syntax = "proto3"; package neo.fs.v2.object; option go_package = "git.frostfs.info/TrueCloudLab/frostfs-api-go/v2/object/grpc;object"; option csharp_namespace = "Neo.FileStorage.API.Object"; import "object/types.proto"; import "refs/types.proto"; import "session/types.proto"; // `ObjectService` provides API for manipulating objects. Object operations do // not affect the sidechain and are only served by nodes in p2p style. service ObjectService { // Receive full object structure, including Headers and payload. Response uses // gRPC stream. First response message carries the object with the requested // address. Chunk messages are parts of the object's payload if it is needed. // All messages, except the first one, carry payload chunks. The requested // object can be restored by concatenation of object message payload and all // chunks keeping the receiving order. // // Extended headers can change `Get` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requsted version of Network Map for object placement // calculation. // * [ __SYSTEM__NETMAP_LOOKUP_DEPTH ] \ // (`__NEOFS__NETMAP_LOOKUP_DEPTH` is deprecated) \ // Will try older versions (starting from `__SYSTEM__NETMAP_EPOCH` // (`__NEOFS__NETMAP_EPOCH` is deprecated) if specified or the latest one // otherwise) of Network Map to find an object until the depth limit is // reached. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // object has been successfully read; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // read access to the object is denied; // - **OBJECT_NOT_FOUND** (2049, SECTION_OBJECT): \ // object not found in container; // - **OBJECT_ALREADY_REMOVED** (2052, SECTION_OBJECT): \ // the requested object has been marked as deleted; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc Get(GetRequest) returns (stream GetResponse); // Put the object into container. Request uses gRPC stream. First message // SHOULD be of PutHeader type. `ContainerID` and `OwnerID` of an object // SHOULD be set. Session token SHOULD be obtained before `PUT` operation (see // session package). Chunk messages are considered by server as a part of an // object payload. All messages, except first one, SHOULD be payload chunks. // Chunk messages SHOULD be sent in the direct order of fragmentation. // // Extended headers can change `Put` behaviour: // * [ __SYSTEM__NETMAP_EPOCH \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requsted version of Network Map for object placement // calculation. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // object has been successfully saved in the container; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // write access to the container is denied; // - **LOCKED** (2050, SECTION_OBJECT): \ // placement of an object of type TOMBSTONE that includes at least one // locked object is prohibited; // - **LOCK_NON_REGULAR_OBJECT** (2051, SECTION_OBJECT): \ // placement of an object of type LOCK that includes at least one object of // type other than REGULAR is prohibited; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object storage container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_NOT_FOUND** (4096, SECTION_SESSION): \ // (for trusted object preparation) session private key does not exist or // has // been deleted; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc Put(stream PutRequest) returns (PutResponse); // Delete the object from a container. There is no immediate removal // guarantee. Object will be marked for removal and deleted eventually. // // Extended headers can change `Delete` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // object has been successfully marked to be removed from the container; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // delete access to the object is denied; // - **OBJECT_NOT_FOUND** (2049, SECTION_OBJECT): \ // the object could not be deleted because it has not been \ // found within the container; // - **LOCKED** (2050, SECTION_OBJECT): \ // deleting a locked object is prohibited; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc Delete(DeleteRequest) returns (DeleteResponse); // Returns the object Headers without data payload. By default full header is // returned. If `main_only` request field is set, the short header with only // the very minimal information will be returned instead. // // Extended headers can change `Head` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // object header has been successfully read; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // access to operation HEAD of the object is denied; // - **OBJECT_NOT_FOUND** (2049, SECTION_OBJECT): \ // object not found in container; // - **OBJECT_ALREADY_REMOVED** (2052, SECTION_OBJECT): \ // the requested object has been marked as deleted; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc Head(HeadRequest) returns (HeadResponse); // Search objects in container. Search query allows to match by Object // Header's filed values. Please see the corresponding NeoFS Technical // Specification section for more details. // // Extended headers can change `Search` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // objects have been successfully selected; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // access to operation SEARCH of the object is denied; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // search container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc Search(SearchRequest) returns (stream SearchResponse); // Get byte range of data payload. Range is set as an (offset, length) tuple. // Like in `Get` method, the response uses gRPC stream. Requested range can be // restored by concatenation of all received payload chunks keeping the // receiving order. // // Extended headers can change `GetRange` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // * [ __SYSTEM__NETMAP_LOOKUP_DEPTH ] \ // (`__NEOFS__NETMAP_LOOKUP_DEPTH` is deprecated) \ // Will try older versions of Network Map to find an object until the depth // limit is reached. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // data range of the object payload has been successfully read; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // access to operation RANGE of the object is denied; // - **OBJECT_NOT_FOUND** (2049, SECTION_OBJECT): \ // object not found in container; // - **OBJECT_ALREADY_REMOVED** (2052, SECTION_OBJECT): \ // the requested object has been marked as deleted. // - **OUT_OF_RANGE** (2053, SECTION_OBJECT): \ // the requested range is out of bounds; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc GetRange(GetRangeRequest) returns (stream GetRangeResponse); // Returns homomorphic or regular hash of object's payload range after // applying XOR operation with the provided `salt`. Ranges are set of (offset, // length) tuples. Hashes order in response corresponds to the ranges order in // the request. Note that hash is calculated for XORed data. // // Extended headers can change `GetRangeHash` behaviour: // * [ __SYSTEM__NETMAP_EPOCH ] \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // * [ __SYSTEM__NETMAP_LOOKUP_DEPTH ] \ // (`__NEOFS__NETMAP_LOOKUP_DEPTH` is deprecated) \ // Will try older versions of Network Map to find an object until the depth // limit is reached. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // data range of the object payload has been successfully hashed; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // access to operation RANGEHASH of the object is denied; // - **OBJECT_NOT_FOUND** (2049, SECTION_OBJECT): \ // object not found in container; // - **OUT_OF_RANGE** (2053, SECTION_OBJECT): \ // the requested range is out of bounds; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc GetRangeHash(GetRangeHashRequest) returns (GetRangeHashResponse); // Put the prepared object into container. // `ContainerID`, `ObjectID`, `OwnerID`, `PayloadHash` and `PayloadLength` of // an object MUST be set. // // Extended headers can change `Put` behaviour: // * [ __SYSTEM__NETMAP_EPOCH \ // (`__NEOFS__NETMAP_EPOCH` is deprecated) \ // Will use the requested version of Network Map for object placement // calculation. // // Please refer to detailed `XHeader` description. // // Statuses: // - **OK** (0, SECTION_SUCCESS): \ // object has been successfully saved in the container; // - Common failures (SECTION_FAILURE_COMMON); // - **ACCESS_DENIED** (2048, SECTION_OBJECT): \ // write access to the container is denied; // - **LOCKED** (2050, SECTION_OBJECT): \ // placement of an object of type TOMBSTONE that includes at least one // locked object is prohibited; // - **LOCK_NON_REGULAR_OBJECT** (2051, SECTION_OBJECT): \ // placement of an object of type LOCK that includes at least one object of // type other than REGULAR is prohibited; // - **CONTAINER_NOT_FOUND** (3072, SECTION_CONTAINER): \ // object storage container not found; // - **CONTAINER_ACCESS_DENIED** (3074, SECTION_CONTAINER): \ // access to container is denied; // - **TOKEN_NOT_FOUND** (4096, SECTION_SESSION): \ // (for trusted object preparation) session private key does not exist or // has // been deleted; // - **TOKEN_EXPIRED** (4097, SECTION_SESSION): \ // provided session token has expired. rpc PutSingle(PutSingleRequest) returns (PutSingleResponse); } // GET object request message GetRequest { // GET Object request body message Body { // Address of the requested object neo.fs.v2.refs.Address address = 1; // If `raw` flag is set, request will work only with objects that are // physically stored on the peer node bool raw = 2; } // Body of get object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // GET object response message GetResponse { // GET Object Response body message Body { // Initial part of the `Object` structure stream. Technically it's a // set of all `Object` structure's fields except `payload`. message Init { // Object's unique identifier. neo.fs.v2.refs.ObjectID object_id = 1; // Signed `ObjectID` neo.fs.v2.refs.Signature signature = 2; // Object metadata headers Header header = 3; } // Single message in the response stream. oneof object_part { // Initial part of the object stream Init init = 1; // Chunked object payload bytes chunk = 2; // Meta information of split hierarchy for object assembly. SplitInfo split_info = 3; // Meta information for EC object assembly. ECInfo ec_info = 4; } } // Body of get object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // PUT object request message PutRequest { // PUT request body message Body { // Newly created object