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package fr.acinq.lightning.channel

import fr.acinq.bitcoin.*
import fr.acinq.bitcoin.Crypto.ripemd160
import fr.acinq.bitcoin.Crypto.sha256
import fr.acinq.bitcoin.Script.pay2wsh
import fr.acinq.bitcoin.Script.write
import fr.acinq.bitcoin.utils.Either
import fr.acinq.bitcoin.utils.Try
import fr.acinq.bitcoin.utils.runTrying
import fr.acinq.lightning.Feature
import fr.acinq.lightning.Features
import fr.acinq.lightning.MilliSatoshi
import fr.acinq.lightning.NodeParams
import fr.acinq.lightning.blockchain.BITCOIN_OUTPUT_SPENT
import fr.acinq.lightning.blockchain.BITCOIN_TX_CONFIRMED
import fr.acinq.lightning.blockchain.WatchConfirmed
import fr.acinq.lightning.blockchain.WatchSpent
import fr.acinq.lightning.blockchain.fee.FeeratePerKw
import fr.acinq.lightning.blockchain.fee.FeerateTolerance
import fr.acinq.lightning.blockchain.fee.OnChainFeerates
import fr.acinq.lightning.channel.Helpers.Closing.inputsAlreadySpent
import fr.acinq.lightning.channel.states.Channel
import fr.acinq.lightning.channel.states.ClosingFeerates
import fr.acinq.lightning.channel.states.ClosingFees
import fr.acinq.lightning.crypto.Bolt3Derivation.deriveForCommitment
import fr.acinq.lightning.crypto.Bolt3Derivation.deriveForRevocation
import fr.acinq.lightning.crypto.KeyManager
import fr.acinq.lightning.crypto.ShaChain
import fr.acinq.lightning.logging.*
import fr.acinq.lightning.transactions.*
import fr.acinq.lightning.transactions.Scripts.multiSig2of2
import fr.acinq.lightning.transactions.Transactions.TransactionWithInputInfo.ClaimHtlcDelayedOutputPenaltyTx
import fr.acinq.lightning.transactions.Transactions.TransactionWithInputInfo.ClaimHtlcTx.ClaimHtlcTimeoutTx
import fr.acinq.lightning.transactions.Transactions.TransactionWithInputInfo.ClosingTx
import fr.acinq.lightning.transactions.Transactions.TransactionWithInputInfo.HtlcTx.HtlcSuccessTx
import fr.acinq.lightning.transactions.Transactions.TransactionWithInputInfo.HtlcTx.HtlcTimeoutTx
import fr.acinq.lightning.transactions.Transactions.commitTxFee
import fr.acinq.lightning.transactions.Transactions.makeCommitTxOutputs
import fr.acinq.lightning.utils.*
import fr.acinq.lightning.wire.*
import kotlin.math.max

object Helpers {

    /**
     * Returns the number of confirmations needed to safely handle the funding transaction,
     * we make sure the cumulative block reward largely exceeds the channel size.
     *
     * @param fundingAmount funding amount of the channel
     * @return number of confirmations needed
     */
    fun minDepthForFunding(nodeParams: NodeParams, fundingAmount: Satoshi): Int {
        val blockReward = 6.25f // this is true as of ~May 2020, but will be too large after 2024
        val scalingFactor = 15
        val btc = fundingAmount.toLong().toDouble() / 100_000_000L
        val blocksToReachFunding: Int = (((scalingFactor * btc) / blockReward) + 1).toInt()
        return max(nodeParams.minDepthBlocks, blocksToReachFunding)
    }

    /** Called by the non-initiator. */
    fun validateParamsNonInitiator(nodeParams: NodeParams, open: OpenDualFundedChannel): Either {
        // NB: we only accept channels from peers who support explicit channel type negotiation.
        val channelType = open.channelType ?: return Either.Left(MissingChannelType(open.temporaryChannelId))
        if (channelType is ChannelType.UnsupportedChannelType) {
            return Either.Left(InvalidChannelType(open.temporaryChannelId, ChannelType.SupportedChannelType.AnchorOutputsZeroReserve, channelType))
        }

        // BOLT #2: if the chain_hash value, within the open_channel, message is set to a hash of a chain that is unknown to the receiver:
        // MUST reject the channel.
        if (nodeParams.chainHash != open.chainHash) {
            return Either.Left(InvalidChainHash(open.temporaryChannelId, local = nodeParams.chainHash, remote = open.chainHash))
        }

        // BOLT #2: The receiving node MUST fail the channel if: push_msat is greater than funding_satoshis * 1000.
        if (open.pushAmount > open.fundingAmount) {
            return Either.Left(InvalidPushAmount(open.temporaryChannelId, open.pushAmount, open.fundingAmount.toMilliSatoshi()))
        }

        // BOLT #2: The receiving node MUST fail the channel if: to_self_delay is unreasonably large.
        if (open.toSelfDelay > Channel.MAX_TO_SELF_DELAY || open.toSelfDelay > nodeParams.maxToLocalDelayBlocks) {
            return Either.Left(ToSelfDelayTooHigh(open.temporaryChannelId, open.toSelfDelay, nodeParams.maxToLocalDelayBlocks))
        }

        // BOLT #2: The receiving node MUST fail the channel if: max_accepted_htlcs is greater than 483.
        if (open.maxAcceptedHtlcs > Channel.MAX_ACCEPTED_HTLCS) {
            return Either.Left(InvalidMaxAcceptedHtlcs(open.temporaryChannelId, open.maxAcceptedHtlcs, Channel.MAX_ACCEPTED_HTLCS))
        }

        // BOLT #2: The receiving node MUST fail the channel if: it considers feerate_per_kw too small for timely processing.
        if (isFeeTooSmall(open.commitmentFeerate)) {
            return Either.Left(FeerateTooSmall(open.temporaryChannelId, open.commitmentFeerate))
        }

        if (open.dustLimit > nodeParams.maxRemoteDustLimit) {
            return Either.Left(DustLimitTooLarge(open.temporaryChannelId, open.dustLimit, nodeParams.maxRemoteDustLimit))
        }

        if (open.dustLimit < Channel.MIN_DUST_LIMIT) {
            return Either.Left(DustLimitTooSmall(open.temporaryChannelId, open.dustLimit, Channel.MIN_DUST_LIMIT))
        }

        if (isFeeDiffTooHigh(FeeratePerKw.CommitmentFeerate, open.commitmentFeerate, nodeParams.onChainFeeConf.feerateTolerance)) {
            return Either.Left(FeerateTooDifferent(open.temporaryChannelId, FeeratePerKw.CommitmentFeerate, open.commitmentFeerate))
        }

