lnd.xprv/lnrpc/routerrpc/router.proto

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syntax = "proto3";
import "rpc.proto";
package routerrpc;
option go_package = "github.com/lightningnetwork/lnd/lnrpc/routerrpc";
message SendPaymentRequest {
/// The identity pubkey of the payment recipient
bytes dest = 1;
/// Number of satoshis to send.
int64 amt = 2;
/// The hash to use within the payment's HTLC
bytes payment_hash = 3;
/**
The CLTV delta from the current height that should be used to set the
timelock for the final hop.
*/
int32 final_cltv_delta = 4;
/**
A bare-bones invoice for a payment within the Lightning Network. With the
details of the invoice, the sender has all the data necessary to send a
payment to the recipient. The amount in the payment request may be zero. In
that case it is required to set the amt field as well. If no payment request
is specified, the following fields are required: dest, amt and payment_hash.
*/
string payment_request = 5;
/**
An upper limit on the amount of time we should spend when attempting to
fulfill the payment. This is expressed in seconds. If we cannot make a
successful payment within this time frame, an error will be returned.
This field must be non-zero.
*/
int32 timeout_seconds = 6;
/**
The maximum number of satoshis that will be paid as a fee of the payment.
If this field is left to the default value of 0, only zero-fee routes will
be considered. This usually means single hop routes connecting directly to
the destination. To send the payment without a fee limit, use max int here.
*/
int64 fee_limit_sat = 7;
/**
The channel id of the channel that must be taken to the first hop. If zero,
any channel may be used.
*/
uint64 outgoing_chan_id = 8;
/**
An optional maximum total time lock for the route. If zero, there is no
maximum enforced.
*/
int32 cltv_limit = 9;
/**
Optional route hints to reach the destination through private channels.
*/
repeated lnrpc.RouteHint route_hints = 10 [json_name = "route_hints"];
}
message TrackPaymentRequest {
/// The hash of the payment to look up.
bytes payment_hash = 1;
}
enum PaymentState {
/**
Payment is still in flight.
*/
IN_FLIGHT = 0;
/**
Payment completed successfully.
*/
SUCCEEDED = 1;
/**
There are more routes to try, but the payment timeout was exceeded.
*/
FAILED_TIMEOUT = 2;
/**
All possible routes were tried and failed permanently. Or were no
routes to the destination at all.
*/
FAILED_NO_ROUTE = 3;
/**
A non-recoverable error has occured.
*/
FAILED_ERROR = 4;
/**
Payment details incorrect (unknown hash, invalid amt or
invalid final cltv delta)
*/
FAILED_INCORRECT_PAYMENT_DETAILS = 5;
}
message PaymentStatus {
/// Current state the payment is in.
PaymentState state = 1;
/**
The pre-image of the payment when state is SUCCEEDED.
*/
bytes preimage = 2;
/**
The taken route when state is SUCCEEDED.
*/
lnrpc.Route route = 3;
}
message RouteFeeRequest {
/**
The destination once wishes to obtain a routing fee quote to.
*/
bytes dest = 1;
/**
The amount one wishes to send to the target destination.
*/
int64 amt_sat = 2;
}
message RouteFeeResponse {
/**
A lower bound of the estimated fee to the target destination within the
network, expressed in milli-satoshis.
*/
int64 routing_fee_msat = 1;
/**
An estimate of the worst case time delay that can occur. Note that callers
will still need to factor in the final CLTV delta of the last hop into this
value.
*/
int64 time_lock_delay = 2;
}
message SendToRouteRequest {
/// The payment hash to use for the HTLC.
bytes payment_hash = 1;
/// Route that should be used to attempt to complete the payment.
lnrpc.Route route = 2;
}
message SendToRouteResponse {
/// The preimage obtained by making the payment.
bytes preimage = 1;
/// The failure message in case the payment failed.
Failure failure = 2;
}
message Failure {
enum FailureCode {
/**
The numbers assigned in this enumeration match the failure codes as
defined in BOLT #4. Because protobuf 3 requires enums to start with 0,
a RESERVED value is added.
*/
RESERVED = 0;
INCORRECT_OR_UNKNOWN_PAYMENT_DETAILS = 1;
INCORRECT_PAYMENT_AMOUNT = 2;
FINAL_INCORRECT_CLTV_EXPIRY = 3;
FINAL_INCORRECT_HTLC_AMOUNT = 4;
FINAL_EXPIRY_TOO_SOON = 5;
INVALID_REALM = 6;
EXPIRY_TOO_SOON = 7;
INVALID_ONION_VERSION = 8;
INVALID_ONION_HMAC = 9;
INVALID_ONION_KEY = 10;
AMOUNT_BELOW_MINIMUM = 11;
FEE_INSUFFICIENT = 12;
INCORRECT_CLTV_EXPIRY = 13;
CHANNEL_DISABLED = 14;
TEMPORARY_CHANNEL_FAILURE = 15;
REQUIRED_NODE_FEATURE_MISSING = 16;
REQUIRED_CHANNEL_FEATURE_MISSING = 17;
UNKNOWN_NEXT_PEER = 18;
TEMPORARY_NODE_FAILURE = 19;
PERMANENT_NODE_FAILURE = 20;
PERMANENT_CHANNEL_FAILURE = 21;
/**
The error source is known, but the failure itself couldn't be decoded.
*/
UNKNOWN_FAILURE = 998;
/**
An unreadable failure result is returned if the received failure message
cannot be decrypted. In that case the error source is unknown.
