All Downloads are FREE. Search and download functionalities are using the official Maven repository.

etcd.etcdserver.etcdserverpb.rpc.proto Maven / Gradle / Ivy

There is a newer version: 3.1.0
Show newest version
syntax = "proto3";

import "etcd/mvcc/mvccpb/kv.proto";
import "etcd/auth/authpb/auth.proto";

package etcdserverpb;

service KV {
    // Range gets the keys in the range from the key-value store.
    rpc Range (RangeRequest) returns (RangeResponse) {
    }

    // Put puts the given key into the key-value store.
    // A put request increments the revision of the key-value store
    // and generates one event in the event history.
    rpc Put (PutRequest) returns (PutResponse) {
    }

    // DeleteRange deletes the given range from the key-value store.
    // A delete request increments the revision of the key-value store
    // and generates a delete event in the event history for every deleted key.
    rpc DeleteRange (DeleteRangeRequest) returns (DeleteRangeResponse) {
    }

    // Txn processes multiple requests in a single transaction.
    // A txn request increments the revision of the key-value store
    // and generates events with the same revision for every completed request.
    // It is not allowed to modify the same key several times within one txn.
    rpc Txn (TxnRequest) returns (TxnResponse) {
    }

    // Compact compacts the event history in the etcd key-value store. The key-value
    // store should be periodically compacted or the event history will continue to grow
    // indefinitely.
    rpc Compact (CompactionRequest) returns (CompactionResponse) {
    }
}

service Watch {
    // Watch watches for events happening or that have happened. Both input and output
    // are streams; the input stream is for creating and canceling watchers and the output
    // stream sends events. One watch RPC can watch on multiple key ranges, streaming events
    // for several watches at once. The entire event history can be watched starting from the
    // last compaction revision.
    rpc Watch (stream WatchRequest) returns (stream WatchResponse) {
    }
}

service Lease {
    // LeaseGrant creates a lease which expires if the server does not receive a keepAlive
    // within a given time to live period. All keys attached to the lease will be expired and
    // deleted if the lease expires. Each expired key generates a delete event in the event history.
    rpc LeaseGrant (LeaseGrantRequest) returns (LeaseGrantResponse) {
    }

    // LeaseRevoke revokes a lease. All keys attached to the lease will expire and be deleted.
    rpc LeaseRevoke (LeaseRevokeRequest) returns (LeaseRevokeResponse) {
    }

    // LeaseKeepAlive keeps the lease alive by streaming keep alive requests from the client
    // to the server and streaming keep alive responses from the server to the client.
    rpc LeaseKeepAlive (stream LeaseKeepAliveRequest) returns (stream LeaseKeepAliveResponse) {
    }

    // LeaseTimeToLive retrieves lease information.
    rpc LeaseTimeToLive (LeaseTimeToLiveRequest) returns (LeaseTimeToLiveResponse) {
    }

    // TODO(xiangli) List all existing Leases?
}

service Cluster {
    // MemberAdd adds a member into the cluster.
    rpc MemberAdd (MemberAddRequest) returns (MemberAddResponse) {
    }

    // MemberRemove removes an existing member from the cluster.
    rpc MemberRemove (MemberRemoveRequest) returns (MemberRemoveResponse) {
    }

    // MemberUpdate updates the member configuration.
    rpc MemberUpdate (MemberUpdateRequest) returns (MemberUpdateResponse) {
    }

    // MemberList lists all the members in the cluster.
    rpc MemberList (MemberListRequest) returns (MemberListResponse) {
    }
}

service Maintenance {
    // Alarm activates, deactivates, and queries alarms regarding cluster health.
    rpc Alarm (AlarmRequest) returns (AlarmResponse) {
    }

    // Status gets the status of the member.
    rpc Status (StatusRequest) returns (StatusResponse) {
    }

    // Defragment defragments a member's backend database to recover storage space.
    rpc Defragment (DefragmentRequest) returns (DefragmentResponse) {
    }

    // Hash returns the hash of the local KV state for consistency checking purpose.
    // This is designed for testing; do not use this in production when there
    // are ongoing transactions.
    rpc Hash (HashRequest) returns (HashResponse) {
    }

    // Snapshot sends a snapshot of the entire backend from a member over a stream to a client.
    rpc Snapshot (SnapshotRequest) returns (stream SnapshotResponse) {
    }
}

service Auth {
    // AuthEnable enables authentication.
    rpc AuthEnable (AuthEnableRequest) returns (AuthEnableResponse) {
    }

