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package org.ldk.structs;
import org.ldk.impl.bindings;
import org.ldk.enums.*;
import org.ldk.util.*;
import java.util.Arrays;
import java.lang.ref.Reference;
import javax.annotation.Nullable;
public class UtilMethods {
/**
* Gets the 128-bit integer, as 16 little-endian bytes
*/
public static byte[] U128_le_bytes(org.ldk.util.UInt128 val) {
byte[] ret = bindings.U128_le_bytes(val.getLEBytes());
Reference.reachabilityFence(val);
return ret;
}
/**
* Constructs a new U128 from 16 little-endian bytes
*/
public static UInt128 U128_new(byte[] le_bytes) {
byte[] ret = bindings.U128_new(InternalUtils.check_arr_len(le_bytes, 16));
Reference.reachabilityFence(le_bytes);
org.ldk.util.UInt128 ret_conv = new org.ldk.util.UInt128(ret);
return ret_conv;
}
/**
* Constructs a new COption_NoneZ containing a
*/
public static COption_NoneZ COption_NoneZ_some() {
COption_NoneZ ret = bindings.COption_NoneZ_some();
return ret;
}
/**
* Constructs a new COption_NoneZ containing nothing
*/
public static COption_NoneZ COption_NoneZ_none() {
COption_NoneZ ret = bindings.COption_NoneZ_none();
return ret;
}
/**
* Read a APIError from a byte array, created by APIError_write
*/
public static Result_COption_APIErrorZDecodeErrorZ APIError_read(byte[] ser) {
long ret = bindings.APIError_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_APIErrorZDecodeErrorZ ret_hu_conv = Result_COption_APIErrorZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Creates a digital signature of a message given a SecretKey, like the node's secret.
* A receiver knowing the PublicKey (e.g. the node's id) and the message can be sure that the signature was generated by the caller.
* Signatures are EC recoverable, meaning that given the message and the signature the PublicKey of the signer can be extracted.
*/
public static Result_StrSecp256k1ErrorZ sign(byte[] msg, byte[] sk) {
long ret = bindings.sign(msg, InternalUtils.check_arr_len(sk, 32));
Reference.reachabilityFence(msg);
Reference.reachabilityFence(sk);
if (ret >= 0 && ret <= 4096) { return null; }
Result_StrSecp256k1ErrorZ ret_hu_conv = Result_StrSecp256k1ErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Recovers the PublicKey of the signer of the message given the message and the signature.
*/
public static Result_PublicKeySecp256k1ErrorZ recover_pk(byte[] msg, java.lang.String sig) {
long ret = bindings.recover_pk(msg, sig);
Reference.reachabilityFence(msg);
Reference.reachabilityFence(sig);
if (ret >= 0 && ret <= 4096) { return null; }
Result_PublicKeySecp256k1ErrorZ ret_hu_conv = Result_PublicKeySecp256k1ErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Verifies a message was signed by a PrivateKey that derives to a given PublicKey, given a message, a signature,
* and the PublicKey.
*/
public static boolean verify(byte[] msg, java.lang.String sig, byte[] pk) {
boolean ret = bindings.verify(msg, sig, InternalUtils.check_arr_len(pk, 33));
Reference.reachabilityFence(msg);
Reference.reachabilityFence(sig);
Reference.reachabilityFence(pk);
return ret;
}
/**
* Construct the invoice's HRP and signatureless data into a preimage to be hashed.
*/
public static byte[] construct_invoice_preimage(byte[] hrp_bytes, UInt5[] data_without_signature) {
byte[] ret = bindings.construct_invoice_preimage(hrp_bytes, data_without_signature != null ? InternalUtils.convUInt5Array(data_without_signature) : null);
Reference.reachabilityFence(hrp_bytes);
Reference.reachabilityFence(data_without_signature);
return ret;
}
/**
* Read previously persisted [`ChannelMonitor`]s from the store.
*/
public static Result_CVec_C2Tuple_ThirtyTwoBytesChannelMonitorZZIOErrorZ read_channel_monitors(org.ldk.structs.KVStore kv_store, org.ldk.structs.EntropySource entropy_source, org.ldk.structs.SignerProvider signer_provider) {
long ret = bindings.read_channel_monitors(kv_store.ptr, entropy_source.ptr, signer_provider.ptr);
Reference.reachabilityFence(kv_store);
Reference.reachabilityFence(entropy_source);
Reference.reachabilityFence(signer_provider);
if (ret >= 0 && ret <= 4096) { return null; }
Result_CVec_C2Tuple_ThirtyTwoBytesChannelMonitorZZIOErrorZ ret_hu_conv = Result_CVec_C2Tuple_ThirtyTwoBytesChannelMonitorZZIOErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(kv_store); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(signer_provider); };
return ret_hu_conv;
}
/**
* Read a MonitorEvent from a byte array, created by MonitorEvent_write
*/
public static Result_COption_MonitorEventZDecodeErrorZ MonitorEvent_read(byte[] ser) {
long ret = bindings.MonitorEvent_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_MonitorEventZDecodeErrorZ ret_hu_conv = Result_COption_MonitorEventZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Read a C2Tuple_ThirtyTwoBytesChannelMonitorZ from a byte array, created by C2Tuple_ThirtyTwoBytesChannelMonitorZ_write
*/
public static Result_C2Tuple_ThirtyTwoBytesChannelMonitorZDecodeErrorZ C2Tuple_ThirtyTwoBytesChannelMonitorZ_read(byte[] ser, org.ldk.structs.EntropySource arg_a, org.ldk.structs.SignerProvider arg_b) {
long ret = bindings.C2Tuple_ThirtyTwoBytesChannelMonitorZ_read(ser, arg_a.ptr, arg_b.ptr);
Reference.reachabilityFence(ser);
Reference.reachabilityFence(arg_a);
Reference.reachabilityFence(arg_b);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_ThirtyTwoBytesChannelMonitorZDecodeErrorZ ret_hu_conv = Result_C2Tuple_ThirtyTwoBytesChannelMonitorZDecodeErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_a); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_b); };
return ret_hu_conv;
}
/**
* Fetches the set of [`InitFeatures`] flags that are provided by or required by
* [`ChannelManager`].
