// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2021 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_POLICY_FEES_H #define BITCOIN_POLICY_FEES_H #include #include #include #include #include #include #include #include #include #include #include #include #include class CAutoFile; class CTxMemPoolEntry; class TxConfirmStats; /* Identifier for each of the 3 different TxConfirmStats which will track * history over different time horizons. */ enum class FeeEstimateHorizon { SHORT_HALFLIFE, MED_HALFLIFE, LONG_HALFLIFE, }; static constexpr auto ALL_FEE_ESTIMATE_HORIZONS = std::array{ FeeEstimateHorizon::SHORT_HALFLIFE, FeeEstimateHorizon::MED_HALFLIFE, FeeEstimateHorizon::LONG_HALFLIFE, }; std::string StringForFeeEstimateHorizon(FeeEstimateHorizon horizon); /* Enumeration of reason for returned fee estimate */ enum class FeeReason { NONE, HALF_ESTIMATE, FULL_ESTIMATE, DOUBLE_ESTIMATE, CONSERVATIVE, MEMPOOL_MIN, PAYTXFEE, FALLBACK, REQUIRED, }; /* Used to return detailed information about a feerate bucket */ struct EstimatorBucket { double start = -1; double end = -1; double withinTarget = 0; double totalConfirmed = 0; double inMempool = 0; double leftMempool = 0; }; /* Used to return detailed information about a fee estimate calculation */ struct EstimationResult { EstimatorBucket pass; EstimatorBucket fail; double decay = 0; unsigned int scale = 0; }; struct FeeCalculation { EstimationResult est; FeeReason reason = FeeReason::NONE; int desiredTarget = 0; int returnedTarget = 0; }; /** \class CBlockPolicyEstimator * The BlockPolicyEstimator is used for estimating the feerate needed * for a transaction to be included in a block within a certain number of * blocks. * * At a high level the algorithm works by grouping transactions into buckets * based on having similar feerates and then tracking how long it * takes transactions in the various buckets to be mined. It operates under * the assumption that in general transactions of higher feerate will be * included in blocks before transactions of lower feerate. So for * example if you wanted to know what feerate you should put on a transaction to * be included in a block within the next 5 blocks, you would start by looking * at the bucket with the highest feerate transactions and verifying that a * sufficiently high percentage of them were confirmed within 5 blocks and * then you would look at the next highest feerate bucket, and so on, stopping at * the last bucket to pass the test. The average feerate of transactions in this * bucket will give you an indication of the lowest feerate you can put on a * transaction and still have a sufficiently high chance of being confirmed * within your desired 5 blocks. * * Here is a brief description of the implementation: * When a transaction enters the mempool, we track the height of the block chain * at entry. All further calculations are conducted only on this set of "seen" * transactions. Whenever a block comes in, we count the number of transactions * in each bucket and the total amount of feerate paid in each bucket. Then we * calculate how many blocks Y it took each transaction to be mined. We convert * from a number of blocks to a number of periods Y' each encompassing "scale" * blocks. This is tracked in 3 different data sets each up to a maximum * number of periods. Within each data set we have an array of counters in each * feerate bucket and we increment all the counters from Y' up to max periods * representing that a tx was successfully confirmed in less than or equal to * that many periods. We want to save a history of this information, so at any * time we have a counter of the total number of transactions that happened in a * given feerate bucket and the total number that were confirmed in each of the * periods or less for any bucket. We save this history by keeping an * exponentially decaying moving average of each one of these stats. This is * done for a different decay in each of the 3 data sets to keep relevant data * from different time horizons. Furthermore we also keep track of the number * unmined (in mempool or left mempool without being included in a block) * transactions in each bucket and for how many blocks they have been * outstanding and use both