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// Copyright (c) 2017-2022 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_WALLET_COINSELECTION_H
#define BITCOIN_WALLET_COINSELECTION_H
#include <consensus/amount.h>
#include <consensus/consensus.h>
#include <policy/feerate.h>
#include <primitives/transaction.h>
#include <random.h>
#include <util/system.h>
#include <util/check.h>
#include <optional>
namespace wallet {
//! lower bound for randomly-chosen target change amount
static constexpr CAmount CHANGE_LOWER{50000};
//! upper bound for randomly-chosen target change amount
static constexpr CAmount CHANGE_UPPER{1000000};
/** A UTXO under consideration for use in funding a new transaction. */
struct COutput {
private:
/** The output's value minus fees required to spend it.*/
std::optional<CAmount> effective_value;
/** The fee required to spend this output at the transaction's target feerate. */
std::optional<CAmount> fee;
public:
/** The outpoint identifying this UTXO */
COutPoint outpoint;
/** The output itself */
CTxOut txout;
/**
* Depth in block chain.
* If > 0: the tx is on chain and has this many confirmations.
* If = 0: the tx is waiting confirmation.
* If < 0: a conflicting tx is on chain and has this many confirmations. */
int depth;
/** Pre-computed estimated size of this output as a fully-signed input in a transaction. Can be -1 if it could not be calculated */
int input_bytes;
/** Whether we have the private keys to spend this output */
bool spendable;
/** Whether we know how to spend this output, ignoring the lack of keys */
bool solvable;
/**
* Whether this output is considered safe to spend. Unconfirmed transactions
* from outside keys and unconfirmed replacement transactions are considered
* unsafe and will not be used to fund new spending transactions.
*/
bool safe;
/** The time of the transaction containing this output as determined by CWalletTx::nTimeSmart */
int64_t time;
/** Whether the transaction containing this output is sent from the owning wallet */
bool from_me;
/** The fee required to spend this output at the consolidation feerate. */
CAmount long_term_fee{0};
COutput(const COutPoint& outpoint, const CTxOut& txout, int depth, int input_bytes, bool spendable, bool solvable, bool safe, int64_t time, bool from_me, const std::optional<CFeeRate> feerate = std::nullopt)
: outpoint{outpoint},
txout{txout},
depth{depth},
input_bytes{input_bytes},
spendable{spendable},
solvable{solvable},
safe{safe},
time{time},
from_me{from_me}
{
if (feerate) {
fee = input_bytes < 0 ? 0 : feerate.value().GetFee(input_bytes);
effective_value = txout.nValue - fee.value();
}
}
COutput(const COutPoint& outpoint, const CTxOut& txout, int depth, int input_bytes, bool spendable, bool solvable, bool safe, int64_t time, bool from_me, const CAmount fees)
: COutput(outpoint, txout, depth, input_bytes, spendable, solvable, safe, time, from_me)
{
// if input_bytes is unknown, then fees should be 0, if input_bytes is known, then the fees should be a positive integer or 0 (input_bytes known and fees = 0 only happens in the tests)
assert((input_bytes < 0 && fees == 0) || (input_bytes > 0 && fees >= 0));
fee = fees;
effective_value = txout.nValue - fee.value();
}
std::string ToString() const;
bool operator<(const COutput& rhs) const
{
return outpoint < rhs.outpoint;
}
CAmount GetFee() const
{
assert(fee.has_value());
return fee.value();
}
CAmount GetEffectiveValue() const
{
assert(effective_value.has_value());
return effective_value.value();
}
bool HasEffectiveValue() const { return effective_value.has_value(); }
};
/** Parameters for one iteration of Coin Selection. */
struct CoinSelectionParams {
/** Randomness to use in the context of coin selection. */
FastRandomContext& rng_fast;
/** Size of a change output in bytes, determined by the output type. */
size_t change_output_size = 0;
/** Size of the input to spend a change output in virtual bytes. */
size_t change_spend_size = 0;
/** Mininmum change to target in Knapsack solver: select coins to cover the payment and
* at least this value of change. */
CAmount m_min_change_target{0};
/** Minimum amount for creating a change output.