*/
public static InitFeatures provided_init_features(org.ldk.structs.UserConfig config) {
long ret = bindings.provided_init_features(config == null ? 0 : config.ptr);
Reference.reachabilityFence(config);
if (ret >= 0 && ret <= 4096) { return null; }
org.ldk.structs.InitFeatures ret_hu_conv = null; if (ret < 0 || ret > 4096) { ret_hu_conv = new org.ldk.structs.InitFeatures(null, ret); }
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(ret_hu_conv); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(config); };
return ret_hu_conv;
}
/**
* Read a C2Tuple_ThirtyTwoBytesChannelManagerZ from a byte array, created by C2Tuple_ThirtyTwoBytesChannelManagerZ_write
*/
public static Result_C2Tuple_ThirtyTwoBytesChannelManagerZDecodeErrorZ C2Tuple_ThirtyTwoBytesChannelManagerZ_read(byte[] ser, EntropySource arg_entropy_source, NodeSigner arg_node_signer, SignerProvider arg_signer_provider, FeeEstimator arg_fee_estimator, Watch arg_chain_monitor, BroadcasterInterface arg_tx_broadcaster, Router arg_router, Logger arg_logger, UserConfig arg_default_config, ChannelMonitor[] arg_channel_monitors) {
long ret = bindings.C2Tuple_ThirtyTwoBytesChannelManagerZ_read(ser, bindings.ChannelManagerReadArgs_new(arg_entropy_source.ptr, arg_node_signer.ptr, arg_signer_provider.ptr, arg_fee_estimator.ptr, arg_chain_monitor.ptr, arg_tx_broadcaster.ptr, arg_router.ptr, arg_logger.ptr, arg_default_config == null ? 0 : arg_default_config.ptr, arg_channel_monitors != null ? Arrays.stream(arg_channel_monitors).mapToLong(arg_channel_monitors_conv_16 -> arg_channel_monitors_conv_16 == null ? 0 : arg_channel_monitors_conv_16.ptr).toArray() : null));
Reference.reachabilityFence(ser);
Reference.reachabilityFence(arg_entropy_source);
Reference.reachabilityFence(arg_node_signer);
Reference.reachabilityFence(arg_signer_provider);
Reference.reachabilityFence(arg_fee_estimator);
Reference.reachabilityFence(arg_chain_monitor);
Reference.reachabilityFence(arg_tx_broadcaster);
Reference.reachabilityFence(arg_router);
Reference.reachabilityFence(arg_logger);
Reference.reachabilityFence(arg_default_config);
Reference.reachabilityFence(arg_channel_monitors);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_ThirtyTwoBytesChannelManagerZDecodeErrorZ ret_hu_conv = Result_C2Tuple_ThirtyTwoBytesChannelManagerZDecodeErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_signer_provider); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_fee_estimator); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_chain_monitor); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_tx_broadcaster); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_router); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_default_config); };
for (ChannelMonitor arg_channel_monitors_conv_16: arg_channel_monitors) { if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(arg_channel_monitors_conv_16); }; };
return ret_hu_conv;
}
/**
* Equivalent to [`crate::ln::channelmanager::ChannelManager::create_inbound_payment`], but no
* `ChannelManager` is required. Useful for generating invoices for [phantom node payments] without
* a `ChannelManager`.
*
* `keys` is generated by calling [`NodeSigner::get_inbound_payment_key_material`] and then
* calling [`ExpandedKey::new`] with its result. It is recommended to cache this value and not
* regenerate it for each new inbound payment.
*
* `current_time` is a Unix timestamp representing the current time.
*
* Note that if `min_final_cltv_expiry_delta` is set to some value, then the payment will not be receivable
* on versions of LDK prior to 0.0.114.
*
* [phantom node payments]: crate::sign::PhantomKeysManager
* [`NodeSigner::get_inbound_payment_key_material`]: crate::sign::NodeSigner::get_inbound_payment_key_material
*/
public static Result_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZNoneZ create(org.ldk.structs.ExpandedKey keys, org.ldk.structs.Option_u64Z min_value_msat, int invoice_expiry_delta_secs, org.ldk.structs.EntropySource entropy_source, long current_time, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create(keys == null ? 0 : keys.ptr, min_value_msat.ptr, invoice_expiry_delta_secs, entropy_source.ptr, current_time, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(keys);
Reference.reachabilityFence(min_value_msat);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(entropy_source);
Reference.reachabilityFence(current_time);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZNoneZ ret_hu_conv = Result_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZNoneZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(keys); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_value_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* Equivalent to [`crate::ln::channelmanager::ChannelManager::create_inbound_payment_for_hash`],
* but no `ChannelManager` is required. Useful for generating invoices for [phantom node payments]
* without a `ChannelManager`.
*
* See [`create`] for information on the `keys` and `current_time` parameters.
*
* Note that if `min_final_cltv_expiry_delta` is set to some value, then the payment will not be receivable
* on versions of LDK prior to 0.0.114.
*
* [phantom node payments]: crate::sign::PhantomKeysManager
*/
public static Result_ThirtyTwoBytesNoneZ create_from_hash(org.ldk.structs.ExpandedKey keys, org.ldk.structs.Option_u64Z min_value_msat, byte[] payment_hash, int invoice_expiry_delta_secs, long current_time, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_from_hash(keys == null ? 0 : keys.ptr, min_value_msat.ptr, InternalUtils.check_arr_len(payment_hash, 32), invoice_expiry_delta_secs, current_time, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(keys);
Reference.reachabilityFence(min_value_msat);
Reference.reachabilityFence(payment_hash);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(current_time);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_ThirtyTwoBytesNoneZ ret_hu_conv = Result_ThirtyTwoBytesNoneZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(keys); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_value_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* Parses an OnionV3 host and port into a [`SocketAddress::OnionV3`].
*
* The host part must end with \".onion\".
*/
public static Result_SocketAddressSocketAddressParseErrorZ parse_onion_address(java.lang.String host, short port) {
long ret = bindings.parse_onion_address(host, port);
Reference.reachabilityFence(host);
Reference.reachabilityFence(port);
if (ret >= 0 && ret <= 4096) { return null; }
Result_SocketAddressSocketAddressParseErrorZ ret_hu_conv = Result_SocketAddressSocketAddressParseErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Gets the weight for an HTLC-Success transaction.
*/
public static long htlc_success_tx_weight(org.ldk.structs.ChannelTypeFeatures channel_type_features) {
long ret = bindings.htlc_success_tx_weight(channel_type_features == null ? 0 : channel_type_features.ptr);
Reference.reachabilityFence(channel_type_features);
return ret;
}
/**
* Gets the weight for an HTLC-Timeout transaction.
*/
public static long htlc_timeout_tx_weight(org.ldk.structs.ChannelTypeFeatures channel_type_features) {
long ret = bindings.htlc_timeout_tx_weight(channel_type_features == null ? 0 : channel_type_features.ptr);
Reference.reachabilityFence(channel_type_features);
return ret;
}
/**
* Check if a given input witness attempts to claim a HTLC.
*/
public static Option_HTLCClaimZ HTLCClaim_from_witness(byte[] witness) {
long ret = bindings.HTLCClaim_from_witness(witness);
Reference.reachabilityFence(witness);
if (ret >= 0 && ret <= 4096) { return null; }
org.ldk.structs.Option_HTLCClaimZ ret_hu_conv = org.ldk.structs.Option_HTLCClaimZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(ret_hu_conv); };
return ret_hu_conv;
}
/**
* Build the commitment secret from the seed and the commitment number
*/
public static byte[] build_commitment_secret(byte[] commitment_seed, long idx) {
byte[] ret = bindings.build_commitment_secret(InternalUtils.check_arr_len(commitment_seed, 32), idx);
Reference.reachabilityFence(commitment_seed);
Reference.reachabilityFence(idx);
return ret;
}
/**
* Build a closing transaction
*/
public static byte[] build_closing_transaction(long to_holder_value_sat, long to_counterparty_value_sat, byte[] to_holder_script, byte[] to_counterparty_script, org.ldk.structs.OutPoint funding_outpoint) {
byte[] ret = bindings.build_closing_transaction(to_holder_value_sat, to_counterparty_value_sat, to_holder_script, to_counterparty_script, funding_outpoint == null ? 0 : funding_outpoint.ptr);
Reference.reachabilityFence(to_holder_value_sat);
Reference.reachabilityFence(to_counterparty_value_sat);
Reference.reachabilityFence(to_holder_script);
Reference.reachabilityFence(to_counterparty_script);
Reference.reachabilityFence(funding_outpoint);
return ret;
}
/**
* Derives a per-commitment-transaction private key (eg an htlc key or delayed_payment key)
* from the base secret and the per_commitment_point.