    // AuthDisable disables authentication.
    rpc AuthDisable (AuthDisableRequest) returns (AuthDisableResponse) {
    }

    // Authenticate processes an authenticate request.
    rpc Authenticate (AuthenticateRequest) returns (AuthenticateResponse) {
    }

    // UserAdd adds a new user.
    rpc UserAdd (AuthUserAddRequest) returns (AuthUserAddResponse) {
    }

    // UserGet gets detailed user information.
    rpc UserGet (AuthUserGetRequest) returns (AuthUserGetResponse) {
    }

    // UserList gets a list of all users.
    rpc UserList (AuthUserListRequest) returns (AuthUserListResponse) {
    }

    // UserDelete deletes a specified user.
    rpc UserDelete (AuthUserDeleteRequest) returns (AuthUserDeleteResponse) {
    }

    // UserChangePassword changes the password of a specified user.
    rpc UserChangePassword (AuthUserChangePasswordRequest) returns (AuthUserChangePasswordResponse) {
    }

    // UserGrant grants a role to a specified user.
    rpc UserGrantRole (AuthUserGrantRoleRequest) returns (AuthUserGrantRoleResponse) {
    }

    // UserRevokeRole revokes a role of specified user.
    rpc UserRevokeRole (AuthUserRevokeRoleRequest) returns (AuthUserRevokeRoleResponse) {
    }

    // RoleAdd adds a new role.
    rpc RoleAdd (AuthRoleAddRequest) returns (AuthRoleAddResponse) {
    }

    // RoleGet gets detailed role information.
    rpc RoleGet (AuthRoleGetRequest) returns (AuthRoleGetResponse) {
    }

    // RoleList gets lists of all roles.
    rpc RoleList (AuthRoleListRequest) returns (AuthRoleListResponse) {
    }

    // RoleDelete deletes a specified role.
    rpc RoleDelete (AuthRoleDeleteRequest) returns (AuthRoleDeleteResponse) {
    }

    // RoleGrantPermission grants a permission of a specified key or range to a specified role.
    rpc RoleGrantPermission (AuthRoleGrantPermissionRequest) returns (AuthRoleGrantPermissionResponse) {
    }

    // RoleRevokePermission revokes a key or range permission of a specified role.
    rpc RoleRevokePermission (AuthRoleRevokePermissionRequest) returns (AuthRoleRevokePermissionResponse) {
    }
}

message ResponseHeader {
    // cluster_id is the ID of the cluster which sent the response.
    uint64 cluster_id = 1;
    // member_id is the ID of the member which sent the response.
    uint64 member_id = 2;
    // revision is the key-value store revision when the request was applied.
    int64 revision = 3;
    // raft_term is the raft term when the request was applied.
    uint64 raft_term = 4;
}

message RangeRequest {
    enum SortOrder {
        NONE = 0; // default, no sorting
        ASCEND = 1; // lowest target value first
        DESCEND = 2; // highest target value first
    }
    enum SortTarget {
        KEY = 0;
        VERSION = 1;
        CREATE = 2;
        MOD = 3;
        VALUE = 4;
    }

    // key is the first key for the range. If range_end is not given, the request only looks up key.
    bytes key = 1;
    // range_end is the upper bound on the requested range [key, range_end).
    // If range_end is '\0', the range is all keys >= key.
    // If range_end is key plus one (e.g., "aa"+1 == "ab", "a\xff"+1 == "b"),
    // then the range request gets all keys prefixed with key.
    // If both key and range_end are '\0', then the range request returns all keys.
    bytes range_end = 2;
    // limit is a limit on the number of keys returned for the request. When limit is set to 0,
    // it is treated as no limit.
    int64 limit = 3;
    // revision is the point-in-time of the key-value store to use for the range.
    // If revision is less or equal to zero, the range is over the newest key-value store.
    // If the revision has been compacted, ErrCompacted is returned as a response.
    int64 revision = 4;

    // sort_order is the order for returned sorted results.
    SortOrder sort_order = 5;

    // sort_target is the key-value field to use for sorting.
    SortTarget sort_target = 6;

    // serializable sets the range request to use serializable member-local reads.
    // Range requests are linearizable by default; linearizable requests have higher
    // latency and lower throughput than serializable requests but reflect the current
    // consensus of the cluster. For better performance, in exchange for possible stale reads,
    // a serializable range request is served locally without needing to reach consensus
    // with other nodes in the cluster.
    bool serializable = 7;

    // keys_only when set returns only the keys and not the values.
    bool keys_only = 8;

