org.apache.hadoop.hbase.client.AsyncTable Maven / Gradle / Ivy
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* to you under the Apache License, Version 2.0 (the
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* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
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* See the License for the specific language governing permissions and
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*/
package org.apache.hadoop.hbase.client;
import static java.util.stream.Collectors.toList;
import static org.apache.hadoop.hbase.client.ConnectionUtils.toCheckExistenceOnly;
import static org.apache.hadoop.hbase.util.FutureUtils.allOf;
import com.google.protobuf.RpcChannel;
import java.util.List;
import java.util.Map;
import java.util.concurrent.CompletableFuture;
import java.util.concurrent.TimeUnit;
import java.util.function.Function;
import org.apache.commons.lang3.NotImplementedException;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.hbase.CompareOperator;
import org.apache.hadoop.hbase.TableName;
import org.apache.hadoop.hbase.filter.Filter;
import org.apache.hadoop.hbase.io.TimeRange;
import org.apache.hadoop.hbase.util.Bytes;
import org.apache.yetus.audience.InterfaceAudience;
import org.apache.hbase.thirdparty.com.google.common.base.Preconditions;
/**
* The interface for asynchronous version of Table. Obtain an instance from a
* {@link AsyncConnection}.
*
* The implementation is required to be thread safe.
*
* Usually the implementation will not throw any exception directly. You need to get the exception
* from the returned {@link CompletableFuture}.
* @since 2.0.0
*/
@InterfaceAudience.Public
public interface AsyncTable {
/**
* Gets the fully qualified table name instance of this table.
*/
TableName getName();
/**
* Returns the {@link org.apache.hadoop.conf.Configuration} object used by this instance.
*
* The reference returned is not a copy, so any change made to it will affect this instance.
*/
Configuration getConfiguration();
/**
* Gets the {@link TableDescriptor} for this table.
*/
CompletableFuture getDescriptor();
/**
* Gets the {@link AsyncTableRegionLocator} for this table.
*/
AsyncTableRegionLocator getRegionLocator();
/**
* Get timeout of each rpc request in this Table instance. It will be overridden by a more
* specific rpc timeout config such as readRpcTimeout or writeRpcTimeout.
* @see #getReadRpcTimeout(TimeUnit)
* @see #getWriteRpcTimeout(TimeUnit)
* @param unit the unit of time the timeout to be represented in
* @return rpc timeout in the specified time unit
*/
long getRpcTimeout(TimeUnit unit);
/**
* Get timeout of each rpc read request in this Table instance.
* @param unit the unit of time the timeout to be represented in
* @return read rpc timeout in the specified time unit
*/
long getReadRpcTimeout(TimeUnit unit);
/**
* Get timeout of each rpc write request in this Table instance.
* @param unit the unit of time the timeout to be represented in
* @return write rpc timeout in the specified time unit
*/
long getWriteRpcTimeout(TimeUnit unit);
/**
* Get timeout of each operation in Table instance.
* @param unit the unit of time the timeout to be represented in
* @return operation rpc timeout in the specified time unit
*/
long getOperationTimeout(TimeUnit unit);
/**
* Get the timeout of a single operation in a scan. It works like operation timeout for other
* operations.
* @param unit the unit of time the timeout to be represented in
* @return scan rpc timeout in the specified time unit
*/
long getScanTimeout(TimeUnit unit);
/**
* Get the map of request attributes
* @return a map of request attributes supplied by the client
*/
default Map getRequestAttributes() {
throw new NotImplementedException("Add an implementation!");
}
/**
* Test for the existence of columns in the table, as specified by the Get.
*
* This will return true if the Get matches one or more keys, false if not.
*
* This is a server-side call so it prevents any data from being transfered to the client.
* @return true if the specified Get matches one or more keys, false if not. The return value will
* be wrapped by a {@link CompletableFuture}.
*/
default CompletableFuture exists(Get get) {
return get(toCheckExistenceOnly(get)).thenApply(r -> r.getExists());
}
/**
* Extracts certain cells from a given row.
* @param get The object that specifies what data to fetch and from which row.
