diff --git a/crates/view/src/planner.rs b/crates/view/src/planner.rs index 7c77099d0f..9ad42333b8 100644 --- a/crates/view/src/planner.rs +++ b/crates/view/src/planner.rs @@ -4,21 +4,21 @@ use std::{ mem, }; -use anyhow::Result; +use anyhow::{ensure, Result}; use penumbra_sct::epoch::Epoch; use rand::{CryptoRng, RngCore}; use rand_core::OsRng; use tracing::instrument; -use penumbra_asset::{asset, Balance, Value}; -// use penumbra_auction::auction::dutch::actions::ActionDutchAuctionWithdrawPlan; -// use penumbra_auction::auction::dutch::DutchAuctionDescription; -// use penumbra_auction::auction::{ -// dutch::actions::{ActionDutchAuctionEnd, ActionDutchAuctionSchedule}, -// AuctionId, -// }; use crate::{SpendableNoteRecord, ViewClient}; use anyhow::anyhow; +use penumbra_asset::{asset, Balance, Value}; +use penumbra_auction::auction::dutch::actions::ActionDutchAuctionWithdrawPlan; +use penumbra_auction::auction::dutch::DutchAuctionDescription; +use penumbra_auction::auction::{ + dutch::actions::{ActionDutchAuctionEnd, ActionDutchAuctionSchedule}, + AuctionId, +}; use penumbra_community_pool::CommunityPoolDeposit; use penumbra_dex::{ lp::action::{PositionClose, PositionOpen}, @@ -38,12 +38,12 @@ use penumbra_governance::{ use penumbra_ibc::IbcRelay; use penumbra_keys::{keys::AddressIndex, Address}; use penumbra_num::Amount; -use penumbra_proto::view::v1::{NotesForVotingRequest, NotesRequest}; +use penumbra_proto::view::v1::NotesRequest; use penumbra_shielded_pool::{Ics20Withdrawal, Note, OutputPlan, SpendPlan}; use penumbra_stake::{rate::RateData, validator, IdentityKey, UndelegateClaimPlan}; use penumbra_tct as tct; use penumbra_transaction::{ - gas::{self, GasCost}, + gas::GasCost, memo::MemoPlaintext, plan::{ActionPlan, MemoPlan, TransactionPlan}, TransactionParameters, @@ -53,33 +53,24 @@ use penumbra_transaction::{ /// finalization to make a transaction balance. pub struct Planner { rng: R, - balance: Balance, - vote_intents: BTreeMap, + /// The transaction plan to materialize. plan: TransactionPlan, - ibc_actions: Vec, - gas_prices: GasPrices, - fee_tier: FeeTier, // A list of the user-specified outputs. actions: Vec, // These are tracked separately for convenience when adjusting change. change_outputs: BTreeMap, - // IMPORTANT: if you add more fields here, make sure to clear them when the planner is finished -} - -#[derive(Debug, Clone)] -struct VoteIntent { - start_block_height: u64, - start_position: tct::Position, - rate_data: BTreeMap, - vote: Vote, + /// The fee tier to apply to this transaction. + fee_tier: FeeTier, + /// The set of prices used for gas estimation. + gas_prices: GasPrices, + /// The set of IBC actions to include in the transaction. + ibc_actions: Vec, + vote_intents: BTreeMap, } impl Debug for Planner { fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { - f.debug_struct("Builder") - .field("balance", &self.balance) - .field("plan", &self.plan) - .finish() + f.debug_struct("Builder").field("plan", &self.plan).finish() } } @@ -88,7 +79,6 @@ impl Planner { pub fn new(rng: R) -> Self { Self { rng, - balance: Balance::default(), vote_intents: BTreeMap::default(), plan: TransactionPlan::default(), ibc_actions: Vec::new(), @@ -99,179 +89,6 @@ impl Planner { } } - fn balance(&self) -> Balance { - let mut balance = Balance::zero(); - for action in &self.actions { - balance += action.balance(); - } - for action in self.change_outputs.values() { - balance += action.balance(); - } - balance - } - - fn push(&mut self, action: ActionPlan) { - self.actions.push(action); - } - - pub fn add_votes( - &mut self, - voting_notes: Vec>, - ) -> Result<()> { - for ( - records, - ( - proposal, - VoteIntent { - start_position, - vote, - rate_data, - .. - }, - ), - ) in voting_notes - .into_iter() - .chain(std::iter::repeat(vec![])) // Chain with infinite repeating no notes, so the zip doesn't stop early - .zip(mem::take(&mut self.vote_intents).into_iter()) - { - // Keep track of whether we successfully could vote on this proposal - let mut voted = false; - - for (record, identity_key) in records { - // Vote with precisely this note on the proposal, computing the correct exchange - // rate for self-minted vote receipt tokens using the exchange rate of the validator - // at voting start time. If the validator was not active at the start of the - // proposal, the