*/
public static byte[] derive_private_key(byte[] per_commitment_point, byte[] base_secret) {
byte[] ret = bindings.derive_private_key(InternalUtils.check_arr_len(per_commitment_point, 33), InternalUtils.check_arr_len(base_secret, 32));
Reference.reachabilityFence(per_commitment_point);
Reference.reachabilityFence(base_secret);
return ret;
}
/**
* Derives a per-commitment-transaction public key (eg an htlc key or a delayed_payment key)
* from the base point and the per_commitment_key. This is the public equivalent of
* derive_private_key - using only public keys to derive a public key instead of private keys.
*/
public static byte[] derive_public_key(byte[] per_commitment_point, byte[] base_point) {
byte[] ret = bindings.derive_public_key(InternalUtils.check_arr_len(per_commitment_point, 33), InternalUtils.check_arr_len(base_point, 33));
Reference.reachabilityFence(per_commitment_point);
Reference.reachabilityFence(base_point);
return ret;
}
/**
* Derives a per-commitment-transaction revocation key from its constituent parts.
*
* Only the cheating participant owns a valid witness to propagate a revoked
* commitment transaction, thus per_commitment_secret always come from cheater
* and revocation_base_secret always come from punisher, which is the broadcaster
* of the transaction spending with this key knowledge.
*/
public static byte[] derive_private_revocation_key(byte[] per_commitment_secret, byte[] countersignatory_revocation_base_secret) {
byte[] ret = bindings.derive_private_revocation_key(InternalUtils.check_arr_len(per_commitment_secret, 32), InternalUtils.check_arr_len(countersignatory_revocation_base_secret, 32));
Reference.reachabilityFence(per_commitment_secret);
Reference.reachabilityFence(countersignatory_revocation_base_secret);
return ret;
}
/**
* Derives a per-commitment-transaction revocation public key from its constituent parts. This is
* the public equivalend of derive_private_revocation_key - using only public keys to derive a
* public key instead of private keys.
*
* Only the cheating participant owns a valid witness to propagate a revoked
* commitment transaction, thus per_commitment_point always come from cheater
* and revocation_base_point always come from punisher, which is the broadcaster
* of the transaction spending with this key knowledge.
*
* Note that this is infallible iff we trust that at least one of the two input keys are randomly
* generated (ie our own).
*/
public static byte[] derive_public_revocation_key(byte[] per_commitment_point, byte[] countersignatory_revocation_base_point) {
byte[] ret = bindings.derive_public_revocation_key(InternalUtils.check_arr_len(per_commitment_point, 33), InternalUtils.check_arr_len(countersignatory_revocation_base_point, 33));
Reference.reachabilityFence(per_commitment_point);
Reference.reachabilityFence(countersignatory_revocation_base_point);
return ret;
}
/**
* A script either spendable by the revocation
* key or the broadcaster_delayed_payment_key and satisfying the relative-locktime OP_CSV constrain.
* Encumbering a `to_holder` output on a commitment transaction or 2nd-stage HTLC transactions.
*/
public static byte[] get_revokeable_redeemscript(byte[] revocation_key, short contest_delay, byte[] broadcaster_delayed_payment_key) {
byte[] ret = bindings.get_revokeable_redeemscript(InternalUtils.check_arr_len(revocation_key, 33), contest_delay, InternalUtils.check_arr_len(broadcaster_delayed_payment_key, 33));
Reference.reachabilityFence(revocation_key);
Reference.reachabilityFence(contest_delay);
Reference.reachabilityFence(broadcaster_delayed_payment_key);
return ret;
}
/**
* Returns the script for the counterparty's output on a holder's commitment transaction based on
* the channel type.
*/
public static byte[] get_counterparty_payment_script(org.ldk.structs.ChannelTypeFeatures channel_type_features, byte[] payment_key) {
byte[] ret = bindings.get_counterparty_payment_script(channel_type_features == null ? 0 : channel_type_features.ptr, InternalUtils.check_arr_len(payment_key, 33));
Reference.reachabilityFence(channel_type_features);
Reference.reachabilityFence(payment_key);
return ret;
}
/**
* Gets the witness redeemscript for an HTLC output in a commitment transaction. Note that htlc
* does not need to have its previous_output_index filled.
*/
public static byte[] get_htlc_redeemscript(org.ldk.structs.HTLCOutputInCommitment htlc, org.ldk.structs.ChannelTypeFeatures channel_type_features, org.ldk.structs.TxCreationKeys keys) {
byte[] ret = bindings.get_htlc_redeemscript(htlc == null ? 0 : htlc.ptr, channel_type_features == null ? 0 : channel_type_features.ptr, keys == null ? 0 : keys.ptr);
Reference.reachabilityFence(htlc);
Reference.reachabilityFence(channel_type_features);
Reference.reachabilityFence(keys);
return ret;
}
/**
* Gets the redeemscript for a funding output from the two funding public keys.
* Note that the order of funding public keys does not matter.
*/
public static byte[] make_funding_redeemscript(byte[] broadcaster, byte[] countersignatory) {
byte[] ret = bindings.make_funding_redeemscript(InternalUtils.check_arr_len(broadcaster, 33), InternalUtils.check_arr_len(countersignatory, 33));
Reference.reachabilityFence(broadcaster);
Reference.reachabilityFence(countersignatory);
return ret;
}
/**
* Builds an unsigned HTLC-Success or HTLC-Timeout transaction from the given channel and HTLC
* parameters. This is used by [`TrustedCommitmentTransaction::get_htlc_sigs`] to fetch the
* transaction which needs signing, and can be used to construct an HTLC transaction which is
* broadcastable given a counterparty HTLC signature.
*
* Panics if htlc.transaction_output_index.is_none() (as such HTLCs do not appear in the
* commitment transaction).
*/
public static byte[] build_htlc_transaction(byte[] commitment_txid, int feerate_per_kw, short contest_delay, org.ldk.structs.HTLCOutputInCommitment htlc, org.ldk.structs.ChannelTypeFeatures channel_type_features, byte[] broadcaster_delayed_payment_key, byte[] revocation_key) {
byte[] ret = bindings.build_htlc_transaction(InternalUtils.check_arr_len(commitment_txid, 32), feerate_per_kw, contest_delay, htlc == null ? 0 : htlc.ptr, channel_type_features == null ? 0 : channel_type_features.ptr, InternalUtils.check_arr_len(broadcaster_delayed_payment_key, 33), InternalUtils.check_arr_len(revocation_key, 33));
Reference.reachabilityFence(commitment_txid);
Reference.reachabilityFence(feerate_per_kw);
Reference.reachabilityFence(contest_delay);
Reference.reachabilityFence(htlc);
Reference.reachabilityFence(channel_type_features);
Reference.reachabilityFence(broadcaster_delayed_payment_key);
Reference.reachabilityFence(revocation_key);
return ret;
}
/**
* Returns the witness required to satisfy and spend a HTLC input.