* @return The data coming from the specified row, if it exists. If the row specified doesn't
* exist, the {@link Result} instance returned won't contain any
* {@link org.apache.hadoop.hbase.KeyValue}, as indicated by {@link Result#isEmpty()}. The
* return value will be wrapped by a {@link CompletableFuture}.
*/
CompletableFuture get(Get get);
/**
* Puts some data to the table.
* @param put The data to put.
* @return A {@link CompletableFuture} that always returns null when complete normally.
*/
CompletableFuture put(Put put);
/**
* Deletes the specified cells/row.
* @param delete The object that specifies what to delete.
* @return A {@link CompletableFuture} that always returns null when complete normally.
*/
CompletableFuture delete(Delete delete);
/**
* Appends values to one or more columns within a single row.
*
* This operation does not appear atomic to readers. Appends are done under a single row lock, so
* write operations to a row are synchronized, but readers do not take row locks so get and scan
* operations can see this operation partially completed.
* @param append object that specifies the columns and amounts to be used for the increment
* operations
* @return values of columns after the append operation (maybe null). The return value will be
* wrapped by a {@link CompletableFuture}.
*/
CompletableFuture append(Append append);
/**
* Increments one or more columns within a single row.
*
* This operation does not appear atomic to readers. Increments are done under a single row lock,
* so write operations to a row are synchronized, but readers do not take row locks so get and
* scan operations can see this operation partially completed.
* @param increment object that specifies the columns and amounts to be used for the increment
* operations
* @return values of columns after the increment. The return value will be wrapped by a
* {@link CompletableFuture}.
*/
CompletableFuture increment(Increment increment);
/**
* See {@link #incrementColumnValue(byte[], byte[], byte[], long, Durability)}
*
* The {@link Durability} is defaulted to {@link Durability#SYNC_WAL}.
* @param row The row that contains the cell to increment.
* @param family The column family of the cell to increment.
* @param qualifier The column qualifier of the cell to increment.
* @param amount The amount to increment the cell with (or decrement, if the amount is
* negative).
* @return The new value, post increment. The return value will be wrapped by a
* {@link CompletableFuture}.
*/
default CompletableFuture incrementColumnValue(byte[] row, byte[] family, byte[] qualifier,
long amount) {
return incrementColumnValue(row, family, qualifier, amount, Durability.SYNC_WAL);
}
/**
* Atomically increments a column value. If the column value already exists and is not a
* big-endian long, this could throw an exception. If the column value does not yet exist it is
* initialized to amount
and written to the specified column.
*
* Setting durability to {@link Durability#SKIP_WAL} means that in a fail scenario you will lose
* any increments that have not been flushed.
* @param row The row that contains the cell to increment.
* @param family The column family of the cell to increment.
* @param qualifier The column qualifier of the cell to increment.
* @param amount The amount to increment the cell with (or decrement, if the amount is
* negative).
* @param durability The persistence guarantee for this increment.
* @return The new value, post increment. The return value will be wrapped by a
* {@link CompletableFuture}.
*/
default CompletableFuture incrementColumnValue(byte[] row, byte[] family, byte[] qualifier,
long amount, Durability durability) {
Preconditions.checkNotNull(row, "row is null");
Preconditions.checkNotNull(family, "family is null");
return increment(
new Increment(row).addColumn(family, qualifier, amount).setDurability(durability))
.thenApply(r -> Bytes.toLong(r.getValue(family, qualifier)));
}
/**
* Atomically checks if a row/family/qualifier value matches the expected value. If it does, it
* adds the Put/Delete/RowMutations.
*
* Use the returned {@link CheckAndMutateBuilder} to construct your request and then execute it.
* This is a fluent style API, the code is like:
*
*
* table.checkAndMutate(row, family).qualifier(qualifier).ifNotExists().thenPut(put)
* .thenAccept(succ -> {
* if (succ) {
* System.out.println("Check and put succeeded");
* } else {
* System.out.println("Check and put failed");
* }
* });
*
*
* @deprecated Since 2.4.0, will be removed in 4.0.0. For internal test use only, do not use it
* any more.
