third_party/googleapis/google/bigtable/v2/bigtable.proto - bazel - Git at Google

 // Copyright 2016 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance 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,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 syntax = "proto3";

 package google.bigtable.v2;

 import "google/api/annotations.proto";
 import "google/bigtable/v2/data.proto";
 import "google/protobuf/wrappers.proto";
 import "google/rpc/status.proto";

 option go_package = "google.golang.org/genproto/googleapis/bigtable/v2;bigtable";
 option java_multiple_files = true;
 option java_outer_classname = "BigtableProto";
 option java_package = "com.google.bigtable.v2";


 // Service for reading from and writing to existing Bigtable tables.
 service Bigtable {
   // Streams back the contents of all requested rows, optionally
   // applying the same Reader filter to each. Depending on their size,
   // rows and cells may be broken up across multiple responses, but
   // atomicity of each row will still be preserved. See the
   // ReadRowsResponse documentation for details.
   rpc ReadRows(ReadRowsRequest) returns (stream ReadRowsResponse) {
     option (google.api.http) = { post: "/v2/{table_name=projects/*/instances/*/tables/*}:readRows" body: "*" };
   }

   // Returns a sample of row keys in the table. The returned row keys will
   // delimit contiguous sections of the table of approximately equal size,
   // which can be used to break up the data for distributed tasks like
   // mapreduces.
   rpc SampleRowKeys(SampleRowKeysRequest) returns (stream SampleRowKeysResponse) {
     option (google.api.http) = { get: "/v2/{table_name=projects/*/instances/*/tables/*}:sampleRowKeys" };
   }

   // Mutates a row atomically. Cells already present in the row are left
   // unchanged unless explicitly changed by `mutation`.
   rpc MutateRow(MutateRowRequest) returns (MutateRowResponse) {
     option (google.api.http) = { post: "/v2/{table_name=projects/*/instances/*/tables/*}:mutateRow" body: "*" };
   }

   // Mutates multiple rows in a batch. Each individual row is mutated
   // atomically as in MutateRow, but the entire batch is not executed
   // atomically.
   rpc MutateRows(MutateRowsRequest) returns (stream MutateRowsResponse) {
     option (google.api.http) = { post: "/v2/{table_name=projects/*/instances/*/tables/*}:mutateRows" body: "*" };
   }

   // Mutates a row atomically based on the output of a predicate Reader filter.
   rpc CheckAndMutateRow(CheckAndMutateRowRequest) returns (CheckAndMutateRowResponse) {
     option (google.api.http) = { post: "/v2/{table_name=projects/*/instances/*/tables/*}:checkAndMutateRow" body: "*" };
   }

   // Modifies a row atomically. The method reads the latest existing timestamp
   // and value from the specified columns and writes a new entry based on
   // pre-defined read/modify/write rules. The new value for the timestamp is the
   // greater of the existing timestamp or the current server time. The method
   // returns the new contents of all modified cells.
   rpc ReadModifyWriteRow(ReadModifyWriteRowRequest) returns (ReadModifyWriteRowResponse) {
     option (google.api.http) = { post: "/v2/{table_name=projects/*/instances/*/tables/*}:readModifyWriteRow" body: "*" };
   }
 }

 // Request message for Bigtable.ReadRows.
 message ReadRowsRequest {
   // The unique name of the table from which to read.
   // Values are of the form
   // `projects/<project>/instances/<instance>/tables/<table>`.
   string table_name = 1;

   // The row keys and/or ranges to read. If not specified, reads from all rows.
   RowSet rows = 2;

   // The filter to apply to the contents of the specified row(s). If unset,
   // reads the entirety of each row.
   RowFilter filter = 3;

   // The read will terminate after committing to N rows' worth of results. The
   // default (zero) is to return all results.
   int64 rows_limit = 4;
 }