        return Either.Right(channelType)
    }

    /** Called by the initiator. */
    fun validateParamsInitiator(nodeParams: NodeParams, init: ChannelCommand.Init.Initiator, open: OpenDualFundedChannel, accept: AcceptDualFundedChannel): Either {
        require(open.channelType != null) { "we should have sent a channel type in open_channel" }
        if (accept.channelType == null) {
            // We only open channels to peers who support explicit channel type negotiation.
            return Either.Left(MissingChannelType(accept.temporaryChannelId))
        }
        if (open.channelType != accept.channelType) {
            return Either.Left(InvalidChannelType(accept.temporaryChannelId, open.channelType!!, accept.channelType!!))
        }

        if (accept.fundingAmount < 0.sat) {
            return Either.Left(InvalidFundingAmount(accept.temporaryChannelId, accept.fundingAmount))
        }

        if (accept.pushAmount > accept.fundingAmount) {
            return Either.Left(InvalidPushAmount(accept.temporaryChannelId, accept.pushAmount, accept.fundingAmount.toMilliSatoshi()))
        }

        if (accept.maxAcceptedHtlcs > Channel.MAX_ACCEPTED_HTLCS) {
            return Either.Left(InvalidMaxAcceptedHtlcs(accept.temporaryChannelId, accept.maxAcceptedHtlcs, Channel.MAX_ACCEPTED_HTLCS))
        }

        if (accept.dustLimit < Channel.MIN_DUST_LIMIT) {
            return Either.Left(DustLimitTooSmall(accept.temporaryChannelId, accept.dustLimit, Channel.MIN_DUST_LIMIT))
        }

        if (accept.dustLimit > nodeParams.maxRemoteDustLimit) {
            return Either.Left(DustLimitTooLarge(accept.temporaryChannelId, accept.dustLimit, nodeParams.maxRemoteDustLimit))
        }

        // if minimum_depth is unreasonably large: MAY reject the channel.
        if (accept.toSelfDelay > Channel.MAX_TO_SELF_DELAY || accept.toSelfDelay > nodeParams.maxToLocalDelayBlocks) {
            return Either.Left(ToSelfDelayTooHigh(accept.temporaryChannelId, accept.toSelfDelay, nodeParams.maxToLocalDelayBlocks))
        }

        return Either.Right(init.channelType)
    }

    /**
     * @param remoteFeerate remote fee rate per kiloweight
     * @return true if the remote fee rate is too small
     */
    private fun isFeeTooSmall(remoteFeerate: FeeratePerKw): Boolean = remoteFeerate < FeeratePerKw.MinimumFeeratePerKw

    /**
     * @param referenceFee reference fee rate per kiloweight
     * @param currentFee current fee rate per kiloweight
     * @param tolerance maximum fee rate mismatch tolerated
     * @return true if the difference between proposed and reference fee rates is too high.
     */
    fun isFeeDiffTooHigh(referenceFee: FeeratePerKw, currentFee: FeeratePerKw, tolerance: FeerateTolerance): Boolean =
        currentFee < referenceFee * tolerance.ratioLow || referenceFee * tolerance.ratioHigh < currentFee

    /**
     * This indicates whether our side of the channel is above the reserve requested by our counterparty. In other words,
     * this tells if we can use the channel to make a payment.
     */
    fun aboveReserve(commitments: Commitments): Boolean = commitments.active.all {
        val remoteCommit = it.nextRemoteCommit?.commit ?: it.remoteCommit
        val toRemote = remoteCommit.spec.toRemote.truncateToSatoshi()
        // NB: this is an approximation (we don't take network fees into account)
        toRemote > it.localChannelReserve(commitments.params)
    }

    /** This helper method will publish txs only if they haven't yet reached minDepth. */
    fun LoggingContext.publishIfNeeded(txs: List, irrevocablySpent: Map): List {
        val (skip, process) = txs.partition { it.tx.inputsAlreadySpent(irrevocablySpent) }
        skip.forEach { tx -> logger.info { "no need to republish txid=${tx.tx.txid}, it has already been confirmed" } }
        return process.map { publish ->
            logger.info(mapOf("txType" to publish.txType)) { "publishing txid=${publish.tx.txid}" }
            publish
        }
    }

    /** This helper method will watch txs only if they haven't yet reached minDepth. */
    fun LoggingContext.watchConfirmedIfNeeded(txs: List, irrevocablySpent: Map, channelId: ByteVector32, minDepth: Long): List {
        val (skip, process) = txs.partition { it.inputsAlreadySpent(irrevocablySpent) }
        skip.forEach { tx -> logger.info { "no need to watch txid=${tx.txid}, it has already been confirmed" } }
        return process.map { tx -> ChannelAction.Blockchain.SendWatch(WatchConfirmed(channelId, tx, minDepth, BITCOIN_TX_CONFIRMED(tx))) }
    }

    /** This helper method will watch txs only if the utxo they spend hasn't already been irrevocably spent. */
    fun LoggingContext.watchSpentIfNeeded(parentTx: Transaction, outputs: List, irrevocablySpent: Map, channelId: ByteVector32): List {
        val (skip, process) = outputs.partition { irrevocablySpent.contains(it) }
        skip.forEach { output -> logger.info { "no need to watch output=${output.txid}:${output.index}, it has already been spent by txid=${irrevocablySpent[output]?.txid}" } }
        return process.map { output ->
            require(output.txid == parentTx.txid) { "output doesn't belong to the given parentTx: txid=${output.txid} but expected txid=${parentTx.txid}" }
            ChannelAction.Blockchain.SendWatch(WatchSpent(channelId, parentTx, output.index.toInt(), BITCOIN_OUTPUT_SPENT))
        }
    }

    object Funding {

        /** Compute the channelId of a dual-funded channel. */
        fun computeChannelId(open: OpenDualFundedChannel, accept: AcceptDualFundedChannel): ByteVector32 {
            return if (LexicographicalOrdering.isLessThan(open.revocationBasepoint.value, accept.revocationBasepoint.value)) {
                (open.revocationBasepoint.value + accept.revocationBasepoint.value).sha256()
            } else {
                (accept.revocationBasepoint.value + open.revocationBasepoint.value).sha256()
            }
        }

        fun makeFundingPubKeyScript(localFundingPubkey: PublicKey, remoteFundingPubkey: PublicKey): ByteVector {
            return write(pay2wsh(multiSig2of2(localFundingPubkey, remoteFundingPubkey))).toByteVector()
        }

        fun makeFundingInputInfo(
            fundingTxId: TxId,
            fundingTxOutputIndex: Int,
            fundingAmount: Satoshi,
            fundingPubkey1: PublicKey,
            fundingPubkey2: PublicKey
        ): Transactions.InputInfo {
            val fundingScript = multiSig2of2(fundingPubkey1, fundingPubkey2)
            val fundingTxOut = TxOut(fundingAmount, pay2wsh(fundingScript))
            return Transactions.InputInfo(
                OutPoint(fundingTxId, fundingTxOutputIndex.toLong()),
                fundingTxOut,
                ByteVector(write(fundingScript))
            )
        }

        data class PairOfCommitTxs(val localSpec: CommitmentSpec, val localCommitTx: Transactions.TransactionWithInputInfo.CommitTx, val localHtlcTxs: List, val remoteSpec: CommitmentSpec, val remoteCommitTx: Transactions.TransactionWithInputInfo.CommitTx, val remoteHtlcTxs: List)