    // count_only when set returns only the count of the keys in the range.
    bool count_only = 9;

    // min_mod_revision is the lower bound for returned key mod revisions; all keys with
    // lesser mod revisions will be filtered away.
    int64 min_mod_revision = 10;

    // max_mod_revision is the upper bound for returned key mod revisions; all keys with
    // greater mod revisions will be filtered away.
    int64 max_mod_revision = 11;

    // min_create_revision is the lower bound for returned key create revisions; all keys with
    // lesser create trevisions will be filtered away.
    int64 min_create_revision = 12;

    // max_create_revision is the upper bound for returned key create revisions; all keys with
    // greater create revisions will be filtered away.
    int64 max_create_revision = 13;
}

message RangeResponse {
    ResponseHeader header = 1;
    // kvs is the list of key-value pairs matched by the range request.
    // kvs is empty when count is requested.
    repeated mvccpb.KeyValue kvs = 2;
    // more indicates if there are more keys to return in the requested range.
    bool more = 3;
    // count is set to the number of keys within the range when requested.
    int64 count = 4;
}

message PutRequest {
    // key is the key, in bytes, to put into the key-value store.
    bytes key = 1;
    // value is the value, in bytes, to associate with the key in the key-value store.
    bytes value = 2;
    // lease is the lease ID to associate with the key in the key-value store. A lease
    // value of 0 indicates no lease.
    int64 lease = 3;

    // If prev_kv is set, etcd gets the previous key-value pair before changing it.
    // The previous key-value pair will be returned in the put response.
    bool prev_kv = 4;

    // If ignore_value is set, etcd updates the key using its current value.
    // Returns an error if the key does not exist.
    bool ignore_value = 5;

    // If ignore_lease is set, etcd updates the key using its current lease.
    // Returns an error if the key does not exist.
    bool ignore_lease = 6;
}

message PutResponse {
    ResponseHeader header = 1;
    // if prev_kv is set in the request, the previous key-value pair will be returned.
    mvccpb.KeyValue prev_kv = 2;
}

message DeleteRangeRequest {
    // key is the first key to delete in the range.
    bytes key = 1;
    // range_end is the key following the last key to delete for the range [key, range_end).
    // If range_end is not given, the range is defined to contain only the key argument.
    // If range_end is one bit larger than the given key, then the range is all the keys
    // with the prefix (the given key).
    // If range_end is '\0', the range is all keys greater than or equal to the key argument.
    bytes range_end = 2;

    // If prev_kv is set, etcd gets the previous key-value pairs before deleting it.
    // The previous key-value pairs will be returned in the delete response.
    bool prev_kv = 3;
}

message DeleteRangeResponse {
    ResponseHeader header = 1;
    // deleted is the number of keys deleted by the delete range request.
    int64 deleted = 2;
    // if prev_kv is set in the request, the previous key-value pairs will be returned.
    repeated mvccpb.KeyValue prev_kvs = 3;
}

message RequestOp {
    // request is a union of request types accepted by a transaction.
    oneof request {
        RangeRequest request_range = 1;
        PutRequest request_put = 2;
        DeleteRangeRequest request_delete_range = 3;
        TxnRequest request_txn = 4;
    }
}

message ResponseOp {
    // response is a union of response types returned by a transaction.
    oneof response {
        RangeResponse response_range = 1;
        PutResponse response_put = 2;
        DeleteRangeResponse response_delete_range = 3;
        TxnResponse response_txn = 4;
    }
}

message Compare {
    enum CompareResult {
        EQUAL = 0;
        GREATER = 1;
        LESS = 2;
        NOT_EQUAL = 3;
    }
    enum CompareTarget {
        VERSION = 0;
        CREATE = 1;
        MOD = 2;
        VALUE = 3;
    }
    // result is logical comparison operation for this comparison.
    CompareResult result = 1;
    // target is the key-value field to inspect for the comparison.
    CompareTarget target = 2;
    // key is the subject key for the comparison operation.
    bytes key = 3;
    oneof target_union {
        // version is the version of the given key
        int64 version = 4;
        // create_revision is the creation revision of the given key
        int64 create_revision = 5;
        // mod_revision is the last modified revision of the given key.
        int64 mod_revision = 6;
        // value is the value of the given key, in bytes.
        bytes value = 7;
    }
    // range_end compares the given target to all keys in the range [key, range_end).
    // See RangeRequest for more details on key ranges.
    bytes range_end = 8;
    // TODO: fill out with most of the rest of RangeRequest fields when needed.
}

