See: Description
Interface | Description |
---|---|
MarshalledTupleEntry |
A marshalling interface implemented by key, data or entity classes that
are represented as tuples.
|
MarshalledTupleKeyEntity |
A marshalling interface implemented by entity classes that represent keys as
tuples.
|
Class | Description |
---|---|
BigDecimalBinding |
A concrete
TupleBinding for an unsorted BigDecimal
value. |
BigIntegerBinding |
A concrete
TupleBinding for a BigInteger value. |
BooleanBinding |
A concrete
TupleBinding for a Boolean primitive
wrapper or a boolean primitive. |
ByteBinding |
A concrete
TupleBinding for a Byte primitive
wrapper or a byte primitive. |
CharacterBinding |
A concrete
TupleBinding for a Character primitive
wrapper or a char primitive. |
DoubleBinding |
A concrete
TupleBinding for an unsorted Double
primitive wrapper or an unsorted double primitive. |
FloatBinding |
A concrete
TupleBinding for an unsorted Float
primitive wrapper or an unsorted float primitive. |
IntegerBinding |
A concrete
TupleBinding for a Integer primitive
wrapper or an int primitive. |
LongBinding |
A concrete
TupleBinding for a Long primitive
wrapper or a long primitive. |
PackedIntegerBinding |
A concrete
TupleBinding for an unsorted Integer
primitive wrapper or an unsorted int primitive, that stores the
value in the smallest number of bytes possible. |
PackedLongBinding |
A concrete
TupleBinding for an unsorted Long
primitive wrapper or an unsorted long primitive, that stores
the value in the smallest number of bytes possible. |
ShortBinding |
A concrete
TupleBinding for a Short primitive
wrapper or a short primitive. |
SortedBigDecimalBinding |
A concrete
TupleBinding for a sorted BigDecimal
value. |
SortedDoubleBinding |
A concrete
TupleBinding for a sorted Double
primitive wrapper or a sorted double primitive. |
SortedFloatBinding |
A concrete
TupleBinding for a sorted Float
primitive wrapper or sorted a float primitive. |
SortedPackedIntegerBinding |
A concrete
TupleBinding for a sorted Integer
primitive wrapper or a sorted int primitive, that stores the
value in the smallest number of bytes possible. |
SortedPackedLongBinding |
A concrete
TupleBinding for a sorted Long
primitive wrapper or a sorted long primitive, that stores the
value in the smallest number of bytes possible. |
StringBinding |
A concrete
TupleBinding for a simple String value. |
TupleBase<E> |
A base class for tuple bindings and tuple key creators that provides control
over the allocation of the output buffer.
|
TupleBinding<E> |
An abstract
EntryBinding that treats a key or data entry as a
tuple; it includes predefined bindings for Java primitive types. |
TupleInput |
An
InputStream with DataInput -like methods for
reading tuple fields. |
TupleInputBinding |
A concrete
EntryBinding that uses the TupleInput
object as the key or data object. |
TupleMarshalledBinding<E extends MarshalledTupleEntry> |
A concrete
TupleBinding that delegates to the
MarshalledTupleEntry interface of the data or key object. |
TupleOutput |
An
OutputStream with DataOutput -like methods for
writing tuple fields. |
TupleTupleBinding<E> |
An abstract
EntityBinding that treats an entity's key entry and
data entry as tuples. |
TupleTupleKeyCreator<E> |
An abstract key creator that uses a tuple key and a tuple data entry.
|
TupleTupleMarshalledBinding<E extends MarshalledTupleEntry & MarshalledTupleKeyEntity> |
A concrete
TupleTupleBinding that delegates to the
MarshalledTupleEntry and
MarshalledTupleKeyEntity interfaces of the entity class. |
TupleTupleMarshalledKeyCreator<E extends MarshalledTupleEntry & MarshalledTupleKeyEntity> |
A concrete key creator that works in conjunction with a
TupleTupleMarshalledBinding . |
The serialization format for tuple bindings are designed for compactness, serialization speed and proper default sorting.
When a format is used for database keys, it is important to use default
sorting for best performance. Although a custom comparator may be specified
for a database
or
entity
index, custom comparators often reduce performance because comparators are
called very frequently during Btree operations.
For proper default sorting, the byte array of the stored format must be
designed so that a byte-by-byte unsigned comparison results in the natural sort
order, as defined by the Comparable.compareTo(T)
method of the
data type. For example, the natural sort order for integers is the standard
mathematical definition, and is implemented by Integer.compareTo
,
Long.compareTo
, etc. This is called default natural
sorting.
Although most tuple formats provide default natural sorting, not all of them do. Certain formats do not provide default natural sorting for historical reasons (see the discussion of packed integer and float formats below.) Other formats sacrifice default natural sorting for other performance factors (see the discussion of BigDecimal formats below.)
Another performance factor has to do with amount of memory used by keys in
the Btree. Keys are stored in their serialized form in the Btree. If keys are
small (currently 16 bytes or less), Btree memory can be optimized. Optimized
memory storage is based on the maximum size of all keys in a single Btree
node. A single Btree node holds N adjacent key values, where N is 128 by
default and can be configured
for each database or index.