        /**
         * Creates both sides' first commitment transaction.
         *
         * @return (localSpec, localTx, remoteSpec, remoteTx, fundingTxOutput)
         */
        fun makeCommitTxs(
            channelKeys: KeyManager.ChannelKeys,
            channelId: ByteVector32,
            localParams: LocalParams,
            remoteParams: RemoteParams,
            fundingAmount: Satoshi,
            toLocal: MilliSatoshi,
            toRemote: MilliSatoshi,
            localHtlcs: Set,
            localCommitmentIndex: Long,
            remoteCommitmentIndex: Long,
            commitTxFeerate: FeeratePerKw,
            fundingTxIndex: Long,
            fundingTxId: TxId,
            fundingTxOutputIndex: Int,
            remoteFundingPubkey: PublicKey,
            remotePerCommitmentPoint: PublicKey
        ): Either {
            val localSpec = CommitmentSpec(localHtlcs, commitTxFeerate, toLocal = toLocal, toRemote = toRemote)
            val remoteSpec = CommitmentSpec(localHtlcs.map{ it.opposite() }.toSet(), commitTxFeerate, toLocal = toRemote, toRemote = toLocal)

            if (!localParams.paysCommitTxFees) {
                // They are responsible for paying the commitment transaction fee: we need to make sure they can afford it!
                // Note that the reserve may not be always be met: we could be using dual funding with a large funding amount on
                // our side and a small funding amount on their side. But we shouldn't care as long as they can pay the fees for
                // the commitment transaction.
                val fees = commitTxFee(remoteParams.dustLimit, remoteSpec)
                val missing = fees - remoteSpec.toLocal.truncateToSatoshi()
                if (missing > 0.sat) {
                    return Either.Left(CannotAffordFirstCommitFees(channelId, missing = missing, fees = fees))
                }
            }

            val fundingPubKey = channelKeys.fundingPubKey(fundingTxIndex)
            val commitmentInput = makeFundingInputInfo(fundingTxId, fundingTxOutputIndex, fundingAmount, fundingPubKey, remoteFundingPubkey)
            val localPerCommitmentPoint = channelKeys.commitmentPoint(localCommitmentIndex)
            val (localCommitTx, localHtlcTxs) = Commitments.makeLocalTxs(
                channelKeys,
                commitTxNumber = localCommitmentIndex,
                localParams,
                remoteParams,
                fundingTxIndex = fundingTxIndex,
                remoteFundingPubKey = remoteFundingPubkey,
                commitmentInput,
                localPerCommitmentPoint = localPerCommitmentPoint,
                localSpec
            )
            val (remoteCommitTx, remoteHtlcTxs) = Commitments.makeRemoteTxs(
                channelKeys,
                commitTxNumber = remoteCommitmentIndex,
                localParams,
                remoteParams,
                fundingTxIndex = fundingTxIndex,
                remoteFundingPubKey = remoteFundingPubkey,
                commitmentInput,
                remotePerCommitmentPoint = remotePerCommitmentPoint,
                remoteSpec
            )

            return Either.Right(PairOfCommitTxs(localSpec, localCommitTx, localHtlcTxs, remoteSpec, remoteCommitTx, remoteHtlcTxs))
        }

    }

    object Closing {
        // used only to compute tx weights and estimate fees
        private val dummyPublicKey by lazy { PrivateKey(ByteArray(32) { 1.toByte() }).publicKey() }

        private fun isValidFinalScriptPubkey(scriptPubKey: ByteArray, allowAnySegwit: Boolean): Boolean {
            return runTrying {
                val script = Script.parse(scriptPubKey)
                when {
                    Script.isPay2pkh(script) -> true
                    Script.isPay2sh(script) -> true
                    Script.isPay2wpkh(script) -> true
                    Script.isPay2wsh(script) -> true
                    // option_shutdown_anysegwit doesn't cover segwit v0
                    Script.isNativeWitnessScript(script) && script[0] != OP_0 -> allowAnySegwit
                    else -> false
                }
            }.getOrElse { false }
        }

        fun isValidFinalScriptPubkey(scriptPubKey: ByteVector, allowAnySegwit: Boolean): Boolean = isValidFinalScriptPubkey(scriptPubKey.toByteArray(), allowAnySegwit)

        private fun firstClosingFee(commitment: FullCommitment, localScriptPubkey: ByteArray, remoteScriptPubkey: ByteArray, requestedFeerate: ClosingFeerates): ClosingFees {
            // this is just to estimate the weight which depends on the size of the pubkey scripts
            val dummyClosingTx = Transactions.makeClosingTx(commitment.commitInput, localScriptPubkey, remoteScriptPubkey, commitment.params.localParams.paysClosingFees, 0.sat, 0.sat, commitment.localCommit.spec)
            val closingWeight = Transaction.weight(Transactions.addSigs(dummyClosingTx, dummyPublicKey, commitment.remoteFundingPubkey, Transactions.PlaceHolderSig, Transactions.PlaceHolderSig).tx)
            return requestedFeerate.computeFees(closingWeight)
        }

        fun firstClosingFee(commitment: FullCommitment, localScriptPubkey: ByteVector, remoteScriptPubkey: ByteVector, requestedFeerate: ClosingFeerates): ClosingFees =
            firstClosingFee(commitment, localScriptPubkey.toByteArray(), remoteScriptPubkey.toByteArray(), requestedFeerate)

        fun nextClosingFee(localClosingFee: Satoshi, remoteClosingFee: Satoshi): Satoshi = ((localClosingFee + remoteClosingFee) / 4) * 2

        fun makeFirstClosingTx(
            channelKeys: KeyManager.ChannelKeys,
            commitment: FullCommitment,
            localScriptPubkey: ByteArray,
            remoteScriptPubkey: ByteArray,
            requestedFeerate: ClosingFeerates
        ): Pair {
            val closingFees = firstClosingFee(commitment, localScriptPubkey, remoteScriptPubkey, requestedFeerate)
            return makeClosingTx(channelKeys, commitment, localScriptPubkey, remoteScriptPubkey, closingFees)
        }