*/
UNREADABLE_FAILURE = 999;
}
/// Failure code as defined in the Lightning spec
FailureCode code = 1;
reserved 2;
/// An optional channel update message.
ChannelUpdate channel_update = 3;
/// A failure type-dependent htlc value.
uint64 htlc_msat = 4;
/// The sha256 sum of the onion payload.
bytes onion_sha_256 = 5;
/// A failure type-dependent cltv expiry value.
uint32 cltv_expiry = 6;
/// A failure type-dependent flags value.
uint32 flags = 7;
/**
The position in the path of the intermediate or final node that generated
the failure message. Position zero is the sender node.
**/
uint32 failure_source_index = 8;
}
message ChannelUpdate {
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/**
The signature that validates the announced data and proves the ownership
of node id.
*/
bytes signature = 1;
/**
The target chain that this channel was opened within. This value
should be the genesis hash of the target chain. Along with the short
channel ID, this uniquely identifies the channel globally in a
blockchain.
*/
bytes chain_hash = 2;
/**
The unique description of the funding transaction.
*/
uint64 chan_id = 3;
/**
A timestamp that allows ordering in the case of multiple announcements.
We should ignore the message if timestamp is not greater than the
last-received.
*/
uint32 timestamp = 4;
/**
The bitfield that describes whether optional fields are present in this
update. Currently, the least-significant bit must be set to 1 if the
optional field MaxHtlc is present.
*/
uint32 message_flags = 10;
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/**
The bitfield that describes additional meta-data concerning how the
update is to be interpreted. Currently, the least-significant bit must be
set to 0 if the creating node corresponds to the first node in the
previously sent channel announcement and 1 otherwise. If the second bit
is set, then the channel is set to be disabled.
*/
uint32 channel_flags = 5;
/**
The minimum number of blocks this node requires to be added to the expiry
of HTLCs. This is a security parameter determined by the node operator.
This value represents the required gap between the time locks of the
incoming and outgoing HTLC's set to this node.
*/
uint32 time_lock_delta = 6;
/**
The minimum HTLC value which will be accepted.
*/
uint64 htlc_minimum_msat = 7;
/**
The base fee that must be used for incoming HTLC's to this particular
channel. This value will be tacked onto the required for a payment
independent of the size of the payment.
*/
uint32 base_fee = 8;
/**
The fee rate that will be charged per millionth of a satoshi.
*/
uint32 fee_rate = 9;
/**
The maximum HTLC value which will be accepted.
*/
uint64 htlc_maximum_msat = 11;
/**
The set of data that was appended to this message, some of which we may
not actually know how to iterate or parse. By holding onto this data, we
ensure that we're able to properly validate the set of signatures that
cover these new fields, and ensure we're able to make upgrades to the
network in a forwards compatible manner.
*/
bytes extra_opaque_data = 12;
}
message ResetMissionControlRequest{}
message ResetMissionControlResponse{}
message QueryMissionControlRequest {}
/// QueryMissionControlResponse contains mission control state.
message QueryMissionControlResponse {
/// Node-level mission control state.
repeated NodeHistory nodes = 1;
/// Node pair-level mission control state.
repeated PairHistory pairs = 2;
}
/// NodeHistory contains the mission control state for a particular node.
message NodeHistory {
/// Node pubkey
bytes pubkey = 1 [json_name = "pubkey"];
/// Time stamp of last failure. Set to zero if no failure happened yet.
int64 last_fail_time = 2 [json_name = "last_fail_time"];
/**
Estimation of success probability of forwarding towards peers of this node
for which no specific history is available.
**/
float other_success_prob = 3 [json_name = "other_success_prob"];
reserved 4;
}
/// PairHistory contains the mission control state for a particular node pair.
message PairHistory {
/// The source node pubkey of the pair.
bytes node_from = 1 [json_name="node_from"];
/// The destination node pubkey of the pair.
bytes node_to = 2 [json_name="node_to"];
/// Time stamp of last failure.
int64 last_fail_time = 3 [json_name = "last_fail_time"];
/// Minimum penalization amount.
int64 min_penalize_amt_sat = 4 [json_name = "min_penalize_amt_sat"];
/// Estimation of success probability for this pair.
float success_prob = 5 [json_name = "success_prob"];
}
service Router {
/**
SendPayment attempts to route a payment described by the passed
PaymentRequest to the final destination. The call returns a stream of
payment status updates.
*/
rpc SendPayment(SendPaymentRequest) returns (stream PaymentStatus);
/**
TrackPayment returns an update stream for the payment identified by the
payment hash.
*/
rpc TrackPayment(TrackPaymentRequest) returns (stream PaymentStatus);
/**
EstimateRouteFee allows callers to obtain a lower bound w.r.t how much it
may cost to send an HTLC to the target end destination.
*/
rpc EstimateRouteFee(RouteFeeRequest) returns (RouteFeeResponse);
/**
SendToRoute attempts to make a payment via the specified route. This method
differs from SendPayment in that it allows users to specify a full route
manually. This can be used for things like rebalancing, and atomic swaps.
*/
rpc SendToRoute(SendToRouteRequest) returns (SendToRouteResponse);
/**
ResetMissionControl clears all mission control state and starts with a clean
slate.
*/
rpc ResetMissionControl(ResetMissionControlRequest) returns (ResetMissionControlResponse);
/**
QueryMissionControl exposes the internal mission control state to callers.
It is a development feature.
*/
rpc QueryMissionControl(QueryMissionControlRequest) returns (QueryMissionControlResponse);
}