Beispiel #1
0
CAmount GetDustThreshold(const CTxOut& txout, const CFeeRate& dustRelayFeeIn)
{
    // "Dust" is defined in terms of dustRelayFee,
    // which has units satoshis-per-kilobyte.
    // If you'd pay more than 1/3 in fees
    // to spend something, then we consider it dust.
    // A typical spendable non-segwit txout is 34 bytes big, and will
    // need a CTxIn of at least 148 bytes to spend:
    // so dust is a spendable txout less than
    // 546*dustRelayFee/1000 (in satoshis).
    // A typical spendable segwit txout is 31 bytes big, and will
    // need a CTxIn of at least 67 bytes to spend:
    // so dust is a spendable txout less than
    // 294*dustRelayFee/1000 (in satoshis).
    if (txout.scriptPubKey.IsUnspendable())
        return 0;

    size_t nSize = GetSerializeSize(txout, SER_DISK, 0);
    int witnessversion = 0;
    std::vector<unsigned char> witnessprogram;

    if (txout.scriptPubKey.IsWitnessProgram(witnessversion, witnessprogram)) {
        // sum the sizes of the parts of a transaction input
        // with 75% segwit discount applied to the script size.
        nSize += (32 + 4 + 1 + (107 / WITNESS_SCALE_FACTOR) + 4);
    } else {
        nSize += (32 + 4 + 1 + 107 + 4); // the 148 mentioned above
    }

    return 3 * dustRelayFeeIn.GetFee(nSize);
}
Beispiel #2
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// Test suite for ancestor feerate transaction selection.
// Implemented as an additional function, rather than a separate test case,
// to allow reusing the blockchain created in CreateNewBlock_validity.
void TestPackageSelection(const CChainParams& chainparams, CScript scriptPubKey, std::vector<CTransactionRef>& txFirst)
{
    // Test the ancestor feerate transaction selection.
    TestMemPoolEntryHelper entry;

    // Test that a medium fee transaction will be selected after a higher fee
    // rate package with a low fee rate parent.
    CMutableTransaction tx;
    tx.vin.resize(1);
    tx.vin[0].scriptSig = CScript() << OP_1;
    tx.vin[0].prevout.hash = txFirst[0]->GetHash();
    tx.vin[0].prevout.n = 0;
    tx.vout.resize(1);
    tx.vout[0].nValue = 5000000000LL - 1000;
    // This tx has a low fee: 1000 satoshis
    uint256 hashParentTx = tx.GetHash(); // save this txid for later use
    mempool.addUnchecked(hashParentTx, entry.Fee(1000).Time(GetTime()).SpendsCoinbase(true).FromTx(tx));

    // This tx has a medium fee: 10000 satoshis
    tx.vin[0].prevout.hash = txFirst[1]->GetHash();
    tx.vout[0].nValue = 5000000000LL - 10000;
    uint256 hashMediumFeeTx = tx.GetHash();
    mempool.addUnchecked(hashMediumFeeTx, entry.Fee(10000).Time(GetTime()).SpendsCoinbase(true).FromTx(tx));

    // This tx has a high fee, but depends on the first transaction
    tx.vin[0].prevout.hash = hashParentTx;
    tx.vout[0].nValue = 5000000000LL - 1000 - 50000; // 50k satoshi fee
    uint256 hashHighFeeTx = tx.GetHash();
    mempool.addUnchecked(hashHighFeeTx, entry.Fee(50000).Time(GetTime()).SpendsCoinbase(false).FromTx(tx));

    std::unique_ptr<CBlockTemplate> pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    BOOST_CHECK(pblocktemplate->block.vtx[1]->GetHash() == hashParentTx);
    BOOST_CHECK(pblocktemplate->block.vtx[2]->GetHash() == hashHighFeeTx);
    BOOST_CHECK(pblocktemplate->block.vtx[3]->GetHash() == hashMediumFeeTx);

    // Test that a package below the block min tx fee doesn't get included
    tx.vin[0].prevout.hash = hashHighFeeTx;
    tx.vout[0].nValue = 5000000000LL - 1000 - 50000; // 0 fee
    uint256 hashFreeTx = tx.GetHash();
    mempool.addUnchecked(hashFreeTx, entry.Fee(0).FromTx(tx));
    size_t freeTxSize = ::GetSerializeSize(tx, SER_NETWORK, PROTOCOL_VERSION);