        fun makeClosingTx(
            channelKeys: KeyManager.ChannelKeys,
            commitment: FullCommitment,
            localScriptPubkey: ByteArray,
            remoteScriptPubkey: ByteArray,
            closingFees: ClosingFees
        ): Pair {
            val allowAnySegwit = Features.canUseFeature(commitment.params.localParams.features, commitment.params.remoteParams.features, Feature.ShutdownAnySegwit)
            require(isValidFinalScriptPubkey(localScriptPubkey, allowAnySegwit)) { "invalid localScriptPubkey" }
            require(isValidFinalScriptPubkey(remoteScriptPubkey, allowAnySegwit)) { "invalid remoteScriptPubkey" }
            val dustLimit = commitment.params.localParams.dustLimit.max(commitment.params.remoteParams.dustLimit)
            val closingTx = Transactions.makeClosingTx(commitment.commitInput, localScriptPubkey, remoteScriptPubkey, commitment.params.localParams.paysClosingFees, dustLimit, closingFees.preferred, commitment.localCommit.spec)
            val localClosingSig = Transactions.sign(closingTx, channelKeys.fundingKey(commitment.fundingTxIndex))
            val closingSigned = ClosingSigned(commitment.channelId, closingFees.preferred, localClosingSig, TlvStream(ClosingSignedTlv.FeeRange(closingFees.min, closingFees.max)))
            return Pair(closingTx, closingSigned)
        }

        fun checkClosingSignature(
            channelKeys: KeyManager.ChannelKeys,
            commitment: FullCommitment,
            localScriptPubkey: ByteArray,
            remoteScriptPubkey: ByteArray,
            remoteClosingFee: Satoshi,
            remoteClosingSig: ByteVector64
        ): Either> {
            val (closingTx, closingSigned) = makeClosingTx(channelKeys, commitment, localScriptPubkey, remoteScriptPubkey, ClosingFees(remoteClosingFee))
            return if (checkClosingDustAmounts(closingTx)) {
                val signedClosingTx = Transactions.addSigs(closingTx, channelKeys.fundingPubKey(commitment.fundingTxIndex), commitment.remoteFundingPubkey, closingSigned.signature, remoteClosingSig)
                when (Transactions.checkSpendable(signedClosingTx)) {
                    is Try.Success -> Either.Right(Pair(signedClosingTx, closingSigned))
                    is Try.Failure -> Either.Left(InvalidCloseSignature(commitment.channelId, signedClosingTx.tx.txid))
                }
            } else {
                Either.Left(InvalidCloseAmountBelowDust(commitment.channelId, closingTx.tx.txid))
            }
        }

        /**
         * Check that all closing outputs are above bitcoin's dust limit for their script type, otherwise there is a risk
         * that the closing transaction will not be relayed to miners' mempool and will not confirm.
         * The various dust limits are detailed in https://github.com/lightningnetwork/lightning-rfc/blob/master/03-transactions.md#dust-limits
         */
        fun checkClosingDustAmounts(closingTx: ClosingTx): Boolean {
            return closingTx.tx.txOut.all { txOut ->
                val publicKeyScript = Script.parse(txOut.publicKeyScript)
                when {
                    Script.isPay2pkh(publicKeyScript) -> txOut.amount >= 546.sat
                    Script.isPay2sh(publicKeyScript) -> txOut.amount >= 540.sat
                    Script.isPay2wpkh(publicKeyScript) -> txOut.amount >= 294.sat
                    Script.isPay2wsh(publicKeyScript) -> txOut.amount >= 330.sat
                    Script.isNativeWitnessScript(publicKeyScript) -> txOut.amount >= 354.sat
                    else -> txOut.amount >= 546.sat
                }
            }
        }

        /**
         * Claim all the outputs that we've received from our current commit tx. This will be done using 2nd stage HTLC transactions.
         *
         * @param commitment our commitment data, which includes payment preimages.
         * @return a list of transactions (one per output that we can claim).
         */
        fun LoggingContext.claimCurrentLocalCommitTxOutputs(channelKeys: KeyManager.ChannelKeys, commitment: FullCommitment, tx: Transaction, feerates: OnChainFeerates): LocalCommitPublished {
            val localCommit = commitment.localCommit
            val localParams = commitment.params.localParams
            require(localCommit.publishableTxs.commitTx.tx.txid == tx.txid) { "txid mismatch, provided tx is not the current local commit tx" }
            val localPerCommitmentPoint = channelKeys.commitmentPoint(commitment.localCommit.index)
            val localRevocationPubkey = commitment.params.remoteParams.revocationBasepoint.deriveForRevocation(localPerCommitmentPoint)
            val localDelayedPubkey = channelKeys.delayedPaymentBasepoint.deriveForCommitment(localPerCommitmentPoint)
            val feerateDelayed = feerates.claimMainFeerate

            // first we will claim our main output as soon as the delay is over
            val mainDelayedTx = generateTx("main-delayed-output") {
                Transactions.makeClaimLocalDelayedOutputTx(
                    tx,
                    localParams.dustLimit,
                    localRevocationPubkey,
                    commitment.params.remoteParams.toSelfDelay,
                    localDelayedPubkey,
                    localParams.defaultFinalScriptPubKey.toByteArray(),
                    feerateDelayed
                )
            }?.let {
                val sig = Transactions.sign(it, channelKeys.delayedPaymentKey.deriveForCommitment(localPerCommitmentPoint), SigHash.SIGHASH_ALL)
                Transactions.addSigs(it, sig)
            }

            // those are the preimages to existing received htlcs
            val preimages = commitment.changes.localChanges.all.filterIsInstance().map { it.paymentPreimage }

            val htlcTxs = localCommit.publishableTxs.htlcTxsAndSigs.associate { (txInfo, localSig, remoteSig) ->
                when (txInfo) {
                    is HtlcSuccessTx -> when (val preimage = preimages.firstOrNull { r -> r.sha256() == txInfo.paymentHash }) {
                        // incoming htlc for which we don't have the preimage: we can't spend it immediately, but we may learn the
                        // preimage later, otherwise it will eventually timeout and they will get their funds back
                        null -> Pair(txInfo.input.outPoint, null)
                        // incoming htlc for which we have the preimage: we can spend it directly
                        else -> Pair(txInfo.input.outPoint, Transactions.addSigs(txInfo, localSig, remoteSig, preimage))
                    }
                    // outgoing htlc: they may or may not have the preimage, the only thing to do is try to get back our funds after timeout
                    is HtlcTimeoutTx -> Pair(txInfo.input.outPoint, Transactions.addSigs(txInfo, localSig, remoteSig))
                }
            }

            // all htlc output to us are delayed, so we need to claim them as soon as the delay is over
            val htlcDelayedTxs = htlcTxs.values.filterNotNull().mapNotNull { txInfo ->
                generateTx("claim-htlc-delayed") {
                    Transactions.makeClaimLocalDelayedOutputTx(
                        txInfo.tx,
                        localParams.dustLimit,
                        localRevocationPubkey,
                        commitment.params.remoteParams.toSelfDelay,
                        localDelayedPubkey,
                        localParams.defaultFinalScriptPubKey.toByteArray(),
                        feerateDelayed
                    )
                }?.let {
                    val sig = Transactions.sign(it, channelKeys.delayedPaymentKey.deriveForCommitment(localPerCommitmentPoint), SigHash.SIGHASH_ALL)
                    Transactions.addSigs(it, sig)
                }
            }

            return LocalCommitPublished(
                commitTx = tx,
                claimMainDelayedOutputTx = mainDelayedTx,
                htlcTxs = htlcTxs,
                claimHtlcDelayedTxs = htlcDelayedTxs,
                claimAnchorTxs = emptyList(),
                irrevocablySpent = emptyMap()
            )
        }