* If change budget is smaller than min_change then we forgo creation of change output.
*/
CAmount min_viable_change{0};
/** Cost of creating the change output. */
CAmount m_change_fee{0};
/** Cost of creating the change output + cost of spending the change output in the future. */
CAmount m_cost_of_change{0};
/** The targeted feerate of the transaction being built. */
CFeeRate m_effective_feerate;
/** The feerate estimate used to estimate an upper bound on what should be sufficient to spend
* the change output sometime in the future. */
CFeeRate m_long_term_feerate;
/** If the cost to spend a change output at the discard feerate exceeds its value, drop it to fees. */
CFeeRate m_discard_feerate;
/** Size of the transaction before coin selection, consisting of the header and recipient
* output(s), excluding the inputs and change output(s). */
size_t tx_noinputs_size = 0;
/** Indicate that we are subtracting the fee from outputs */
bool m_subtract_fee_outputs = false;
/** When true, always spend all (up to OUTPUT_GROUP_MAX_ENTRIES) or none of the outputs
* associated with the same address. This helps reduce privacy leaks resulting from address
* reuse. Dust outputs are not eligible to be added to output groups and thus not considered. */
bool m_avoid_partial_spends = false;
CoinSelectionParams(FastRandomContext& rng_fast, size_t change_output_size, size_t change_spend_size,
CAmount min_change_target, CFeeRate effective_feerate,
CFeeRate long_term_feerate, CFeeRate discard_feerate, size_t tx_noinputs_size, bool avoid_partial)
: rng_fast{rng_fast},
change_output_size(change_output_size),
change_spend_size(change_spend_size),
m_min_change_target(min_change_target),
m_effective_feerate(effective_feerate),
m_long_term_feerate(long_term_feerate),
m_discard_feerate(discard_feerate),
tx_noinputs_size(tx_noinputs_size),
m_avoid_partial_spends(avoid_partial)
{
}
CoinSelectionParams(FastRandomContext& rng_fast)
: rng_fast{rng_fast} {}
};
/** Parameters for filtering which OutputGroups we may use in coin selection.
* We start by being very selective and requiring multiple confirmations and
* then get more permissive if we cannot fund the transaction. */
struct CoinEligibilityFilter
{
/** Minimum number of confirmations for outputs that we sent to ourselves.
* We may use unconfirmed UTXOs sent from ourselves, e.g. change outputs. */
const int conf_mine;
/** Minimum number of confirmations for outputs received from a different wallet. */
const int conf_theirs;
/** Maximum number of unconfirmed ancestors aggregated across all UTXOs in an OutputGroup. */
const uint64_t max_ancestors;
/** Maximum number of descendants that a single UTXO in the OutputGroup may have. */
const uint64_t max_descendants;
/** When avoid_reuse=true and there are full groups (OUTPUT_GROUP_MAX_ENTRIES), whether or not to use any partial groups.*/
const bool m_include_partial_groups{false};
CoinEligibilityFilter() = delete;
CoinEligibilityFilter(int conf_mine, int conf_theirs, uint64_t max_ancestors) : conf_mine(conf_mine), conf_theirs(conf_theirs), max_ancestors(max_ancestors), max_descendants(max_ancestors) {}
CoinEligibilityFilter(int conf_mine, int conf_theirs, uint64_t max_ancestors, uint64_t max_descendants) : conf_mine(conf_mine), conf_theirs(conf_theirs), max_ancestors(max_ancestors), max_descendants(max_descendants) {}
CoinEligibilityFilter(int conf_mine, int conf_theirs, uint64_t max_ancestors, uint64_t max_descendants, bool include_partial) : conf_mine(conf_mine), conf_theirs(conf_theirs), max_ancestors(max_ancestors), max_descendants(max_descendants), m_include_partial_groups(include_partial) {}
};
/** A group of UTXOs paid to the same output script. */
struct OutputGroup
{
/** The list of UTXOs contained in this output group. */
std::vector<COutput> m_outputs;
/** Whether the UTXOs were sent by the wallet to itself. This is relevant because we may want at