*/
public static byte[] build_htlc_input_witness(byte[] local_sig, byte[] remote_sig, org.ldk.structs.Option_ThirtyTwoBytesZ preimage, byte[] redeem_script, org.ldk.structs.ChannelTypeFeatures channel_type_features) {
byte[] ret = bindings.build_htlc_input_witness(InternalUtils.check_arr_len(local_sig, 64), InternalUtils.check_arr_len(remote_sig, 64), preimage.ptr, redeem_script, channel_type_features == null ? 0 : channel_type_features.ptr);
Reference.reachabilityFence(local_sig);
Reference.reachabilityFence(remote_sig);
Reference.reachabilityFence(preimage);
Reference.reachabilityFence(redeem_script);
Reference.reachabilityFence(channel_type_features);
return ret;
}
/**
* Gets the witnessScript for the to_remote output when anchors are enabled.
*/
public static byte[] get_to_countersignatory_with_anchors_redeemscript(byte[] payment_point) {
byte[] ret = bindings.get_to_countersignatory_with_anchors_redeemscript(InternalUtils.check_arr_len(payment_point, 33));
Reference.reachabilityFence(payment_point);
return ret;
}
/**
* Gets the witnessScript for an anchor output from the funding public key.
* The witness in the spending input must be:
*
* After 16 blocks of confirmation, an alternative satisfying witness could be:
* <>
* (empty vector required to satisfy compliance with MINIMALIF-standard rule)
*/
public static byte[] get_anchor_redeemscript(byte[] funding_pubkey) {
byte[] ret = bindings.get_anchor_redeemscript(InternalUtils.check_arr_len(funding_pubkey, 33));
Reference.reachabilityFence(funding_pubkey);
return ret;
}
/**
* Returns the witness required to satisfy and spend an anchor input.
*/
public static byte[] build_anchor_input_witness(byte[] funding_key, byte[] funding_sig) {
byte[] ret = bindings.build_anchor_input_witness(InternalUtils.check_arr_len(funding_key, 33), InternalUtils.check_arr_len(funding_sig, 64));
Reference.reachabilityFence(funding_key);
Reference.reachabilityFence(funding_sig);
return ret;
}
/**
* Commitment transaction numbers which appear in the transactions themselves are XOR'd with a
* shared secret first. This prevents on-chain observers from discovering how many commitment
* transactions occurred in a channel before it was closed.
*
* This function gets the shared secret from relevant channel public keys and can be used to
* \"decrypt\" the commitment transaction number given a commitment transaction on-chain.
*/
public static long get_commitment_transaction_number_obscure_factor(byte[] broadcaster_payment_basepoint, byte[] countersignatory_payment_basepoint, boolean outbound_from_broadcaster) {
long ret = bindings.get_commitment_transaction_number_obscure_factor(InternalUtils.check_arr_len(broadcaster_payment_basepoint, 33), InternalUtils.check_arr_len(countersignatory_payment_basepoint, 33), outbound_from_broadcaster);
Reference.reachabilityFence(broadcaster_payment_basepoint);
Reference.reachabilityFence(countersignatory_payment_basepoint);
Reference.reachabilityFence(outbound_from_broadcaster);
return ret;
}
/**
* Read a NetworkUpdate from a byte array, created by NetworkUpdate_write
*/
public static Result_COption_NetworkUpdateZDecodeErrorZ NetworkUpdate_read(byte[] ser) {
long ret = bindings.NetworkUpdate_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_NetworkUpdateZDecodeErrorZ ret_hu_conv = Result_COption_NetworkUpdateZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Verifies the signature of a [`NodeAnnouncement`].
*
* Returns an error if it is invalid.
*/
public static Result_NoneLightningErrorZ verify_node_announcement(org.ldk.structs.NodeAnnouncement msg) {
long ret = bindings.verify_node_announcement(msg == null ? 0 : msg.ptr);
Reference.reachabilityFence(msg);
if (ret >= 0 && ret <= 4096) { return null; }
Result_NoneLightningErrorZ ret_hu_conv = Result_NoneLightningErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(msg); };
return ret_hu_conv;
}
/**
* Verifies all signatures included in a [`ChannelAnnouncement`].
*
* Returns an error if one of the signatures is invalid.
*/
public static Result_NoneLightningErrorZ verify_channel_announcement(org.ldk.structs.ChannelAnnouncement msg) {
long ret = bindings.verify_channel_announcement(msg == null ? 0 : msg.ptr);
Reference.reachabilityFence(msg);
if (ret >= 0 && ret <= 4096) { return null; }
Result_NoneLightningErrorZ ret_hu_conv = Result_NoneLightningErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(msg); };
return ret_hu_conv;
}
/**
* Finds a route from us (payer) to the given target node (payee).
*
* If the payee provided features in their invoice, they should be provided via the `payee` field
* in the given [`RouteParameters::payment_params`].
* Without this, MPP will only be used if the payee's features are available in the network graph.
*
* Private routing paths between a public node and the target may be included in the `payee` field
* of [`RouteParameters::payment_params`].
*
* If some channels aren't announced, it may be useful to fill in `first_hops` with the results
* from [`ChannelManager::list_usable_channels`]. If it is filled in, the view of these channels
* from `network_graph` will be ignored, and only those in `first_hops` will be used.
*
* The fees on channels from us to the next hop are ignored as they are assumed to all be equal.
* However, the enabled/disabled bit on such channels as well as the `htlc_minimum_msat` /
* `htlc_maximum_msat` *are* checked as they may change based on the receiving node.
*
* # Panics
*
* Panics if first_hops contains channels without `short_channel_id`s;
* [`ChannelManager::list_usable_channels`] will never include such channels.
*
* [`ChannelManager::list_usable_channels`]: crate::ln::channelmanager::ChannelManager::list_usable_channels
* [`Event::PaymentPathFailed`]: crate::events::Event::PaymentPathFailed
* [`NetworkGraph`]: crate::routing::gossip::NetworkGraph
*
* Note that first_hops (or a relevant inner pointer) may be NULL or all-0s to represent None
*/
public static Result_RouteLightningErrorZ find_route(byte[] our_node_pubkey, org.ldk.structs.RouteParameters route_params, org.ldk.structs.NetworkGraph network_graph, @Nullable ChannelDetails[] first_hops, org.ldk.structs.Logger logger, org.ldk.structs.ScoreLookUp scorer, org.ldk.structs.ProbabilisticScoringFeeParameters score_params, byte[] random_seed_bytes) {
long ret = bindings.find_route(InternalUtils.check_arr_len(our_node_pubkey, 33), route_params == null ? 0 : route_params.ptr, network_graph == null ? 0 : network_graph.ptr, first_hops != null ? Arrays.stream(first_hops).mapToLong(first_hops_conv_16 -> first_hops_conv_16 == null ? 0 : first_hops_conv_16.ptr).toArray() : null, logger.ptr, scorer.ptr, score_params == null ? 0 : score_params.ptr, InternalUtils.check_arr_len(random_seed_bytes, 32));
Reference.reachabilityFence(our_node_pubkey);
Reference.reachabilityFence(route_params);
Reference.reachabilityFence(network_graph);
Reference.reachabilityFence(first_hops);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(scorer);
Reference.reachabilityFence(score_params);
Reference.reachabilityFence(random_seed_bytes);
if (ret >= 0 && ret <= 4096) { return null; }
Result_RouteLightningErrorZ ret_hu_conv = Result_RouteLightningErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(route_params); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(network_graph); };
if (first_hops != null) { for (ChannelDetails first_hops_conv_16: first_hops) { if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(first_hops_conv_16); }; } };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(scorer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(score_params); };
return ret_hu_conv;
}
/**
* Construct a route from us (payer) to the target node (payee) via the given hops (which should
* exclude the payer, but include the payee). This may be useful, e.g., for probing the chosen path.