// From google paxosdb paper:
// Our implementation hinges around a powerful primitive which we call MultiOp. All other database
// operations except for iteration are implemented as a single call to MultiOp. A MultiOp is applied atomically
// and consists of three components:
// 1. A list of tests called guard. Each test in guard checks a single entry in the database. It may check
// for the absence or presence of a value, or compare with a given value. Two different tests in the guard
// may apply to the same or different entries in the database. All tests in the guard are applied and
// MultiOp returns the results. If all tests are true, MultiOp executes t op (see item 2 below), otherwise
// it executes f op (see item 3 below).
// 2. A list of database operations called t op. Each operation in the list is either an insert, delete, or
// lookup operation, and applies to a single database entry. Two different operations in the list may apply
// to the same or different entries in the database. These operations are executed
// if guard evaluates to
// true.
// 3. A list of database operations called f op. Like t op, but executed if guard evaluates to false.
message TxnRequest {
    // compare is a list of predicates representing a conjunction of terms.
    // If the comparisons succeed, then the success requests will be processed in order,
    // and the response will contain their respective responses in order.
    // If the comparisons fail, then the failure requests will be processed in order,
    // and the response will contain their respective responses in order.
    repeated Compare compare = 1;
    // success is a list of requests which will be applied when compare evaluates to true.
    repeated RequestOp success = 2;
    // failure is a list of requests which will be applied when compare evaluates to false.
    repeated RequestOp failure = 3;
}

message TxnResponse {
    ResponseHeader header = 1;
    // succeeded is set to true if the compare evaluated to true or false otherwise.
    bool succeeded = 2;
    // responses is a list of responses corresponding to the results from applying
    // success if succeeded is true or failure if succeeded is false.
    repeated ResponseOp responses = 3;
}

// CompactionRequest compacts the key-value store up to a given revision. All superseded keys
// with a revision less than the compaction revision will be removed.
message CompactionRequest {
    // revision is the key-value store revision for the compaction operation.
    int64 revision = 1;
    // physical is set so the RPC will wait until the compaction is physically
    // applied to the local database such that compacted entries are totally
    // removed from the backend database.
    bool physical = 2;
}

message CompactionResponse {
    ResponseHeader header = 1;
}

message HashRequest {
}

message HashResponse {
    ResponseHeader header = 1;
    // hash is the hash value computed from the responding member's key-value store.
    uint32 hash = 2;
}

message SnapshotRequest {
}

message SnapshotResponse {
    // header has the current key-value store information. The first header in the snapshot
    // stream indicates the point in time of the snapshot.
    ResponseHeader header = 1;

    // remaining_bytes is the number of blob bytes to be sent after this message
    uint64 remaining_bytes = 2;

    // blob contains the next chunk of the snapshot in the snapshot stream.
    bytes blob = 3;
}

message WatchRequest {
    // request_union is a request to either create a new watcher or cancel an existing watcher.
    oneof request_union {
        WatchCreateRequest create_request = 1;
        WatchCancelRequest cancel_request = 2;
    }
}

message WatchCreateRequest {
    // key is the key to register for watching.
    bytes key = 1;
    // range_end is the end of the range [key, range_end) to watch. If range_end is not given,
    // only the key argument is watched. If range_end is equal to '\0', all keys greater than
    // or equal to the key argument are watched.
    // If the range_end is one bit larger than the given key,
    // then all keys with the prefix (the given key) will be watched.
    bytes range_end = 2;
    // start_revision is an optional revision to watch from (inclusive). No start_revision is "now".
    int64 start_revision = 3;
    // progress_notify is set so that the etcd server will periodically send a WatchResponse with
    // no events to the new watcher if there are no recent events. It is useful when clients
    // wish to recover a disconnected watcher starting from a recent known revision.
    // The etcd server may decide how often it will send notifications based on current load.
    bool progress_notify = 4;

    enum FilterType {
        // filter out put event.
        NOPUT = 0;
        // filter out delete event.
        NODELETE = 1;
    }
    // filters filter the events at server side before it sends back to the watcher.
    repeated FilterType filters = 5;