* least a certain number of confirmations on UTXOs received from outside wallets while trusting
* our own UTXOs more. */
bool m_from_me{true};
/** The total value of the UTXOs in sum. */
CAmount m_value{0};
/** The minimum number of confirmations the UTXOs in the group have. Unconfirmed is 0. */
int m_depth{999};
/** The aggregated count of unconfirmed ancestors of all UTXOs in this
* group. Not deduplicated and may overestimate when ancestors are shared. */
size_t m_ancestors{0};
/** The maximum count of descendants of a single UTXO in this output group. */
size_t m_descendants{0};
/** The value of the UTXOs after deducting the cost of spending them at the effective feerate. */
CAmount effective_value{0};
/** The fee to spend these UTXOs at the effective feerate. */
CAmount fee{0};
/** The target feerate of the transaction we're trying to build. */
CFeeRate m_effective_feerate{0};
/** The fee to spend these UTXOs at the long term feerate. */
CAmount long_term_fee{0};
/** The feerate for spending a created change output eventually (i.e. not urgently, and thus at
* a lower feerate). Calculated using long term fee estimate. This is used to decide whether
* it could be economical to create a change output. */
CFeeRate m_long_term_feerate{0};
/** Indicate that we are subtracting the fee from outputs.
* When true, the value that is used for coin selection is the UTXO's real value rather than effective value */
bool m_subtract_fee_outputs{false};
/** Total weight of the UTXOs in this group. */
int m_weight{0};
OutputGroup() {}
OutputGroup(const CoinSelectionParams& params) :
m_effective_feerate(params.m_effective_feerate),
m_long_term_feerate(params.m_long_term_feerate),
m_subtract_fee_outputs(params.m_subtract_fee_outputs)
{}
void Insert(const COutput& output, size_t ancestors, size_t descendants, bool positive_only);
bool EligibleForSpending(const CoinEligibilityFilter& eligibility_filter) const;
CAmount GetSelectionAmount() const;
};
/** Compute the waste for this result given the cost of change
* and the opportunity cost of spending these inputs now vs in the future.
* If change exists, waste = change_cost + inputs * (effective_feerate - long_term_feerate)
* If no change, waste = excess + inputs * (effective_feerate - long_term_feerate)
* where excess = selected_effective_value - target
* change_cost = effective_feerate * change_output_size + long_term_feerate * change_spend_size
*
* Note this function is separate from SelectionResult for the tests.
*
* @param[in] inputs The selected inputs
* @param[in] change_cost The cost of creating change and spending it in the future.
* Only used if there is change, in which case it must be positive.
* Must be 0 if there is no change.
* @param[in] target The amount targeted by the coin selection algorithm.
* @param[in] use_effective_value Whether to use the input's effective value (when true) or the real value (when false).
* @return The waste
*/
[[nodiscard]] CAmount GetSelectionWaste(const std::set<COutput>& inputs, CAmount change_cost, CAmount target, bool use_effective_value = true);
/** Choose a random change target for each transaction to make it harder to fingerprint the Core
* wallet based on the change output values of transactions it creates.
* Change target covers at least change fees and adds a random value on top of it.
* The random value is between 50ksat and min(2 * payment_value, 1milsat)
* When payment_value <= 25ksat, the value is just 50ksat.
*
* Making change amounts similar to the payment value may help disguise which output(s) are payments
* are which ones are change. Using double the payment value may increase the number of inputs
* needed (and thus be more expensive in fees), but breaks analysis techniques which assume the
* coins selected are just sufficient to cover the payment amount ("unnecessary input" heuristic).
*
* @param[in] payment_value Average payment value of the transaction output(s).
* @param[in] change_fee Fee for creating a change output.