*
* Re-uses logic from `find_route`, so the restrictions described there also apply here.
*/
public static Result_RouteLightningErrorZ build_route_from_hops(byte[] our_node_pubkey, byte[][] hops, org.ldk.structs.RouteParameters route_params, org.ldk.structs.NetworkGraph network_graph, org.ldk.structs.Logger logger, byte[] random_seed_bytes) {
long ret = bindings.build_route_from_hops(InternalUtils.check_arr_len(our_node_pubkey, 33), hops != null ? Arrays.stream(hops).map(hops_conv_8 -> InternalUtils.check_arr_len(hops_conv_8, 33)).toArray(byte[][]::new) : null, route_params == null ? 0 : route_params.ptr, network_graph == null ? 0 : network_graph.ptr, logger.ptr, InternalUtils.check_arr_len(random_seed_bytes, 32));
Reference.reachabilityFence(our_node_pubkey);
Reference.reachabilityFence(hops);
Reference.reachabilityFence(route_params);
Reference.reachabilityFence(network_graph);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(random_seed_bytes);
if (ret >= 0 && ret <= 4096) { return null; }
Result_RouteLightningErrorZ ret_hu_conv = Result_RouteLightningErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(route_params); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(network_graph); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
return ret_hu_conv;
}
/**
* Creates an unsigned [`PartiallySignedTransaction`] which spends the given descriptors to
* the given outputs, plus an output to the given change destination (if sufficient
* change value remains). The PSBT will have a feerate, at least, of the given value.
*
* The `locktime` argument is used to set the transaction's locktime. If `None`, the
* transaction will have a locktime of 0. It it recommended to set this to the current block
* height to avoid fee sniping, unless you have some specific reason to use a different
* locktime.
*
* Returns the PSBT and expected max transaction weight.
*
* Returns `Err(())` if the output value is greater than the input value minus required fee,
* if a descriptor was duplicated, or if an output descriptor `script_pubkey`
* does not match the one we can spend.
*
* We do not enforce that outputs meet the dust limit or that any output scripts are standard.
*/
public static Result_C2Tuple_CVec_u8ZusizeZNoneZ SpendableOutputDescriptor_create_spendable_outputs_psbt(SpendableOutputDescriptor[] descriptors, TxOut[] outputs, byte[] change_destination_script, int feerate_sat_per_1000_weight, org.ldk.structs.Option_u32Z locktime) {
long ret = bindings.SpendableOutputDescriptor_create_spendable_outputs_psbt(descriptors != null ? Arrays.stream(descriptors).mapToLong(descriptors_conv_27 -> descriptors_conv_27.ptr).toArray() : null, outputs != null ? Arrays.stream(outputs).mapToLong(outputs_conv_7 -> outputs_conv_7.ptr).toArray() : null, change_destination_script, feerate_sat_per_1000_weight, locktime.ptr);
Reference.reachabilityFence(descriptors);
Reference.reachabilityFence(outputs);
Reference.reachabilityFence(change_destination_script);
Reference.reachabilityFence(feerate_sat_per_1000_weight);
Reference.reachabilityFence(locktime);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_CVec_u8ZusizeZNoneZ ret_hu_conv = Result_C2Tuple_CVec_u8ZusizeZNoneZ.constr_from_ptr(ret);
for (SpendableOutputDescriptor descriptors_conv_27: descriptors) { if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(descriptors_conv_27); }; };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(locktime); };
return ret_hu_conv;
}
/**
* Creates an [`OnionMessage`] with the given `contents` for sending to the destination of
* `path`.
*
* Returns both the node id of the peer to send the message to and the message itself.
*
* Note that reply_path (or a relevant inner pointer) may be NULL or all-0s to represent None
*/
public static Result_C2Tuple_PublicKeyOnionMessageZSendErrorZ create_onion_message(org.ldk.structs.EntropySource entropy_source, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.OnionMessagePath path, org.ldk.structs.OnionMessageContents contents, @Nullable org.ldk.structs.BlindedPath reply_path) {
long ret = bindings.create_onion_message(entropy_source.ptr, node_signer.ptr, path == null ? 0 : path.ptr, contents.ptr, reply_path == null ? 0 : reply_path.ptr);
Reference.reachabilityFence(entropy_source);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(path);
Reference.reachabilityFence(contents);
Reference.reachabilityFence(reply_path);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_PublicKeyOnionMessageZSendErrorZ ret_hu_conv = Result_C2Tuple_PublicKeyOnionMessageZSendErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(path); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(contents); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(reply_path); };
return ret_hu_conv;
}
/**
* Decode one layer of an incoming [`OnionMessage`].
*
* Returns either the next layer of the onion for forwarding or the decrypted content for the
* receiver.
*/
public static Result_PeeledOnionNoneZ peel_onion_message(org.ldk.structs.OnionMessage msg, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.structs.CustomOnionMessageHandler custom_handler) {
long ret = bindings.peel_onion_message(msg == null ? 0 : msg.ptr, node_signer.ptr, logger.ptr, custom_handler.ptr);
Reference.reachabilityFence(msg);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(custom_handler);
if (ret >= 0 && ret <= 4096) { return null; }
Result_PeeledOnionNoneZ ret_hu_conv = Result_PeeledOnionNoneZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(msg); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(custom_handler); };
return ret_hu_conv;
}
/**
* Returns whether `tlv_type` corresponds to a TLV record for Offers.
*/
public static boolean OffersMessage_is_known_type(long tlv_type) {
boolean ret = bindings.OffersMessage_is_known_type(tlv_type);
Reference.reachabilityFence(tlv_type);
return ret;
}
/**
* Create a one-hop blinded path for a payment.
*/
public static Result_C2Tuple_BlindedPayInfoBlindedPathZNoneZ BlindedPath_one_hop_for_payment(byte[] payee_node_id, org.ldk.structs.ReceiveTlvs payee_tlvs, org.ldk.structs.EntropySource entropy_source) {
long ret = bindings.BlindedPath_one_hop_for_payment(InternalUtils.check_arr_len(payee_node_id, 33), payee_tlvs == null ? 0 : payee_tlvs.ptr, entropy_source.ptr);
Reference.reachabilityFence(payee_node_id);
Reference.reachabilityFence(payee_tlvs);
Reference.reachabilityFence(entropy_source);
if (ret >= 0 && ret <= 4096) { return null; }
Result_C2Tuple_BlindedPayInfoBlindedPathZNoneZ ret_hu_conv = Result_C2Tuple_BlindedPayInfoBlindedPathZNoneZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(payee_tlvs); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
return ret_hu_conv;
}
/**
* Read a PathFailure from a byte array, created by PathFailure_write
*/
public static Result_COption_PathFailureZDecodeErrorZ PathFailure_read(byte[] ser) {
long ret = bindings.PathFailure_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_PathFailureZDecodeErrorZ ret_hu_conv = Result_COption_PathFailureZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Read a ClosureReason from a byte array, created by ClosureReason_write
*/
public static Result_COption_ClosureReasonZDecodeErrorZ ClosureReason_read(byte[] ser) {
long ret = bindings.ClosureReason_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_ClosureReasonZDecodeErrorZ ret_hu_conv = Result_COption_ClosureReasonZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Read a HTLCDestination from a byte array, created by HTLCDestination_write
*/
public static Result_COption_HTLCDestinationZDecodeErrorZ HTLCDestination_read(byte[] ser) {
long ret = bindings.HTLCDestination_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_HTLCDestinationZDecodeErrorZ ret_hu_conv = Result_COption_HTLCDestinationZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Read a Event from a byte array, created by Event_write
*/
public static Result_COption_EventZDecodeErrorZ Event_read(byte[] ser) {
long ret = bindings.Event_read(ser);
Reference.reachabilityFence(ser);
if (ret >= 0 && ret <= 4096) { return null; }
Result_COption_EventZDecodeErrorZ ret_hu_conv = Result_COption_EventZDecodeErrorZ.constr_from_ptr(ret);
return ret_hu_conv;
}
/**
* Pays the given [`Bolt11Invoice`], retrying if needed based on [`Retry`].