    // If prev_kv is set, created watcher gets the previous KV before the event happens.
    // If the previous KV is already compacted, nothing will be returned.
    bool prev_kv = 6;
}

message WatchCancelRequest {
    // watch_id is the watcher id to cancel so that no more events are transmitted.
    int64 watch_id = 1;
}

message WatchResponse {
    ResponseHeader header = 1;
    // watch_id is the ID of the watcher that corresponds to the response.
    int64 watch_id = 2;
    // created is set to true if the response is for a create watch request.
    // The client should record the watch_id and expect to receive events for
    // the created watcher from the same stream.
    // All events sent to the created watcher will attach with the same watch_id.
    bool created = 3;
    // canceled is set to true if the response is for a cancel watch request.
    // No further events will be sent to the canceled watcher.
    bool canceled = 4;
    // compact_revision is set to the minimum index if a watcher tries to watch
    // at a compacted index.
    //
    // This happens when creating a watcher at a compacted revision or the watcher cannot
    // catch up with the progress of the key-value store.
    //
    // The client should treat the watcher as canceled and should not try to create any
    // watcher with the same start_revision again.
    int64 compact_revision = 5;

    // cancel_reason indicates the reason for canceling the watcher.
    string cancel_reason = 6;

    repeated mvccpb.Event events = 11;
}

message LeaseGrantRequest {
    // TTL is the advisory time-to-live in seconds.
    int64 TTL = 1;
    // ID is the requested ID for the lease. If ID is set to 0, the lessor chooses an ID.
    int64 ID = 2;
}

message LeaseGrantResponse {
    ResponseHeader header = 1;
    // ID is the lease ID for the granted lease.
    int64 ID = 2;
    // TTL is the server chosen lease time-to-live in seconds.
    int64 TTL = 3;
    string error = 4;
}

message LeaseRevokeRequest {
    // ID is the lease ID to revoke. When the ID is revoked, all associated keys will be deleted.
    int64 ID = 1;
}

message LeaseRevokeResponse {
    ResponseHeader header = 1;
}

message LeaseKeepAliveRequest {
    // ID is the lease ID for the lease to keep alive.
    int64 ID = 1;
}

message LeaseKeepAliveResponse {
    ResponseHeader header = 1;
    // ID is the lease ID from the keep alive request.
    int64 ID = 2;
    // TTL is the new time-to-live for the lease.
    int64 TTL = 3;
}

message LeaseTimeToLiveRequest {
    // ID is the lease ID for the lease.
    int64 ID = 1;
    // keys is true to query all the keys attached to this lease.
    bool keys = 2;
}

message LeaseTimeToLiveResponse {
    ResponseHeader header = 1;
    // ID is the lease ID from the keep alive request.
    int64 ID = 2;
    // TTL is the remaining TTL in seconds for the lease; the lease will expire in under TTL+1 seconds.
    int64 TTL = 3;
    // GrantedTTL is the initial granted time in seconds upon lease creation/renewal.
    int64 grantedTTL = 4;
    // Keys is the list of keys attached to this lease.
    repeated bytes keys = 5;
}

message Member {
    // ID is the member ID for this member.
    uint64 ID = 1;
    // name is the human-readable name of the member. If the member is not started, the name will be an empty string.
    string name = 2;
    // peerURLs is the list of URLs the member exposes to the cluster for communication.
    repeated string peerURLs = 3;
    // clientURLs is the list of URLs the member exposes to clients for communication. If the member is not started, clientURLs will be empty.
    repeated string clientURLs = 4;
}

message MemberAddRequest {
    // peerURLs is the list of URLs the added member will use to communicate with the cluster.
    repeated string peerURLs = 1;
}

message MemberAddResponse {
    ResponseHeader header = 1;
    // member is the member information for the added member.
    Member member = 2;
    // members is a list of all members after adding the new member.
    repeated Member members = 3;
}

message MemberRemoveRequest {
    // ID is the member ID of the member to remove.
    uint64 ID = 1;
}

message MemberRemoveResponse {
    ResponseHeader header = 1;
    // members is a list of all members after removing the member.
    repeated Member members = 2;
}

message MemberUpdateRequest {
    // ID is the member ID of the member to update.
    uint64 ID = 1;
    // peerURLs is the new list of URLs the member will use to communicate with the cluster.
    repeated string peerURLs = 2;
}

message MemberUpdateResponse {
    ResponseHeader header = 1;
    // members is a list of all members after updating the member.
    repeated Member members = 2;
}

message MemberListRequest {
}

message MemberListResponse {
    ResponseHeader header = 1;
    // members is a list of all members associated with the cluster.
    repeated Member members = 2;
}

message DefragmentRequest {
}

message DefragmentResponse {
    ResponseHeader header = 1;
}

enum AlarmType {
    NONE = 0; // default, used to query if any alarm is active
    NOSPACE = 1; // space quota is exhausted
}