 // Response message for Bigtable.ReadRows.
 message ReadRowsResponse {
   // Specifies a piece of a row's contents returned as part of the read
   // response stream.
   message CellChunk {
     // The row key for this chunk of data.  If the row key is empty,
     // this CellChunk is a continuation of the same row as the previous
     // CellChunk in the response stream, even if that CellChunk was in a
     // previous ReadRowsResponse message.
     bytes row_key = 1;

     // The column family name for this chunk of data.  If this message
     // is not present this CellChunk is a continuation of the same column
     // family as the previous CellChunk.  The empty string can occur as a
     // column family name in a response so clients must check
     // explicitly for the presence of this message, not just for
     // `family_name.value` being non-empty.
     google.protobuf.StringValue family_name = 2;

     // The column qualifier for this chunk of data.  If this message
     // is not present, this CellChunk is a continuation of the same column
     // as the previous CellChunk.  Column qualifiers may be empty so
     // clients must check for the presence of this message, not just
     // for `qualifier.value` being non-empty.
     google.protobuf.BytesValue qualifier = 3;

     // The cell's stored timestamp, which also uniquely identifies it
     // within its column.  Values are always expressed in
     // microseconds, but individual tables may set a coarser
     // granularity to further restrict the allowed values. For
     // example, a table which specifies millisecond granularity will
     // only allow values of `timestamp_micros` which are multiples of
     // 1000.  Timestamps are only set in the first CellChunk per cell
     // (for cells split into multiple chunks).
     int64 timestamp_micros = 4;

     // Labels applied to the cell by a
     // [RowFilter][google.bigtable.v2.RowFilter].  Labels are only set
     // on the first CellChunk per cell.
     repeated string labels = 5;

     // The value stored in the cell.  Cell values can be split across
     // multiple CellChunks.  In that case only the value field will be
     // set in CellChunks after the first: the timestamp and labels
     // will only be present in the first CellChunk, even if the first
     // CellChunk came in a previous ReadRowsResponse.
     bytes value = 6;

     // If this CellChunk is part of a chunked cell value and this is
     // not the final chunk of that cell, value_size will be set to the
     // total length of the cell value.  The client can use this size
     // to pre-allocate memory to hold the full cell value.
     int32 value_size = 7;

     oneof row_status {
       // Indicates that the client should drop all previous chunks for
       // `row_key`, as it will be re-read from the beginning.
       bool reset_row = 8;

       // Indicates that the client can safely process all previous chunks for
       // `row_key`, as its data has been fully read.
       bool commit_row = 9;
     }
   }

   repeated CellChunk chunks = 1;

   // Optionally the server might return the row key of the last row it
   // has scanned.  The client can use this to construct a more
   // efficient retry request if needed: any row keys or portions of
   // ranges less than this row key can be dropped from the request.
   // This is primarily useful for cases where the server has read a
   // lot of data that was filtered out since the last committed row
   // key, allowing the client to skip that work on a retry.
   bytes last_scanned_row_key = 2;
 }

 // Request message for Bigtable.SampleRowKeys.
 message SampleRowKeysRequest {
   // The unique name of the table from which to sample row keys.
   // Values are of the form
   // `projects/<project>/instances/<instance>/tables/<table>`.
   string table_name = 1;
 }

 // Response message for Bigtable.SampleRowKeys.
 message SampleRowKeysResponse {
   // Sorted streamed sequence of sample row keys in the table. The table might
   // have contents before the first row key in the list and after the last one,
   // but a key containing the empty string indicates "end of table" and will be
   // the last response given, if present.
   // Note that row keys in this list may not have ever been written to or read
   // from, and users should therefore not make any assumptions about the row key
   // structure that are specific to their use case.
   bytes row_key = 1;

   // Approximate total storage space used by all rows in the table which precede
   // `row_key`. Buffering the contents of all rows between two subsequent
   // samples would require space roughly equal to the difference in their
   // `offset_bytes` fields.
   int64 offset_bytes = 2;
 }

 // Request message for Bigtable.MutateRow.
 message MutateRowRequest {
   // The unique name of the table to which the mutation should be applied.
   // Values are of the form
   // `projects/<project>/instances/<instance>/tables/<table>`.
   string table_name = 1;