vote will be rejected by stateful verification, so skip the note - // and continue to the next one. - let Some(rate_data) = rate_data.get(&identity_key) else { - continue; - }; - let unbonded_amount = rate_data.unbonded_amount(record.note.amount()).into(); - - // If the delegation token is unspent, "roll it over" by spending it (this will - // result in change sent back to us). This unlinks nullifiers used for voting on - // multiple non-overlapping proposals, increasing privacy. - if record.height_spent.is_none() { - self.push( - SpendPlan::new(&mut OsRng, record.note.clone(), record.position).into(), - ); - } - - self.delegator_vote_precise( - proposal, - start_position, - vote, - record.note, - record.position, - unbonded_amount, - ); - - voted = true; - } - - if !voted { - // If there are no notes to vote with, return an error, because otherwise the user - // would compose a transaction that would not satisfy their intention, and would - // silently eat the fee. - anyhow::bail!( - "can't vote on proposal {} because no delegation notes were staked to an active validator when voting started", - proposal - ); - } - } - - Ok(()) - } - - fn gas_estimate(&self) -> Gas { - // TODO: this won't include the gas cost for the bytes of the tx itself - // so this gas estimate will be an underestimate, but since the tx-bytes contribution - // to the fee is ideally small, hopefully it doesn't matter. - let mut gas = Gas::zero(); - for action in &self.actions { - // TODO missing AddAssign - gas = gas + action.gas_cost(); - } - for action in self.change_outputs.values() { - // TODO missing AddAssign - // TODO missing GasCost impl on OutputPlan - gas = gas + ActionPlan::from(action.clone()).gas_cost(); - } - - gas - } - - fn fee_estimate(&self, gas_prices: &GasPrices, fee_tier: &FeeTier) -> Fee { - let base_fee = Fee::from_staking_token_amount(gas_prices.fee(&self.gas_estimate())); - let fee = base_fee.apply_tier(*fee_tier); - - fee - } - - fn balance_with_fee_estimate(&self, gas_prices: &GasPrices, fee_tier: &FeeTier) -> Balance { - self.balance() - self.fee_estimate(gas_prices, fee_tier).0 - } - - fn refresh_change(&mut self, change_address: Address) { - self.change_outputs = BTreeMap::new(); - // For each "provided" balance component, create a change note. - for value in self.balance().provided() { - self.change_outputs.insert( - value.asset_id, - OutputPlan::new(&mut OsRng, value, change_address.clone()), - ); - } - } - - fn adjust_change_for_fee(&mut self, fee: Fee) { - self.change_outputs.entry(fee.0.asset_id).and_modify(|e| { - e.value.amount = e.value.amount.saturating_sub(&fee.0.amount); - }); - } - - /// Prioritize notes to spend to release value of a specific transaction. - /// - /// Various logic is possible for note selection. Currently, this method - /// prioritizes notes sent to a one-time address, then notes with the largest - /// value: - /// - /// - Prioritizing notes sent to one-time addresses optimizes for a future in - /// which we implement DAGSync keyed by fuzzy message detection (which will not - /// be able to detect notes sent to one-time addresses). Spending these notes - /// immediately converts them into change notes, sent to the default address for - /// the users' account, which are detectable. - /// - /// - Prioritizing notes with the largest value optimizes for gas used by the - /// transaction. - /// - /// We may want to make note prioritization configurable in the future. For - /// instance, a user might prefer a note prioritization strategy that harvested - /// capital losses when possible, using cost basis information retained by the - /// view server. - fn prioritize_and_filter_spendable_notes( - records: Vec, - ) -> Vec { - let mut filtered = records - .into_iter() - .filter(|record| record.note.amount() > Amount::zero()) - .collect::>(); - - filtered.sort_by(|a, b| { - // Sort by whether the note was sent to an ephemeral address... - match ( - a.address_index.is_ephemeral(), - b.address_index.is_ephemeral(), - ) { - (true, false) => std::cmp::Ordering::Less, - (false, true) => std::cmp::Ordering::Greater, - // ... then by largest amount. - _ => b.note.amount().cmp(&a.note.amount()), - } - }); - - filtered - } - /// Set the current gas prices for fee prediction. #[instrument(skip(self))] pub fn set_gas_prices(&mut self, gas_prices: GasPrices) -> &mut Self { @@ -286,38 +103,6 @@ impl Planner { self } - /// Get all the note requests necessary to fulfill the current [`Balance`]. - pub fn notes_requests( - &self, - source: AddressIndex, - ) -> (Vec, Vec) { - ( - self.balance - .required() - .map(|Value { asset_id, amount }| NotesRequest { - asset_id: Some(asset_id.into()), - address_index: Some(source.into()), - amount_to_spend: Some(amount.into()), - include_spent: false, - }) - .collect(), - self.vote_intents - .iter() - .map( - |( - _proposal, // The request only cares about the start block height - VoteIntent { - start_block_height, .. - }, - )| NotesForVotingRequest { - votable_at_height: *start_block_height, - address_index: Some(source.into()), - }, - ) - .collect(), - ) - } - /// Set the expiry height for the transaction plan. #[instrument(skip(self))] pub fn expiry_height(&mut self, expiry_height: u64) -> &mut Self { @@ -339,47 +124,25 @@ impl Planner { /// This function should be called once. #[instrument(skip(self))] pub fn fee(&mut self, fee: Fee) -> &mut Self { - self.balance += fee.0; self.plan.transaction_parameters.fee = fee; self } - /// Calculate gas cost-based fees and add to the transaction plan. - /// - /// This function should be called once. - // TODO: clarify why we have both `add_gas_fees` and `fee` - // should one be `auto_fee` and the other `set_fee`? + /// Spend a specific positioned note in the transaction. #[instrument(skip(self))] - pub fn add_gas_fees(&mut self) -> &mut Self { - // Add a single Spend + Output to the minimum fee to cover paying the fee - let minimum_fee = self - .gas_prices - .fee(&(self.plan.gas_cost() + gas::output_gas_cost() + gas::spend_gas_cost())); - - // Since paying the fee possibly requires adding additional Spends and Outputs - // to the transaction, which would then change the fee calculation, we multiply - // the fee here by a factor of 128 and then recalculate and capture the excess as - // change outputs. - // - // TODO: this is gross and depending on gas costs could make the gas overpayment - // ridiculously large (so large that the account may not have notes available to cover it) - // or too small. We may need a cyclical calculation of fees on the transaction plan, - // or a "simulated" transaction plan with infinite assets to calculate fees on before - // copying the exact fees to the real transaction. - let fee = Fee::from_staking_token_amount(minimum_fee * Amount::from(128u32)); - self.balance -= fee.0; - self.plan.transaction_parameters.fee = fee.clone(); + pub fn spend(&mut self, note: Note, position: tct::Position) -> &mut Self { + let spend = SpendPlan::new(&mut self.rng, note, position).into(); + self.action(spend); self } - /// Spend a specific positioned note in the transaction. + /// Add an output note from this transaction. /// - /// If you don't use this method to specify spends, they will be filled in automatically from - /// the view service when the plan is [`finish`](Planner::finish)ed. + /// Any unused output value will be redirected back to the originating address as change notes. #[instrument(skip(self))] - pub fn spend(&mut self, note: Note, position: tct::Position) -> &mut Self { - let spend = SpendPlan::new(&mut self.rng, note, position).into(); - self.action(spend); + pub fn output(&mut self, value: Value, address: Address) -> &mut Self { + let output = OutputPlan::new(&mut self.rng, value, address).into(); + self.action(output); self } @@ -417,16 +180,59 @@ impl Planner { self } - /// Perform a swap claim based on an input swap NFT with a pre-paid fee. + /// Schedule a Dutch auction. #[instrument(skip(self))] - pub fn swap_claim(&mut self, plan: SwapClaimPlan) -> &mut Self { - // Nothing needs to be spent, since the fee is pre-paid and the - // swap NFT will be automatically consumed when the SwapClaim action - // is processed by the validators. - // TODO: need to set the intended fee so the tx actually balances, - // otherwise the planner will create an output - self.action(plan.into()); - self + pub fn dutch_auction_schedule( + &mut self, + input: Value, + output_id: asset::Id, + max_output: Amount, + min_output: Amount, + start_height: u64, + end_height: u64, + step_count: u64, + nonce: [u8; 32], + ) -> &mut Self { + self.action(ActionPlan::ActionDutchAuctionSchedule( + ActionDutchAuctionSchedule { + description: DutchAuctionDescription { + input, + output_id, + max_output, + min_output, + start_height, + end_height, + step_count, + nonce, + }, + }, + )) + } + + /// Ends a Dutch auction. + #[instrument(skip(self))] + pub fn dutch_auction_end(&mut self, auction_id: AuctionId) -> &mut Self { + self.action(ActionPlan::ActionDutchAuctionEnd(ActionDutchAuctionEnd { + auction_id, + })) + } + /// Withdraws the reserves of the Dutch auction. + #[instrument(skip(self))] + pub fn dutch_auction_withdraw( + &mut self, + auction_id: AuctionId, + seq: u64, + reserves_input: Value, + reserves_output: Value, + ) -> &mut Self { + self.action(ActionPlan::ActionDutchAuctionWithdraw( + ActionDutchAuctionWithdrawPlan { + auction_id, + seq, + reserves_input, + reserves_output, + }, + )) } /// Perform a swap based on input notes in the transaction. @@ -473,14 +279,10 @@ impl Planner { Ok(self) } - /// Add an output note from this transaction. - /// - /// Any unused output value will be redirected back to the originating address as change notes - /// when the plan is [`finish`](Builder::finish)ed. + /// Perform a swap claim based on an input swap NFT with a pre-paid fee. #[instrument(skip(self))] - pub fn output(&mut self, value: Value, address: Address) -> &mut Self { - let output = OutputPlan::new(&mut self.rng, value, address).into(); - self.action(output); + pub fn swap_claim(&mut self, plan: SwapClaimPlan) -> &mut Self { + self.action(plan.into()); self } @@ -500,8 +302,6 @@ impl Planner { } /// Add an undelegation to this transaction. - /// - /// TODO: can we put the chain parameters into the planner at the start, so we can compute end_epoch_index? #[instrument(skip(self))] pub fn undelegate( &mut self, @@ -647,36 +447,139 @@ impl Planner { self } - fn action(&mut self, action: ActionPlan) -> &mut Self { - // Track the contribution of the action to the transaction's balance - self.balance += action.balance(); + fn balance(&self) -> Balance { + let mut balance = Balance::zero(); + for action in &self.actions { + balance += action.balance(); + } + for action in self.change_outputs.values() { + balance += action.balance(); + } + balance + } - // Add the action to the plan - self.plan.actions.push(action); - self + fn push(&mut self, action: ActionPlan) { + self.actions.push(action); } - /// Collect value balance surplus into a map of asset_id to amount. - /// If an asset is in deficit, its entry will be zero. - // TODO(tal): this code is somewhat hazardous, we should refactor it to have safer handling - // of surplus balance so that we don't burn user funds. - fn collect_surplus(&self) -> BTreeMap { - let mut surplus = BTreeMap::new(); - self.balance.provided().for_each(|value| { - surplus - .entry(value.asset_id) - .and_modify(|e| *e += value.amount) - .or_insert(value.amount); + /// Estimate the gas cost for the transaction, based on the actions in the plan, + /// and the change outputs. + /// + /// This does not include the gas cost for the tx bytes itself, so the gas estimate always + /// *undershoots*. We typically add them separately, deducting from the change outputs. + fn gas_estimate(&self) -> Gas { + let mut gas = Gas::zero(); + for action in &self.actions { + gas += action.gas_cost(); + } + for action in self.change_outputs.values() { + gas += ActionPlan::from(action.clone()).gas_cost(); + } + + gas + } + + /// Estimate the fee for each action and output in the transaction, scaled by a fee tier. + fn fee_estimate(&self, gas_prices: &GasPrices, fee_tier: &FeeTier) -> Fee { + let base_fee = Fee::from_staking_token_amount(gas_prices.fee(&self.gas_estimate())); + let fee = base_fee.apply_tier(*fee_tier); + + fee + } + + /// Return a total balance for the transaction, deducting fees for each action and change notes. + fn balance_with_fee_estimate(&self, gas_prices: &GasPrices, fee_tier: &FeeTier) -> Balance { + self.balance() - self.fee_estimate(gas_prices, fee_tier).0 + } + + /// Actualize the change outputs for the transaction, based on the current balance. + fn refresh_change(&mut self, change_address: Address) { + self.change_outputs = BTreeMap::new(); + // For each "provided" balance component, create a change note. + tracing::error!(refresh_change_balance = ?self.balance(), " time to create some notes!"); + for value in self.balance().provided() { + tracing::warn!