Key& k) {
MOZ_ASSERT(valid());
Data& entry = ht->data[i];
HashNumber oldHash = ht->prepareHash(Ops::getKey(entry.element)) >> ht->hashShift;
HashNumber newHash = ht->prepareHash(k) >> ht->hashShift;
Ops::setKey(entry.element, k);
if (newHash != oldHash) {
// Remove this entry from its old hash chain. (If this crashes
// reading nullptr, it would mean we did not find this entry on
// the hash chain where we expected it. That probably means the
// key's hash code changed since it was inserted, breaking the
// hash code invariant.)
Data** ep = &ht->hashTable[oldHash];
while (*ep != &entry)
ep = &(*ep)->chain;
*ep = entry.chain;
// Add it to the new hash chain. We could just insert it at the
// beginning of the chain. Instead, we do a bit of work to
// preserve the invariant that hash chains always go in reverse
// insertion order (descending memory order). No code currently
// depends on this invariant, so it's fine to kill it if
// needed.
ep = &ht->hashTable[newHash];
while (*ep && *ep > &entry)
ep = &(*ep)->chain;
entry.chain = *ep;
*ep = &entry;
}
}
static size_t offsetOfHashTable() {
return offsetof(Range, ht);
}
static size_t offsetOfI() {
return offsetof(Range, i);
}
static size_t offsetOfCount() {
return offsetof(Range, count);
}
static size_t offsetOfPrevP() {
return offsetof(Range, prevp);
}
static size_t offsetOfNext() {
return offsetof(Range, next);
}
};
Range all() { return Range(this); }
/*
* Change the value of the given key.
*
* This calls Ops::hash on both the current key and the new key.
* Ops::hash on the current key must return the same hash code as
* when the entry was added to the table.
*/
void rekeyOneEntry(const Key& current, const Key& newKey, const T& element) {
if (current == newKey)
return;
Data* entry = lookup(current, prepareHash(current));
if (!entry)
return;
HashNumber oldHash = prepareHash(current) >> hashShift;
HashNumber newHash = prepareHash(newKey) >> hashShift;
entry->element = element;
// Remove this entry from its old hash chain. (If this crashes
// reading nullptr, it would mean we did not find this entry on
// the hash chain where we expected it. That probably means the
// key's hash code changed since it was inserted, breaking the
// hash code invariant.)
Data** ep = &hashTable[oldHash];
while (*ep != entry)
ep = &(*ep)->chain;
*ep = entry->chain;
// Add it to the new hash chain. We could just insert it at the
// beginning of the chain. Instead, we do a bit of work to
// preserve the invariant that hash chains always go in reverse
// insertion order (descending memory order). No code currently
// depends on this invariant, so it's fine to kill it if
// needed.
ep = &hashTable[newHash];
while (*ep && *ep > entry)
ep = &(*ep)->chain;
entry->chain = *ep;
*ep = entry;
}
static size_t offsetOfDataLength() {
return offsetof(OrderedHashTable, dataLength);
}
static size_t offsetOfData() {
return offsetof(OrderedHashTable, data);
}
static constexpr size_t offsetOfDataElement() {
static_assert(offsetof(Data, element) == 0,
"RangeFront and RangePopFront depend on offsetof(Data, element) being 0");
return offsetof(Data, element);
}
static constexpr size_t sizeofData() {
return sizeof(Data);
}
private:
/* Logarithm base 2 of the number of buckets in the hash table initially. */
static uint32_t initialBucketsLog2() { return 1; }
static uint32_t initialBuckets() { return 1 << initialBucketsLog2(); }
/*
* The maximum load factor (mean number of entries per bucket).
* It is an invariant that
* dataCapacity == floor(hashBuckets() * fillFactor()).
*
* The fill factor should be between 2 and 4, and it should be chosen so that
* the fill factor times sizeof(Data) is close to but <= a power of 2.
* This fixed fill factor was chosen to make the size of the data
* array, in bytes, close to a power of two when sizeof(T) is 16.
*/
static double fillFactor() { return 8.0 / 3.0; }
/*
* The minimum permitted value of (liveCount / dataLength).
* If that ratio drops below this value, we shrink the table.
