@Internal public class DoubleValueArrayComparator extends TypeComparator<DoubleValueArray>
This can be used for grouping keys but not for sorting keys.
Constructor and Description |
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DoubleValueArrayComparator(boolean ascending) |
Modifier and Type | Method and Description |
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int |
compare(DoubleValueArray first,
DoubleValueArray second)
Compares two records in object form.
|
int |
compareSerialized(DataInputView firstSource,
DataInputView secondSource)
Compares two records in serialized form.
|
int |
compareToReference(TypeComparator<DoubleValueArray> referencedComparator)
This method compares the element that has been set as reference in this type accessor, to the
element set as reference in the given type accessor.
|
TypeComparator<DoubleValueArray> |
duplicate()
Creates a copy of this class.
|
boolean |
equalToReference(DoubleValueArray candidate)
Checks, whether the given element is equal to the element that has been set as the comparison
reference in this comparator instance.
|
int |
extractKeys(Object record,
Object[] target,
int index)
Extracts the key fields from a record.
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TypeComparator<?>[] |
getFlatComparators()
Get the field comparators.
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int |
getNormalizeKeyLen()
Gets the number of bytes that the normalized key would maximally take.
|
int |
hash(DoubleValueArray record)
Computes a hash value for the given record.
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boolean |
invertNormalizedKey()
Flag whether normalized key comparisons should be inverted key should be interpreted
inverted, i.e.
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boolean |
isNormalizedKeyPrefixOnly(int keyDoubles)
Checks, whether the given number of bytes for a normalized is only a prefix to determine the order of elements
of the data type for which this comparator provides the comparison methods.
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void |
putNormalizedKey(DoubleValueArray record,
MemorySegment target,
int offset,
int numDoubles)
Writes a normalized key for the given record into the target byte array, starting at the specified position
and writing exactly the given number of bytes.
|
DoubleValueArray |
readWithKeyDenormalization(DoubleValueArray reuse,
DataInputView source)
Reads the record back while de-normalizing the key fields.
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void |
setReference(DoubleValueArray toCompare)
Sets the given element as the comparison reference for future calls to
TypeComparator.equalToReference(Object) and TypeComparator.compareToReference(TypeComparator) . |
boolean |
supportsNormalizedKey()
Checks whether the data type supports the creation of a normalized key for comparison.
|
boolean |
supportsSerializationWithKeyNormalization()
Check whether this comparator supports to serialize the record in a format that replaces its keys by a normalized
key.
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void |
writeWithKeyNormalization(DoubleValueArray record,
DataOutputView target)
Writes the record in such a fashion that all keys are normalizing and at the beginning of the serialized data.
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compareAgainstReference, supportsCompareAgainstReference
public int hash(DoubleValueArray record)
TypeComparator
The hash code is typically not used as it is in hash tables and for partitioning, but it is further scrambled to make sure that a projection of the hash values to a lower cardinality space is as results in a rather uniform value distribution. However, any collisions produced by this method cannot be undone. While it is NOT important to create hash codes that cover the full spectrum of bits in the integer, it IS important to avoid collisions when combining two value as much as possible.
hash
in class TypeComparator<DoubleValueArray>
record
- The record to be hashed.Object.hashCode()
public void setReference(DoubleValueArray toCompare)
TypeComparator
TypeComparator.equalToReference(Object)
and TypeComparator.compareToReference(TypeComparator)
. This method
must set the given element into this comparator instance's state. If the comparison happens on a subset
of the fields from the record, this method may extract those fields.
A typical example for checking the equality of two elements is the following:
E e1 = ...;
E e2 = ...;
TypeComparator<E> acc = ...;
acc.setReference(e1);
boolean equal = acc.equalToReference(e2);
The rational behind this method is that elements are typically compared using certain features that
are extracted from them, (such de-serializing as a subset of fields). When setting the
reference, this extraction happens. The extraction needs happen only once per element,
even though an element is often compared to multiple other elements, such as when finding equal elements
in the process of grouping the elements.setReference
in class TypeComparator<DoubleValueArray>
toCompare
- The element to set as the comparison reference.public boolean equalToReference(DoubleValueArray candidate)
TypeComparator
equalToReference
in class TypeComparator<DoubleValueArray>
candidate
- The candidate to check.TypeComparator.setReference(Object)
public int compareToReference(TypeComparator<DoubleValueArray> referencedComparator)
TypeComparator
e1
and e2
via a comparator, this method can be used the
following way.
