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|
// Copyright (c) 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.
#include <consensus/amount.h>
#include <consensus/validation.h>
#include <interfaces/chain.h>
#include <policy/policy.h>
#include <script/signingprovider.h>
#include <util/check.h>
#include <util/fees.h>
#include <util/moneystr.h>
#include <util/rbf.h>
#include <util/translation.h>
#include <wallet/coincontrol.h>
#include <wallet/fees.h>
#include <wallet/receive.h>
#include <wallet/spend.h>
#include <wallet/transaction.h>
#include <wallet/wallet.h>
using interfaces::FoundBlock;
static constexpr size_t OUTPUT_GROUP_MAX_ENTRIES{100};
int GetTxSpendSize(const CWallet& wallet, const CWalletTx& wtx, unsigned int out, bool use_max_sig)
{
return CalculateMaximumSignedInputSize(wtx.tx->vout[out], &wallet, use_max_sig);
}
std::string COutput::ToString() const
{
return strprintf("COutput(%s, %d, %d) [%s]", tx->GetHash().ToString(), i, nDepth, FormatMoney(tx->tx->vout[i].nValue));
}
int CalculateMaximumSignedInputSize(const CTxOut& txout, const SigningProvider* provider, bool use_max_sig)
{
CMutableTransaction txn;
txn.vin.push_back(CTxIn(COutPoint()));
if (!provider || !DummySignInput(*provider, txn.vin[0], txout, use_max_sig)) {
return -1;
}
return GetVirtualTransactionInputSize(txn.vin[0]);
}
int CalculateMaximumSignedInputSize(const CTxOut& txout, const CWallet* wallet, bool use_max_sig)
{
const std::unique_ptr<SigningProvider> provider = wallet->GetSolvingProvider(txout.scriptPubKey);
return CalculateMaximumSignedInputSize(txout, provider.get(), use_max_sig);
}
// txouts needs to be in the order of tx.vin
TxSize CalculateMaximumSignedTxSize(const CTransaction &tx, const CWallet *wallet, const std::vector<CTxOut>& txouts, const CCoinControl* coin_control)
{
CMutableTransaction txNew(tx);
if (!wallet->DummySignTx(txNew, txouts, coin_control)) {
return TxSize{-1, -1};
}
CTransaction ctx(txNew);
int64_t vsize = GetVirtualTransactionSize(ctx);
int64_t weight = GetTransactionWeight(ctx);
return TxSize{vsize, weight};
}
TxSize CalculateMaximumSignedTxSize(const CTransaction &tx, const CWallet *wallet, const CCoinControl* coin_control)
{
std::vector<CTxOut> txouts;
// Look up the inputs. The inputs are either in the wallet, or in coin_control.
for (const CTxIn& input : tx.vin) {
const auto mi = wallet->mapWallet.find(input.prevout.hash);
// Can not estimate size without knowing the input details
if (mi != wallet->mapWallet.end()) {
assert(input.prevout.n < mi->second.tx->vout.size());
txouts.emplace_back(mi->second.tx->vout.at(input.prevout.n));
} else if (coin_control) {
CTxOut txout;
if (!coin_control->GetExternalOutput(input.prevout, txout)) {
return TxSize{-1, -1};
}
txouts.emplace_back(txout);
} else {
return TxSize{-1, -1};
}
}
return CalculateMaximumSignedTxSize(tx, wallet, txouts, coin_control);
}
void AvailableCoins(const CWallet& wallet, std::vector<COutput>& vCoins, const CCoinControl* coinControl, const CAmount& nMinimumAmount, const CAmount& nMaximumAmount, const CAmount& nMinimumSumAmount, const uint64_t nMaximumCount)
{
AssertLockHeld(wallet.cs_wallet);
vCoins.clear();
CAmount nTotal = 0;
// Either the WALLET_FLAG_AVOID_REUSE flag is not set (in which case we always allow), or we default to avoiding, and only in the case where
// a coin control object is provided, and has the avoid address reuse flag set to false, do we allow already used addresses
bool allow_used_addresses = !wallet.IsWalletFlagSet(WALLET_FLAG_AVOID_REUSE) || (coinControl && !coinControl->m_avoid_address_reuse);
const int min_depth = {coinControl ? coinControl->m_min_depth : DEFAULT_MIN_DEPTH};
const int max_depth = {coinControl ? coinControl->m_max_depth : DEFAULT_MAX_DEPTH};
const bool only_safe = {coinControl ? !coinControl->m_include_unsafe_inputs : true};
std::set<uint256> trusted_parents;
for (const auto& entry : wallet.mapWallet)
{
const uint256& wtxid = entry.first;
const CWalletTx& wtx = entry.second;
if (!wallet.chain().checkFinalTx(*wtx.tx)) {
continue;
}
if (wallet.IsTxImmatureCoinBase(wtx))
continue;
int nDepth = wallet.GetTxDepthInMainChain(wtx);
if (nDepth < 0)
continue;
// We should not consider coins which aren't at least in our mempool
// It's possible for these to be conflicted via ancestors which we may never be able to detect
if (nDepth == 0 && !wtx.InMempool())
continue;
bool safeTx = CachedTxIsTrusted(wallet, wtx, trusted_parents);
// We should not consider coins from transactions that are replacing
// other transactions.
//
// Example: There is a transaction A which is replaced by bumpfee
// transaction B. In this case, we want to prevent creation of
// a transaction B' which spends an output of B.