structure parameters. If some optional parameters // are not set, they will be calculated by a peer node. message Init { // ObjectID if available. neo.fs.v2.refs.ObjectID object_id = 1; // Object signature if available neo.fs.v2.refs.Signature signature = 2; // Object's Header Header header = 3; // Number of copies of the object to store within the RPC call. By // default, object is processed according to the container's placement // policy. Can be one of: // 1. A single number; applied to the whole request and is treated as // a minimal number of nodes that must store an object to complete the // request successfully. // 2. An ordered array; every number is treated as a minimal number of // nodes in a corresponding placement vector that must store an object // to complete the request successfully. The length MUST equal the // placement vectors number, otherwise request is considered malformed. repeated uint32 copies_number = 4; } // Single message in the request stream. oneof object_part { // Initial part of the object stream Init init = 1; // Chunked object payload bytes chunk = 2; } } // Body of put object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // PUT Object response message PutResponse { // PUT Object response body message Body { // Identifier of the saved object neo.fs.v2.refs.ObjectID object_id = 1; } // Body of put object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Object DELETE request message DeleteRequest { // Object DELETE request body message Body { // Address of the object to be deleted neo.fs.v2.refs.Address address = 1; } // Body of delete object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // DeleteResponse body is empty because we cannot guarantee permanent object // removal in distributed system. message DeleteResponse { // Object DELETE Response has an empty body. message Body { // Address of the tombstone created for the deleted object neo.fs.v2.refs.Address tombstone = 1; } // Body of delete object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Object HEAD request message HeadRequest { // Object HEAD request body message Body { // Address of the object with the requested Header neo.fs.v2.refs.Address address = 1; // Return only minimal header subset bool main_only = 2; // If `raw` flag is set, request will work only with objects that are // physically stored on the peer node bool raw = 3; } // Body of head object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // Tuple of a full object header and signature of an `ObjectID`. \ // Signed `ObjectID` is present to verify full header's authenticity through the // following steps: // // 1. Calculate `SHA-256` of the marshalled `Header` structure // 2. Check if the resulting hash matches `ObjectID` // 3. Check if `ObjectID` signature in `signature` field is correct message HeaderWithSignature { // Full object header Header header = 1 [ json_name = "header" ]; // Signed `ObjectID` to verify full header's authenticity neo.fs.v2.refs.Signature signature = 2 [ json_name = "signature" ]; } // Object HEAD response message HeadResponse { // Object HEAD response body message Body { // Requested object header, it's part or meta information about split // object. oneof head { // Full object's `Header` with `ObjectID` signature HeaderWithSignature header = 1; // Short object header ShortHeader short_header = 2; // Meta information of split hierarchy. SplitInfo split_info = 3; // Meta information for EC object assembly. ECInfo ec_info = 4; } } // Body of head object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Object Search request message SearchRequest { // Object Search request body message Body { // Container identifier were to search neo.fs.v2.refs.ContainerID container_id = 1; // Version of the Query Language used uint32 version = 2; // Filter structure checks if the object header field or the attribute // content matches a value. // // If no filters are set, search request will return all objects of the // container, including Regular object and Tombstone // objects. Most human users expect to get only object they can directly // work with. In that case, `$Object:ROOT` filter should be used. // // By default `key` field refers to the corresponding object's `Attribute`. // Some Object's header fields can also be accessed by adding `$Object:` // prefix to the name. Here is the list of fields available via this prefix: // // * $Object:version \ // version // * $Object:objectID \ // object_id // * $Object:containerID \ // container_id // * $Object:ownerID \ // owner_id // * $Object:creationEpoch \ // creation_epoch // * $Object:payloadLength \ // payload_length // * $Object:payloadHash \ // payload_hash // * $Object:objectType \ // object_type // * $Object:homomorphicHash \ // homomorphic_hash // * $Object:split.parent \ // object_id of parent // * $Object:split.splitID \ // 16 byte UUIDv4 used to identify the split object hierarchy parts // * $Object:ec.parent \ // If the object is stored according to EC policy, then ec_parent attribute // is set to return an id list of all related EC chunks. // // There are some well-known filter aliases to match objects by certain // properties: // // * $Object:ROOT \ // Returns only `REGULAR` type objects that are not