        /**
         * Claim all the outputs that we've received from their current commit tx.
         *
         * @param commitment our commitment data, which includes payment preimages.
         * @param remoteCommit the remote commitment data to use to claim outputs (it can be their current or next commitment).
         * @param tx the remote commitment transaction that has just been published.
         * @return a list of transactions (one per output that we can claim).
         */
        fun LoggingContext.claimRemoteCommitTxOutputs(channelKeys: KeyManager.ChannelKeys, commitment: FullCommitment, remoteCommit: RemoteCommit, tx: Transaction, feerates: OnChainFeerates): RemoteCommitPublished {
            val localParams = commitment.params.localParams
            val remoteParams = commitment.params.remoteParams
            val commitInput = commitment.commitInput
            val (remoteCommitTx, _) = Commitments.makeRemoteTxs(
                channelKeys,
                commitTxNumber = remoteCommit.index,
                localParams,
                remoteParams,
                fundingTxIndex = commitment.fundingTxIndex,
                remoteFundingPubKey = commitment.remoteFundingPubkey,
                commitInput,
                remoteCommit.remotePerCommitmentPoint,
                remoteCommit.spec
            )
            require(remoteCommitTx.tx.txid == tx.txid) { "txid mismatch, provided tx is not the current remote commit tx" }

            val localPaymentPubkey = channelKeys.paymentBasepoint
            val localHtlcPubkey = channelKeys.htlcBasepoint.deriveForCommitment(remoteCommit.remotePerCommitmentPoint)
            val remoteDelayedPaymentPubkey = remoteParams.delayedPaymentBasepoint.deriveForCommitment(remoteCommit.remotePerCommitmentPoint)
            val remoteHtlcPubkey = remoteParams.htlcBasepoint.deriveForCommitment(remoteCommit.remotePerCommitmentPoint)
            val remoteRevocationPubkey = channelKeys.revocationBasepoint.deriveForRevocation(remoteCommit.remotePerCommitmentPoint)
            val outputs = makeCommitTxOutputs(
                commitment.remoteFundingPubkey,
                channelKeys.fundingPubKey(commitment.fundingTxIndex),
                !localParams.paysCommitTxFees,
                remoteParams.dustLimit,
                remoteRevocationPubkey,
                localParams.toSelfDelay,
                remoteDelayedPaymentPubkey,
                localPaymentPubkey,
                remoteHtlcPubkey,
                localHtlcPubkey,
                remoteCommit.spec
            )

            // we need to use a rather high fee for htlc-claim because we compete with the counterparty
            val feerateClaimHtlc = feerates.fastFeerate

            // those are the preimages to existing received htlcs
            val preimages = commitment.changes.localChanges.all.filterIsInstance().map { it.paymentPreimage }

            // remember we are looking at the remote commitment so IN for them is really OUT for us and vice versa
            val claimHtlcTxs = remoteCommit.spec.htlcs.mapNotNull { htlc ->
                when (htlc) {
                    is OutgoingHtlc -> {
                        generateTx("claim-htlc-success") {
                            Transactions.makeClaimHtlcSuccessTx(
                                remoteCommitTx.tx,
                                outputs,
                                localParams.dustLimit,
                                localHtlcPubkey,
                                remoteHtlcPubkey,
                                remoteRevocationPubkey,
                                localParams.defaultFinalScriptPubKey.toByteArray(),
                                htlc.add,
                                feerateClaimHtlc
                            )
                        }?.let { claimHtlcTx ->
                            when (val preimage = preimages.firstOrNull { r -> r.sha256() == htlc.add.paymentHash }) {
                                // incoming htlc for which we don't have the preimage: we can't spend it immediately, but we may learn the
                                // preimage later, otherwise it will eventually timeout and they will get their funds back
                                null -> Pair(claimHtlcTx.input.outPoint, null)
                                // incoming htlc for which we have the preimage: we can spend it directly
                                else -> {
                                    val sig = Transactions.sign(claimHtlcTx, channelKeys.htlcKey.deriveForCommitment(remoteCommit.remotePerCommitmentPoint), SigHash.SIGHASH_ALL)
                                    Pair(claimHtlcTx.input.outPoint, Transactions.addSigs(claimHtlcTx, sig, preimage))
                                }
                            }
                        }
                    }
                    is IncomingHtlc -> {
                        // outgoing htlc: they may or may not have the preimage, the only thing to do is try to get back our funds after timeout
                        generateTx("claim-htlc-timeout") {
                            Transactions.makeClaimHtlcTimeoutTx(
                                remoteCommitTx.tx,
                                outputs,
                                localParams.dustLimit,
                                localHtlcPubkey,
                                remoteHtlcPubkey,
                                remoteRevocationPubkey,
                                localParams.defaultFinalScriptPubKey.toByteArray(),
                                htlc.add,
                                feerateClaimHtlc
                            )
                        }?.let { claimHtlcTx ->
                            val sig = Transactions.sign(claimHtlcTx, channelKeys.htlcKey.deriveForCommitment(remoteCommit.remotePerCommitmentPoint), SigHash.SIGHASH_ALL)
                            Pair(claimHtlcTx.input.outPoint, Transactions.addSigs(claimHtlcTx, sig))
                        }
                    }
                }
            }.toMap()

            // we claim our output and add the htlc txs we just created
            return claimRemoteCommitMainOutput(channelKeys, commitment.params, tx, feerates.claimMainFeerate).copy(claimHtlcTxs = claimHtlcTxs)
        }

        /**
         * Claim our main output only from their commit tx.
         *
         * @param tx the remote commitment transaction that has just been published.
         * @return a transaction to claim our main output.
         */
        internal fun LoggingContext.claimRemoteCommitMainOutput(channelKeys: KeyManager.ChannelKeys, params: ChannelParams, tx: Transaction, claimMainFeerate: FeeratePerKw): RemoteCommitPublished {
            val localPaymentPoint = channelKeys.paymentBasepoint

            val mainTx = generateTx("claim-remote-delayed-output") {
                Transactions.makeClaimRemoteDelayedOutputTx(
                    tx,
                    params.localParams.dustLimit,
                    localPaymentPoint,
                    params.localParams.defaultFinalScriptPubKey,
                    claimMainFeerate
                )
            }?.let {
                val sig = Transactions.sign(it, channelKeys.paymentKey)
                Transactions.addSigs(it, sig)
            }

            return RemoteCommitPublished(commitTx = tx, claimMainOutputTx = mainTx)
        }