All String
formats support default natural sorting.
Strings are stored as a byte array of UTF encoded characters, either where the length must be known by the application, or the byte array is zero-terminated. The UTF encoding is described below.
Binding classes and methods are provided for zero-terminated and
known-length String
values.
String
values.String
values.All fixed size integer formats support default natural sorting.
The size of the stored value depends on the type, and ranges (as one would
expect) from 1 byte for type byte
and class Byte
, to 8 bytes for
type long
and class Long
.
Signed numbers are stored in the buffer in MSB (most significant byte first) order with their sign bit (high-order bit) inverted to cause negative numbers to be sorted first when comparing values as unsigned byte arrays, as done in a database.
Unsigned numbers, including characters, are stored in MSB order with no
change to their sign bit. Arrays of characters and unsigned bytes may also be
stored and may be treated as String
values. For booleans, true
is stored as the unsigned byte value one and false
as the unsigned byte
value zero.
TupleOutput.writeBoolean(boolean)
TupleInput.readBoolean()
TupleOutput.writeChar(int)
TupleInput.readChar()
TupleOutput.writeUnsignedByte(int)
TupleInput.readUnsignedByte()
TupleOutput.writeUnsignedShort(int)
TupleInput.readUnsignedShort()
TupleOutput.writeUnsignedInt(long)
TupleInput.readUnsignedInt()
String
values.The packed integer format stores integers with small absolute values in a
single byte. The size increases as the absolute value increases, up to a
maximum of 5 bytes for int
values and 9 bytes for long
values.
The packed integer format can be used for integer values between Long.MIN_VALUE
and Long.MAX_VALUE
. However,
different bindings and methods are provided for type int
and long
, to avoid unsafe casting from long
to int
when int
values are used.
Because the same packed format is used for int
and long
values, stored int
values may be expanded to long
values
without introducing a format incompatibility. In other words, you can treat
previously stored packed int
values as packed long
values.
Packed integer formats come in two varieties: those that support default natural sorting and those that don't. The formats of the two varieties are incompatible. For new applications, the format that supports default natural sorting should normally be used. There is no performance advantage to using the unsorted format.
The format with support for default natural sorting stores values in the inclusive range [-119,120] in a single byte.
The unsorted packed integer format is an older, legacy format that is used internally and supported for compatibility. It stores values in the inclusive range [-119,119] in a single byte. Because default natural sorting is not supported, this format should not be used for keys. However, it so happens that packed integers in the inclusive range [0,630] are sorted correctly by default, and this may be useful for some applications.
All BigInteger
formats support default natural sorting.
BigInteger
values are variable length and are stored as signed
values with a preceding byte length. The length has the same sign as the
value, in order to support default natural sorting.
The length is stored as a 2-byte (short), fixed size, signed integer.
Supported values are therefore limited to those with a byte array (BigInteger.toByteArray()
) representation with a size of 0x7fff bytes
or less. The maximum BigInteger
value is (20x3fff7 - 1) and
the minimum value is (-20x3fff7).
BigInteger
values.BigInteger
values.Floats and doubles are stored in a fixed size, 4 and 8 byte format, respectively. Floats and doubles are stored using two different representations: a representation with default natural sorting, and an unsorted, integer-bit (IEEE 754) representation. For new applications, the format that supports default natural sorting should normally be used. There is no performance advantage to using the unsorted format.
For float
values, Float.floatToIntBits
and the following
bit manipulations are used to convert the signed float value to a
representation that is sorted correctly by default.
int intVal = Float.floatToIntBits(val); intVal ^= (intVal < 0) ? 0xffffffff : 0x80000000;
For double
values, Float.doubleToLongBits
and the
following bit manipulations are used to convert the signed double value to a
representation that is sorted correctly by default.
long longVal = Double.doubleToLongBits(val); longVal ^= (longVal < 0) ? 0xffffffffffffffffL : 0x8000000000000000L;
In both cases, the resulting int
or long
value is stored as
an unsigned value.
float
and double
values
with default natural sorting.float
and double
values
with default natural sorting.The unsorted floating point format is an older, legacy format that is supported for compatibility. With this format, only zero and positive values have default natural sorting; negative values do not.
float
and double
values.float
and double
values.BigDecimal
values are stored using two different, variable length
representations: a representation that supports default natural sorting, and an
unsorted representation. Differences between the two formats are:
BigDecimal
format with default natural sorting should normally
be used for database keys.BigDecimal
format should normally be used for non-key
values.Both formats store the scale or exponent separately from the unscaled value, and the stored size does not increase proportionally as the absolute value of the scale or exponent increases.
BigDecimal
values with default
natural sorting.BigDecimal
values with default
natural sorting.TupleOutput.writeSortedBigDecimal(java.math.BigDecimal)
TupleOutput.getSortedBigDecimalMaxByteLength(java.math.BigDecimal)
TupleInput.readSortedBigDecimal()
TupleInput.getSortedBigDecimalByteLength()
BigDecimal
values.BigDecimal
values.Copyright (c) 2002, 2017 Oracle and/or its affiliates. All rights reserved.