   // The key of the row to which the mutation should be applied.
   bytes row_key = 2;

   // Changes to be atomically applied to the specified row. Entries are applied
   // in order, meaning that earlier mutations can be masked by later ones.
   // Must contain at least one entry and at most 100000.
   repeated Mutation mutations = 3;
 }

 // Response message for Bigtable.MutateRow.
 message MutateRowResponse {

 }

 // Request message for BigtableService.MutateRows.
 message MutateRowsRequest {
   message Entry {
     // The key of the row to which the `mutations` should be applied.
     bytes row_key = 1;

     // Changes to be atomically applied to the specified row. Mutations are
     // applied in order, meaning that earlier mutations can be masked by
     // later ones.
     // You must specify at least one mutation.
     repeated Mutation mutations = 2;
   }

   // The unique name of the table to which the mutations should be applied.
   string table_name = 1;

   // The row keys and corresponding mutations to be applied in bulk.
   // Each entry is applied as an atomic mutation, but the entries may be
   // applied in arbitrary order (even between entries for the same row).
   // At least one entry must be specified, and in total the entries can
   // contain at most 100000 mutations.
   repeated Entry entries = 2;
 }

 // Response message for BigtableService.MutateRows.
 message MutateRowsResponse {
   message Entry {
     // The index into the original request's `entries` list of the Entry
     // for which a result is being reported.
     int64 index = 1;

     // The result of the request Entry identified by `index`.
     // Depending on how requests are batched during execution, it is possible
     // for one Entry to fail due to an error with another Entry. In the event
     // that this occurs, the same error will be reported for both entries.
     google.rpc.Status status = 2;
   }

   // One or more results for Entries from the batch request.
   repeated Entry entries = 1;
 }

 // Request message for Bigtable.CheckAndMutateRow.
 message CheckAndMutateRowRequest {
   // The unique name of the table to which the conditional mutation should be
   // applied.
   // Values are of the form
   // `projects/<project>/instances/<instance>/tables/<table>`.
   string table_name = 1;

   // The key of the row to which the conditional mutation should be applied.
   bytes row_key = 2;

   // The filter to be applied to the contents of the specified row. Depending
   // on whether or not any results are yielded, either `true_mutations` or
   // `false_mutations` will be executed. If unset, checks that the row contains
   // any values at all.
   RowFilter predicate_filter = 6;

   // Changes to be atomically applied to the specified row if `predicate_filter`
   // yields at least one cell when applied to `row_key`. Entries are applied in
   // order, meaning that earlier mutations can be masked by later ones.
   // Must contain at least one entry if `false_mutations` is empty, and at most
   // 100000.
   repeated Mutation true_mutations = 4;

   // Changes to be atomically applied to the specified row if `predicate_filter`
   // does not yield any cells when applied to `row_key`. Entries are applied in
   // order, meaning that earlier mutations can be masked by later ones.
   // Must contain at least one entry if `true_mutations` is empty, and at most
   // 100000.
   repeated Mutation false_mutations = 5;
 }

 // Response message for Bigtable.CheckAndMutateRow.
 message CheckAndMutateRowResponse {
   // Whether or not the request's `predicate_filter` yielded any results for
   // the specified row.
   bool predicate_matched = 1;
 }

 // Request message for Bigtable.ReadModifyWriteRow.
 message ReadModifyWriteRowRequest {
   // The unique name of the table to which the read/modify/write rules should be
   // applied.
   // Values are of the form
   // `projects/<project>/instances/<instance>/tables/<table>`.
   string table_name = 1;

   // The key of the row to which the read/modify/write rules should be applied.
   bytes row_key = 2;

   // Rules specifying how the specified row's contents are to be transformed
   // into writes. Entries are applied in order, meaning that earlier rules will
   // affect the results of later ones.
   repeated ReadModifyWriteRule rules = 3;
 }