*/
[[nodiscard]] CAmount GenerateChangeTarget(const CAmount payment_value, const CAmount change_fee, FastRandomContext& rng);
enum class SelectionAlgorithm : uint8_t
{
BNB = 0,
KNAPSACK = 1,
SRD = 2,
MANUAL = 3,
};
std::string GetAlgorithmName(const SelectionAlgorithm algo);
struct SelectionResult
{
private:
/** Set of inputs selected by the algorithm to use in the transaction */
std::set<COutput> m_selected_inputs;
/** The target the algorithm selected for. Equal to the recipient amount plus non-input fees */
CAmount m_target;
/** The algorithm used to produce this result */
SelectionAlgorithm m_algo;
/** Whether the input values for calculations should be the effective value (true) or normal value (false) */
bool m_use_effective{false};
/** The computed waste */
std::optional<CAmount> m_waste;
/** Total weight of the selected inputs */
int m_weight{0};
template<typename T>
void InsertInputs(const T& inputs)
{
// Store sum of combined input sets to check that the results have no shared UTXOs
const size_t expected_count = m_selected_inputs.size() + inputs.size();
util::insert(m_selected_inputs, inputs);
if (m_selected_inputs.size() != expected_count) {
throw std::runtime_error(STR_INTERNAL_BUG("Shared UTXOs among selection results"));
}
}
public:
explicit SelectionResult(const CAmount target, SelectionAlgorithm algo)
: m_target(target), m_algo(algo) {}
SelectionResult() = delete;
/** Get the sum of the input values */
[[nodiscard]] CAmount GetSelectedValue() const;
[[nodiscard]] CAmount GetSelectedEffectiveValue() const;
void Clear();
void AddInput(const OutputGroup& group);
void AddInputs(const std::set<COutput>& inputs, bool subtract_fee_outputs);
/** Calculates and stores the waste for this selection via GetSelectionWaste */
void ComputeAndSetWaste(const CAmount min_viable_change, const CAmount change_cost, const CAmount change_fee);
[[nodiscard]] CAmount GetWaste() const;
/**
* Combines the @param[in] other selection result into 'this' selection result.
*
* Important note:
* There must be no shared 'COutput' among the two selection results being combined.
*/
void Merge(const SelectionResult& other);
/** Get m_selected_inputs */
const std::set<COutput>& GetInputSet() const;
/** Get the vector of COutputs that will be used to fill in a CTransaction's vin */
std::vector<COutput> GetShuffledInputVector() const;
bool operator<(SelectionResult other) const;
/** Get the amount for the change output after paying needed fees.
*
* The change amount is not 100% precise due to discrepancies in fee calculation.
* The final change amount (if any) should be corrected after calculating the final tx fees.
* When there is a discrepancy, most of the time the final change would be slightly bigger than estimated.
*
* Following are the possible factors of discrepancy:
* + non-input fees always include segwit flags
* + input fee estimation always include segwit stack size
* + input fees are rounded individually and not collectively, which leads to small rounding errors
* - input counter size is always assumed to be 1vbyte
*
* @param[in] min_viable_change Minimum amount for change output, if change would be less then we forgo change
* @param[in] change_fee Fees to include change output in the tx
* @returns Amount for change output, 0 when there is no change.
*
*/
CAmount GetChange(const CAmount min_viable_change, const CAmount change_fee) const;
CAmount GetTarget() const { return m_target; }
SelectionAlgorithm GetAlgo() const { return m_algo; }
int GetWeight() const { return m_weight; }
};
std::optional<SelectionResult> SelectCoinsBnB(std::vector<OutputGroup>& utxo_pool, const CAmount& selection_target, const CAmount& cost_of_change);
/** Select coins by Single Random Draw. OutputGroups are selected randomly from the eligible
* outputs until the target is satisfied
*
* @param[in] utxo_pool The positive effective value OutputGroups eligible for selection
* @param[in] target_value The target value to select for
* @returns If successful, a SelectionResult, otherwise, std::nullopt
*/
std::optional<SelectionResult> SelectCoinsSRD(const std::vector<OutputGroup>& utxo_pool, CAmount target_value, FastRandomContext& rng);
// Original coin selection algorithm as a fallback
std::optional<SelectionResult> KnapsackSolver(std::vector<OutputGroup>& groups, const CAmount& nTargetValue,
CAmount change_target, FastRandomContext& rng);
} // namespace wallet
#endif // BITCOIN_WALLET_COINSELECTION_H
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