//
// Reason: If transaction A were initially confirmed, transactions B
// and B' would no longer be valid, so the user would have to create
// a new transaction C to replace B'. However, in the case of a
// one-block reorg, transactions B' and C might BOTH be accepted,
// when the user only wanted one of them. Specifically, there could
// be a 1-block reorg away from the chain where transactions A and C
// were accepted to another chain where B, B', and C were all
// accepted.
if (nDepth == 0 && wtx.mapValue.count("replaces_txid")) {
safeTx = false;
}
// Similarly, we should not consider coins from transactions that
// have been replaced. In the example above, we would want to prevent
// creation of a transaction A' spending an output of A, because if
// transaction B were initially confirmed, conflicting with A and
// A', we wouldn't want to the user to create a transaction D
// intending to replace A', but potentially resulting in a scenario
// where A, A', and D could all be accepted (instead of just B and
// D, or just A and A' like the user would want).
if (nDepth == 0 && wtx.mapValue.count("replaced_by_txid")) {
safeTx = false;
}
if (only_safe && !safeTx) {
continue;
}
if (nDepth < min_depth || nDepth > max_depth) {
continue;
}
for (unsigned int i = 0; i < wtx.tx->vout.size(); i++) {
// Only consider selected coins if add_inputs is false
if (coinControl && !coinControl->m_add_inputs && !coinControl->IsSelected(COutPoint(entry.first, i))) {
continue;
}
if (wtx.tx->vout[i].nValue < nMinimumAmount || wtx.tx->vout[i].nValue > nMaximumAmount)
continue;
if (coinControl && coinControl->HasSelected() && !coinControl->fAllowOtherInputs && !coinControl->IsSelected(COutPoint(entry.first, i)))
continue;
if (wallet.IsLockedCoin(entry.first, i))
continue;
if (wallet.IsSpent(wtxid, i))
continue;
isminetype mine = wallet.IsMine(wtx.tx->vout[i]);
if (mine == ISMINE_NO) {
continue;
}
if (!allow_used_addresses && wallet.IsSpentKey(wtxid, i)) {
continue;
}
std::unique_ptr<SigningProvider> provider = wallet.GetSolvingProvider(wtx.tx->vout[i].scriptPubKey);
bool solvable = provider ? IsSolvable(*provider, wtx.tx->vout[i].scriptPubKey) : false;
bool spendable = ((mine & ISMINE_SPENDABLE) != ISMINE_NO) || (((mine & ISMINE_WATCH_ONLY) != ISMINE_NO) && (coinControl && coinControl->fAllowWatchOnly && solvable));
vCoins.push_back(COutput(wallet, wtx, i, nDepth, spendable, solvable, safeTx, (coinControl && coinControl->fAllowWatchOnly)));
// Checks the sum amount of all UTXO's.
if (nMinimumSumAmount != MAX_MONEY) {
nTotal += wtx.tx->vout[i].nValue;
if (nTotal >= nMinimumSumAmount) {
return;
}
}
// Checks the maximum number of UTXO's.
if (nMaximumCount > 0 && vCoins.size() >= nMaximumCount) {
return;
}
}
}
}
CAmount GetAvailableBalance(const CWallet& wallet, const CCoinControl* coinControl)
{
LOCK(wallet.cs_wallet);
CAmount balance = 0;
std::vector<COutput> vCoins;
AvailableCoins(wallet, vCoins, coinControl);
for (const COutput& out : vCoins) {
if (out.fSpendable) {
balance += out.tx->tx->vout[out.i].nValue;
}
}
return balance;
}
const CTxOut& FindNonChangeParentOutput(const CWallet& wallet, const CTransaction& tx, int output)
{
AssertLockHeld(wallet.cs_wallet);
const CTransaction* ptx = &tx;
int n = output;
while (OutputIsChange(wallet, ptx->vout[n]) && ptx->vin.size() > 0) {
const COutPoint& prevout = ptx->vin[0].prevout;
auto it = wallet.mapWallet.find(prevout.hash);
if (it == wallet.mapWallet.end() || it->second.tx->vout.size() <= prevout.n ||
!wallet.IsMine(it->second.tx->vout[prevout.n])) {
break;
}
ptx = it->second.tx.get();
n = prevout.n;
}
return ptx->vout[n];
}
std::map<CTxDestination, std::vector<COutput>> ListCoins(const CWallet& wallet)
{
AssertLockHeld(wallet.cs_wallet);
std::map<CTxDestination, std::vector<COutput>> result;
std::vector<COutput> availableCoins;
AvailableCoins(wallet, availableCoins);
for (const COutput& coin : availableCoins) {
CTxDestination address;
if ((coin.fSpendable || (wallet.IsWalletFlagSet(WALLET_FLAG_DISABLE_PRIVATE_KEYS) && coin.fSolvable)) &&
ExtractDestination(FindNonChangeParentOutput(wallet, *coin.tx->tx, coin.i).scriptPubKey, address)) {
result[address].emplace_back(std::move(coin));
}
}
std::vector<COutPoint> lockedCoins;
wallet.ListLockedCoins(lockedCoins);
// Include watch-only for LegacyScriptPubKeyMan wallets without private keys
const bool include_watch_only = wallet.GetLegacyScriptPubKeyMan() && wallet.IsWalletFlagSet(WALLET_FLAG_DISABLE_PRIVATE_KEYS);
const isminetype is_mine_filter = include_watch_only ? ISMINE_WATCH_ONLY : ISMINE_SPENDABLE;
for (const COutPoint& output : lockedCoins) {
auto it = wallet.mapWallet.find(output.hash);
if (it != wallet.mapWallet.end()) {
int depth = wallet.GetTxDepthInMainChain(it->second);
if (depth >= 0 && output.n < it->second.tx->vout.size() &&
wallet.IsMine(it->second.tx->vout[output.n]) == is_mine_filter
) {
CTxDestination address;
if (ExtractDestination(FindNonChangeParentOutput(wallet, *it->second.tx, output.n).scriptPubKey, address)) {
result[address].emplace_back(
wallet, it->second, output.n, depth, true /* spendable */, true /* solvable */, false /* safe */);
}
}
}
}
return result;
}
std::vector<OutputGroup> GroupOutputs(const CWallet& wallet, const std::vector<COutput>& outputs, const CoinSelectionParams& coin_sel_params, const CoinEligibilityFilter& filter, bool positive_only)
{
std::vector<OutputGroup> groups_out;
if (!coin_sel_params.m_avoid_partial_spends) {
// Allowing partial spends means no grouping. Each COutput gets its own OutputGroup.