E e1 = ...;
E e2 = ...;
TypeComparator<E> acc1 = ...;
TypeComparator<E> acc2 = ...;
acc1.setReference(e1);
acc2.setReference(e2);
int comp = acc1.compareToReference(acc2);
The rational behind this method is that elements are typically compared using certain features that
are extracted from them, (such de-serializing as a subset of fields). When setting the
reference, this extraction happens. The extraction needs happen only once per element,
even though an element is typically compared to many other elements when establishing a
sorted order. The actual comparison performed by this method may be very cheap, as it
happens on the extracted features.compareToReference
in class TypeComparator<DoubleValueArray>
referencedComparator
- The type accessors where the element for comparison has been set
as reference.referencedAccessors
is smaller
than the reference value of this type accessor; a value greater than zero, if it is larger;
zero, if both are equal.TypeComparator.setReference(Object)
public int compare(DoubleValueArray first, DoubleValueArray second)
TypeComparator
Comparator.compare(Object, Object)
.compare
in class TypeComparator<DoubleValueArray>
first
- The first record.second
- The second record.Comparator.compare(Object, Object)
.Comparator.compare(Object, Object)
public int compareSerialized(DataInputView firstSource, DataInputView secondSource) throws IOException
TypeComparator
Comparator.compare(Object, Object)
.
This method may de-serialize the records or compare them directly based on their binary representation.
compareSerialized
in class TypeComparator<DoubleValueArray>
firstSource
- The input view containing the first record.secondSource
- The input view containing the second record.Comparator.compare(Object, Object)
.IOException
- Thrown, if any of the input views raised an exception when reading the records.Comparator.compare(Object, Object)
public boolean supportsNormalizedKey()
TypeComparator
supportsNormalizedKey
in class TypeComparator<DoubleValueArray>
public int getNormalizeKeyLen()
TypeComparator
Integer
.MAX_VALUE is interpreted as infinite.getNormalizeKeyLen
in class TypeComparator<DoubleValueArray>
public boolean isNormalizedKeyPrefixOnly(int keyDoubles)
TypeComparator
isNormalizedKeyPrefixOnly
in class TypeComparator<DoubleValueArray>
public void putNormalizedKey(DoubleValueArray record, MemorySegment target, int offset, int numDoubles)
TypeComparator
int byteI = bytes[i] & 0xFF;
If the meaningful part of the normalized key takes less than the given number of bytes, then it must be padded.
Padding is typically required for variable length data types, such as strings. The padding uses a special
character, either 0
or 0xff
, depending on whether shorter values are sorted to the beginning or
the end.
This method is similar to NormalizableKey.copyNormalizedKey(MemorySegment, int, int)
. In the case that
multiple fields of a record contribute to the normalized key, it is crucial that the fields align on the
byte field, i.e. that every field always takes up the exact same number of bytes.
putNormalizedKey
in class TypeComparator<DoubleValueArray>
record
- The record for which to create the normalized key.target
- The byte array into which to write the normalized key bytes.offset
- The offset in the byte array, where to start writing the normalized key bytes.numDoubles
- The number of bytes to be written exactly.NormalizableKey.copyNormalizedKey(MemorySegment, int, int)
public boolean invertNormalizedKey()
TypeComparator
invertNormalizedKey
in class TypeComparator<DoubleValueArray>
public TypeComparator<DoubleValueArray> duplicate()
TypeComparator
duplicate
in class TypeComparator<DoubleValueArray>
public int extractKeys(Object record, Object[] target, int index)
TypeComparator
extractKeys
in class TypeComparator<DoubleValueArray>
record
- The record that contains the key(s)target
- The array to write the key(s) into.index
- The offset of the target array to start writing into.public TypeComparator<?>[] getFlatComparators()
TypeComparator
TypeComparator.extractKeys(Object, Object[], int)
to provide interoperability between different record types. Note, that this should return at
least one Comparator and that the number of Comparators must match the number of extracted
keys.getFlatComparators
in class TypeComparator<DoubleValueArray>
public boolean supportsSerializationWithKeyNormalization()
TypeComparator
supportsSerializationWithKeyNormalization
in class TypeComparator<DoubleValueArray>
public void writeWithKeyNormalization(DoubleValueArray record, DataOutputView target) throws IOException
TypeComparator
#supportsSerializationWithKeyNormalization()
allows to check that.writeWithKeyNormalization
in class TypeComparator<DoubleValueArray>
record
- The record object into which to read the record data.target
- The stream to which to write the data,IOException
TypeComparator.supportsSerializationWithKeyNormalization()
,
TypeComparator.readWithKeyDenormalization(Object, DataInputView)
,
NormalizableKey.copyNormalizedKey(MemorySegment, int, int)
public DoubleValueArray readWithKeyDenormalization(DoubleValueArray reuse, DataInputView source) throws IOException
TypeComparator
#supportsSerializationWithKeyNormalization()
method.readWithKeyDenormalization
in class TypeComparator<DoubleValueArray>
reuse
- The reuse object into which to read the record data.source
- The stream from which to read the data,IOException
TypeComparator.supportsSerializationWithKeyNormalization()
,
TypeComparator.writeWithKeyNormalization(Object, DataOutputView)
,
NormalizableKey.copyNormalizedKey(MemorySegment, int, int)
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