    // Calculate a fee on child transaction that will put the package just
    // below the block min tx fee (assuming 1 child tx of the same size).
    CAmount feeToUse = blockMinFeeRate.GetFee(2*freeTxSize) - 1;

    tx.vin[0].prevout.hash = hashFreeTx;
    tx.vout[0].nValue = 5000000000LL - 1000 - 50000 - feeToUse;
    uint256 hashLowFeeTx = tx.GetHash();
    mempool.addUnchecked(hashLowFeeTx, entry.Fee(feeToUse).FromTx(tx));
    pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    // Verify that the free tx and the low fee tx didn't get selected
    for (size_t i=0; i<pblocktemplate->block.vtx.size(); ++i) {
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashFreeTx);
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashLowFeeTx);
    }

    // Test that packages above the min relay fee do get included, even if one
    // of the transactions is below the min relay fee
    // Remove the low fee transaction and replace with a higher fee transaction
    mempool.removeRecursive(tx);
    tx.vout[0].nValue -= 2; // Now we should be just over the min relay fee
    hashLowFeeTx = tx.GetHash();
    mempool.addUnchecked(hashLowFeeTx, entry.Fee(feeToUse+2).FromTx(tx));
    pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    BOOST_CHECK(pblocktemplate->block.vtx[4]->GetHash() == hashFreeTx);
    BOOST_CHECK(pblocktemplate->block.vtx[5]->GetHash() == hashLowFeeTx);

    // Test that transaction selection properly updates ancestor fee
    // calculations as ancestor transactions get included in a block.
    // Add a 0-fee transaction that has 2 outputs.
    tx.vin[0].prevout.hash = txFirst[2]->GetHash();
    tx.vout.resize(2);
    tx.vout[0].nValue = 5000000000LL - 100000000;
    tx.vout[1].nValue = 100000000; // 1BTC output
    uint256 hashFreeTx2 = tx.GetHash();
    mempool.addUnchecked(hashFreeTx2, entry.Fee(0).SpendsCoinbase(true).FromTx(tx));

    // This tx can't be mined by itself
    tx.vin[0].prevout.hash = hashFreeTx2;
    tx.vout.resize(1);
    feeToUse = blockMinFeeRate.GetFee(freeTxSize);
    tx.vout[0].nValue = 5000000000LL - 100000000 - feeToUse;
    uint256 hashLowFeeTx2 = tx.GetHash();
    mempool.addUnchecked(hashLowFeeTx2, entry.Fee(feeToUse).SpendsCoinbase(false).FromTx(tx));
    pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);

    // Verify that this tx isn't selected.
    for (size_t i=0; i<pblocktemplate->block.vtx.size(); ++i) {
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashFreeTx2);
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashLowFeeTx2);
    }

    // This tx will be mineable, and should cause hashLowFeeTx2 to be selected
    // as well.
    tx.vin[0].prevout.n = 1;
    tx.vout[0].nValue = 100000000 - 10000; // 10k satoshi fee
    mempool.addUnchecked(tx.GetHash(), entry.Fee(10000).FromTx(tx));
    pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    BOOST_CHECK(pblocktemplate->block.vtx[8]->GetHash() == hashLowFeeTx2);
}
Beispiel #3
0
CFeeBumper::CFeeBumper(const CWallet *pWallet, const uint256 txidIn, int newConfirmTarget, bool specifiedConfirmTarget, CAmount totalFee, bool newTxReplaceable)
    :
    txid(std::move(txidIn)),
    nOldFee(0),
    nNewFee(0)
{
    vErrors.clear();
    bumpedTxid.SetNull();
    AssertLockHeld(pWallet->cs_wallet);
    if (!pWallet->mapWallet.count(txid)) {
        vErrors.push_back("Invalid or non-wallet transaction id");
        currentResult = BumpFeeResult::INVALID_ADDRESS_OR_KEY;
        return;
    }
    auto it = pWallet->mapWallet.find(txid);
    const CWalletTx& wtx = it->second;