for (const COutput& output : outputs) {
// Skip outputs we cannot spend
if (!output.fSpendable) continue;
size_t ancestors, descendants;
wallet.chain().getTransactionAncestry(output.tx->GetHash(), ancestors, descendants);
CInputCoin input_coin = output.GetInputCoin();
// Make an OutputGroup containing just this output
OutputGroup group{coin_sel_params};
group.Insert(input_coin, output.nDepth, CachedTxIsFromMe(wallet, *output.tx, ISMINE_ALL), ancestors, descendants, positive_only);
// Check the OutputGroup's eligibility. Only add the eligible ones.
if (positive_only && group.GetSelectionAmount() <= 0) continue;
if (group.m_outputs.size() > 0 && group.EligibleForSpending(filter)) groups_out.push_back(group);
}
return groups_out;
}
// We want to combine COutputs that have the same scriptPubKey into single OutputGroups
// except when there are more than OUTPUT_GROUP_MAX_ENTRIES COutputs grouped in an OutputGroup.
// To do this, we maintain a map where the key is the scriptPubKey and the value is a vector of OutputGroups.
// For each COutput, we check if the scriptPubKey is in the map, and if it is, the COutput's CInputCoin is added
// to the last OutputGroup in the vector for the scriptPubKey. When the last OutputGroup has
// OUTPUT_GROUP_MAX_ENTRIES CInputCoins, a new OutputGroup is added to the end of the vector.
std::map<CScript, std::vector<OutputGroup>> spk_to_groups_map;
for (const auto& output : outputs) {
// Skip outputs we cannot spend
if (!output.fSpendable) continue;
size_t ancestors, descendants;
wallet.chain().getTransactionAncestry(output.tx->GetHash(), ancestors, descendants);
CInputCoin input_coin = output.GetInputCoin();
CScript spk = input_coin.txout.scriptPubKey;
std::vector<OutputGroup>& groups = spk_to_groups_map[spk];
if (groups.size() == 0) {
// No OutputGroups for this scriptPubKey yet, add one
groups.emplace_back(coin_sel_params);
}
// Get the last OutputGroup in the vector so that we can add the CInputCoin to it
// A pointer is used here so that group can be reassigned later if it is full.
OutputGroup* group = &groups.back();
// Check if this OutputGroup is full. We limit to OUTPUT_GROUP_MAX_ENTRIES when using -avoidpartialspends
// to avoid surprising users with very high fees.
if (group->m_outputs.size() >= OUTPUT_GROUP_MAX_ENTRIES) {
// The last output group is full, add a new group to the vector and use that group for the insertion
groups.emplace_back(coin_sel_params);
group = &groups.back();
}
// Add the input_coin to group
group->Insert(input_coin, output.nDepth, CachedTxIsFromMe(wallet, *output.tx, ISMINE_ALL), ancestors, descendants, positive_only);
}
// Now we go through the entire map and pull out the OutputGroups
for (const auto& spk_and_groups_pair: spk_to_groups_map) {
const std::vector<OutputGroup>& groups_per_spk= spk_and_groups_pair.second;
// Go through the vector backwards. This allows for the first item we deal with being the partial group.
for (auto group_it = groups_per_spk.rbegin(); group_it != groups_per_spk.rend(); group_it++) {
const OutputGroup& group = *group_it;
// Don't include partial groups if there are full groups too and we don't want partial groups
if (group_it == groups_per_spk.rbegin() && groups_per_spk.size() > 1 && !filter.m_include_partial_groups) {
continue;
}
// Check the OutputGroup's eligibility. Only add the eligible ones.
if (positive_only && group.GetSelectionAmount() <= 0) continue;
if (group.m_outputs.size() > 0 && group.EligibleForSpending(filter)) groups_out.push_back(group);
}
}
return groups_out;
}
bool AttemptSelection(const CWallet& wallet, const CAmount& nTargetValue, const CoinEligibilityFilter& eligibility_filter, std::vector<COutput> coins,
std::set<CInputCoin>& setCoinsRet, CAmount& nValueRet, const CoinSelectionParams& coin_selection_params)
{
setCoinsRet.clear();
nValueRet = 0;
// Vector of results for use with waste calculation
// In order: calculated waste, selected inputs, selected input value (sum of input values)
// TODO: Use a struct representing the selection result
std::vector<std::tuple<CAmount, std::set<CInputCoin>, CAmount>> results;
// Note that unlike KnapsackSolver, we do not include the fee for creating a change output as BnB will not create a change output.
std::vector<OutputGroup> positive_groups = GroupOutputs(wallet, coins, coin_selection_params, eligibility_filter, true /* positive_only */);
if (auto bnb_result{SelectCoinsBnB(positive_groups, nTargetValue, coin_selection_params.m_cost_of_change)}) {
bnb_result->ComputeAndSetWaste(CAmount(0));
results.emplace_back(std::make_tuple(bnb_result->GetWaste(), bnb_result->GetInputSet(), bnb_result->GetSelectedValue()));
}
// The knapsack solver has some legacy behavior where it will spend dust outputs. We retain this behavior, so don't filter for positive only here.
std::vector<OutputGroup> all_groups = GroupOutputs(wallet, coins, coin_selection_params, eligibility_filter, false /* positive_only */);
// While nTargetValue includes the transaction fees for non-input things, it does not include the fee for creating a change output.