*
* [`Bolt11Invoice::payment_hash`] is used as the [`PaymentId`], which ensures idempotency as long
* as the payment is still pending. If the payment succeeds, you must ensure that a second payment
* with the same [`PaymentHash`] is never sent.
*
* If you wish to use a different payment idempotency token, see [`pay_invoice_with_id`].
*/
public static Result_ThirtyTwoBytesPaymentErrorZ pay_invoice(org.ldk.structs.Bolt11Invoice invoice, org.ldk.structs.Retry retry_strategy, org.ldk.structs.ChannelManager channelmanager) {
long ret = bindings.pay_invoice(invoice == null ? 0 : invoice.ptr, retry_strategy.ptr, channelmanager == null ? 0 : channelmanager.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(retry_strategy);
Reference.reachabilityFence(channelmanager);
if (ret >= 0 && ret <= 4096) { return null; }
Result_ThirtyTwoBytesPaymentErrorZ ret_hu_conv = Result_ThirtyTwoBytesPaymentErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(retry_strategy); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
return ret_hu_conv;
}
/**
* Pays the given [`Bolt11Invoice`] with a custom idempotency key, retrying if needed based on
* [`Retry`].
*
* Note that idempotency is only guaranteed as long as the payment is still pending. Once the
* payment completes or fails, no idempotency guarantees are made.
*
* You should ensure that the [`Bolt11Invoice::payment_hash`] is unique and the same
* [`PaymentHash`] has never been paid before.
*
* See [`pay_invoice`] for a variant which uses the [`PaymentHash`] for the idempotency token.
*/
public static Result_NonePaymentErrorZ pay_invoice_with_id(org.ldk.structs.Bolt11Invoice invoice, byte[] payment_id, org.ldk.structs.Retry retry_strategy, org.ldk.structs.ChannelManager channelmanager) {
long ret = bindings.pay_invoice_with_id(invoice == null ? 0 : invoice.ptr, InternalUtils.check_arr_len(payment_id, 32), retry_strategy.ptr, channelmanager == null ? 0 : channelmanager.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(payment_id);
Reference.reachabilityFence(retry_strategy);
Reference.reachabilityFence(channelmanager);
if (ret >= 0 && ret <= 4096) { return null; }
Result_NonePaymentErrorZ ret_hu_conv = Result_NonePaymentErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(retry_strategy); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
return ret_hu_conv;
}
/**
* Pays the given zero-value [`Bolt11Invoice`] using the given amount, retrying if needed based on
* [`Retry`].
*
* [`Bolt11Invoice::payment_hash`] is used as the [`PaymentId`], which ensures idempotency as long
* as the payment is still pending. If the payment succeeds, you must ensure that a second payment
* with the same [`PaymentHash`] is never sent.
*
* If you wish to use a different payment idempotency token, see
* [`pay_zero_value_invoice_with_id`].
*/
public static Result_ThirtyTwoBytesPaymentErrorZ pay_zero_value_invoice(org.ldk.structs.Bolt11Invoice invoice, long amount_msats, org.ldk.structs.Retry retry_strategy, org.ldk.structs.ChannelManager channelmanager) {
long ret = bindings.pay_zero_value_invoice(invoice == null ? 0 : invoice.ptr, amount_msats, retry_strategy.ptr, channelmanager == null ? 0 : channelmanager.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(amount_msats);
Reference.reachabilityFence(retry_strategy);
Reference.reachabilityFence(channelmanager);
if (ret >= 0 && ret <= 4096) { return null; }
Result_ThirtyTwoBytesPaymentErrorZ ret_hu_conv = Result_ThirtyTwoBytesPaymentErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(retry_strategy); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
return ret_hu_conv;
}
/**
* Pays the given zero-value [`Bolt11Invoice`] using the given amount and custom idempotency key,
* retrying if needed based on [`Retry`].
*
* Note that idempotency is only guaranteed as long as the payment is still pending. Once the
* payment completes or fails, no idempotency guarantees are made.
*
* You should ensure that the [`Bolt11Invoice::payment_hash`] is unique and the same
* [`PaymentHash`] has never been paid before.
*
* See [`pay_zero_value_invoice`] for a variant which uses the [`PaymentHash`] for the
* idempotency token.
*/
public static Result_NonePaymentErrorZ pay_zero_value_invoice_with_id(org.ldk.structs.Bolt11Invoice invoice, long amount_msats, byte[] payment_id, org.ldk.structs.Retry retry_strategy, org.ldk.structs.ChannelManager channelmanager) {
long ret = bindings.pay_zero_value_invoice_with_id(invoice == null ? 0 : invoice.ptr, amount_msats, InternalUtils.check_arr_len(payment_id, 32), retry_strategy.ptr, channelmanager == null ? 0 : channelmanager.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(amount_msats);
Reference.reachabilityFence(payment_id);
Reference.reachabilityFence(retry_strategy);
Reference.reachabilityFence(channelmanager);
if (ret >= 0 && ret <= 4096) { return null; }
Result_NonePaymentErrorZ ret_hu_conv = Result_NonePaymentErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(retry_strategy); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
return ret_hu_conv;
}
/**
* Sends payment probes over all paths of a route that would be used to pay the given invoice.
*
* See [`ChannelManager::send_preflight_probes`] for more information.
*/
public static Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ preflight_probe_invoice(org.ldk.structs.Bolt11Invoice invoice, org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.Option_u64Z liquidity_limit_multiplier) {
long ret = bindings.preflight_probe_invoice(invoice == null ? 0 : invoice.ptr, channelmanager == null ? 0 : channelmanager.ptr, liquidity_limit_multiplier.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(liquidity_limit_multiplier);
if (ret >= 0 && ret <= 4096) { return null; }
Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ ret_hu_conv = Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(liquidity_limit_multiplier); };
return ret_hu_conv;
}
/**
* Sends payment probes over all paths of a route that would be used to pay the given zero-value
* invoice using the given amount.
*
* See [`ChannelManager::send_preflight_probes`] for more information.
