@Experimental(value=SOURCE_SINK) public abstract static class BoundedSource.BoundedReader<T> extends Source.Reader<T>
Reader
that reads a bounded amount of input and supports some additional operations,
such as progress estimation and dynamic work rebalancing.
Once Source.Reader.start()
or Source.Reader.advance()
has returned false, neither will be called again on
this object.
All methods will be run from the same thread except splitAtFraction(double)
, getFractionConsumed()
, getCurrentSource()
, getSplitPointsConsumed()
, and getSplitPointsRemaining()
, all of which can be called concurrently from a different thread.
There will not be multiple concurrent calls to splitAtFraction(double)
.
It must be safe to call splitAtFraction(double)
, getFractionConsumed()
, getCurrentSource()
, getSplitPointsConsumed()
, and getSplitPointsRemaining()
concurrently with other methods.
Additionally, a successful splitAtFraction(double)
call must, by definition, cause getCurrentSource()
to start returning a different value. Callers of getCurrentSource()
need to be aware of the possibility that the returned value can change at any time, and must
only access the properties of the source returned by getCurrentSource()
which do not
change between splitAtFraction(double)
calls.
splitAtFraction(double)
In the course of dynamic work rebalancing, the method splitAtFraction(double)
may be called
concurrently with Source.Reader.advance()
or Source.Reader.start()
. It is critical that their interaction is
implemented in a thread-safe way, otherwise data loss is possible.
Sources which support dynamic work rebalancing should use RangeTracker
to manage the (source-specific) range of positions
that is being split.
Modifier and Type | Field and Description |
---|---|
static long |
SPLIT_POINTS_UNKNOWN
A constant to use as the return value for
getSplitPointsConsumed() or getSplitPointsRemaining() when the exact value is unknown. |
Constructor and Description |
---|
BoundedReader() |
Modifier and Type | Method and Description |
---|---|
abstract BoundedSource<T> |
getCurrentSource()
Returns a
Source describing the same input that this Reader currently reads
(including items already read). |
Instant |
getCurrentTimestamp()
By default, returns the minimum possible timestamp.
|
@Nullable java.lang.Double |
getFractionConsumed()
Returns a value in [0, 1] representing approximately what fraction of the
current source this reader has read so far, or null if such an
estimate is not available. |
long |
getSplitPointsConsumed()
Returns the total amount of parallelism in the consumed (returned and processed) range of
this reader's current
BoundedSource (as would be returned by getCurrentSource() ). |
long |
getSplitPointsRemaining()
Returns the total amount of parallelism in the unprocessed part of this reader's current
BoundedSource (as would be returned by getCurrentSource() ). |
@Nullable BoundedSource<T> |
splitAtFraction(double fraction)
Tells the reader to narrow the range of the input it's going to read and give up the
remainder, so that the new range would contain approximately the given fraction of the amount
of data in the current range.
|
advance, close, getCurrent, start
public static final long SPLIT_POINTS_UNKNOWN
getSplitPointsConsumed()
or getSplitPointsRemaining()
when the exact value is unknown.public @Nullable java.lang.Double getFractionConsumed()
current source
this reader has read so far, or null
if such an
estimate is not available.
It is recommended that this method should satisfy the following properties:
Source.Reader.start()
call.
Source.Reader.start()
or Source.Reader.advance()
call that returns false.
By default, returns null to indicate that this cannot be estimated.
splitAtFraction(double)
is implemented, this method can be called concurrently to other
methods (including itself), and it is therefore critical for it to be implemented in a
thread-safe way.public long getSplitPointsConsumed()
BoundedSource
(as would be returned by getCurrentSource()
). This corresponds to all split point records (see RangeTracker
)
returned by this reader, excluding the last split point returned if the reader is
not finished.
Consider the following examples: (1) An input that can be read in parallel down to the
individual records, such as CountingSource.upTo(long)
, is called "perfectly splittable".
(2) a "block-compressed" file format such as AvroIO
, in which a block of records has
to be read as a whole, but different blocks can be read in parallel. (3) An "unsplittable"
input such as a cursor in a database.
reader
that is unstarted (aka, has never had a call to Source.Reader.start()
) has a consumed parallelism of 0. This condition holds independent of whether
the input is splittable.
reader
that has only returned its first element (aka, has
never had a call to Source.Reader.advance()
) has a consumed parallelism of 0: the first
element is the current element and is still being processed. This condition holds
independent of whether the input is splittable.
Source.Reader.start()
returned false), the consumed
parallelism is 0. This condition holds independent of whether the input is splittable.
Source.Reader.start()
returned true and
a call to Source.Reader.advance()
has returned false), the value returned must be at least 1
and should equal the total parallelism in the source.
Source.Reader.advance()
returned false,
at which point it becomes 1.