// So we need to include that for KnapsackSolver as well, as we are expecting to create a change output.
if (auto knapsack_result{KnapsackSolver(all_groups, nTargetValue + coin_selection_params.m_change_fee)}) {
knapsack_result->ComputeAndSetWaste(coin_selection_params.m_cost_of_change);
results.emplace_back(std::make_tuple(knapsack_result->GetWaste(), knapsack_result->GetInputSet(), knapsack_result->GetSelectedValue()));
}
// We include the minimum final change for SRD as we do want to avoid making really small change.
// KnapsackSolver does not need this because it includes MIN_CHANGE internally.
const CAmount srd_target = nTargetValue + coin_selection_params.m_change_fee + MIN_FINAL_CHANGE;
if (auto srd_result{SelectCoinsSRD(positive_groups, srd_target)}) {
srd_result->ComputeAndSetWaste(coin_selection_params.m_cost_of_change);
results.emplace_back(std::make_tuple(srd_result->GetWaste(), srd_result->GetInputSet(), srd_result->GetSelectedValue()));
}
if (results.size() == 0) {
// No solution found
return false;
}
// Choose the result with the least waste
// If the waste is the same, choose the one which spends more inputs.
const auto& best_result = std::min_element(results.begin(), results.end(), [](const auto& a, const auto& b) {
return std::get<0>(a) < std::get<0>(b) || (std::get<0>(a) == std::get<0>(b) && std::get<1>(a).size() > std::get<1>(b).size());
});
setCoinsRet = std::get<1>(*best_result);
nValueRet = std::get<2>(*best_result);
return true;
}
bool SelectCoins(const CWallet& wallet, const std::vector<COutput>& vAvailableCoins, const CAmount& nTargetValue, std::set<CInputCoin>& setCoinsRet, CAmount& nValueRet, const CCoinControl& coin_control, CoinSelectionParams& coin_selection_params)
{
std::vector<COutput> vCoins(vAvailableCoins);
CAmount value_to_select = nTargetValue;
// coin control -> return all selected outputs (we want all selected to go into the transaction for sure)
if (coin_control.HasSelected() && !coin_control.fAllowOtherInputs)
{
for (const COutput& out : vCoins)
{
if (!out.fSpendable)
continue;
nValueRet += out.tx->tx->vout[out.i].nValue;
setCoinsRet.insert(out.GetInputCoin());
}
return (nValueRet >= nTargetValue);
}
// calculate value from preset inputs and store them
std::set<CInputCoin> setPresetCoins;
CAmount nValueFromPresetInputs = 0;
std::vector<COutPoint> vPresetInputs;
coin_control.ListSelected(vPresetInputs);
for (const COutPoint& outpoint : vPresetInputs) {
int input_bytes = -1;
CTxOut txout;
std::map<uint256, CWalletTx>::const_iterator it = wallet.mapWallet.find(outpoint.hash);
if (it != wallet.mapWallet.end()) {
const CWalletTx& wtx = it->second;
// Clearly invalid input, fail
if (wtx.tx->vout.size() <= outpoint.n) {
return false;
}
input_bytes = GetTxSpendSize(wallet, wtx, outpoint.n, false);
txout = wtx.tx->vout.at(outpoint.n);
}
if (input_bytes == -1) {
// The input is external. We either did not find the tx in mapWallet, or we did but couldn't compute the input size with wallet data
if (!coin_control.GetExternalOutput(outpoint, txout)) {
// Not ours, and we don't have solving data.
return false;
}
input_bytes = CalculateMaximumSignedInputSize(txout, &coin_control.m_external_provider, /* use_max_sig */ true);
}
CInputCoin coin(outpoint, txout, input_bytes);
nValueFromPresetInputs += coin.txout.nValue;
if (coin.m_input_bytes == -1) {
return false; // Not solvable, can't estimate size for fee
}
coin.effective_value = coin.txout.nValue - coin_selection_params.m_effective_feerate.GetFee(coin.m_input_bytes);
if (coin_selection_params.m_subtract_fee_outputs) {
value_to_select -= coin.txout.nValue;
} else {
value_to_select -= coin.effective_value;
}
setPresetCoins.insert(coin);
}
// remove preset inputs from vCoins so that Coin Selection doesn't pick them.
for (std::vector<COutput>::iterator it = vCoins.begin(); it != vCoins.end() && coin_control.HasSelected();)
{
if (setPresetCoins.count(it->GetInputCoin()))
it = vCoins.erase(it);
else
++it;
}
unsigned int limit_ancestor_count = 0;
unsigned int limit_descendant_count = 0;
wallet.chain().getPackageLimits(limit_ancestor_count, limit_descendant_count);
const size_t max_ancestors = (size_t)std::max<int64_t>(1, limit_ancestor_count);
const size_t max_descendants = (size_t)std::max<int64_t>(1, limit_descendant_count);
const bool fRejectLongChains = gArgs.GetBoolArg("-walletrejectlongchains", DEFAULT_WALLET_REJECT_LONG_CHAINS);
// form groups from remaining coins; note that preset coins will not
// automatically have their associated (same address) coins included
if (coin_control.m_avoid_partial_spends && vCoins.size() > OUTPUT_GROUP_MAX_ENTRIES) {
// Cases where we have 101+ outputs all pointing to the same destination may result in
// privacy leaks as they will potentially be deterministically sorted. We solve that by
// explicitly shuffling the outputs before processing
Shuffle(vCoins.begin(), vCoins.end(), FastRandomContext());
}
// Coin Selection attempts to select inputs from a pool of eligible UTXOs to fund the
// transaction at a target feerate. If an attempt fails, more attempts may be made using a more
// permissive CoinEligibilityFilter.
const bool res = [&] {
// Pre-selected inputs already cover the target amount.
if (value_to_select <= 0) return true;
// If possible, fund the transaction with confirmed UTXOs only. Prefer at least six
// confirmations on outputs received from other wallets and only spend confirmed change.