*/
public static Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ preflight_probe_zero_value_invoice(org.ldk.structs.Bolt11Invoice invoice, long amount_msat, org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.Option_u64Z liquidity_limit_multiplier) {
long ret = bindings.preflight_probe_zero_value_invoice(invoice == null ? 0 : invoice.ptr, amount_msat, channelmanager == null ? 0 : channelmanager.ptr, liquidity_limit_multiplier.ptr);
Reference.reachabilityFence(invoice);
Reference.reachabilityFence(amount_msat);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(liquidity_limit_multiplier);
if (ret >= 0 && ret <= 4096) { return null; }
Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ ret_hu_conv = Result_CVec_C2Tuple_ThirtyTwoBytesThirtyTwoBytesZZProbingErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(invoice); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(liquidity_limit_multiplier); };
return ret_hu_conv;
}
/**
* Utility to create an invoice that can be paid to one of multiple nodes, or a \"phantom invoice.\"
* See [`PhantomKeysManager`] for more information on phantom node payments.
*
* `phantom_route_hints` parameter:
* Contains channel info for all nodes participating in the phantom invoice
* Entries are retrieved from a call to [`ChannelManager::get_phantom_route_hints`] on each
* participating node
* It is fine to cache `phantom_route_hints` and reuse it across invoices, as long as the data is
* updated when a channel becomes disabled or closes
* Note that if too many channels are included in [`PhantomRouteHints::channels`], the invoice
* may be too long for QR code scanning. To fix this, `PhantomRouteHints::channels` may be pared
* down
*
* `payment_hash` can be specified if you have a specific need for a custom payment hash (see the difference
* between [`ChannelManager::create_inbound_payment`] and [`ChannelManager::create_inbound_payment_for_hash`]).
* If `None` is provided for `payment_hash`, then one will be created.
*
* `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
* in excess of the current time.
*
* `duration_since_epoch` is the current time since epoch in seconds.
*
* You can specify a custom `min_final_cltv_expiry_delta`, or let LDK default it to
* [`MIN_FINAL_CLTV_EXPIRY_DELTA`]. The provided expiry must be at least [`MIN_FINAL_CLTV_EXPIRY_DELTA`] - 3.
* Note that LDK will add a buffer of 3 blocks to the delta to allow for up to a few new block
* confirmations during routing.
*
* Note that the provided `keys_manager`'s `NodeSigner` implementation must support phantom
* invoices in its `sign_invoice` implementation ([`PhantomKeysManager`] satisfies this
* requirement).
*
* [`PhantomKeysManager`]: lightning::sign::PhantomKeysManager
* [`ChannelManager::get_phantom_route_hints`]: lightning::ln::channelmanager::ChannelManager::get_phantom_route_hints
* [`ChannelManager::create_inbound_payment`]: lightning::ln::channelmanager::ChannelManager::create_inbound_payment
* [`ChannelManager::create_inbound_payment_for_hash`]: lightning::ln::channelmanager::ChannelManager::create_inbound_payment_for_hash
* [`PhantomRouteHints::channels`]: lightning::ln::channelmanager::PhantomRouteHints::channels
* [`MIN_FINAL_CLTV_EXPIRY_DETLA`]: lightning::ln::channelmanager::MIN_FINAL_CLTV_EXPIRY_DELTA
*
* This can be used in a `no_std` environment, where [`std::time::SystemTime`] is not
* available and the current time is supplied by the caller.
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_phantom_invoice(org.ldk.structs.Option_u64Z amt_msat, org.ldk.structs.Option_ThirtyTwoBytesZ payment_hash, java.lang.String description, int invoice_expiry_delta_secs, PhantomRouteHints[] phantom_route_hints, org.ldk.structs.EntropySource entropy_source, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta, long duration_since_epoch) {
long ret = bindings.create_phantom_invoice(amt_msat.ptr, payment_hash.ptr, description, invoice_expiry_delta_secs, phantom_route_hints != null ? Arrays.stream(phantom_route_hints).mapToLong(phantom_route_hints_conv_19 -> phantom_route_hints_conv_19 == null ? 0 : phantom_route_hints_conv_19.ptr).toArray() : null, entropy_source.ptr, node_signer.ptr, logger.ptr, network, min_final_cltv_expiry_delta.ptr, duration_since_epoch);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(payment_hash);
Reference.reachabilityFence(description);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(phantom_route_hints);
Reference.reachabilityFence(entropy_source);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
Reference.reachabilityFence(duration_since_epoch);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(payment_hash); };
for (PhantomRouteHints phantom_route_hints_conv_19: phantom_route_hints) { if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(phantom_route_hints_conv_19); }; };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* Utility to create an invoice that can be paid to one of multiple nodes, or a \"phantom invoice.\"
* See [`PhantomKeysManager`] for more information on phantom node payments.
*
* `phantom_route_hints` parameter:
* Contains channel info for all nodes participating in the phantom invoice
* Entries are retrieved from a call to [`ChannelManager::get_phantom_route_hints`] on each
* participating node
* It is fine to cache `phantom_route_hints` and reuse it across invoices, as long as the data is
* updated when a channel becomes disabled or closes
* Note that the route hints generated from `phantom_route_hints` will be limited to a maximum
* of 3 hints to ensure that the invoice can be scanned in a QR code. These hints are selected
* in the order that the nodes in `PhantomRouteHints` are specified, selecting one hint per node
* until the maximum is hit. Callers may provide as many `PhantomRouteHints::channels` as
* desired, but note that some nodes will be trimmed if more than 3 nodes are provided.
*
* `description_hash` is a SHA-256 hash of the description text
*
* `payment_hash` can be specified if you have a specific need for a custom payment hash (see the difference
* between [`ChannelManager::create_inbound_payment`] and [`ChannelManager::create_inbound_payment_for_hash`]).
* If `None` is provided for `payment_hash`, then one will be created.
*
* `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
* in excess of the current time.
*
* `duration_since_epoch` is the current time since epoch in seconds.
*
* Note that the provided `keys_manager`'s `NodeSigner` implementation must support phantom
* invoices in its `sign_invoice` implementation ([`PhantomKeysManager`] satisfies this
* requirement).
*
* [`PhantomKeysManager`]: lightning::sign::PhantomKeysManager
* [`ChannelManager::get_phantom_route_hints`]: lightning::ln::channelmanager::ChannelManager::get_phantom_route_hints
* [`ChannelManager::create_inbound_payment`]: lightning::ln::channelmanager::ChannelManager::create_inbound_payment
* [`ChannelManager::create_inbound_payment_for_hash`]: lightning::ln::channelmanager::ChannelManager::create_inbound_payment_for_hash
* [`PhantomRouteHints::channels`]: lightning::ln::channelmanager::PhantomRouteHints::channels
*
* This can be used in a `no_std` environment, where [`std::time::SystemTime`] is not
* available and the current time is supplied by the caller.
