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consul/proto/private/pbpeering/peering.proto

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// Copyright (c) HashiCorp, Inc.
[COMPLIANCE] License changes (#18443) * Adding explicit MPL license for sub-package This directory and its subdirectories (packages) contain files licensed with the MPLv2 `LICENSE` file in this directory and are intentionally licensed separately from the BSL `LICENSE` file at the root of this repository. * Adding explicit MPL license for sub-package This directory and its subdirectories (packages) contain files licensed with the MPLv2 `LICENSE` file in this directory and are intentionally licensed separately from the BSL `LICENSE` file at the root of this repository. * Updating the license from MPL to Business Source License Going forward, this project will be licensed under the Business Source License v1.1. Please see our blog post for more details at <Blog URL>, FAQ at www.hashicorp.com/licensing-faq, and details of the license at www.hashicorp.com/bsl. * add missing license headers * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 * Update copyright file headers to BUSL-1.1 --------- Co-authored-by: hashicorp-copywrite[bot] <110428419+hashicorp-copywrite[bot]@users.noreply.github.com>
1 year ago
// SPDX-License-Identifier: BUSL-1.1
syntax = "proto3";
package hashicorp.consul.internal.peering;
Protobuf Refactoring for Multi-Module Cleanliness (#16302) Protobuf Refactoring for Multi-Module Cleanliness This commit includes the following: Moves all packages that were within proto/ to proto/private Rewrites imports to account for the packages being moved Adds in buf.work.yaml to enable buf workspaces Names the proto-public buf module so that we can override the Go package imports within proto/buf.yaml Bumps the buf version dependency to 1.14.0 (I was trying out the version to see if it would get around an issue - it didn't but it also doesn't break things and it seemed best to keep up with the toolchain changes) Why: In the future we will need to consume other protobuf dependencies such as the Google HTTP annotations for openapi generation or grpc-gateway usage. There were some recent changes to have our own ratelimiting annotations. The two combined were not working when I was trying to use them together (attempting to rebase another branch) Buf workspaces should be the solution to the problem Buf workspaces means that each module will have generated Go code that embeds proto file names relative to the proto dir and not the top level repo root. This resulted in proto file name conflicts in the Go global protobuf type registry. The solution to that was to add in a private/ directory into the path within the proto/ directory. That then required rewriting all the imports. Is this safe? AFAICT yes The gRPC wire protocol doesn't seem to care about the proto file names (although the Go grpc code does tack on the proto file name as Metadata in the ServiceDesc) Other than imports, there were no changes to any generated code as a result of this.
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import "annotations/ratelimit/ratelimit.proto";
import "google/protobuf/timestamp.proto";
import "private/pbcommon/common.proto";
// PeeringService handles operations for establishing peering relationships
// between disparate Consul clusters.
service PeeringService {
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rpc GenerateToken(GenerateTokenRequest) returns (GenerateTokenResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_WRITE,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
rpc Establish(EstablishRequest) returns (EstablishResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_WRITE,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
rpc PeeringRead(PeeringReadRequest) returns (PeeringReadResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_READ,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
rpc PeeringList(PeeringListRequest) returns (PeeringListResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_READ,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
rpc PeeringDelete(PeeringDeleteRequest) returns (PeeringDeleteResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_WRITE,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
// TODO(peering): As of writing, this method is only used in tests to set up Peerings in the state store.
// Consider removing if we can find another way to populate state store in peering_endpoint_test.go
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rpc PeeringWrite(PeeringWriteRequest) returns (PeeringWriteResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_WRITE,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
// TODO(peering): Rename this to PeeredServiceRoots? or something like that?
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rpc TrustBundleListByService(TrustBundleListByServiceRequest) returns (TrustBundleListByServiceResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_READ,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
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rpc TrustBundleRead(TrustBundleReadRequest) returns (TrustBundleReadResponse) {
option (hashicorp.consul.internal.ratelimit.spec) = {
operation_type: OPERATION_TYPE_READ,
operation_category: OPERATION_CATEGORY_PEERING
};
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}
}
// PeeringState enumerates all the states a peering can be in.
enum PeeringState {
// Undefined represents an unset value for PeeringState during
// writes.