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(1, 6, 0), vCoins, setCoinsRet, nValueRet, coin_selection_params)) return true;
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(1, 1, 0), vCoins, setCoinsRet, nValueRet, coin_selection_params)) return true;
// Fall back to using zero confirmation change (but with as few ancestors in the mempool as
// possible) if we cannot fund the transaction otherwise.
if (wallet.m_spend_zero_conf_change) {
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(0, 1, 2), vCoins, setCoinsRet, nValueRet, coin_selection_params)) return true;
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(0, 1, std::min((size_t)4, max_ancestors/3), std::min((size_t)4, max_descendants/3)),
vCoins, setCoinsRet, nValueRet, coin_selection_params)) {
return true;
}
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(0, 1, max_ancestors/2, max_descendants/2),
vCoins, setCoinsRet, nValueRet, coin_selection_params)) {
return true;
}
// If partial groups are allowed, relax the requirement of spending OutputGroups (groups
// of UTXOs sent to the same address, which are obviously controlled by a single wallet)
// in their entirety.
if (AttemptSelection(wallet, value_to_select, CoinEligibilityFilter(0, 1, max_ancestors-1, max_descendants-1, true /* include_partial_groups */),
vCoins, setCoinsRet, nValueRet, coin_selection_params)) {
return true;
}
// Try with unsafe inputs if they are allowed. This may spend unconfirmed outputs
// received from other wallets.
if (coin_control.m_include_unsafe_inputs
&& AttemptSelection(wallet, value_to_select,
CoinEligibilityFilter(0 /* conf_mine */, 0 /* conf_theirs */, max_ancestors-1, max_descendants-1, true /* include_partial_groups */),
vCoins, setCoinsRet, nValueRet, coin_selection_params)) {
return true;
}
// Try with unlimited ancestors/descendants. The transaction will still need to meet
// mempool ancestor/descendant policy to be accepted to mempool and broadcasted, but
// OutputGroups use heuristics that may overestimate ancestor/descendant counts.
if (!fRejectLongChains && AttemptSelection(wallet, value_to_select,
CoinEligibilityFilter(0, 1, std::numeric_limits<uint64_t>::max(), std::numeric_limits<uint64_t>::max(), true /* include_partial_groups */),
vCoins, setCoinsRet, nValueRet, coin_selection_params)) {
return true;
}
}
// Coin Selection failed.
return false;
}();
// AttemptSelection clears setCoinsRet, so add the preset inputs from coin_control to the coinset
util::insert(setCoinsRet, setPresetCoins);
// add preset inputs to the total value selected
nValueRet += nValueFromPresetInputs;
return res;
}
static bool IsCurrentForAntiFeeSniping(interfaces::Chain& chain, const uint256& block_hash)
{
if (chain.isInitialBlockDownload()) {
return false;
}
constexpr int64_t MAX_ANTI_FEE_SNIPING_TIP_AGE = 8 * 60 * 60; // in seconds
int64_t block_time;
CHECK_NONFATAL(chain.findBlock(block_hash, FoundBlock().time(block_time)));
if (block_time < (GetTime() - MAX_ANTI_FEE_SNIPING_TIP_AGE)) {
return false;
}
return true;
}
/**
* Return a height-based locktime for new transactions (uses the height of the
* current chain tip unless we are not synced with the current chain
*/
static uint32_t GetLocktimeForNewTransaction(interfaces::Chain& chain, const uint256& block_hash, int block_height)
{
uint32_t locktime;
// Discourage fee sniping.
//
// For a large miner the value of the transactions in the best block and
// the mempool can exceed the cost of deliberately attempting to mine two
// blocks to orphan the current best block. By setting nLockTime such that
// only the next block can include the transaction, we discourage this
// practice as the height restricted and limited blocksize gives miners
// considering fee sniping fewer options for pulling off this attack.
//
// A simple way to think about this is from the wallet's point of view we
// always want the blockchain to move forward. By setting nLockTime this
// way we're basically making the statement that we only want this
// transaction to appear in the next block; we don't want to potentially
// encourage reorgs by allowing transactions to appear at lower heights
// than the next block in forks of the best chain.
//
// Of course, the subsidy is high enough, and transaction volume low
// enough, that fee sniping isn't a problem yet, but by implementing a fix
// now we ensure code won't be written that makes assumptions about
// nLockTime that preclude a fix later.
if (IsCurrentForAntiFeeSniping(chain, block_hash)) {
locktime = block_height;
// Secondly occasionally randomly pick a nLockTime even further back, so
// that transactions that are delayed after signing for whatever reason,
// e.g. high-latency mix networks and some CoinJoin implementations, have
// better privacy.
if (GetRandInt(10) == 0)
locktime = std::max(0, (int)locktime - GetRandInt(100));
} else {
// If our chain is lagging behind, we can't discourage fee sniping nor help
// the privacy of high-latency transactions. To avoid leaking a potentially
// unique "nLockTime fingerprint", set nLockTime to a constant.