*/
@Deprecated
CheckAndMutateBuilder checkAndMutate(byte[] row, byte[] family);
/**
* A helper class for sending checkAndMutate request.
* @deprecated Since 2.4.0, will be removed in 4.0.0. For internal test use only, do not use it
* any more.
*/
@Deprecated
interface CheckAndMutateBuilder {
/**
* Match a qualifier.
* @param qualifier column qualifier to check.
*/
CheckAndMutateBuilder qualifier(byte[] qualifier);
/**
* Match a timerange.
* @param timeRange time range to check.
*/
CheckAndMutateBuilder timeRange(TimeRange timeRange);
/**
* Check for lack of column.
*/
CheckAndMutateBuilder ifNotExists();
/**
* Check for equality.
* @param value the expected value
*/
default CheckAndMutateBuilder ifEquals(byte[] value) {
return ifMatches(CompareOperator.EQUAL, value);
}
/**
* Compare a value
* @param compareOp comparison operator to use
* @param value the expected value
*/
CheckAndMutateBuilder ifMatches(CompareOperator compareOp, byte[] value);
/**
* Specify a Put to commit if the check succeeds.
* @param put data to put if check succeeds
* @return {@code true} if the new put was executed, {@code false} otherwise. The return value
* will be wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenPut(Put put);
/**
* Specify a Delete to commit if the check succeeds.
* @param delete data to delete if check succeeds
* @return {@code true} if the new delete was executed, {@code false} otherwise. The return
* value will be wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenDelete(Delete delete);
/**
* Specify a RowMutations to commit if the check succeeds.
* @param mutation mutations to perform if check succeeds
* @return true if the new mutation was executed, false otherwise. The return value will be
* wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenMutate(RowMutations mutation);
}
/**
* Atomically checks if a row matches the specified filter. If it does, it adds the
* Put/Delete/RowMutations.
*
* Use the returned {@link CheckAndMutateWithFilterBuilder} to construct your request and then
* execute it. This is a fluent style API, the code is like:
*
*
* table.checkAndMutate(row, filter).thenPut(put).thenAccept(succ -> {
* if (succ) {
* System.out.println("Check and put succeeded");
* } else {
* System.out.println("Check and put failed");
* }
* });
*
*
* @deprecated Since 2.4.0, will be removed in 4.0.0. For internal test use only, do not use it
* any more.
*/
@Deprecated
CheckAndMutateWithFilterBuilder checkAndMutate(byte[] row, Filter filter);
/**
* A helper class for sending checkAndMutate request with a filter.
* @deprecated Since 2.4.0, will be removed in 4.0.0. For internal test use only, do not use it
* any more.
*/
@Deprecated
interface CheckAndMutateWithFilterBuilder {
/**
* Match a timerange.
* @param timeRange time range to check.
*/
CheckAndMutateWithFilterBuilder timeRange(TimeRange timeRange);
/**
* Specify a Put to commit if the check succeeds.
* @param put data to put if check succeeds
* @return {@code true} if the new put was executed, {@code false} otherwise. The return value
* will be wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenPut(Put put);
/**
* Specify a Delete to commit if the check succeeds.
* @param delete data to delete if check succeeds
* @return {@code true} if the new delete was executed, {@code false} otherwise. The return
* value will be wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenDelete(Delete delete);
/**
* Specify a RowMutations to commit if the check succeeds.
* @param mutation mutations to perform if check succeeds
* @return true if the new mutation was executed, false otherwise. The return value will be
* wrapped by a {@link CompletableFuture}.
*/
CompletableFuture thenMutate(RowMutations mutation);
}
/**
* checkAndMutate that atomically checks if a row matches the specified condition. If it does, it
* performs the specified action.
* @param checkAndMutate The CheckAndMutate object.
* @return A {@link CompletableFuture}s that represent the result for the CheckAndMutate.
*/
CompletableFuture checkAndMutate(CheckAndMutate checkAndMutate);
/**
* Batch version of checkAndMutate. The specified CheckAndMutates are batched only in the sense
* that they are sent to a RS in one RPC, but each CheckAndMutate operation is still executed
* atomically (and thus, each may fail independently of others).