*/
static double minDataFill() { return 0.25; }
public:
HashNumber prepareHash(const Lookup& l) const {
return ScrambleHashCode(Ops::hash(l, hcs));
}
private:
/* The size of hashTable, in elements. Always a power of two. */
uint32_t hashBuckets() const {
return 1 << (HashNumberSizeBits - hashShift);
}
static void destroyData(Data* data, uint32_t length) {
for (Data* p = data + length; p != data; )
(--p)->~Data();
}
void freeData(Data* data, uint32_t length) {
destroyData(data, length);
alloc.free_(data);
}
Data* lookup(const Lookup& l, HashNumber h) {
for (Data* e = hashTable[h >> hashShift]; e; e = e->chain) {
if (Ops::match(Ops::getKey(e->element), l))
return e;
}
return nullptr;
}
const Data* lookup(const Lookup& l) const {
return const_cast<OrderedHashTable*>(this)->lookup(l, prepareHash(l));
}
/* This is called after rehashing the table. */
void compacted() {
// If we had any empty entries, compacting may have moved live entries
// to the left within |data|. Notify all live Ranges of the change.
for (Range* r = ranges; r; r = r->next)
r->onCompact();
}
/* Compact the entries in |data| and rehash them. */
void rehashInPlace() {
for (uint32_t i = 0, N = hashBuckets(); i < N; i++)
hashTable[i] = nullptr;
Data* wp = data;
Data* end = data + dataLength;
for (Data* rp = data; rp != end; rp++) {
if (!Ops::isEmpty(Ops::getKey(rp->element))) {
HashNumber h = prepareHash(Ops::getKey(rp->element)) >> hashShift;
if (rp != wp)
wp->element = Move(rp->element);
wp->chain = hashTable[h];
hashTable[h] = wp;
wp++;
}
}
MOZ_ASSERT(wp == data + liveCount);
while (wp != end)
(--end)->~Data();
dataLength = liveCount;
compacted();
}
/*
* Grow, shrink, or compact both |hashTable| and |data|.
*
* On success, this returns true, dataLength == liveCount, and there are no
* empty elements in data[0:dataLength]. On allocation failure, this
* leaves everything as it was and returns false.
*/
MOZ_MUST_USE bool rehash(uint32_t newHashShift) {
// If the size of the table is not changing, rehash in place to avoid
// allocating memory.
if (newHashShift == hashShift) {
rehashInPlace();
return true;
}
size_t newHashBuckets =
size_t(1) << (HashNumberSizeBits - newHashShift);
Data** newHashTable = alloc.template pod_malloc<Data*>(newHashBuckets);
if (!newHashTable)
return false;
for (uint32_t i = 0; i < newHashBuckets; i++)
newHashTable[i] = nullptr;
uint32_t newCapacity = uint32_t(newHashBuckets * fillFactor());
Data* newData = alloc.template pod_malloc<Data>(newCapacity);
if (!newData) {
alloc.free_(newHashTable);
return false;
}
Data* wp = newData;
Data* end = data + dataLength;
for (Data* p = data; p != end; p++) {
if (!Ops::isEmpty(Ops::getKey(p->element))) {
HashNumber h = prepareHash(Ops::getKey(p->element)) >> newHashShift;
new (wp) Data(Move(p->element), newHashTable[h]);
newHashTable[h] = wp;
wp++;
}
}
MOZ_ASSERT(wp == newData + liveCount);
alloc.free_(hashTable);
freeData(data, dataLength);
hashTable = newHashTable;
data = newData;
dataLength = liveCount;
dataCapacity = newCapacity;
hashShift = newHashShift;
MOZ_ASSERT(hashBuckets() == newHashBuckets);
compacted();
return true;
}
// Not copyable.