(value = ?value, address = ?change_address, "Creating change note to change address"); + self.change_outputs.insert( + value.asset_id, + OutputPlan::new(&mut OsRng, value, change_address.clone()), + ); + } + } + + /// Deduct the fee from the change outputs, if possible. + fn adjust_change_for_fee(&mut self, fee: Fee) { + self.change_outputs.entry(fee.0.asset_id).and_modify(|e| { + e.value.amount = e.value.amount.saturating_sub(&fee.0.amount); }); + } - self.balance.required().for_each(|value| { - surplus - .entry(value.asset_id) - .and_modify(|e| *e -= value.amount) - .or_insert(Amount::zero()); + /// Prioritize notes to spend to release value of a specific transaction. + /// + /// Various logic is possible for note selection. Currently, this method + /// prioritizes notes sent to a one-time address, then notes with the largest + /// value: + /// + /// - Prioritizing notes sent to one-time addresses optimizes for a future in + /// which we implement DAGSync keyed by fuzzy message detection (which will not + /// be able to detect notes sent to one-time addresses). Spending these notes + /// immediately converts them into change notes, sent to the default address for + /// the users' account, which are detectable. + /// + /// - Prioritizing notes with the largest value optimizes for gas used by the + /// transaction. + /// + /// We may want to make note prioritization configurable in the future. For + /// instance, a user might prefer a note prioritization strategy that harvested + /// capital losses when possible, using cost basis information retained by the + /// view server. + fn prioritize_and_filter_spendable_notes( + records: Vec, + ) -> Vec { + let mut filtered = records + .into_iter() + .filter(|record| record.note.amount() > Amount::zero()) + .collect::>(); + + filtered.sort_by(|a, b| { + // Sort by whether the note was sent to an ephemeral address... + match ( + a.address_index.is_ephemeral(), + b.address_index.is_ephemeral(), + ) { + (true, false) => std::cmp::Ordering::Less, + (false, true) => std::cmp::Ordering::Greater, + // ... then by largest amount. + _ => b.note.amount().cmp(&a.note.amount()), + } }); - surplus + filtered + } + + fn action(&mut self, action: ActionPlan) -> &mut Self { + // Add the action to the plan + self.plan.actions.push(action); + self + } + + // Collect and tally all the surplus value balance from `SwapClaim` actions. + fn swap_claim_surplus(&self) -> Fee { + let total = self + .actions + .iter() + .filter(|action| matches!(action, ActionPlan::SwapClaim(_))) + .map(|action| match action { + ActionPlan::SwapClaim(claim) => { + // Multi-asset fees require changing this logic so that we tally `Balance` for fees, + // and mint notes opportunistically. Without changing this logic, the transaction won't + // balance if it has prepaid fees that are not staking tokens. + claim.swap_plaintext.claim_fee.amount() + } + _ => Amount::zero(), + }) + .sum(); + + Fee::from_staking_token_amount(total) } /// Add spends and change outputs as required to balance the transaction, using the view service @@ -704,6 +607,13 @@ impl Planner { let mut notes_by_asset_id = BTreeMap::new(); + let basic_balance = self.balance(); + tracing::error!(all_actions = ?self.plan.actions, "all actions"); + tracing::error!(?basic_balance, "balance"); + + let full_balance = self.balance_with_fee_estimate(&self.gas_prices, &self.fee_tier); + tracing::error!(?full_balance, "full"); + for required in self .balance_with_fee_estimate(&self.gas_prices, &self.fee_tier) .required() @@ -752,9 +662,6 @@ impl Planner { let fee = self.fee_estimate(&self.gas_prices, &self.fee_tier); self.adjust_change_for_fee(fee); - // Need to account to balance after applying fees. - self.balance = self.balance_with_fee_estimate(&self.gas_prices, &self.fee_tier); - iterations = iterations + 1; if iterations > 100 { return Err(anyhow!("failed to plan transaction after 100 iterations").into()); @@ -773,19 +680,12 @@ impl Planner { // increase the fee, ahead of the prepaid surplus available. This thing is a proper // state machine, and since I want to go bed, we'll just release it into the transaction // fee directly. - let surplus = self.collect_surplus(); - - let surplus_fee = if surplus.len() == 1 { - let (_, amount) = surplus.into_iter().next().unwrap(); - Fee::from_staking_token_amount(amount) - } else { - Fee::from_staking_token_amount(Amount::zero()) - }; - - let fee = Fee::from_staking_token_amount(fee.0.amount.max(surplus_fee.0.amount)); + let swap_claim_surplus = self.swap_claim_surplus(); - self.balance -= surplus_fee.0; + tracing::debug!