* @param checkAndMutates The list of CheckAndMutate.
* @return A list of {@link CompletableFuture}s that represent the result for each CheckAndMutate.
*/
List>
checkAndMutate(List checkAndMutates);
/**
* A simple version of batch checkAndMutate. It will fail if there are any failures.
* @param checkAndMutates The list of rows to apply.
* @return A {@link CompletableFuture} that wrapper the result list.
*/
default CompletableFuture>
checkAndMutateAll(List checkAndMutates) {
return allOf(checkAndMutate(checkAndMutates));
}
/**
* Performs multiple mutations atomically on a single row. Currently {@link Put} and
* {@link Delete} are supported.
* @param mutation object that specifies the set of mutations to perform atomically
* @return A {@link CompletableFuture} that returns results of Increment/Append operations
*/
CompletableFuture mutateRow(RowMutations mutation);
/**
* The scan API uses the observer pattern.
* @param scan A configured {@link Scan} object.
* @param consumer the consumer used to receive results.
* @see ScanResultConsumer
* @see AdvancedScanResultConsumer
*/
void scan(Scan scan, C consumer);
/**
* Gets a scanner on the current table for the given family.
* @param family The column family to scan.
* @return A scanner.
*/
default ResultScanner getScanner(byte[] family) {
return getScanner(new Scan().addFamily(family));
}
/**
* Gets a scanner on the current table for the given family and qualifier.
* @param family The column family to scan.
* @param qualifier The column qualifier to scan.
* @return A scanner.
*/
default ResultScanner getScanner(byte[] family, byte[] qualifier) {
return getScanner(new Scan().addColumn(family, qualifier));
}
/**
* Returns a scanner on the current table as specified by the {@link Scan} object.
* @param scan A configured {@link Scan} object.
* @return A scanner.
*/
ResultScanner getScanner(Scan scan);
/**
* Return all the results that match the given scan object.
*
* Notice that usually you should use this method with a {@link Scan} object that has limit set.
* For example, if you want to get the closest row after a given row, you could do this:
*
*
*
* table.scanAll(new Scan().withStartRow(row, false).setLimit(1)).thenAccept(results -> {
* if (results.isEmpty()) {
* System.out.println("No row after " + Bytes.toStringBinary(row));
* } else {
* System.out.println("The closest row after " + Bytes.toStringBinary(row) + " is "
* + Bytes.toStringBinary(results.stream().findFirst().get().getRow()));
* }
* });
*
*
* If your result set is very large, you should use other scan method to get a scanner or use
* callback to process the results. They will do chunking to prevent OOM. The scanAll method will
* fetch all the results and store them in a List and then return the list to you.
*
* The scan metrics will be collected background if you enable it but you have no way to get it.
* Usually you can get scan metrics from {@code ResultScanner}, or through
* {@code ScanResultConsumer.onScanMetricsCreated} but this method only returns a list of results.
* So if you really care about scan metrics then you'd better use other scan methods which return
* a {@code ResultScanner} or let you pass in a {@code ScanResultConsumer}. There is no
* performance difference between these scan methods so do not worry.
* @param scan A configured {@link Scan} object. So if you use this method to fetch a really large
* result set, it is likely to cause OOM.
* @return The results of this small scan operation. The return value will be wrapped by a
* {@link CompletableFuture}.
*/
CompletableFuture> scanAll(Scan scan);
/**
* Test for the existence of columns in the table, as specified by the Gets.
*
* This will return a list of booleans. Each value will be true if the related Get matches one or
* more keys, false if not.
*
* This is a server-side call so it prevents any data from being transferred to the client.
* @param gets the Gets
* @return A list of {@link CompletableFuture}s that represent the existence for each get.
*/
default List> exists(List gets) {
return get(toCheckExistenceOnly(gets)).stream()
.> map(f -> f.thenApply(r -> r.getExists())).collect(toList());
}
/**
* A simple version for batch exists. It will fail if there are any failures and you will get the
* whole result boolean list at once if the operation is succeeded.