        /**
         * When an unexpected transaction spending the funding tx is detected, we must be in one of the following scenarios:
         *
         *  - it is a revoked commitment: we then extract the remote per-commitment secret and publish penalty transactions
         *  - it is a future commitment: if we lost future state, our peer could publish a future commitment (which may be
         *    revoked, but we won't be able to know because we lost the corresponding state)
         *  - it is not a valid commitment transaction: if our peer was able to steal our funding private key, they can
         *    spend the funding transaction however they want, and we won't be able to do anything about it
         *
         * This function returns the per-commitment secret in the first case, and null in the other cases.
         */
        fun getRemotePerCommitmentSecret(channelKeys: KeyManager.ChannelKeys, params: ChannelParams, remotePerCommitmentSecrets: ShaChain, tx: Transaction): Pair? {
            // a valid tx will always have at least one input, but this ensures we don't throw in tests
            val sequence = tx.txIn.first().sequence
            val obscuredTxNumber = Transactions.decodeTxNumber(sequence, tx.lockTime)
            val localPaymentPoint = channelKeys.paymentBasepoint
            // this tx has been published by remote, so we need to invert local/remote params
            val commitmentNumber = Transactions.obscuredCommitTxNumber(obscuredTxNumber, !params.localParams.isChannelOpener, params.remoteParams.paymentBasepoint, localPaymentPoint)
            if (commitmentNumber > 0xffffffffffffL) {
                // txNumber must be lesser than 48 bits long
                return null
            }
            // now we know what commit number this tx is referring to, we can derive the commitment point from the shachain
            val hash = remotePerCommitmentSecrets.getHash(0xFFFFFFFFFFFFL - commitmentNumber) ?: return null
            return Pair(PrivateKey(hash), commitmentNumber)
        }

        /**
         * When a revoked commitment transaction spending the funding tx is detected, we build a set of transactions that
         * will punish our peer by stealing all their funds.
         */
        fun LoggingContext.claimRevokedRemoteCommitTxOutputs(channelKeys: KeyManager.ChannelKeys, params: ChannelParams, remotePerCommitmentSecret: PrivateKey, commitTx: Transaction, feerates: OnChainFeerates): RevokedCommitPublished {
            val localPaymentPoint = channelKeys.paymentBasepoint
            val remotePerCommitmentPoint = remotePerCommitmentSecret.publicKey()
            val remoteDelayedPaymentPubkey = params.remoteParams.delayedPaymentBasepoint.deriveForCommitment(remotePerCommitmentPoint)
            val remoteRevocationPubkey = channelKeys.revocationBasepoint.deriveForRevocation(remotePerCommitmentPoint)

            val feerateMain = feerates.claimMainFeerate
            // we need to use a high fee here for punishment txs because after a delay they can be spent by the counterparty
            val feeratePenalty = feerates.fastFeerate

            // first we will claim our main output right away
            val mainTx = generateTx("claim-remote-delayed-output") {
                Transactions.makeClaimRemoteDelayedOutputTx(
                    commitTx,
                    params.localParams.dustLimit,
                    localPaymentPoint,
                    params.localParams.defaultFinalScriptPubKey,
                    feerateMain
                )
            }?.let {
                val sig = Transactions.sign(it, channelKeys.paymentKey)
                Transactions.addSigs(it, sig)
            }

            // then we punish them by stealing their main output
            val mainPenaltyTx = generateTx("main-penalty") {
                Transactions.makeMainPenaltyTx(
                    commitTx,
                    params.localParams.dustLimit,
                    remoteRevocationPubkey,
                    params.localParams.defaultFinalScriptPubKey.toByteArray(),
                    params.localParams.toSelfDelay,
                    remoteDelayedPaymentPubkey,
                    feeratePenalty
                )
            }?.let {
                val sig = Transactions.sign(it, channelKeys.revocationKey.deriveForRevocation(remotePerCommitmentSecret))
                Transactions.addSigs(it, sig)
            }

            return RevokedCommitPublished(commitTx = commitTx, remotePerCommitmentSecret = remotePerCommitmentSecret, claimMainOutputTx = mainTx, mainPenaltyTx = mainPenaltyTx)
        }

        /**
         * Once we've fetched htlc information for a revoked commitment from the DB, we create penalty transactions to claim all htlc outputs.
         */
        fun LoggingContext.claimRevokedRemoteCommitTxHtlcOutputs(
            channelKeys: KeyManager.ChannelKeys,
            params: ChannelParams,
            revokedCommitPublished: RevokedCommitPublished,
            feerates: OnChainFeerates,
            htlcInfos: List
        ): RevokedCommitPublished {
            // we need to use a high fee here for punishment txs because after a delay they can be spent by the counterparty
            val feeratePenalty = feerates.fastFeerate
            val remotePerCommitmentPoint = revokedCommitPublished.remotePerCommitmentSecret.publicKey()
            val remoteRevocationPubkey = channelKeys.revocationBasepoint.deriveForRevocation(remotePerCommitmentPoint)
            val remoteHtlcPubkey = params.remoteParams.htlcBasepoint.deriveForCommitment(remotePerCommitmentPoint)
            val localHtlcPubkey = channelKeys.htlcBasepoint.deriveForCommitment(remotePerCommitmentPoint)

            // we retrieve the information needed to rebuild htlc scripts
            logger.info { "found ${htlcInfos.size} htlcs for txid=${revokedCommitPublished.commitTx.txid}" }
            val htlcsRedeemScripts = htlcInfos.flatMap { htlcInfo ->
                val htlcReceived = Scripts.htlcReceived(remoteHtlcPubkey, localHtlcPubkey, remoteRevocationPubkey, ripemd160(htlcInfo.paymentHash), htlcInfo.cltvExpiry)
                val htlcOffered = Scripts.htlcOffered(remoteHtlcPubkey, localHtlcPubkey, remoteRevocationPubkey, ripemd160(htlcInfo.paymentHash))
                listOf(htlcReceived, htlcOffered)
            }.associate { redeemScript -> write(pay2wsh(redeemScript)).toByteVector() to write(redeemScript).toByteVector() }

            // and finally we steal the htlc outputs
            val htlcPenaltyTxs = revokedCommitPublished.commitTx.txOut.mapIndexedNotNull { outputIndex, txOut ->
                htlcsRedeemScripts[txOut.publicKeyScript]?.let { redeemScript ->
                    generateTx("htlc-penalty") {
                        Transactions.makeHtlcPenaltyTx(
                            revokedCommitPublished.commitTx,
                            outputIndex,
                            redeemScript.toByteArray(),
                            params.localParams.dustLimit,
                            params.localParams.defaultFinalScriptPubKey.toByteArray(),
                            feeratePenalty
                        )
                    }?.let { htlcPenaltyTx ->
                        val sig = Transactions.sign(htlcPenaltyTx, channelKeys.revocationKey.deriveForRevocation(revokedCommitPublished.remotePerCommitmentSecret))
                        Transactions.addSigs(htlcPenaltyTx, sig, remoteRevocationPubkey)
                    }
                }
            }