(?swap_claim_surplus, "detected swap claim surplus value"); + let total_fee = + Fee::from_staking_token_amount(fee.0.amount.max(swap_claim_surplus.0.amount)); let expiry_height = self.plan.transaction_parameters.expiry_height; let mut plan = TransactionPlan { @@ -796,28 +696,14 @@ impl Planner { .chain(self.change_outputs.clone().into_values().map(Into::into)) .collect(), transaction_parameters: TransactionParameters { - expiry_height: expiry_height, + expiry_height, chain_id, - fee, + fee: total_fee, }, detection_data: None, memo: None, }; - // All actions have now been added, so check to make sure that you don't build and submit an - // empty transaction - if self.plan.actions.is_empty() { - anyhow::bail!("planned transaction would be empty, so should not be submitted"); - } - - // Now the transaction should be fully balanced, unless we didn't have enough to spend - if !self.balance.is_zero() { - anyhow::bail!( - "balance is non-zero after attempting to balance transaction: {:?}", - self.balance - ); - } - if let Some(memo_plan) = self.plan.memo.clone() { plan.memo = Some(MemoPlan::new(&mut OsRng, memo_plan.plaintext)?); } else if plan.output_plans().next().is_some() { @@ -833,10 +719,22 @@ impl Planner { self.plan = plan; - tracing::debug!(plan = ?self.plan, "finished balancing transaction"); + tracing::info!(plan = ?self.plan, "finished balancing transaction"); + + // We add some early checks to return an informative error message, even if the transaction + // would fail anyway. + ensure!( + !self.plan.actions.is_empty(), + "planned transaction should have actions" + ); + + ensure!( + self.balance_with_fee_estimate(&self.gas_prices, &self.fee_tier) + .is_zero(), + "transaction is not balanced: {:?}", + self.balance() + ); - // Clear the planner and pull out the plan to return - self.balance = Balance::zero(); self.vote_intents = BTreeMap::new(); self.ibc_actions = Vec::new(); self.gas_prices = GasPrices::zero(); @@ -844,4 +742,82 @@ impl Planner { Ok(plan) } + + pub fn add_votes( + &mut self, + voting_notes: Vec>, + ) -> Result<()> { + for ( + records, + ( + proposal, + VoteIntent { + start_position, + vote, + rate_data, + .. + }, + ), + ) in voting_notes + .into_iter() + .chain(std::iter::repeat(vec![])) // Chain with infinite repeating no notes, so the zip doesn't stop early + .zip(mem::take(&mut self.vote_intents).into_iter()) + { + // Keep track of whether we successfully could vote on this proposal + let mut voted = false; + + for (record, identity_key) in records { + // Vote with precisely this note on the proposal, computing the correct exchange + // rate for self-minted vote receipt tokens using the exchange rate of the validator + // at voting start time. If the validator was not active at the start of the + // proposal, the vote will be rejected by stateful verification, so skip the note + // and continue to the next one. + let Some(rate_data) = rate_data.get(&identity_key) else { + continue; + }; + let unbonded_amount = rate_data.unbonded_amount(record.note.amount()).into(); + + // If the delegation token is unspent, "roll it over" by spending it (this will + // result in change sent back to us). This unlinks nullifiers used for voting on + // multiple non-overlapping proposals, increasing privacy. + if record.height_spent.is_none() { + self.push( + SpendPlan::new(&mut OsRng, record.note.clone(), record.position).into(), + ); + } + + self.delegator_vote_precise( + proposal, + start_position, + vote, + record.note, + record.position, + unbonded_amount, + ); + + voted = true; + } + + if !voted { + // If there are no notes to vote with, return an error, because otherwise the user + // would compose a transaction that would not satisfy their intention, and would + // silently eat the fee. + anyhow::bail!( + "can't vote on proposal {} because no delegation notes were staked to an active validator when voting started", + proposal + ); + } + } + + Ok(()) + } +} + +#[derive(Debug, Clone)] +struct VoteIntent { + #[allow(dead_code)] + start_block_height: u64, + start_position: tct::Position, + rate_data: BTreeMap, + vote: Vote, }