* @param gets the Gets
* @return A {@link CompletableFuture} that wrapper the result boolean list.
*/
default CompletableFuture> existsAll(List gets) {
return allOf(exists(gets));
}
/**
* Extracts certain cells from the given rows, in batch.
*
* Notice that you may not get all the results with this function, which means some of the
* returned {@link CompletableFuture}s may succeed while some of the other returned
* {@link CompletableFuture}s may fail.
* @param gets The objects that specify what data to fetch and from which rows.
* @return A list of {@link CompletableFuture}s that represent the result for each get.
*/
List> get(List gets);
/**
* A simple version for batch get. It will fail if there are any failures and you will get the
* whole result list at once if the operation is succeeded.
* @param gets The objects that specify what data to fetch and from which rows.
* @return A {@link CompletableFuture} that wrapper the result list.
*/
default CompletableFuture> getAll(List gets) {
return allOf(get(gets));
}
/**
* Puts some data in the table, in batch.
* @param puts The list of mutations to apply.
* @return A list of {@link CompletableFuture}s that represent the result for each put.
*/
List> put(List puts);
/**
* A simple version of batch put. It will fail if there are any failures.
* @param puts The list of mutations to apply.
* @return A {@link CompletableFuture} that always returns null when complete normally.
*/
default CompletableFuture putAll(List puts) {
return allOf(put(puts)).thenApply(r -> null);
}
/**
* Deletes the specified cells/rows in bulk.
* @param deletes list of things to delete.
* @return A list of {@link CompletableFuture}s that represent the result for each delete.
*/
List> delete(List deletes);
/**
* A simple version of batch delete. It will fail if there are any failures.
* @param deletes list of things to delete.
* @return A {@link CompletableFuture} that always returns null when complete normally.
*/
default CompletableFuture deleteAll(List deletes) {
return allOf(delete(deletes)).thenApply(r -> null);
}
/**
* Method that does a batch call on Deletes, Gets, Puts, Increments, Appends and RowMutations. The
* ordering of execution of the actions is not defined. Meaning if you do a Put and a Get in the
* same {@link #batch} call, you will not necessarily be guaranteed that the Get returns what the
* Put had put.
* @param actions list of Get, Put, Delete, Increment, Append, and RowMutations objects
* @return A list of {@link CompletableFuture}s that represent the result for each action.
*/
List> batch(List extends Row> actions);
/**
* A simple version of batch. It will fail if there are any failures and you will get the whole
* result list at once if the operation is succeeded.
* @param actions list of Get, Put, Delete, Increment, Append and RowMutations objects
* @return A list of the result for the actions. Wrapped by a {@link CompletableFuture}.
*/
default CompletableFuture> batchAll(List extends Row> actions) {
return allOf(batch(actions));
}
/**
* Execute the given coprocessor call on the region which contains the given {@code row}.
*
* The {@code stubMaker} is just a delegation to the {@code newStub} call. Usually it is only a
* one line lambda expression, like:
*
*
* channel -> xxxService.newStub(channel)
*
*
* @param stubMaker a delegation to the actual {@code newStub} call.
* @param callable a delegation to the actual protobuf rpc call. See the comment of
* {@link ServiceCaller} for more details.
* @param row The row key used to identify the remote region location
* @param the type of the asynchronous stub
* @param the type of the return value
* @return the return value of the protobuf rpc call, wrapped by a {@link CompletableFuture}.
* @see ServiceCaller
*/
CompletableFuture coprocessorService(Function stubMaker,
ServiceCaller callable, byte[] row);
/**
* The callback when we want to execute a coprocessor call on a range of regions.
*
* As the locating itself also takes some time, the implementation may want to send rpc calls on
* the fly, which means we do not know how many regions we have when we get the return value of
* the rpc calls, so we need an {@link #onComplete()} which is used to tell you that we have
* passed all the return values to you(through the {@link #onRegionComplete(RegionInfo, Object)}
* or {@link #onRegionError(RegionInfo, Throwable)} calls), i.e, there will be no
* {@link #onRegionComplete(RegionInfo, Object)} or {@link #onRegionError(RegionInfo, Throwable)}
* calls in the future.