            return revokedCommitPublished.copy(htlcPenaltyTxs = htlcPenaltyTxs)
        }

        /**
         * Claims the output of an [[HtlcSuccessTx]] or [[HtlcTimeoutTx]] transaction using a revocation key.
         *
         * In case a revoked commitment with pending HTLCs is published, there are two ways the HTLC outputs can be taken as punishment:
         * - by spending the corresponding output of the commitment tx, using [[ClaimHtlcDelayedOutputPenaltyTx]] that we generate as soon as we detect that a revoked commit
         * has been spent; note that those transactions will compete with [[HtlcSuccessTx]] and [[HtlcTimeoutTx]] published by the counterparty.
         * - by spending the delayed output of [[HtlcSuccessTx]] and [[HtlcTimeoutTx]] if those get confirmed; because the output of these txs is protected by
         * an OP_CSV delay, we will have time to spend them with a revocation key. In that case, we generate the spending transactions "on demand",
         * this is the purpose of this method.
         *
         * NB: when anchor outputs is used, htlc transactions can be aggregated in a single transaction if they share the same
         * lockTime (thanks to the use of sighash_single | sighash_anyonecanpay), so we may need to claim multiple outputs.
         */
        fun LoggingContext.claimRevokedHtlcTxOutputs(
            channelKeys: KeyManager.ChannelKeys,
            params: ChannelParams,
            revokedCommitPublished: RevokedCommitPublished,
            htlcTx: Transaction,
            feerates: OnChainFeerates
        ): Pair> {
            val claimTxs = buildList {
                revokedCommitPublished.claimMainOutputTx?.let { add(it) }
                revokedCommitPublished.mainPenaltyTx?.let { add(it) }
                addAll(revokedCommitPublished.htlcPenaltyTxs)
            }
            val isHtlcTx = htlcTx.txIn.any { it.outPoint.txid == revokedCommitPublished.commitTx.txid } && !claimTxs.any { it.tx.txid == htlcTx.txid }
            if (isHtlcTx) {
                logger.info { "looks like txid=${htlcTx.txid} could be a 2nd level htlc tx spending revoked commit txid=${revokedCommitPublished.commitTx.txid}" }
                // Let's assume that htlcTx is an HtlcSuccessTx or HtlcTimeoutTx and try to generate a tx spending its output using a revocation key
                val remotePerCommitmentPoint = revokedCommitPublished.remotePerCommitmentSecret.publicKey()
                val remoteDelayedPaymentPubkey = params.remoteParams.delayedPaymentBasepoint.deriveForCommitment(remotePerCommitmentPoint)
                val remoteRevocationPubkey = channelKeys.revocationBasepoint.deriveForRevocation(remotePerCommitmentPoint)

                // we need to use a high fee here for punishment txs because after a delay they can be spent by the counterparty
                val feeratePenalty = feerates.fastFeerate

                val penaltyTxs = Transactions.makeClaimDelayedOutputPenaltyTxs(
                    htlcTx,
                    params.localParams.dustLimit,
                    remoteRevocationPubkey,
                    params.localParams.toSelfDelay,
                    remoteDelayedPaymentPubkey,
                    params.localParams.defaultFinalScriptPubKey.toByteArray(),
                    feeratePenalty
                ).mapNotNull { claimDelayedOutputPenaltyTx ->
                    generateTx("claim-htlc-delayed-penalty") {
                        claimDelayedOutputPenaltyTx
                    }?.let {
                        val sig = Transactions.sign(it, channelKeys.revocationKey.deriveForRevocation(revokedCommitPublished.remotePerCommitmentSecret))
                        val signedTx = Transactions.addSigs(it, sig)
                        // we need to make sure that the tx is indeed valid
                        when (runTrying { signedTx.tx.correctlySpends(listOf(htlcTx), ScriptFlags.STANDARD_SCRIPT_VERIFY_FLAGS) }) {
                            is Try.Success -> signedTx
                            is Try.Failure -> null
                        }
                    }
                }

                return revokedCommitPublished.copy(claimHtlcDelayedPenaltyTxs = revokedCommitPublished.claimHtlcDelayedPenaltyTxs + penaltyTxs) to penaltyTxs
            } else {
                return revokedCommitPublished to listOf()
            }
        }

        /**
         * In CLOSING state, any time we see a new transaction, we try to extract a preimage from it in order to fulfill the
         * corresponding incoming htlc in an upstream channel.
         *
         * Not doing that would result in us losing money, because the downstream node would pull money from one side, and
         * the upstream node would get refunded after a timeout.
         *
         * @return a set of pairs (add, preimage) if extraction was successful:
         *           - add is the htlc in the downstream channel from which we extracted the preimage
         *           - preimage needs to be sent to the upstream channel
         */
        fun LoggingContext.extractPreimages(localCommit: LocalCommit, tx: Transaction): Set> {
            val htlcSuccess = tx.txIn.map { it.witness }.mapNotNull(Scripts.extractPreimageFromHtlcSuccess())
                .onEach { logger.info { "extracted paymentPreimage=$it from tx=$tx (htlc-success)" } }
            val claimHtlcSuccess = tx.txIn.map { it.witness }.mapNotNull(Scripts.extractPreimageFromClaimHtlcSuccess())
                .onEach { logger.info { "extracted paymentPreimage=$it from tx=$tx (claim-htlc-success)" } }
            val paymentPreimages = (htlcSuccess + claimHtlcSuccess).toSet()

            return paymentPreimages.flatMap { paymentPreimage ->
                // we only consider htlcs in our local commitment, because we only care about outgoing htlcs, which disappear first in the remote commitment
                // if an outgoing htlc is in the remote commitment, then:
                // - either it is in the local commitment (it was never fulfilled)
                // - or we have already received the fulfill and forwarded it upstream
                localCommit.spec.htlcs.filter { it is OutgoingHtlc && it.add.paymentHash.contentEquals(sha256(paymentPreimage)) }.map { it.add to paymentPreimage }
            }.toSet()
        }

        /**
         * In CLOSING state, when we are notified that a transaction has been confirmed, we analyze it to find out if one or
         * more htlcs have timed out and need to be failed in an upstream channel.
         *
         * @param tx a tx that has reached min_depth
         * @return a set of htlcs that need to be failed upstream
         */
        fun LoggingContext.timedOutHtlcs(localCommit: LocalCommit, localCommitPublished: LocalCommitPublished, localDustLimit: Satoshi, tx: Transaction): Set {
            val untrimmedHtlcs = Transactions.trimOfferedHtlcs(localDustLimit, localCommit.spec).map { it.add }
            return when {
                tx.txid == localCommit.publishableTxs.commitTx.tx.txid -> {
                    // the tx is a commitment tx, we can immediately fail all dust htlcs (they don't have an output in the tx)
                    (localCommit.spec.htlcs.outgoings() - untrimmedHtlcs.toSet()).toSet()
                }
                localCommitPublished.isHtlcTimeout(tx) -> {
                    // maybe this is a timeout tx, in that case we can resolve and fail the corresponding htlc
                    tx.txIn.mapNotNull { txIn ->
                        when (val htlcTx = localCommitPublished.htlcTxs[txIn.outPoint]) {
                            is HtlcTimeoutTx -> when (val htlc = untrimmedHtlcs.find { it.id == htlcTx.htlcId }) {
                                null -> {
                                    logger.error { "could not find htlc #${htlcTx.htlcId} for htlc-timeout tx=$tx" }
                                    null
                                }
                                else -> {
                                    logger.info { "htlc-timeout tx for htlc #${htlc.id} paymentHash=${htlc.paymentHash} expiry=${tx.lockTime} has been confirmed (tx=$tx)" }
                                    htlc
                                }
                            }
                            else -> null
                        }
                    }.toSet()
                }
                else -> emptySet()
            }
        }