 // Response message for Bigtable.ReadModifyWriteRow.
 message ReadModifyWriteRowResponse {
   // A Row containing the new contents of all cells modified by the request.
   Row row = 1;
 }
	// Copyright 2016 Google Inc.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance 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,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	syntax = "proto3";

	package google.bigtable.v2;

	import "google/api/annotations.proto";
	import "google/bigtable/v2/data.proto";
	import "google/protobuf/wrappers.proto";
	import "google/rpc/status.proto";

	option go_package = "google.golang.org/genproto/googleapis/bigtable/v2;bigtable";
	option java_multiple_files = true;
	option java_outer_classname = "BigtableProto";
	option java_package = "com.google.bigtable.v2";


	// Service for reading from and writing to existing Bigtable tables.
	service Bigtable {
	// Streams back the contents of all requested rows, optionally
	// applying the same Reader filter to each. Depending on their size,
	// rows and cells may be broken up across multiple responses, but
	// atomicity of each row will still be preserved. See the
	// ReadRowsResponse documentation for details.
	rpc ReadRows(ReadRowsRequest) returns (stream ReadRowsResponse) {
	option (google.api.http) = { post: "/v2/{table_name=projects//instances//tables/}:readRows" body: "" };
	}

	// Returns a sample of row keys in the table. The returned row keys will
	// delimit contiguous sections of the table of approximately equal size,
	// which can be used to break up the data for distributed tasks like
	// mapreduces.
	rpc SampleRowKeys(SampleRowKeysRequest) returns (stream SampleRowKeysResponse) {
	option (google.api.http) = { get: "/v2/{table_name=projects//instances//tables/*}:sampleRowKeys" };
	}

	// Mutates a row atomically. Cells already present in the row are left
	// unchanged unless explicitly changed by `mutation`.
	rpc MutateRow(MutateRowRequest) returns (MutateRowResponse) {
	option (google.api.http) = { post: "/v2/{table_name=projects//instances//tables/}:mutateRow" body: "" };
	}

	// Mutates multiple rows in a batch. Each individual row is mutated
	// atomically as in MutateRow, but the entire batch is not executed
	// atomically.
	rpc MutateRows(MutateRowsRequest) returns (stream MutateRowsResponse) {
	option (google.api.http) = { post: "/v2/{table_name=projects//instances//tables/}:mutateRows" body: "" };
	}

	// Mutates a row atomically based on the output of a predicate Reader filter.
	rpc CheckAndMutateRow(CheckAndMutateRowRequest) returns (CheckAndMutateRowResponse) {
	option (google.api.http) = { post: "/v2/{table_name=projects//instances//tables/}:checkAndMutateRow" body: "" };
	}

	// Modifies a row atomically. The method reads the latest existing timestamp
	// and value from the specified columns and writes a new entry based on
	// pre-defined read/modify/write rules. The new value for the timestamp is the
	// greater of the existing timestamp or the current server time. The method
	// returns the new contents of all modified cells.
	rpc ReadModifyWriteRow(ReadModifyWriteRowRequest) returns (ReadModifyWriteRowResponse) {
	option (google.api.http) = { post: "/v2/{table_name=projects//instances//tables/}:readModifyWriteRow" body: "" };
	}
	}

	// Request message for Bigtable.ReadRows.
	message ReadRowsRequest {
	// The unique name of the table from which to read.
	// Values are of the form
	// `projects/<project>/instances/<instance>/tables/<table>`.
	string table_name = 1;

	// The row keys and/or ranges to read. If not specified, reads from all rows.
	RowSet rows = 2;

	// The filter to apply to the contents of the specified row(s). If unset,
	// reads the entirety of each row.
	RowFilter filter = 3;

	// The read will terminate after committing to N rows' worth of results. The
	// default (zero) is to return all results.
	int64 rows_limit = 4;
	}

	// Response message for Bigtable.ReadRows.
	message ReadRowsResponse {
	// Specifies a piece of a row's contents returned as part of the read
	// response stream.
	message CellChunk {
	// The row key for this chunk of data. If the row key is empty,
	// this CellChunk is a continuation of the same row as the previous
	// CellChunk in the response stream, even if that CellChunk was in a
	// previous ReadRowsResponse message.
	bytes row_key = 1;