    if (!preconditionChecks(pWallet, wtx)) {
        return;
    }

    if (!SignalsOptInRBF(wtx)) {
        vErrors.push_back("Transaction is not BIP 125 replaceable");
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    if (wtx.mapValue.count("replaced_by_txid")) {
        vErrors.push_back(strprintf("Cannot bump transaction %s which was already bumped by transaction %s", txid.ToString(), wtx.mapValue.at("replaced_by_txid")));
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    // check that original tx consists entirely of our inputs
    // if not, we can't bump the fee, because the wallet has no way of knowing the value of the other inputs (thus the fee)
    if (!pWallet->IsAllFromMe(wtx, ISMINE_SPENDABLE)) {
        vErrors.push_back("Transaction contains inputs that don't belong to this wallet");
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    // figure out which output was change
    // if there was no change output or multiple change outputs, fail
    int nOutput = -1;
    for (size_t i = 0; i < wtx.tx->vout.size(); ++i) {
        if (pWallet->IsChange(wtx.tx->vout[i])) {
            if (nOutput != -1) {
                vErrors.push_back("Transaction has multiple change outputs");
                currentResult = BumpFeeResult::WALLET_ERROR;
                return;
            }
            nOutput = i;
        }
    }
    if (nOutput == -1) {
        vErrors.push_back("Transaction does not have a change output");
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    // Calculate the expected size of the new transaction.
    int64_t txSize = GetVirtualTransactionSize(*(wtx.tx));
    const int64_t maxNewTxSize = CalculateMaximumSignedTxSize(*wtx.tx, pWallet);
    if (maxNewTxSize < 0) {
        vErrors.push_back("Transaction contains inputs that cannot be signed");
        currentResult = BumpFeeResult::INVALID_ADDRESS_OR_KEY;
        return;
    }

    // calculate the old fee and fee-rate
    nOldFee = wtx.GetDebit(ISMINE_SPENDABLE) - wtx.tx->GetValueOut();
    CFeeRate nOldFeeRate(nOldFee, txSize);
    CFeeRate nNewFeeRate;
    // The wallet uses a conservative WALLET_INCREMENTAL_RELAY_FEE value to
    // future proof against changes to network wide policy for incremental relay
    // fee that our node may not be aware of.
    CFeeRate walletIncrementalRelayFee = CFeeRate(WALLET_INCREMENTAL_RELAY_FEE);
    if (::incrementalRelayFee > walletIncrementalRelayFee) {
        walletIncrementalRelayFee = ::incrementalRelayFee;
    }

    if (totalFee > 0) {
        CAmount minTotalFee = nOldFeeRate.GetFee(maxNewTxSize) + ::incrementalRelayFee.GetFee(maxNewTxSize);
        if (totalFee < minTotalFee) {
            vErrors.push_back(strprintf("Insufficient totalFee, must be at least %s (oldFee %s + incrementalFee %s)",
                                                                FormatMoney(minTotalFee), FormatMoney(nOldFeeRate.GetFee(maxNewTxSize)), FormatMoney(::incrementalRelayFee.GetFee(maxNewTxSize))));
            currentResult = BumpFeeResult::INVALID_PARAMETER;
            return;
        }
        CAmount requiredFee = CWallet::GetRequiredFee(maxNewTxSize);
        if (totalFee < requiredFee) {
            vErrors.push_back(strprintf("Insufficient totalFee (cannot be less than required fee %s)",
                                                                FormatMoney(requiredFee)));
            currentResult = BumpFeeResult::INVALID_PARAMETER;
            return;
        }
        nNewFee = totalFee;
        nNewFeeRate = CFeeRate(totalFee, maxNewTxSize);
    } else {
        // if user specified a confirm target then don't consider any global payTxFee
        if (specifiedConfirmTarget) {
            nNewFee = CWallet::GetMinimumFee(maxNewTxSize, newConfirmTarget, mempool, ::feeEstimator, true);
        }
        // otherwise use the regular wallet logic to select payTxFee or default confirm target
        else {
            nNewFee = CWallet::GetMinimumFee(maxNewTxSize, newConfirmTarget, mempool, ::feeEstimator);
        }

        nNewFeeRate = CFeeRate(nNewFee, maxNewTxSize);

        // New fee rate must be at least old rate + minimum incremental relay rate
        // walletIncrementalRelayFee.GetFeePerK() should be exact, because it's initialized
        // in that unit (fee per kb).
        // However, nOldFeeRate is a calculated value from the tx fee/size, so
        // add 1 satoshi to the result, because it may have been rounded down.
        if (nNewFeeRate.GetFeePerK() < nOldFeeRate.GetFeePerK() + 1 + walletIncrementalRelayFee.GetFeePerK()) {
            nNewFeeRate = CFeeRate(nOldFeeRate.GetFeePerK() + 1 + walletIncrementalRelayFee.GetFeePerK());
            nNewFee = nNewFeeRate.GetFee(maxNewTxSize);
        }
    }