UNDEFINED = 0;
// Pending means the peering was created by generating a peering token.
// Peerings stay in a pending state until the peer uses the token to dial
// the local cluster.
PENDING = 1;
// Establishing means the peering is being established from a peering token.
// This is the initial state for dialing peers.
ESTABLISHING = 2;
// Active means that the peering connection is active and healthy.
ACTIVE = 3;
// Failing means the peering connection has been interrupted but has not yet
// been terminated.
FAILING = 4;
// Deleting means a peering was marked for deletion and is in the process
// of being deleted.
DELETING = 5;
// Terminated means the peering relationship has been removed.
TERMINATED = 6;
}
// SecretsWriteRequest encodes a request to write a peering secret as the result
// of some operation. Different operations, such as generating a peering token,
// lead to modifying the known secrets associated with a peering.
message SecretsWriteRequest {
// PeerID is the local UUID of the peering this request applies to.
string PeerID = 1;
oneof Request {
GenerateTokenRequest generate_token = 2;
ExchangeSecretRequest exchange_secret = 3;
PromotePendingRequest promote_pending = 4;
EstablishRequest establish = 5;
}
// GenerateTokenRequest encodes a request to persist a peering establishment
// secret. It is triggered by generating a new peering token for a peer cluster.
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message GenerateTokenRequest {
// establishment_secret is the proposed secret ID to store as the establishment
// secret for this peering.
string establishment_secret = 1;
}
// ExchangeSecretRequest encodes a request to persist a pending stream secret
// secret. It is triggered by an acceptor peer generating a long-lived stream secret
// in exchange for an establishment secret.
message ExchangeSecretRequest {
// establishment_secret is the secret to exchange for the given pending stream secret.
string establishment_secret = 1;
// pending_stream_secret is the proposed secret ID to store as the pending stream
// secret for this peering.
string pending_stream_secret = 2;
}
// PromotePendingRequest encodes a request to promote a pending stream secret
// to be an active stream secret. It is triggered when the accepting stream handler
// validates an Open request from a peer with a pending stream secret.
message PromotePendingRequest {
// active_stream_secret is the proposed secret ID to store as the active stream
// secret for this peering.
string active_stream_secret = 1;
}
// EstablishRequest encodes a request to persist an active stream secret.
// It is triggered after a dialing peer exchanges their establishment secret
// for a long-lived active stream secret.
message EstablishRequest {
// active_stream_secret is the proposed secret ID to store as the active stream
// secret for this peering.
string active_stream_secret = 1;
}
}
// PeeringSecrets defines a secret used for authenticating/authorizing peer clusters.
message PeeringSecrets {
// PeerID is the local UUID of the peering this secret was generated for.
string PeerID = 1;
message Establishment {
// SecretID is the one-time-use peering establishment secret.
string SecretID = 1;
}
message Stream {
// ActiveSecretID is the active UUID-v4 secret being used for authorization at
// the peering stream.
string ActiveSecretID = 1;
// PendingSecretID is a UUID-v4 secret introduced during secret rotation.
// When a peering is established or re-established, both the active secret and
// pending secret are considered valid. However, once the dialing peer uses
// the pending secret then it transitions to active and the previously active
// secret is discarded.
//
// Pending secret IDs are only valid for long-lived stream secrets.
// Only one establishment secret can exist for a peer at a time since they
// are designed for one-time use.
string PendingSecretID = 2;
}
Establishment establishment = 2;
Stream stream = 3;
}
// Peering defines a peering relationship between two disparate Consul clusters
//
// mog annotation:
//
// target=github.com/hashicorp/consul/api.Peering
// output=peering.gen.go
// name=API
message Peering {
// ID is a datacenter-scoped UUID for the peering.