	// The column family name for this chunk of data. If this message
	// is not present this CellChunk is a continuation of the same column
	// family as the previous CellChunk. The empty string can occur as a
	// column family name in a response so clients must check
	// explicitly for the presence of this message, not just for
	// `family_name.value` being non-empty.
	google.protobuf.StringValue family_name = 2;

	// The column qualifier for this chunk of data. If this message
	// is not present, this CellChunk is a continuation of the same column
	// as the previous CellChunk. Column qualifiers may be empty so
	// clients must check for the presence of this message, not just
	// for `qualifier.value` being non-empty.
	google.protobuf.BytesValue qualifier = 3;

	// The cell's stored timestamp, which also uniquely identifies it
	// within its column. Values are always expressed in
	// microseconds, but individual tables may set a coarser
	// granularity to further restrict the allowed values. For
	// example, a table which specifies millisecond granularity will
	// only allow values of `timestamp_micros` which are multiples of
	// 1000. Timestamps are only set in the first CellChunk per cell
	// (for cells split into multiple chunks).
	int64 timestamp_micros = 4;

	// Labels applied to the cell by a
	// [RowFilter][google.bigtable.v2.RowFilter]. Labels are only set
	// on the first CellChunk per cell.
	repeated string labels = 5;

	// The value stored in the cell. Cell values can be split across
	// multiple CellChunks. In that case only the value field will be
	// set in CellChunks after the first: the timestamp and labels
	// will only be present in the first CellChunk, even if the first
	// CellChunk came in a previous ReadRowsResponse.
	bytes value = 6;

	// If this CellChunk is part of a chunked cell value and this is
	// not the final chunk of that cell, value_size will be set to the
	// total length of the cell value. The client can use this size
	// to pre-allocate memory to hold the full cell value.
	int32 value_size = 7;

	oneof row_status {
	// Indicates that the client should drop all previous chunks for
	// `row_key`, as it will be re-read from the beginning.
	bool reset_row = 8;

	// Indicates that the client can safely process all previous chunks for
	// `row_key`, as its data has been fully read.
	bool commit_row = 9;
	}
	}

	repeated CellChunk chunks = 1;

	// Optionally the server might return the row key of the last row it
	// has scanned. The client can use this to construct a more
	// efficient retry request if needed: any row keys or portions of
	// ranges less than this row key can be dropped from the request.
	// This is primarily useful for cases where the server has read a
	// lot of data that was filtered out since the last committed row
	// key, allowing the client to skip that work on a retry.
	bytes last_scanned_row_key = 2;
	}

	// Request message for Bigtable.SampleRowKeys.
	message SampleRowKeysRequest {
	// The unique name of the table from which to sample row keys.
	// Values are of the form
	// `projects/<project>/instances/<instance>/tables/<table>`.
	string table_name = 1;
	}

	// Response message for Bigtable.SampleRowKeys.
	message SampleRowKeysResponse {
	// Sorted streamed sequence of sample row keys in the table. The table might
	// have contents before the first row key in the list and after the last one,
	// but a key containing the empty string indicates "end of table" and will be
	// the last response given, if present.
	// Note that row keys in this list may not have ever been written to or read
	// from, and users should therefore not make any assumptions about the row key
	// structure that are specific to their use case.
	bytes row_key = 1;

	// Approximate total storage space used by all rows in the table which precede
	// `row_key`. Buffering the contents of all rows between two subsequent
	// samples would require space roughly equal to the difference in their
	// `offset_bytes` fields.
	int64 offset_bytes = 2;
	}

	// Request message for Bigtable.MutateRow.
	message MutateRowRequest {
	// The unique name of the table to which the mutation should be applied.
	// Values are of the form
	// `projects/<project>/instances/<instance>/tables/<table>`.
	string table_name = 1;

	// The key of the row to which the mutation should be applied.
	bytes row_key = 2;