OrderedHashTable& operator=(const OrderedHashTable&) = delete;
OrderedHashTable(const OrderedHashTable&) = delete;
};
} // namespace detail
template <class Key, class Value, class OrderedHashPolicy, class AllocPolicy>
class OrderedHashMap
{
public:
class Entry
{
template <class, class, class> friend class detail::OrderedHashTable;
void operator=(const Entry& rhs) {
const_cast<Key&>(key) = rhs.key;
value = rhs.value;
}
void operator=(Entry&& rhs) {
MOZ_ASSERT(this != &rhs, "self-move assignment is prohibited");
const_cast<Key&>(key) = Move(rhs.key);
value = Move(rhs.value);
}
public:
Entry() : key(), value() {}
template <typename V>
Entry(const Key& k, V&& v) : key(k), value(Forward<V>(v)) {}
Entry(Entry&& rhs) : key(Move(rhs.key)), value(Move(rhs.value)) {}
const Key key;
Value value;
static size_t offsetOfKey() {
return offsetof(Entry, key);
}
static size_t offsetOfValue() {
return offsetof(Entry, value);
}
};
private:
struct MapOps : OrderedHashPolicy
{
typedef Key KeyType;
static void makeEmpty(Entry* e) {
OrderedHashPolicy::makeEmpty(const_cast<Key*>(&e->key));
// Clear the value. Destroying it is another possibility, but that
// would complicate class Entry considerably.
e->value = Value();
}
static const Key& getKey(const Entry& e) { return e.key; }
static void setKey(Entry& e, const Key& k) { const_cast<Key&>(e.key) = k; }
};
typedef detail::OrderedHashTable<Entry, MapOps, AllocPolicy> Impl;
Impl impl;
public:
typedef typename Impl::Range Range;
OrderedHashMap(AllocPolicy ap, mozilla::HashCodeScrambler hcs) : impl(ap, hcs) {}
MOZ_MUST_USE bool init() { return impl.init(); }
uint32_t count() const { return impl.count(); }
bool has(const Key& key) const { return impl.has(key); }
Range all() { return impl.all(); }
const Entry* get(const Key& key) const { return impl.get(key); }
Entry* get(const Key& key) { return impl.get(key); }
bool remove(const Key& key, bool* foundp) { return impl.remove(key, foundp); }
MOZ_MUST_USE bool clear() { return impl.clear(); }
template <typename V>
MOZ_MUST_USE bool put(const Key& key, V&& value) {
return impl.put(Entry(key, Forward<V>(value)));
}
HashNumber hash(const Key& key) const { return impl.prepareHash(key); }
void rekeyOneEntry(const Key& current, const Key& newKey) {
const Entry* e = get(current);
if (!e)
return;
return impl.rekeyOneEntry(current, newKey, Entry(newKey, e->value));
}
static size_t offsetOfEntryKey() {
return Entry::offsetOfKey();
}
static size_t offsetOfImplDataLength() {
return Impl::offsetOfDataLength();
}
static size_t offsetOfImplData() {
return Impl::offsetOfData();
}
static constexpr size_t offsetOfImplDataElement() {
return Impl::offsetOfDataElement();
}
static constexpr size_t sizeofImplData() {
return Impl::sizeofData();
}
};
template <class T, class OrderedHashPolicy, class AllocPolicy>
class OrderedHashSet
{
private:
struct SetOps : OrderedHashPolicy
{
typedef const T KeyType;
static const T& getKey(const T& v) { return v; }
static void setKey(const T& e, const T& v) { const_cast<T&>(e) = v; }
};
typedef detail::OrderedHashTable<T, SetOps, AllocPolicy> Impl;
Impl impl;
public:
typedef typename Impl::Range Range;
explicit OrderedHashSet(AllocPolicy ap, mozilla::HashCodeScrambler hcs) : impl(ap, hcs) {}
MOZ_MUST_USE bool init() { return impl.init(); }
uint32_t count() const { return impl.count(); }
bool has(const T& value) const { return impl.has(value); }
Range all() { return impl.all(); }
MOZ_MUST_USE bool put(const T& value) { return impl.put(value); }
bool remove(const T& value, bool* foundp) { return impl.remove(value, foundp); }
MOZ_MUST_USE bool clear() { return impl.clear(); }
HashNumber hash(const T& value) const { return impl.prepareHash(value); }
void rekeyOneEntry(const T& current, const T& newKey) {
return impl.rekeyOneEntry(current, newKey, newKey);
}
static size_t offsetOfEntryKey() {
return 0;
}
static size_t offsetOfImplDataLength() {
return Impl::offsetOfDataLength();
}
static size_t offsetOfImplData() {
return Impl::offsetOfData();
}
static constexpr size_t offsetOfImplDataElement() {
return Impl::offsetOfDataElement();
}
static constexpr size_t sizeofImplData() {
return Impl::sizeofData();
}
};
} // namespace js
#endif /* ds_OrderedHashTable_h */
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