split or that are the // top level root objects in a split hierarchy. This includes objects not // present physically, like large objects split into smaller objects // without a separate top-level root object. Objects of other types like // Locks and Tombstones will not be shown. This filter may be // useful for listing objects like `ls` command of some virtual file // system. This filter is activated if the `key` exists, disregarding the // value and matcher type. // * $Object:PHY \ // Returns only objects physically stored in the system. This filter is // activated if the `key` exists, disregarding the value and matcher type. // // Note: using filters with a key with prefix `$Object:` and match type // `NOT_PRESENT `is not recommended since this is not a cross-version // approach. Behavior when processing this kind of filters is undefined. message Filter { // Match type to use MatchType match_type = 1 [ json_name = "matchType" ]; // Attribute or Header fields to match string key = 2 [ json_name = "key" ]; // Value to match string value = 3 [ json_name = "value" ]; } // List of search expressions repeated Filter filters = 3; } // Body of search object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // Search response message SearchResponse { // Object Search response body message Body { // List of `ObjectID`s that match the search query repeated neo.fs.v2.refs.ObjectID id_list = 1; } // Body of search object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Object payload range.Ranges of zero length SHOULD be considered as invalid. message Range { // Offset of the range from the object payload start uint64 offset = 1; // Length in bytes of the object payload range uint64 length = 2; } // Request part of object's payload message GetRangeRequest { // Byte range of object's payload request body message Body { // Address of the object containing the requested payload range neo.fs.v2.refs.Address address = 1; // Requested payload range Range range = 2; // If `raw` flag is set, request will work only with objects that are // physically stored on the peer node. bool raw = 3; } // Body of get range object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // Get part of object's payload message GetRangeResponse { // Get Range response body uses streams to transfer the response. Because // object payload considered a byte sequence, there is no need to have some // initial preamble message. The requested byte range is sent as a series // chunks. message Body { // Requested object range or meta information about split object. oneof range_part { // Chunked object payload's range. bytes chunk = 1; // Meta information of split hierarchy. SplitInfo split_info = 2; // Meta information for EC object assembly. ECInfo ec_info = 3; } } // Body of get range object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Get hash of object's payload part message GetRangeHashRequest { // Get hash of object's payload part request body. message Body { // Address of the object that containing the requested payload range neo.fs.v2.refs.Address address = 1; // List of object's payload ranges to calculate homomorphic hash repeated Range ranges = 2; // Binary salt to XOR object's payload ranges before hash calculation bytes salt = 3; // Checksum algorithm type neo.fs.v2.refs.ChecksumType type = 4; } // Body of get range hash object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // Get hash of object's payload part message GetRangeHashResponse { // Get hash of object's payload part response body. message Body { // Checksum algorithm type neo.fs.v2.refs.ChecksumType type = 1; // List of range hashes in a binary format repeated bytes hash_list = 2; } // Body of get range hash object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; } // Object PUT Single request message PutSingleRequest { // PUT Single request body message Body { // Prepared object with payload. Object object = 1; // Number of copies of the object to store within the RPC call. By default, // object is processed according to the container's placement policy. // Every number is treated as a minimal number of // nodes in a corresponding placement vector that must store an object // to complete the request successfully. The length MUST equal the placement // vectors number, otherwise request is considered malformed. repeated uint32 copies_number = 2; } // Body of put single object request message. Body body = 1; // Carries request meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.RequestMetaHeader meta_header = 2; // Carries request verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.RequestVerificationHeader verify_header = 3; } // Object PUT Single response message PutSingleResponse { // PUT Single Object response body message Body {} // Body of put single object response message. Body body = 1; // Carries response meta information. Header data is used only to regulate // message transport and does not affect request execution. neo.fs.v2.session.ResponseMetaHeader meta_header = 2; // Carries response verification information. This header is used to // authenticate the nodes of the message route and check the correctness of // transmission. neo.fs.v2.session.ResponseVerificationHeader verify_header = 3; }