locktime = 0;
}
assert(locktime < LOCKTIME_THRESHOLD);
return locktime;
}
static bool CreateTransactionInternal(
CWallet& wallet,
const std::vector<CRecipient>& vecSend,
CTransactionRef& tx,
CAmount& nFeeRet,
int& nChangePosInOut,
bilingual_str& error,
const CCoinControl& coin_control,
FeeCalculation& fee_calc_out,
bool sign) EXCLUSIVE_LOCKS_REQUIRED(wallet.cs_wallet)
{
AssertLockHeld(wallet.cs_wallet);
CMutableTransaction txNew; // The resulting transaction that we make
txNew.nLockTime = GetLocktimeForNewTransaction(wallet.chain(), wallet.GetLastBlockHash(), wallet.GetLastBlockHeight());
CoinSelectionParams coin_selection_params; // Parameters for coin selection, init with dummy
coin_selection_params.m_avoid_partial_spends = coin_control.m_avoid_partial_spends;
// Set the long term feerate estimate to the wallet's consolidate feerate
coin_selection_params.m_long_term_feerate = wallet.m_consolidate_feerate;
CAmount recipients_sum = 0;
const OutputType change_type = wallet.TransactionChangeType(coin_control.m_change_type ? *coin_control.m_change_type : wallet.m_default_change_type, vecSend);
ReserveDestination reservedest(&wallet, change_type);
unsigned int outputs_to_subtract_fee_from = 0; // The number of outputs which we are subtracting the fee from
for (const auto& recipient : vecSend) {
recipients_sum += recipient.nAmount;
if (recipient.fSubtractFeeFromAmount) {
outputs_to_subtract_fee_from++;
coin_selection_params.m_subtract_fee_outputs = true;
}
}
// Create change script that will be used if we need change
// TODO: pass in scriptChange instead of reservedest so
// change transaction isn't always pay-to-bitcoin-address
CScript scriptChange;
// coin control: send change to custom address
if (!std::get_if<CNoDestination>(&coin_control.destChange)) {
scriptChange = GetScriptForDestination(coin_control.destChange);
} else { // no coin control: send change to newly generated address
// Note: We use a new key here to keep it from being obvious which side is the change.
// The drawback is that by not reusing a previous key, the change may be lost if a
// backup is restored, if the backup doesn't have the new private key for the change.
// If we reused the old key, it would be possible to add code to look for and
// rediscover unknown transactions that were written with keys of ours to recover
// post-backup change.
// Reserve a new key pair from key pool. If it fails, provide a dummy
// destination in case we don't need change.
CTxDestination dest;
bilingual_str dest_err;
if (!reservedest.GetReservedDestination(dest, true, dest_err)) {
error = _("Transaction needs a change address, but we can't generate it.") + Untranslated(" ") + dest_err;
}
scriptChange = GetScriptForDestination(dest);
// A valid destination implies a change script (and
// vice-versa). An empty change script will abort later, if the
// change keypool ran out, but change is required.
CHECK_NONFATAL(IsValidDestination(dest) != scriptChange.empty());
}
CTxOut change_prototype_txout(0, scriptChange);
coin_selection_params.change_output_size = GetSerializeSize(change_prototype_txout);
// Get size of spending the change output
int change_spend_size = CalculateMaximumSignedInputSize(change_prototype_txout, &wallet);
// If the wallet doesn't know how to sign change output, assume p2sh-p2wpkh
// as lower-bound to allow BnB to do it's thing
if (change_spend_size == -1) {
coin_selection_params.change_spend_size = DUMMY_NESTED_P2WPKH_INPUT_SIZE;
} else {
coin_selection_params.change_spend_size = (size_t)change_spend_size;
}
// Set discard feerate
coin_selection_params.m_discard_feerate = GetDiscardRate(wallet);
// Get the fee rate to use effective values in coin selection
FeeCalculation feeCalc;
coin_selection_params.m_effective_feerate = GetMinimumFeeRate(wallet, coin_control, &feeCalc);
// Do not, ever, assume that it's fine to change the fee rate if the user has explicitly
// provided one
if (coin_control.m_feerate && coin_selection_params.m_effective_feerate > *coin_control.m_feerate) {
error = strprintf(_("Fee rate (%s) is lower than the minimum fee rate setting (%s)"), coin_control.m_feerate->ToString(FeeEstimateMode::SAT_VB), coin_selection_params.m_effective_feerate.ToString(FeeEstimateMode::SAT_VB));
return false;
}
if (feeCalc.reason == FeeReason::FALLBACK && !wallet.m_allow_fallback_fee) {
// eventually allow a fallback fee
error = _("Fee estimation failed. Fallbackfee is disabled. Wait a few blocks or enable -fallbackfee.");
return false;
}
// Calculate the cost of change
// Cost of change is the cost of creating the change output + cost of spending the change output in the future.
// For creating the change output now, we use the effective feerate.
// For spending the change output in the future, we use the discard feerate for now.
// So cost of change = (change output size * effective feerate) + (size of spending change output * discard feerate)
coin_selection_params.m_change_fee = coin_selection_params.m_effective_feerate.GetFee(coin_selection_params.change_output_size);
coin_selection_params.m_cost_of_change = coin_selection_params.m_discard_feerate.GetFee(coin_selection_params.change_spend_size) + coin_selection_params.m_change_fee;
// vouts to the payees
if (!coin_selection_params.m_subtract_fee_outputs) {
coin_selection_params.tx_noinputs_size = 11; // Static vsize overhead + outputs vsize. 4 nVersion, 4 nLocktime, 1 input count, 1 output count, 1 witness overhead (dummy, flag, stack size)
}
for (const auto& recipient : vecSend)
{
CTxOut txout(recipient.nAmount, recipient.scriptPubKey);
// Include the fee cost for outputs.
if (!coin_selection_params.m_subtract_fee_outputs) {
coin_selection_params.tx_noinputs_size += ::GetSerializeSize(txout, PROTOCOL_VERSION);
}
if (IsDust(txout, wallet.chain().relayDustFee()))
{
error = _("Transaction amount too small");
return false;
}
txNew.vout.push_back(txout);
}
// Include the fees for things that aren't inputs, excluding the change output
const CAmount not_input_fees = coin_selection_params.m_effective_feerate.GetFee(coin_selection_params.tx_noinputs_size);
CAmount selection_target = recipients_sum + not_input_fees;
// Get available coins
std::vector<COutput> vAvailableCoins;
AvailableCoins(wallet, vAvailableCoins, &coin_control, 1, MAX_MONEY, MAX_MONEY, 0);
// Choose coins to use
CAmount inputs_sum = 0;
std::set<CInputCoin> setCoins;
if (!SelectCoins(wallet, vAvailableCoins, /* nTargetValue */ selection_target, setCoins, inputs_sum, coin_control, coin_selection_params))
{
error = _("Insufficient funds");
return false;
}
// Always make a change output
// We will reduce the fee from this change output later, and remove the output if it is too small.