message AlarmRequest {
    enum AlarmAction {
        GET = 0;
        ACTIVATE = 1;
        DEACTIVATE = 2;
    }
    // action is the kind of alarm request to issue. The action
    // may GET alarm statuses, ACTIVATE an alarm, or DEACTIVATE a
    // raised alarm.
    AlarmAction action = 1;
    // memberID is the ID of the member associated with the alarm. If memberID is 0, the
    // alarm request covers all members.
    uint64 memberID = 2;
    // alarm is the type of alarm to consider for this request.
    AlarmType alarm = 3;
}

message AlarmMember {
    // memberID is the ID of the member associated with the raised alarm.
    uint64 memberID = 1;
    // alarm is the type of alarm which has been raised.
    AlarmType alarm = 2;
}

message AlarmResponse {
    ResponseHeader header = 1;
    // alarms is a list of alarms associated with the alarm request.
    repeated AlarmMember alarms = 2;
}

message StatusRequest {
}

message StatusResponse {
    ResponseHeader header = 1;
    // version is the cluster protocol version used by the responding member.
    string version = 2;
    // dbSize is the size of the backend database, in bytes, of the responding member.
    int64 dbSize = 3;
    // leader is the member ID which the responding member believes is the current leader.
    uint64 leader = 4;
    // raftIndex is the current raft index of the responding member.
    uint64 raftIndex = 5;
    // raftTerm is the current raft term of the responding member.
    uint64 raftTerm = 6;
}

message AuthEnableRequest {
}

message AuthDisableRequest {
}

message AuthenticateRequest {
    string name = 1;
    string password = 2;
}

message AuthUserAddRequest {
    string name = 1;
    string password = 2;
}

message AuthUserGetRequest {
    string name = 1;
}

message AuthUserDeleteRequest {
    // name is the name of the user to delete.
    string name = 1;
}

message AuthUserChangePasswordRequest {
    // name is the name of the user whose password is being changed.
    string name = 1;
    // password is the new password for the user.
    string password = 2;
}

message AuthUserGrantRoleRequest {
    // user is the name of the user which should be granted a given role.
    string user = 1;
    // role is the name of the role to grant to the user.
    string role = 2;
}

message AuthUserRevokeRoleRequest {
    string name = 1;
    string role = 2;
}

message AuthRoleAddRequest {
    // name is the name of the role to add to the authentication system.
    string name = 1;
}

message AuthRoleGetRequest {
    string role = 1;
}

message AuthUserListRequest {
}

message AuthRoleListRequest {
}

message AuthRoleDeleteRequest {
    string role = 1;
}

message AuthRoleGrantPermissionRequest {
    // name is the name of the role which will be granted the permission.
    string name = 1;
    // perm is the permission to grant to the role.
    authpb.Permission perm = 2;
}

message AuthRoleRevokePermissionRequest {
    string role = 1;
    string key = 2;
    string range_end = 3;
}

message AuthEnableResponse {
    ResponseHeader header = 1;
}

message AuthDisableResponse {
    ResponseHeader header = 1;
}

message AuthenticateResponse {
    ResponseHeader header = 1;
    // token is an authorized token that can be used in succeeding RPCs
    string token = 2;
}

message AuthUserAddResponse {
    ResponseHeader header = 1;
}

message AuthUserGetResponse {
    ResponseHeader header = 1;

    repeated string roles = 2;
}

message AuthUserDeleteResponse {
    ResponseHeader header = 1;
}

message AuthUserChangePasswordResponse {
    ResponseHeader header = 1;
}

message AuthUserGrantRoleResponse {
    ResponseHeader header = 1;
}

message AuthUserRevokeRoleResponse {
    ResponseHeader header = 1;
}

message AuthRoleAddResponse {
    ResponseHeader header = 1;
}

message AuthRoleGetResponse {
    ResponseHeader header = 1;

    repeated authpb.Permission perm = 2;
}

message AuthRoleListResponse {
    ResponseHeader header = 1;

    repeated string roles = 2;
}

message AuthUserListResponse {
    ResponseHeader header = 1;

    repeated string users = 2;
}

message AuthRoleDeleteResponse {
    ResponseHeader header = 1;
}

message AuthRoleGrantPermissionResponse {
    ResponseHeader header = 1;
}

message AuthRoleRevokePermissionResponse {
    ResponseHeader header = 1;
}




© 2015 - 2024 Weber Informatics LLC | Privacy Policy