	// Changes to be atomically applied to the specified row. Entries are applied
	// in order, meaning that earlier mutations can be masked by later ones.
	// Must contain at least one entry and at most 100000.
	repeated Mutation mutations = 3;
	}

	// Response message for Bigtable.MutateRow.
	message MutateRowResponse {

	}

	// Request message for BigtableService.MutateRows.
	message MutateRowsRequest {
	message Entry {
	// The key of the row to which the `mutations` should be applied.
	bytes row_key = 1;

	// Changes to be atomically applied to the specified row. Mutations are
	// applied in order, meaning that earlier mutations can be masked by
	// later ones.
	// You must specify at least one mutation.
	repeated Mutation mutations = 2;
	}

	// The unique name of the table to which the mutations should be applied.
	string table_name = 1;

	// The row keys and corresponding mutations to be applied in bulk.
	// Each entry is applied as an atomic mutation, but the entries may be
	// applied in arbitrary order (even between entries for the same row).
	// At least one entry must be specified, and in total the entries can
	// contain at most 100000 mutations.
	repeated Entry entries = 2;
	}

	// Response message for BigtableService.MutateRows.
	message MutateRowsResponse {
	message Entry {
	// The index into the original request's `entries` list of the Entry
	// for which a result is being reported.
	int64 index = 1;

	// The result of the request Entry identified by `index`.
	// Depending on how requests are batched during execution, it is possible
	// for one Entry to fail due to an error with another Entry. In the event
	// that this occurs, the same error will be reported for both entries.
	google.rpc.Status status = 2;
	}

	// One or more results for Entries from the batch request.
	repeated Entry entries = 1;
	}

	// Request message for Bigtable.CheckAndMutateRow.
	message CheckAndMutateRowRequest {
	// The unique name of the table to which the conditional mutation should be
	// applied.
	// Values are of the form
	// `projects/<project>/instances/<instance>/tables/<table>`.
	string table_name = 1;

	// The key of the row to which the conditional mutation should be applied.
	bytes row_key = 2;

	// The filter to be applied to the contents of the specified row. Depending
	// on whether or not any results are yielded, either `true_mutations` or
	// `false_mutations` will be executed. If unset, checks that the row contains
	// any values at all.
	RowFilter predicate_filter = 6;

	// Changes to be atomically applied to the specified row if `predicate_filter`
	// yields at least one cell when applied to `row_key`. Entries are applied in
	// order, meaning that earlier mutations can be masked by later ones.
	// Must contain at least one entry if `false_mutations` is empty, and at most
	// 100000.
	repeated Mutation true_mutations = 4;

	// Changes to be atomically applied to the specified row if `predicate_filter`
	// does not yield any cells when applied to `row_key`. Entries are applied in
	// order, meaning that earlier mutations can be masked by later ones.
	// Must contain at least one entry if `true_mutations` is empty, and at most
	// 100000.
	repeated Mutation false_mutations = 5;
	}

	// Response message for Bigtable.CheckAndMutateRow.
	message CheckAndMutateRowResponse {
	// Whether or not the request's `predicate_filter` yielded any results for
	// the specified row.
	bool predicate_matched = 1;
	}

	// Request message for Bigtable.ReadModifyWriteRow.
	message ReadModifyWriteRowRequest {
	// The unique name of the table to which the read/modify/write rules should be
	// applied.
	// Values are of the form
	// `projects/<project>/instances/<instance>/tables/<table>`.
	string table_name = 1;

	// The key of the row to which the read/modify/write rules should be applied.
	bytes row_key = 2;

	// Rules specifying how the specified row's contents are to be transformed
	// into writes. Entries are applied in order, meaning that earlier rules will
	// affect the results of later ones.
	repeated ReadModifyWriteRule rules = 3;
	}

	// Response message for Bigtable.ReadModifyWriteRow.
	message ReadModifyWriteRowResponse {
	// A Row containing the new contents of all cells modified by the request.
	Row row = 1;
	}