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_phantom_invoice_with_description_hash(org.ldk.structs.Option_u64Z amt_msat, org.ldk.structs.Option_ThirtyTwoBytesZ payment_hash, int invoice_expiry_delta_secs, org.ldk.structs.Sha256 description_hash, PhantomRouteHints[] phantom_route_hints, org.ldk.structs.EntropySource entropy_source, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta, long duration_since_epoch) {
long ret = bindings.create_phantom_invoice_with_description_hash(amt_msat.ptr, payment_hash.ptr, invoice_expiry_delta_secs, description_hash == null ? 0 : description_hash.ptr, phantom_route_hints != null ? Arrays.stream(phantom_route_hints).mapToLong(phantom_route_hints_conv_19 -> phantom_route_hints_conv_19 == null ? 0 : phantom_route_hints_conv_19.ptr).toArray() : null, entropy_source.ptr, node_signer.ptr, logger.ptr, network, min_final_cltv_expiry_delta.ptr, duration_since_epoch);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(payment_hash);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(description_hash);
Reference.reachabilityFence(phantom_route_hints);
Reference.reachabilityFence(entropy_source);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
Reference.reachabilityFence(duration_since_epoch);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(payment_hash); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(description_hash); };
for (PhantomRouteHints phantom_route_hints_conv_19: phantom_route_hints) { if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(phantom_route_hints_conv_19); }; };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(entropy_source); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* Utility to construct an invoice. Generally, unless you want to do something like a custom
* cltv_expiry, this is what you should be using to create an invoice. The reason being, this
* method stores the invoice's payment secret and preimage in `ChannelManager`, so (a) the user
* doesn't have to store preimage/payment secret information and (b) `ChannelManager` can verify
* that the payment secret is valid when the invoice is paid.
*
* `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
* in excess of the current time.
*
* You can specify a custom `min_final_cltv_expiry_delta`, or let LDK default it to
* [`MIN_FINAL_CLTV_EXPIRY_DELTA`]. The provided expiry must be at least [`MIN_FINAL_CLTV_EXPIRY_DELTA`].
* Note that LDK will add a buffer of 3 blocks to the delta to allow for up to a few new block
* confirmations during routing.
*
* [`MIN_FINAL_CLTV_EXPIRY_DETLA`]: lightning::ln::channelmanager::MIN_FINAL_CLTV_EXPIRY_DELTA
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_invoice_from_channelmanager(org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u64Z amt_msat, java.lang.String description, int invoice_expiry_delta_secs, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_invoice_from_channelmanager(channelmanager == null ? 0 : channelmanager.ptr, node_signer.ptr, logger.ptr, network, amt_msat.ptr, description, invoice_expiry_delta_secs, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(description);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* Utility to construct an invoice. Generally, unless you want to do something like a custom
* cltv_expiry, this is what you should be using to create an invoice. The reason being, this
* method stores the invoice's payment secret and preimage in `ChannelManager`, so (a) the user
* doesn't have to store preimage/payment secret information and (b) `ChannelManager` can verify
* that the payment secret is valid when the invoice is paid.
* Use this variant if you want to pass the `description_hash` to the invoice.
*
* `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
* in excess of the current time.
*
* You can specify a custom `min_final_cltv_expiry_delta`, or let LDK default it to
* [`MIN_FINAL_CLTV_EXPIRY_DELTA`]. The provided expiry must be at least [`MIN_FINAL_CLTV_EXPIRY_DELTA`].
* Note that LDK will add a buffer of 3 blocks to the delta to allow for up to a few new block
* confirmations during routing.
*
* [`MIN_FINAL_CLTV_EXPIRY_DETLA`]: lightning::ln::channelmanager::MIN_FINAL_CLTV_EXPIRY_DELTA
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_invoice_from_channelmanager_with_description_hash(org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u64Z amt_msat, org.ldk.structs.Sha256 description_hash, int invoice_expiry_delta_secs, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_invoice_from_channelmanager_with_description_hash(channelmanager == null ? 0 : channelmanager.ptr, node_signer.ptr, logger.ptr, network, amt_msat.ptr, description_hash == null ? 0 : description_hash.ptr, invoice_expiry_delta_secs, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(description_hash);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(description_hash); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* See [`create_invoice_from_channelmanager_with_description_hash`]
* This version can be used in a `no_std` environment, where [`std::time::SystemTime`] is not
* available and the current time is supplied by the caller.
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_invoice_from_channelmanager_with_description_hash_and_duration_since_epoch(org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u64Z amt_msat, org.ldk.structs.Sha256 description_hash, long duration_since_epoch, int invoice_expiry_delta_secs, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_invoice_from_channelmanager_with_description_hash_and_duration_since_epoch(channelmanager == null ? 0 : channelmanager.ptr, node_signer.ptr, logger.ptr, network, amt_msat.ptr, description_hash == null ? 0 : description_hash.ptr, duration_since_epoch, invoice_expiry_delta_secs, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(description_hash);
Reference.reachabilityFence(duration_since_epoch);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(description_hash); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* See [`create_invoice_from_channelmanager`]
* This version can be used in a `no_std` environment, where [`std::time::SystemTime`] is not
* available and the current time is supplied by the caller.
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_invoice_from_channelmanager_and_duration_since_epoch(org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u64Z amt_msat, java.lang.String description, long duration_since_epoch, int invoice_expiry_delta_secs, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_invoice_from_channelmanager_and_duration_since_epoch(channelmanager == null ? 0 : channelmanager.ptr, node_signer.ptr, logger.ptr, network, amt_msat.ptr, description, duration_since_epoch, invoice_expiry_delta_secs, min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(description);
Reference.reachabilityFence(duration_since_epoch);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
/**
* See [`create_invoice_from_channelmanager_and_duration_since_epoch`]
* This version allows for providing a custom [`PaymentHash`] for the invoice.
* This may be useful if you're building an on-chain swap or involving another protocol where
* the payment hash is also involved outside the scope of lightning.
*/
public static Result_Bolt11InvoiceSignOrCreationErrorZ create_invoice_from_channelmanager_and_duration_since_epoch_with_payment_hash(org.ldk.structs.ChannelManager channelmanager, org.ldk.structs.NodeSigner node_signer, org.ldk.structs.Logger logger, org.ldk.enums.Currency network, org.ldk.structs.Option_u64Z amt_msat, java.lang.String description, long duration_since_epoch, int invoice_expiry_delta_secs, byte[] payment_hash, org.ldk.structs.Option_u16Z min_final_cltv_expiry_delta) {
long ret = bindings.create_invoice_from_channelmanager_and_duration_since_epoch_with_payment_hash(channelmanager == null ? 0 : channelmanager.ptr, node_signer.ptr, logger.ptr, network, amt_msat.ptr, description, duration_since_epoch, invoice_expiry_delta_secs, InternalUtils.check_arr_len(payment_hash, 32), min_final_cltv_expiry_delta.ptr);
Reference.reachabilityFence(channelmanager);
Reference.reachabilityFence(node_signer);
Reference.reachabilityFence(logger);
Reference.reachabilityFence(network);
Reference.reachabilityFence(amt_msat);
Reference.reachabilityFence(description);
Reference.reachabilityFence(duration_since_epoch);
Reference.reachabilityFence(invoice_expiry_delta_secs);
Reference.reachabilityFence(payment_hash);
Reference.reachabilityFence(min_final_cltv_expiry_delta);
if (ret >= 0 && ret <= 4096) { return null; }
Result_Bolt11InvoiceSignOrCreationErrorZ ret_hu_conv = Result_Bolt11InvoiceSignOrCreationErrorZ.constr_from_ptr(ret);
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(channelmanager); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(node_signer); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(logger); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(amt_msat); };
if (ret_hu_conv != null) { ret_hu_conv.ptrs_to.add(min_final_cltv_expiry_delta); };
return ret_hu_conv;
}
}