const CAmount change_and_fee = inputs_sum - recipients_sum;
assert(change_and_fee >= 0);
CTxOut newTxOut(change_and_fee, scriptChange);
if (nChangePosInOut == -1)
{
// Insert change txn at random position:
nChangePosInOut = GetRandInt(txNew.vout.size()+1);
}
else if ((unsigned int)nChangePosInOut > txNew.vout.size())
{
error = _("Change index out of range");
return false;
}
assert(nChangePosInOut != -1);
auto change_position = txNew.vout.insert(txNew.vout.begin() + nChangePosInOut, newTxOut);
// Shuffle selected coins and fill in final vin
std::vector<CInputCoin> selected_coins(setCoins.begin(), setCoins.end());
Shuffle(selected_coins.begin(), selected_coins.end(), FastRandomContext());
// Note how the sequence number is set to non-maxint so that
// the nLockTime set above actually works.
//
// BIP125 defines opt-in RBF as any nSequence < maxint-1, so
// we use the highest possible value in that range (maxint-2)
// to avoid conflicting with other possible uses of nSequence,
// and in the spirit of "smallest possible change from prior
// behavior."
const uint32_t nSequence = coin_control.m_signal_bip125_rbf.value_or(wallet.m_signal_rbf) ? MAX_BIP125_RBF_SEQUENCE : (CTxIn::SEQUENCE_FINAL - 1);
for (const auto& coin : selected_coins) {
txNew.vin.push_back(CTxIn(coin.outpoint, CScript(), nSequence));
}
// Calculate the transaction fee
TxSize tx_sizes = CalculateMaximumSignedTxSize(CTransaction(txNew), &wallet, &coin_control);
int nBytes = tx_sizes.vsize;
if (nBytes == -1) {
error = _("Missing solving data for estimating transaction size");
return false;
}
nFeeRet = coin_selection_params.m_effective_feerate.GetFee(nBytes);
// Subtract fee from the change output if not subtracting it from recipient outputs
CAmount fee_needed = nFeeRet;
if (!coin_selection_params.m_subtract_fee_outputs) {
change_position->nValue -= fee_needed;
}
// We want to drop the change to fees if:
// 1. The change output would be dust
// 2. The change is within the (almost) exact match window, i.e. it is less than or equal to the cost of the change output (cost_of_change)
CAmount change_amount = change_position->nValue;
if (IsDust(*change_position, coin_selection_params.m_discard_feerate) || change_amount <= coin_selection_params.m_cost_of_change)
{
nChangePosInOut = -1;
change_amount = 0;
txNew.vout.erase(change_position);
// Because we have dropped this change, the tx size and required fee will be different, so let's recalculate those
tx_sizes = CalculateMaximumSignedTxSize(CTransaction(txNew), &wallet, &coin_control);
nBytes = tx_sizes.vsize;
fee_needed = coin_selection_params.m_effective_feerate.GetFee(nBytes);
}
// The only time that fee_needed should be less than the amount available for fees (in change_and_fee - change_amount) is when
// we are subtracting the fee from the outputs. If this occurs at any other time, it is a bug.
assert(coin_selection_params.m_subtract_fee_outputs || fee_needed <= change_and_fee - change_amount);
// Update nFeeRet in case fee_needed changed due to dropping the change output
if (fee_needed <= change_and_fee - change_amount) {
nFeeRet = change_and_fee - change_amount;
}
// Reduce output values for subtractFeeFromAmount
if (coin_selection_params.m_subtract_fee_outputs) {
CAmount to_reduce = fee_needed + change_amount - change_and_fee;
int i = 0;
bool fFirst = true;
for (const auto& recipient : vecSend)
{
if (i == nChangePosInOut) {
++i;
}
CTxOut& txout = txNew.vout[i];
if (recipient.fSubtractFeeFromAmount)
{
txout.nValue -= to_reduce / outputs_to_subtract_fee_from; // Subtract fee equally from each selected recipient
if (fFirst) // first receiver pays the remainder not divisible by output count
{
fFirst = false;
txout.nValue -= to_reduce % outputs_to_subtract_fee_from;
}
// Error if this output is reduced to be below dust
if (IsDust(txout, wallet.chain().relayDustFee())) {
if (txout.nValue < 0) {
error = _("The transaction amount is too small to pay the fee");
} else {
error = _("The transaction amount is too small to send after the fee has been deducted");
}
return false;
}
}
++i;
}
nFeeRet = fee_needed;
}
// Give up if change keypool ran out and change is required
if (scriptChange.empty() && nChangePosInOut != -1) {
return false;
}
if (sign && !wallet.SignTransaction(txNew)) {
error = _("Signing transaction failed");
return false;
}
// Return the constructed transaction data.
tx = MakeTransactionRef(std::move(txNew));
// Limit size
if ((sign && GetTransactionWeight(*tx) > MAX_STANDARD_TX_WEIGHT) ||
(!sign && tx_sizes.weight > MAX_STANDARD_TX_WEIGHT))
{
error = _("Transaction too large");
return false;
}
if (nFeeRet > wallet.m_default_max_tx_fee) {
error = TransactionErrorString(TransactionError::MAX_FEE_EXCEEDED);
return false;
}
if (gArgs.GetBoolArg("-walletrejectlongchains", DEFAULT_WALLET_REJECT_LONG_CHAINS)) {
// Lastly, ensure this tx will pass the mempool's chain limits
if (!wallet.chain().checkChainLimits(tx)) {
error = _("Transaction has too long of a mempool chain");
return false;
}
}
// Before we return success, we assume any change key will be used to prevent
// accidental re-use.