// The ID is generated when a peering is first written to the state store.
string ID = 1;
// Name is the local alias for the peering relationship.
string Name = 2;
// Partition is the local partition connecting to the peer.
string Partition = 3;
// DeletedAt is the time when the Peering was marked for deletion
// This is nullable so that we can omit if empty when encoding in JSON
// mog: func-to=TimePtrFromProto func-from=TimePtrToProto
google.protobuf.Timestamp DeletedAt = 4;
// Meta is a mapping of some string value to any other string value
map<string, string> Meta = 5;
// State is one of the valid PeeringState values to represent the status of
// peering relationship.
//
// mog: func-to=PeeringStateToAPI func-from=PeeringStateFromAPI
PeeringState State = 6;
// PeerID is the ID that our peer assigned to this peering.
// This ID is to be used when dialing the peer, so that it can know who dialed it.
string PeerID = 7;
// PeerCAPems contains all the CA certificates for the remote peer.
repeated string PeerCAPems = 8;
// PeerServerName is the name of the remote server as it relates to TLS.
string PeerServerName = 9;
// PeerServerAddresses contains all the connection addresses for the remote peer.
repeated string PeerServerAddresses = 10;
// StreamStatus contains information computed on read based on the state of the stream.
//
// mog: func-to=StreamStatusToAPI func-from=StreamStatusFromAPI
StreamStatus StreamStatus = 13;
// CreateIndex is the Raft index at which the Peering was created.
// @gotags: bexpr:"-"
uint64 CreateIndex = 11;
// ModifyIndex is the latest Raft index at which the Peering. was modified.
// @gotags: bexpr:"-"
uint64 ModifyIndex = 12;
// Remote contains metadata about the remote peer.
RemoteInfo Remote = 17;
// ManualServerAddresses provides a list of manually specified server addresses from the
// user. If this is defined, then the automatic PeerServerAddresses are ignored.
repeated string ManualServerAddresses = 18;
}
// RemoteInfo contains metadata about the remote peer.
// mog annotation:
//
// target=github.com/hashicorp/consul/api.PeeringRemoteInfo
// output=peering.gen.go
// name=API
message RemoteInfo {
// Partition is the remote peer's partition.
string Partition = 1;
// Datacenter is the remote peer's datacenter.
string Datacenter = 2;
// Locality identifies where the peer is running.
// mog: func-to=LocalityToAPI func-from=LocalityFromAPI
common.Locality Locality = 3;
}
// StreamStatus represents information about an active peering stream.
message StreamStatus {
// ImportedServices is the list of services imported from this peering.
repeated string ImportedServices = 1;
// ExportedServices is the list of services exported to this peering.
repeated string ExportedServices = 2;
// LastHeartbeat represents when the last heartbeat message was received.
google.protobuf.Timestamp LastHeartbeat = 3;
// LastReceive represents when any message was last received, regardless of success or error.
google.protobuf.Timestamp LastReceive = 4;
// LastSend represents when any message was last sent, regardless of success or error.
google.protobuf.Timestamp LastSend = 5;
}
// PeeringTrustBundle holds the trust information for validating requests from a peer.
message PeeringTrustBundle {
// TrustDomain is the domain for the bundle, example.com, foo.bar.gov for example. Note that this must not have a prefix such as "spiffe://".
string TrustDomain = 1;
// PeerName associates the trust bundle with a peer.
string PeerName = 2;
// Partition isolates the bundle from other trust bundles in separate local partitions.
string Partition = 3;
// RootPEMs holds ASN.1 DER encoded X.509 certificate data for the trust bundle.
repeated string RootPEMs = 4;
// ExportedPartition references the remote partition of the peer
// which sent this trust bundle. Used for generating SpiffeIDs.
string ExportedPartition = 5;
// CreateIndex is the Raft index at which the trust domain was created.
