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adf2d8b689
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533fa3b023
@ -171,24 +171,29 @@ package struct HashArray(alias hasher, K, V = void)
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this.length = that.length;
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}
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@property size_t bucketCount() const
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{
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return primes[this.lengthIndex];
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}
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/*
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* Returns bucket position for `hash`. `0` may mean the 0th position or an
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* empty `buckets` array.
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*/
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size_t locateBucket(ref const Key key) const
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{
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return this.array.length == 0
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? 0
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: hasher(key) % primes[this.lengthIndex];
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return this.array.length == 0 ? 0 : hasher(key) % bucketCount;
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}
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/*
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* Inserts a key into an empty or deleted bucket. If the key is
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* already in there, does nothing. Returns the bucket with the key.
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* If the key doesn't already exists, returns an empty bucket the key can
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* be inserted in and adjusts the element count. Otherwise returns the
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* bucket containing the key.
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*/
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ref Bucket insert(ref Key key)
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{
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while ((this.lengthIndex + 1) != primes.length)
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const newLengthIndex = this.lengthIndex + 1;
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if (newLengthIndex != primes.length)
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{
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foreach (ref e; this.array[locateBucket(key) .. $])
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{
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@ -203,17 +208,29 @@ package struct HashArray(alias hasher, K, V = void)
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}
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}
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if (this.rehashToSize(this.lengthIndex + 1))
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this.rehashToSize(newLengthIndex);
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}
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foreach (ref e; this.array[locateBucket(key) .. $])
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{
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++this.lengthIndex;
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if (e == key)
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{
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return e;
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}
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else if (e.status != BucketStatus.used)
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{
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++this.length;
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return e;
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}
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}
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this.array.insertBack(Bucket(key));
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this.array.length = this.array.length + 1;
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++this.length;
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return this.array[$ - 1];
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}
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// Takes an index in the primes array.
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bool rehashToSize(const size_t n)
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void rehashToSize(const size_t n)
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in
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{
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assert(n < primes.length);
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@ -231,15 +248,15 @@ package struct HashArray(alias hasher, K, V = void)
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{
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if (e2.status != BucketStatus.used) // Insert the key
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{
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e2 = e1;
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.move(e1, e2);
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continue DataLoop;
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}
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}
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return false; // Rehashing failed.
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storage.insertBack(.move(e1));
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}
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}
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.move(storage, this.array);
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return true;
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this.lengthIndex = n;
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}
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void rehash(const size_t n)
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@ -252,9 +269,9 @@ package struct HashArray(alias hasher, K, V = void)
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break;
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}
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}
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if (this.rehashToSize(lengthIndex))
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if (lengthIndex > this.lengthIndex)
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{
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this.lengthIndex = lengthIndex;
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this.rehashToSize(lengthIndex);
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}
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}
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@ -174,8 +174,6 @@ if (is(typeof(hasher(Key.init)) == size_t))
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invariant
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{
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assert(this.data.lengthIndex < primes.length);
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assert(this.data.array.length == 0
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|| this.data.array.length == primes[this.data.lengthIndex]);
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}
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/**
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@ -440,6 +438,23 @@ if (is(typeof(hasher(Key.init)) == size_t))
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assert(hashTable.empty);
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}
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/**
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* Returns current bucket count in the container.
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*
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* Bucket count equals to the number of the elements can be saved in the
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* container in the best case scenario for key distribution, i.d. every key
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* has a unique hash value. In a worse case the bucket count can be less
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* than the number of elements stored in the container.
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*
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* Returns: Current bucket count.
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*
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* See_Also: $(D_PSYMBOL rehash).
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*/
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@property size_t bucketCount() const
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{
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return this.data.bucketCount;
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}
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/// The maximum number of buckets the container can have.
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enum size_t maxBucketCount = primes[$ - 1];
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@ -645,18 +660,15 @@ if (is(typeof(hasher(Key.init)) == size_t))
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* Sets the number of buckets in the container to at least $(D_PARAM n)
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* and rearranges all the elements according to their hash values.
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*
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* If $(D_PARAM n) is greater than the current $(D_PSYMBOL capacity)
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* If $(D_PARAM n) is greater than the current $(D_PSYMBOL bucketCount)
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* and lower than or equal to $(D_PSYMBOL maxBucketCount), a rehash is
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* forced.
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*
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* If $(D_PARAM n) is greater than $(D_PSYMBOL maxBucketCount),
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* $(D_PSYMBOL maxBucketCount) is used instead as a new number of buckets.
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*
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* If $(D_PARAM n) is equal to the current $(D_PSYMBOL capacity), rehashing
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* is forced without resizing the container.
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*
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* If $(D_PARAM n) is lower than the current $(D_PSYMBOL capacity), the
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* function may have no effect.
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* If $(D_PARAM n) is less than or equal to the current
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* $(D_PSYMBOL bucketCount), the function may have no effect.
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*
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* Rehashing is automatically performed whenever the container needs space
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* to insert new elements.
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@ -773,3 +785,27 @@ if (is(typeof(hasher(Key.init)) == size_t))
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}
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testFunc(hashTable);
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}
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// Issue 53: https://github.com/caraus-ecms/tanya/issues/53
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@nogc nothrow pure @safe unittest
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{
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{
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HashTable!(uint, uint) hashTable;
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foreach (uint i; 0 .. 14)
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{
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hashTable[i + 1] = i;
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}
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assert(hashTable.length == 14);
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}
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{
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HashTable!(int, int) hashtable;
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hashtable[1194250162] = 3;
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hashtable[-1131293824] = 6;
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hashtable[838100082] = 9;
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hashtable.rehash(11);
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assert(hashtable[-1131293824] == 6);
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}
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}
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@ -432,6 +432,23 @@ if (is(typeof(hasher(T.init)) == size_t))
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assert(set.empty);
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}
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/**
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* Returns current bucket count in the container.
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*
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* Bucket count equals to the number of the elements can be saved in the
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* container in the best case scenario for key distribution, i.d. every key
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* has a unique hash value. In a worse case the bucket count can be less
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* than the number of elements stored in the container.
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*
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* Returns: Current bucket count.
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*
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* See_Also: $(D_PSYMBOL rehash).
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*/
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@property size_t bucketCount() const
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{
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return this.data.bucketCount;
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}
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/// The maximum number of buckets the container can have.
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enum size_t maxBucketCount = primes[$ - 1];
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@ -559,18 +576,15 @@ if (is(typeof(hasher(T.init)) == size_t))
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* Sets the number of buckets in the container to at least $(D_PARAM n)
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* and rearranges all the elements according to their hash values.
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*
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* If $(D_PARAM n) is greater than the current $(D_PSYMBOL capacity)
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* If $(D_PARAM n) is greater than the current $(D_PSYMBOL bucketCount)
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* and lower than or equal to $(D_PSYMBOL maxBucketCount), a rehash is
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* forced.
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*
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* If $(D_PARAM n) is greater than $(D_PSYMBOL maxBucketCount),
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* $(D_PSYMBOL maxBucketCount) is used instead as a new number of buckets.
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*
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* If $(D_PARAM n) is equal to the current $(D_PSYMBOL capacity), rehashing
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* is forced without resizing the container.
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*
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* If $(D_PARAM n) is lower than the current $(D_PSYMBOL capacity), the
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* function may have no effect.
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* If $(D_PARAM n) is less than or equal to the current
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* $(D_PSYMBOL bucketCount), the function may have no effect.
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*
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* Rehashing is automatically performed whenever the container needs space
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* to insert new elements.
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