*
* Here is a pseudo code to describe a typical implementation of a range coprocessor service
* method to help you better understand how the {@link CoprocessorCallback} will be called. The
* {@code callback} in the pseudo code is our {@link CoprocessorCallback}. And notice that the
* {@code whenComplete} is {@code CompletableFuture.whenComplete}.
*
*
* locateThenCall(byte[] row) {
* locate(row).whenComplete((location, locateError) -> {
* if (locateError != null) {
* callback.onError(locateError);
* return;
* }
* incPendingCall();
* region = location.getRegion();
* if (region.getEndKey() > endKey) {
* locateEnd = true;
* } else {
* locateThenCall(region.getEndKey());
* }
* sendCall().whenComplete((resp, error) -> {
* if (error != null) {
* callback.onRegionError(region, error);
* } else {
* callback.onRegionComplete(region, resp);
* }
* if (locateEnd && decPendingCallAndGet() == 0) {
* callback.onComplete();
* }
* });
* });
* }
*
*/
@InterfaceAudience.Public
interface CoprocessorCallback {
/**
* Indicate that the respose of a region is available
* @param region the region that the response belongs to
* @param resp the response of the coprocessor call
*/
void onRegionComplete(RegionInfo region, R resp);
/**
* Indicate that the error for a region is available
* @param region the region that the error belongs to
* @param error the response error of the coprocessor call
*/
void onRegionError(RegionInfo region, Throwable error);
/**
* Indicate that all responses of the regions have been notified by calling
* {@link #onRegionComplete(RegionInfo, Object)} or
* {@link #onRegionError(RegionInfo, Throwable)}.
*/
void onComplete();
/**
* Indicate that we got an error which does not belong to any regions. Usually a locating error.
*/
void onError(Throwable error);
}
/**
* Helper class for sending coprocessorService request that executes a coprocessor call on regions
* which are covered by a range.
*
* If {@code fromRow} is not specified the selection will start with the first table region. If
* {@code toRow} is not specified the selection will continue through the last table region.
* @param the type of the protobuf Service you want to call.
* @param the type of the return value.
*/
interface CoprocessorServiceBuilder {
/**
* Specify a start row
* @param startKey start region selection with region containing this row, inclusive.
*/
default CoprocessorServiceBuilder fromRow(byte[] startKey) {
return fromRow(startKey, true);
}
/**
* Specify a start row
* @param startKey start region selection with region containing this row
* @param inclusive whether to include the startKey
*/
CoprocessorServiceBuilder fromRow(byte[] startKey, boolean inclusive);
/**
* Specify a stop row
* @param endKey select regions up to and including the region containing this row, exclusive.
*/
default CoprocessorServiceBuilder toRow(byte[] endKey) {
return toRow(endKey, false);
}
/**
* Specify a stop row
* @param endKey select regions up to and including the region containing this row
* @param inclusive whether to include the endKey
*/
CoprocessorServiceBuilder toRow(byte[] endKey, boolean inclusive);
/**
* Execute the coprocessorService request. You can get the response through the
* {@link CoprocessorCallback}.
*/
void execute();
}
/**
* Execute a coprocessor call on the regions which are covered by a range.
*
* Use the returned {@link CoprocessorServiceBuilder} construct your request and then execute it.
*
* The {@code stubMaker} is just a delegation to the {@code xxxService.newStub} call. Usually it
* is only a one line lambda expression, like:
*
*
* channel -> xxxService.newStub(channel)
*
*
* @param stubMaker a delegation to the actual {@code newStub} call.
* @param callable a delegation to the actual protobuf rpc call. See the comment of
* {@link ServiceCaller} for more details.
* @param callback callback to get the response. See the comment of {@link CoprocessorCallback}
* for more details.
*/
CoprocessorServiceBuilder coprocessorService(Function stubMaker,
ServiceCaller callable, CoprocessorCallback callback);
}