// @gotags: bexpr:"-"
uint64 CreateIndex = 6;
// ModifyIndex is the latest Raft index at which the trust bundle was modified.
// @gotags: bexpr:"-"
uint64 ModifyIndex = 7;
}
// PeeringServerAddresses contains the latest snapshot of all known
// server addresses for a peer.
message PeeringServerAddresses {
repeated string Addresses = 1;
}
message PeeringReadRequest {
string Name = 1;
string Partition = 2;
}
message PeeringReadResponse {
Peering Peering = 1;
}
message PeeringListRequest {
string Partition = 1;
}
message PeeringListResponse {
repeated Peering Peerings = 1;
uint64 OBSOLETE_Index = 2; // Deprecated in favor of gRPC metadata
}
message PeeringWriteRequest {
// Peering is the peering to write with the request.
Peering Peering = 1;
// SecretsWriteRequest contains the optional peering secrets to persist
// with the peering. Peering secrets are not embedded in the peering
// object to avoid leaking them.
SecretsWriteRequest SecretsRequest = 2;
map<string, string> Meta = 3;
}
// TODO(peering): Consider returning Peering if we keep this endpoint around
message PeeringWriteResponse {}
message PeeringDeleteRequest {
string Name = 1;
string Partition = 2;
}
message PeeringDeleteResponse {}
message TrustBundleListByServiceRequest {
string ServiceName = 1;
string Namespace = 2;
string Partition = 3;
string Kind = 4;
}
message TrustBundleListByServiceResponse {
uint64 OBSOLETE_Index = 1; // Deprecated in favor of gRPC metadata
repeated PeeringTrustBundle Bundles = 2;
}
message TrustBundleReadRequest {
string Name = 1;
string Partition = 2;
}
message TrustBundleReadResponse {
uint64 OBSOLETE_Index = 1; // Deprecated in favor of gRPC metadata
PeeringTrustBundle Bundle = 2;
}
// This is a purely internal type and does not require query metadata.
message PeeringTerminateByIDRequest {
string ID = 1;
}
message PeeringTerminateByIDResponse {}
message PeeringTrustBundleWriteRequest {
PeeringTrustBundle PeeringTrustBundle = 1;
}
message PeeringTrustBundleWriteResponse {}
message PeeringTrustBundleDeleteRequest {
string Name = 1;
string Partition = 2;
}
message PeeringTrustBundleDeleteResponse {}
// mog annotation:
//
// target=github.com/hashicorp/consul/api.PeeringGenerateTokenRequest
// output=peering.gen.go
// name=API
message GenerateTokenRequest {
// Name of the remote peer.
string PeerName = 1;
// Partition is the local partition being peered.
string Partition = 2;
// Meta is a mapping of some string value to any other string value
map<string, string> Meta = 5;
// ServerExternalAddresses is a list of addresses to put into the generated token. This could be used to specify
// load balancer(s) or external IPs to reach the servers from the dialing side, and will override any server
// addresses obtained from the "consul" service.
repeated string ServerExternalAddresses = 6;
}
// mog annotation:
//
// target=github.com/hashicorp/consul/api.PeeringGenerateTokenResponse
// output=peering.gen.go
// name=API
message GenerateTokenResponse {
// PeeringToken is an opaque string provided to the remote peer for it to complete
// the peering initialization handshake.
string PeeringToken = 1;
}
// mog annotation:
//
// target=github.com/hashicorp/consul/api.PeeringEstablishRequest
// output=peering.gen.go
// name=API
message EstablishRequest {
// Name of the remote peer.
string PeerName = 1;
// The peering token returned from the peer's GenerateToken endpoint.
string PeeringToken = 2;
// Partition is the local partition being peered.
string Partition = 3;
// Meta is a mapping of some string value to any other string value
map<string, string> Meta = 4;
}
// mog annotation:
//
// target=github.com/hashicorp/consul/api.PeeringEstablishResponse
// output=peering.gen.go
// name=API
message EstablishResponse {}