of these numbers to increase the number of transactions * we've seen in that feerate bucket when calculating an estimate for any number * of confirmations below the number of blocks they've been outstanding. * * We want to be able to estimate feerates that are needed on tx's to be included in * a certain number of blocks. Every time a block is added to the best chain, this class records * stats on the transactions included in that block */ class CBlockPolicyEstimator { private: /** Track confirm delays up to 12 blocks for short horizon */ static constexpr unsigned int SHORT_BLOCK_PERIODS = 12; static constexpr unsigned int SHORT_SCALE = 1; /** Track confirm delays up to 48 blocks for medium horizon */ static constexpr unsigned int MED_BLOCK_PERIODS = 24; static constexpr unsigned int MED_SCALE = 2; /** Track confirm delays up to 1008 blocks for long horizon */ static constexpr unsigned int LONG_BLOCK_PERIODS = 42; static constexpr unsigned int LONG_SCALE = 24; /** Historical estimates that are older than this aren't valid */ static const unsigned int OLDEST_ESTIMATE_HISTORY = 6 * 1008; /** Decay of .962 is a half-life of 18 blocks or about 3 hours */ static constexpr double SHORT_DECAY = .962; /** Decay of .9952 is a half-life of 144 blocks or about 1 day */ static constexpr double MED_DECAY = .9952; /** Decay of .99931 is a half-life of 1008 blocks or about 1 week */ static constexpr double LONG_DECAY = .99931; /** Require greater than 60% of X feerate transactions to be confirmed within Y/2 blocks*/ static constexpr double HALF_SUCCESS_PCT = .6; /** Require greater than 85% of X feerate transactions to be confirmed within Y blocks*/ static constexpr double SUCCESS_PCT = .85; /** Require greater than 95% of X feerate transactions to be confirmed within 2 * Y blocks*/ static constexpr double DOUBLE_SUCCESS_PCT = .95; /** Require an avg of 0.1 tx in the combined feerate bucket per block to have stat significance */ static constexpr double SUFFICIENT_FEETXS = 0.1; /** Require an avg of 0.5 tx when using short decay since there are fewer blocks considered*/ static constexpr double SUFFICIENT_TXS_SHORT = 0.5; /** Minimum and Maximum values for tracking feerates * The MIN_BUCKET_FEERATE should just be set to the lowest reasonable feerate we * might ever want to track. Historically this has been 1000 since it was * inheriting DEFAULT_MIN_RELAY_TX_FEE and changing it is disruptive as it * invalidates old estimates files. So leave it at 1000 unless it becomes * necessary to lower it, and then lower it substantially. */ static constexpr double MIN_BUCKET_FEERATE = 1000; static constexpr double MAX_BUCKET_FEERATE = 1e7; /** Spacing of FeeRate buckets * We have to lump transactions into buckets based on feerate, but we want to be able * to give accurate estimates over a large range of potential feerates * Therefore it makes sense to exponentially space the buckets */ static constexpr double FEE_SPACING = 1.05; const fs::path m_estimation_filepath; public: /** Create new BlockPolicyEstimator and initialize stats tracking classes with default values */ CBlockPolicyEstimator(const fs::path& estimation_filepath); ~CBlockPolicyEstimator(); /** Process all the transactions that have been included in a block */ void processBlock(unsigned int nBlockHeight, std::vector& entries) EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Process a transaction accepted to the mempool*/ void processTransaction(const CTxMemPoolEntry& entry, bool validFeeEstimate) EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Remove a transaction from the mempool tracking stats*/ bool removeTx(uint256 hash, bool inBlock) EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** DEPRECATED. Return a feerate estimate */ CFeeRate estimateFee(int confTarget) const EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Estimate feerate needed to get be included in a block within confTarget * blocks. If no answer can be given at confTarget, return an estimate at * the closest target where one can be given. 