        /**
         * In CLOSING state, when we are notified that a transaction has been confirmed, we analyze it to find out if one or
         * more htlcs have timed out and need to be failed in an upstream channel.
         *
         * @param tx a tx that has reached min_depth
         * @return a set of htlcs that need to be failed upstream
         */
        fun LoggingContext.timedOutHtlcs(remoteCommit: RemoteCommit, remoteCommitPublished: RemoteCommitPublished, remoteDustLimit: Satoshi, tx: Transaction): Set {
            val untrimmedHtlcs = Transactions.trimReceivedHtlcs(remoteDustLimit, remoteCommit.spec).map { it.add }
            return when {
                tx.txid == remoteCommit.txid -> {
                    // the tx is a commitment tx, we can immediately fail all dust htlcs (they don't have an output in the tx)
                    (remoteCommit.spec.htlcs.incomings() - untrimmedHtlcs.toSet()).toSet()
                }
                remoteCommitPublished.isClaimHtlcTimeout(tx) -> {
                    // maybe this is a timeout tx, in that case we can resolve and fail the corresponding htlc
                    tx.txIn.mapNotNull { txIn ->
                        when (val htlcTx = remoteCommitPublished.claimHtlcTxs[txIn.outPoint]) {
                            is ClaimHtlcTimeoutTx -> when (val htlc = untrimmedHtlcs.find { it.id == htlcTx.htlcId }) {
                                null -> {
                                    logger.error { "could not find htlc #${htlcTx.htlcId} for claim-htlc-timeout tx=$tx" }
                                    null
                                }
                                else -> {
                                    logger.info { "claim-htlc-timeout tx for htlc #${htlc.id} paymentHash=${htlc.paymentHash} expiry=${tx.lockTime} has been confirmed (tx=$tx)" }
                                    htlc
                                }
                            }
                            else -> null
                        }
                    }.toSet()
                }
                else -> emptySet()
            }
        }

        /**
         * As soon as a local or remote commitment reaches min_depth, we know which htlcs will be settled on-chain (whether
         * or not they actually have an output in the commitment tx).
         *
         * @param tx a transaction that is sufficiently buried in the blockchain
         */
        fun onChainOutgoingHtlcs(localCommit: LocalCommit, remoteCommit: RemoteCommit, nextRemoteCommit: RemoteCommit?, tx: Transaction): Set = when {
            localCommit.publishableTxs.commitTx.tx.txid == tx.txid -> localCommit.spec.htlcs.outgoings().toSet()
            remoteCommit.txid == tx.txid -> remoteCommit.spec.htlcs.incomings().toSet()
            nextRemoteCommit?.txid == tx.txid -> nextRemoteCommit.spec.htlcs.incomings().toSet()
            else -> emptySet()
        }

        /**
         * If a commitment tx reaches min_depth, we need to fail the outgoing htlcs that will never reach the blockchain.
         * It could be because only us had signed them, or because a revoked commitment got confirmed.
         */
        fun overriddenOutgoingHtlcs(localCommit: LocalCommit, remoteCommit: RemoteCommit, nextRemoteCommit: RemoteCommit?, revokedCommitPublished: List, tx: Transaction): Set = when {
            localCommit.publishableTxs.commitTx.tx.txid == tx.txid -> {
                // our commit got confirmed, so any htlc that is in their commitment but not in ours will never reach the chain
                val htlcsInRemoteCommit = remoteCommit.spec.htlcs + nextRemoteCommit?.spec?.htlcs.orEmpty()
                // NB: from the point of view of the remote, their incoming htlcs are our outgoing htlcs
                htlcsInRemoteCommit.incomings().toSet() - localCommit.spec.htlcs.outgoings().toSet()
            }
            revokedCommitPublished.map { it.commitTx.txid }.contains(tx.txid) -> {
                // a revoked commitment got confirmed: we will claim its outputs, but we also need to fail htlcs that are pending in the latest commitment
                (nextRemoteCommit ?: remoteCommit).spec.htlcs.incomings().toSet()
            }
            remoteCommit.txid == tx.txid -> when (nextRemoteCommit) {
                null -> emptySet() // their last commitment got confirmed, so no htlcs will be overridden, they will timeout or be fulfilled on chain
                else -> {
                    // we had signed a new commitment but they committed the previous one
                    // any htlc that we signed in the new commitment that they didn't sign will never reach the chain
                    nextRemoteCommit.spec.htlcs.incomings().toSet() - localCommit.spec.htlcs.outgoings().toSet()
                }
            }
            else -> emptySet()
        }

        /**
         * This helper function tells if the utxos consumed by the given transaction has already been irrevocably spent (possibly by this very transaction)
         *
         * It can be useful to:
         *   - not attempt to publish this tx when we know this will fail
         *   - not watch for confirmations if we know the tx is already confirmed
         *   - not watch the corresponding utxo when we already know the final spending tx
         *
         * @param irrevocablySpent a map of known spent outpoints
         * @return true if we know for sure that the utxos consumed by the tx have already irrevocably been spent, false otherwise
         */
        fun Transaction.inputsAlreadySpent(irrevocablySpent: Map): Boolean {
            // NB: some transactions may have multiple inputs (e.g. htlc txs)
            val outPoints = txIn.map { it.outPoint }
            return outPoints.any { irrevocablySpent.contains(it) }
        }

        /**
         * Wraps transaction generation in a Try and filters failures to avoid one transaction negatively impacting a whole commitment.
         */
        private fun  LoggingContext.generateTx(desc: String, attempt: () -> Transactions.TxResult): T? =
            when (val result = runTrying { attempt() }) {
                is Try.Success -> when (val txResult = result.get()) {
                    is Transactions.TxResult.Success -> {
                        logger.info { "tx generation success: desc=$desc txid=${txResult.result.tx.txid} amount=${txResult.result.tx.txOut.map { it.amount }.sum()} tx=${txResult.result.tx}" }
                        txResult.result
                    }
                    is Transactions.TxResult.Skipped -> {
                        logger.info { "tx generation skipped: desc=$desc reason: ${txResult.why}" }
                        null
                    }
                }
                is Try.Failure -> {
                    logger.warning { "tx generation failure: desc=$desc reason: ${result.error.message}" }
                    null
                }
            }
    }
}




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