A reader that is implemented using a RangeTracker
is encouraged to use the range
tracker's ability to count split points to implement this method. See OffsetBasedSource.OffsetBasedReader
and OffsetRangeTracker
for an example.
Defaults to SPLIT_POINTS_UNKNOWN
. Any value less than 0 will be interpreted as
unknown.
BoundedSource.BoundedReader
for information about thread safety.getSplitPointsRemaining()
public long getSplitPointsRemaining()
BoundedSource
(as would be returned by getCurrentSource()
). This corresponds
to all unprocessed split point records (see RangeTracker
), including the last split
point returned, in the remainder part of the source.
This function should be implemented only in addition to getSplitPointsConsumed()
and only if an exact value can be returned.
Consider the following examples: (1) An input that can be read in parallel down to the
individual records, such as CountingSource.upTo(long)
, is called "perfectly splittable".
(2) a "block-compressed" file format such as AvroIO
, in which a block of records has
to be read as a whole, but different blocks can be read in parallel. (3) An "unsplittable"
input such as a cursor in a database.
Assume for examples (1) and (2) that the number of records or blocks remaining is known:
reader
for which the last call to Source.Reader.start()
or Source.Reader.advance()
has returned true should should not return 0, because this reader itself
represents parallelism at least 1. This condition holds independent of whether the
input is splittable.
Source.Reader.start()
or Source.Reader.advance()
) has returned false
should return a value of 0. This condition holds independent of whether the input is
splittable.
Defaults to SPLIT_POINTS_UNKNOWN
. Any value less than 0 will be interpreted as
unknown.
BoundedSource.BoundedReader
for information about thread safety.getSplitPointsConsumed()
public abstract BoundedSource<T> getCurrentSource()
Source
describing the same input that this Reader
currently reads
(including items already read).
Reader subclasses can use this method for convenience to access unchanging properties of the source being read. Alternatively, they can cache these properties in the constructor.
The framework will call this method in the course of dynamic work rebalancing, e.g. after
a successful splitAtFraction(double)
call.
Remember that Source
objects must always be immutable. However, the return value
of this function may be affected by dynamic work rebalancing, happening asynchronously via
splitAtFraction(double)
, meaning it can return a different Source
object. However, the returned object itself will still itself be immutable. Callers
must take care not to rely on properties of the returned source that may be asynchronously
changed as a result of this process (e.g. do not cache an end offset when reading a file).
For convenience, subclasses should usually return the most concrete subclass of Source
possible. In practice, the implementation of this method should nearly always be one
of the following:
getCurrentSource()
: delegate to base class. In this case, it is almost always an error
for the subclass to maintain its own copy of the source.
public FooReader(FooSource<T> source) {
super(source);
}
public FooSource<T> getCurrentSource() {
return (FooSource<T>)super.getCurrentSource();
}
private final FooSource<T> source;
public FooReader(FooSource<T> source) {
this.source = source;
}
public FooSource<T> getCurrentSource() {
return source;
}
BoundedSource.BoundedReader
that explicitly supports dynamic work rebalancing:
maintain a variable pointing to an immutable source object, and protect it with
synchronization.
private FooSource<T> source;
public FooReader(FooSource<T> source) {
this.source = source;
}
public synchronized FooSource<T> getCurrentSource() {
return source;
}
public synchronized FooSource<T> splitAtFraction(double fraction) {
...
FooSource<T> primary = ...;
FooSource<T> residual = ...;
this.source = primary;
return residual;
}
getCurrentSource
in class Source.Reader<T>
public @Nullable BoundedSource<T> splitAtFraction(double fraction)
Returns a BoundedSource
representing the remainder.
BoundedSource<T> initial = reader.getCurrentSource();
BoundedSource<T> residual = reader.splitAtFraction(fraction);
BoundedSource<T> primary = reader.getCurrentSource();
This method should return null
if the split cannot be performed for this fraction
while satisfying the semantics above. E.g., a reader that reads a range of offsets in a file
should return null
if it is already past the position in its range corresponding to
the given fraction. In this case, the method MUST have no effect (the reader must behave as
if the method hadn't been called at all).
It is also very important that this method always completes quickly. In particular, it should not perform or wait on any blocking operations such as I/O, RPCs etc. Violating this requirement may stall completion of the work item or even cause it to fail.
It is incorrect to make both this method and Source.Reader.start()
/Source.Reader.advance()
synchronized
, because those methods can perform blocking operations, and then this method
would have to wait for those calls to complete.
RangeTracker
makes it easy to implement this method
safely and correctly.
By default, returns null to indicate that splitting is not possible.
public Instant getCurrentTimestamp() throws java.util.NoSuchElementException
getCurrentTimestamp
in class Source.Reader<T>
java.util.NoSuchElementException
- if the reader is at the beginning of the input and Source.Reader.start()
or Source.Reader.advance()
wasn't called, or if the last Source.Reader.start()
or Source.Reader.advance()
returned false
.