'conservative' estimates are * valid over longer time horizons also. */ CFeeRate estimateSmartFee(int confTarget, FeeCalculation *feeCalc, bool conservative) const EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Return a specific fee estimate calculation with a given success * threshold and time horizon, and optionally return detailed data about * calculation */ CFeeRate estimateRawFee(int confTarget, double successThreshold, FeeEstimateHorizon horizon, EstimationResult* result = nullptr) const EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Write estimation data to a file */ bool Write(CAutoFile& fileout) const EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Read estimation data from a file */ bool Read(CAutoFile& filein) EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Empty mempool transactions on shutdown to record failure to confirm for txs still in mempool */ void FlushUnconfirmed() EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Calculation of highest target that estimates are tracked for */ unsigned int HighestTargetTracked(FeeEstimateHorizon horizon) const EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); /** Drop still unconfirmed transactions and record current estimations, if the fee estimation file is present. */ void Flush() EXCLUSIVE_LOCKS_REQUIRED(!m_cs_fee_estimator); private: mutable Mutex m_cs_fee_estimator; unsigned int nBestSeenHeight GUARDED_BY(m_cs_fee_estimator); unsigned int firstRecordedHeight GUARDED_BY(m_cs_fee_estimator); unsigned int historicalFirst GUARDED_BY(m_cs_fee_estimator); unsigned int historicalBest GUARDED_BY(m_cs_fee_estimator); struct TxStatsInfo { unsigned int blockHeight; unsigned int bucketIndex; TxStatsInfo() : blockHeight(0), bucketIndex(0) {} }; // map of txids to information about that transaction std::map mapMemPoolTxs GUARDED_BY(m_cs_fee_estimator); /** Classes to track historical data on transaction confirmations */ std::unique_ptr feeStats PT_GUARDED_BY(m_cs_fee_estimator); std::unique_ptr shortStats PT_GUARDED_BY(m_cs_fee_estimator); std::unique_ptr longStats PT_GUARDED_BY(m_cs_fee_estimator); unsigned int trackedTxs GUARDED_BY(m_cs_fee_estimator); unsigned int untrackedTxs GUARDED_BY(m_cs_fee_estimator); std::vector buckets GUARDED_BY(m_cs_fee_estimator); // The upper-bound of the range for the bucket (inclusive) std::map bucketMap GUARDED_BY(m_cs_fee_estimator); // Map of bucket upper-bound to index into all vectors by bucket /** Process a transaction confirmed in a block*/ bool processBlockTx(unsigned int nBlockHeight, const CTxMemPoolEntry* entry) EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** Helper for estimateSmartFee */ double estimateCombinedFee(unsigned int confTarget, double successThreshold, bool checkShorterHorizon, EstimationResult *result) const EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** Helper for estimateSmartFee */ double estimateConservativeFee(unsigned int doubleTarget, EstimationResult *result) const EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** Number of blocks of data recorded while fee estimates have been running */ unsigned int BlockSpan() const EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** Number of blocks of recorded fee estimate data represented in saved data file */ unsigned int HistoricalBlockSpan() const EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** Calculation of highest target that reasonable estimate can be provided for */ unsigned int MaxUsableEstimate() const EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); /** A non-thread-safe helper for the removeTx function */ bool _removeTx(const uint256& hash, bool inBlock) EXCLUSIVE_LOCKS_REQUIRED(m_cs_fee_estimator); }; class FeeFilterRounder { private: static constexpr double MAX_FILTER_FEERATE = 1e7; /** FEE_FILTER_SPACING is just used to provide some quantization of fee * filter results. Historically it reused FEE_SPACING, but it is completely * unrelated, and was made a separate constant so the two concepts are not * tied together */ static constexpr double FEE_FILTER_SPACING = 1.1; public: /** Create new FeeFilterRounder */ explicit FeeFilterRounder(const CFeeRate& minIncrementalFee); /** Quantize a minimum fee for privacy purpose before broadcast. Not thread-safe due to use of FastRandomContext */ CAmount round(CAmount currentMinFee); private: std::set feeset; FastRandomContext insecure_rand; }; #endif // BITCOIN_POLICY_FEES_H