reservedest.KeepDestination();
fee_calc_out = feeCalc;
wallet.WalletLogPrintf("Fee Calculation: Fee:%d Bytes:%u Tgt:%d (requested %d) Reason:\"%s\" Decay %.5f: Estimation: (%g - %g) %.2f%% %.1f/(%.1f %d mem %.1f out) Fail: (%g - %g) %.2f%% %.1f/(%.1f %d mem %.1f out)\n",
nFeeRet, nBytes, feeCalc.returnedTarget, feeCalc.desiredTarget, StringForFeeReason(feeCalc.reason), feeCalc.est.decay,
feeCalc.est.pass.start, feeCalc.est.pass.end,
(feeCalc.est.pass.totalConfirmed + feeCalc.est.pass.inMempool + feeCalc.est.pass.leftMempool) > 0.0 ? 100 * feeCalc.est.pass.withinTarget / (feeCalc.est.pass.totalConfirmed + feeCalc.est.pass.inMempool + feeCalc.est.pass.leftMempool) : 0.0,
feeCalc.est.pass.withinTarget, feeCalc.est.pass.totalConfirmed, feeCalc.est.pass.inMempool, feeCalc.est.pass.leftMempool,
feeCalc.est.fail.start, feeCalc.est.fail.end,
(feeCalc.est.fail.totalConfirmed + feeCalc.est.fail.inMempool + feeCalc.est.fail.leftMempool) > 0.0 ? 100 * feeCalc.est.fail.withinTarget / (feeCalc.est.fail.totalConfirmed + feeCalc.est.fail.inMempool + feeCalc.est.fail.leftMempool) : 0.0,
feeCalc.est.fail.withinTarget, feeCalc.est.fail.totalConfirmed, feeCalc.est.fail.inMempool, feeCalc.est.fail.leftMempool);
return true;
}
bool CreateTransaction(
CWallet& wallet,
const std::vector<CRecipient>& vecSend,
CTransactionRef& tx,
CAmount& nFeeRet,
int& nChangePosInOut,
bilingual_str& error,
const CCoinControl& coin_control,
FeeCalculation& fee_calc_out,
bool sign)
{
if (vecSend.empty()) {
error = _("Transaction must have at least one recipient");
return false;
}
if (std::any_of(vecSend.cbegin(), vecSend.cend(), [](const auto& recipient){ return recipient.nAmount < 0; })) {
error = _("Transaction amounts must not be negative");
return false;
}
LOCK(wallet.cs_wallet);
int nChangePosIn = nChangePosInOut;
Assert(!tx); // tx is an out-param. TODO change the return type from bool to tx (or nullptr)
bool res = CreateTransactionInternal(wallet, vecSend, tx, nFeeRet, nChangePosInOut, error, coin_control, fee_calc_out, sign);
// try with avoidpartialspends unless it's enabled already
if (res && nFeeRet > 0 /* 0 means non-functional fee rate estimation */ && wallet.m_max_aps_fee > -1 && !coin_control.m_avoid_partial_spends) {
CCoinControl tmp_cc = coin_control;
tmp_cc.m_avoid_partial_spends = true;
CAmount nFeeRet2;
CTransactionRef tx2;
int nChangePosInOut2 = nChangePosIn;
bilingual_str error2; // fired and forgotten; if an error occurs, we discard the results
if (CreateTransactionInternal(wallet, vecSend, tx2, nFeeRet2, nChangePosInOut2, error2, tmp_cc, fee_calc_out, sign)) {
// if fee of this alternative one is within the range of the max fee, we use this one
const bool use_aps = nFeeRet2 <= nFeeRet + wallet.m_max_aps_fee;
wallet.WalletLogPrintf("Fee non-grouped = %lld, grouped = %lld, using %s\n", nFeeRet, nFeeRet2, use_aps ? "grouped" : "non-grouped");
if (use_aps) {
tx = tx2;
nFeeRet = nFeeRet2;
nChangePosInOut = nChangePosInOut2;
}
}
}
return res;
}
bool FundTransaction(CWallet& wallet, CMutableTransaction& tx, CAmount& nFeeRet, int& nChangePosInOut, bilingual_str& error, bool lockUnspents, const std::set<int>& setSubtractFeeFromOutputs, CCoinControl coinControl)
{
std::vector<CRecipient> vecSend;
// Turn the txout set into a CRecipient vector.
for (size_t idx = 0; idx < tx.vout.size(); idx++) {
const CTxOut& txOut = tx.vout[idx];
CRecipient recipient = {txOut.scriptPubKey, txOut.nValue, setSubtractFeeFromOutputs.count(idx) == 1};
vecSend.push_back(recipient);
}
coinControl.fAllowOtherInputs = true;
for (const CTxIn& txin : tx.vin) {
coinControl.Select(txin.prevout);
}
// Acquire the locks to prevent races to the new locked unspents between the
// CreateTransaction call and LockCoin calls (when lockUnspents is true).
LOCK(wallet.cs_wallet);
CTransactionRef tx_new;
FeeCalculation fee_calc_out;
if (!CreateTransaction(wallet, vecSend, tx_new, nFeeRet, nChangePosInOut, error, coinControl, fee_calc_out, false)) {
return false;
}
if (nChangePosInOut != -1) {
tx.vout.insert(tx.vout.begin() + nChangePosInOut, tx_new->vout[nChangePosInOut]);
}
// Copy output sizes from new transaction; they may have had the fee
// subtracted from them.
for (unsigned int idx = 0; idx < tx.vout.size(); idx++) {
tx.vout[idx].nValue = tx_new->vout[idx].nValue;
}
// Add new txins while keeping original txin scriptSig/order.
for (const CTxIn& txin : tx_new->vin) {
if (!coinControl.IsSelected(txin.prevout)) {
tx.vin.push_back(txin);
}
if (lockUnspents) {
wallet.LockCoin(txin.prevout);
}
}
return true;
}
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