    // Check that in all cases the new fee doesn't violate maxTxFee
     if (nNewFee > maxTxFee) {
         vErrors.push_back(strprintf("Specified or calculated fee %s is too high (cannot be higher than maxTxFee %s)",
                               FormatMoney(nNewFee), FormatMoney(maxTxFee)));
         currentResult = BumpFeeResult::WALLET_ERROR;
         return;
     }

    // check that fee rate is higher than mempool's minimum fee
    // (no point in bumping fee if we know that the new tx won't be accepted to the mempool)
    // This may occur if the user set TotalFee or paytxfee too low, if fallbackfee is too low, or, perhaps,
    // in a rare situation where the mempool minimum fee increased significantly since the fee estimation just a
    // moment earlier. In this case, we report an error to the user, who may use totalFee to make an adjustment.
    CFeeRate minMempoolFeeRate = mempool.GetMinFee(GetArg("-maxmempool", DEFAULT_MAX_MEMPOOL_SIZE) * 1000000);
    if (nNewFeeRate.GetFeePerK() < minMempoolFeeRate.GetFeePerK()) {
        vErrors.push_back(strprintf("New fee rate (%s) is less than the minimum fee rate (%s) to get into the mempool. totalFee value should to be at least %s or settxfee value should be at least %s to add transaction.", FormatMoney(nNewFeeRate.GetFeePerK()), FormatMoney(minMempoolFeeRate.GetFeePerK()), FormatMoney(minMempoolFeeRate.GetFee(maxNewTxSize)), FormatMoney(minMempoolFeeRate.GetFeePerK())));
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    // Now modify the output to increase the fee.
    // If the output is not large enough to pay the fee, fail.
    CAmount nDelta = nNewFee - nOldFee;
    assert(nDelta > 0);
    mtx =  *wtx.tx;
    CTxOut* poutput = &(mtx.vout[nOutput]);
    if (poutput->nValue < nDelta) {
        vErrors.push_back("Change output is too small to bump the fee");
        currentResult = BumpFeeResult::WALLET_ERROR;
        return;
    }

    // If the output would become dust, discard it (converting the dust to fee)
    poutput->nValue -= nDelta;
    if (poutput->nValue <= GetDustThreshold(*poutput, ::dustRelayFee)) {
        LogPrint(BCLog::RPC, "Bumping fee and discarding dust output\n");
        nNewFee += poutput->nValue;
        mtx.vout.erase(mtx.vout.begin() + nOutput);
    }

    // Mark new tx not replaceable, if requested.
    if (!newTxReplaceable) {
        for (auto& input : mtx.vin) {
            if (input.nSequence < 0xfffffffe) input.nSequence = 0xfffffffe;
        }
    }

    currentResult = BumpFeeResult::OK;
}
Beispiel #4
0
    std::unique_ptr<CBlockTemplate> pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    BOOST_CHECK(pblocktemplate->block.vtx[1]->GetHash() == hashParentTx);
    BOOST_CHECK(pblocktemplate->block.vtx[2]->GetHash() == hashHighFeeTx);
    BOOST_CHECK(pblocktemplate->block.vtx[3]->GetHash() == hashMediumFeeTx);

    // Test that a package below the block min tx fee doesn't get included
    tx.vin[0].prevout.hash = hashHighFeeTx;
    tx.vout[0].nValue = 5000000000LL - 1000 - 50000; // 0 fee
    uint256 hashFreeTx = tx.GetHash();
    mempool.addUnchecked(entry.Fee(0).FromTx(tx));
    size_t freeTxSize = ::GetSerializeSize(tx, PROTOCOL_VERSION);

    // Calculate a fee on child transaction that will put the package just
    // below the block min tx fee (assuming 1 child tx of the same size).
    CAmount feeToUse = blockMinFeeRate.GetFee(2*freeTxSize) - 1;

    tx.vin[0].prevout.hash = hashFreeTx;
    tx.vout[0].nValue = 5000000000LL - 1000 - 50000 - feeToUse;
    uint256 hashLowFeeTx = tx.GetHash();
    mempool.addUnchecked(entry.Fee(feeToUse).FromTx(tx));
    pblocktemplate = AssemblerForTest(chainparams).CreateNewBlock(scriptPubKey);
    // Verify that the free tx and the low fee tx didn't get selected
    for (size_t i=0; i<pblocktemplate->block.vtx.size(); ++i) {
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashFreeTx);
        BOOST_CHECK(pblocktemplate->block.vtx[i]->GetHash() != hashLowFeeTx);
    }

    // Test that packages above the min relay fee do get included, even if one
    // of the transactions is below the min relay fee
    // Remove the low fee transaction and replace with a higher fee transaction