cairo_lang_sierra_gas/
compute_costs.rs

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use std::ops::{Add, Sub};

use cairo_lang_sierra::algorithm::topological_order::reverse_topological_ordering;
use cairo_lang_sierra::extensions::gas::{BuiltinCostsType, CostTokenType};
use cairo_lang_sierra::ids::ConcreteLibfuncId;
use cairo_lang_sierra::program::{BranchInfo, Invocation, Program, Statement, StatementIdx};
use cairo_lang_utils::casts::IntoOrPanic;
use cairo_lang_utils::iterators::zip_eq3;
use cairo_lang_utils::ordered_hash_map::OrderedHashMap;
use cairo_lang_utils::ordered_hash_set::OrderedHashSet;
use cairo_lang_utils::unordered_hash_map::{Entry, UnorderedHashMap};
use cairo_lang_utils::unordered_hash_set::UnorderedHashSet;
use itertools::zip_eq;

use crate::CostError;
use crate::gas_info::GasInfo;
use crate::objects::{BranchCost, BranchCostSign, ConstCost, PreCost, WithdrawGasBranchInfo};

type VariableValues = OrderedHashMap<(StatementIdx, CostTokenType), i64>;

/// A trait for the cost type (either [PreCost] for pre-cost computation, or `i32` for the post-cost
/// computation).
pub trait CostTypeTrait:
    std::fmt::Debug + Default + Clone + Eq + Add<Output = Self> + Sub<Output = Self>
{
    /// Computes the minimum of the given two value (for each token type).
    ///
    /// Assumes that the arguments are non-negative.
    fn min2(value1: &Self, value2: &Self) -> Self;

    /// Computes the maximum of the given value (for each token type).
    ///
    /// Assumes that the arguments are non-negative.
    fn max(values: impl Iterator<Item = Self>) -> Self;

    /// For each token type, returns the value if it is non-negative and 0 otherwise.
    fn rectify(value: &Self) -> Self;
}

impl CostTypeTrait for i32 {
    fn min2(value1: &Self, value2: &Self) -> Self {
        *std::cmp::min(value1, value2)
    }

    fn max(values: impl Iterator<Item = Self>) -> Self {
        values.max().unwrap_or_default()
    }

    fn rectify(value: &Self) -> Self {
        std::cmp::max(*value, 0)
    }
}

impl CostTypeTrait for ConstCost {
    fn min2(value1: &Self, value2: &Self) -> Self {
        ConstCost {
            steps: std::cmp::min(value1.steps, value2.steps),
            holes: std::cmp::min(value1.holes, value2.holes),
            range_checks: std::cmp::min(value1.range_checks, value2.range_checks),
            range_checks96: std::cmp::min(value1.range_checks96, value2.range_checks96),
        }
    }

    fn max(values: impl Iterator<Item = Self>) -> Self {
        values
            .reduce(|acc, value| ConstCost {
                steps: std::cmp::max(acc.steps, value.steps),
                holes: std::cmp::max(acc.holes, value.holes),
                range_checks: std::cmp::max(acc.range_checks, value.range_checks),
                range_checks96: std::cmp::max(acc.range_checks96, value.range_checks96),
            })
            .unwrap_or_default()
    }

    fn rectify(value: &Self) -> Self {
        ConstCost {
            steps: std::cmp::max(value.steps, 0),
            holes: std::cmp::max(value.holes, 0),
            range_checks: std::cmp::max(value.range_checks, 0),
            range_checks96: std::cmp::max(value.range_checks96, 0),
        }
    }
}

impl CostTypeTrait for PreCost {
    fn min2(value1: &Self, value2: &Self) -> Self {
        let map_fn = |(token_type, val1)| {
            // The tokens that should appear are the tokens that appear in the intersection of both
            // parameters. Return `None` if the token does not appear in `value2`.
            let val2 = value2.0.get(token_type)?;
            Some((*token_type, *std::cmp::min(val1, val2)))
        };
        PreCost(value1.0.iter().filter_map(map_fn).collect())
    }

    fn max(values: impl Iterator<Item = Self>) -> Self {
        let mut res = Self::default();
        for value in values {
            for (token_type, val) in value.0 {
                res.0.insert(token_type, std::cmp::max(*res.0.get(&token_type).unwrap_or(&0), val));
            }
        }
        res
    }

    fn rectify(value: &Self) -> Self {
        let map_fn =
            |(token_type, val): (&CostTokenType, &i32)| (*token_type, std::cmp::max(*val, 0));
        PreCost(value.0.iter().map(map_fn).collect())
    }
}

/// Computes the [GasInfo] for a given program.
///
/// The `specific_cost_context` argument controls whether the computation is pre-cost or post-cost.
pub fn compute_costs<
    CostType: CostTypeTrait,
    SpecificCostContext: SpecificCostContextTrait<CostType>,
>(
    program: &Program,
    get_cost_fn: &dyn Fn(&ConcreteLibfuncId) -> Vec<BranchCost>,
    specific_cost_context: &SpecificCostContext,
    enforced_wallet_values: &OrderedHashMap<StatementIdx, CostType>,
) -> Result<GasInfo, CostError> {
    let mut context = CostContext {
        program,
        get_cost_fn,
        enforced_wallet_values,
        costs: Default::default(),
        target_values: Default::default(),
    };

    context.prepare_wallet(specific_cost_context)?;

    // Compute the excess cost and the corresponding target value for each statement.
    context.target_values = context.compute_target_values(specific_cost_context)?;

    // Recompute the wallet values for each statement, after setting the target values.
    context.costs = Default::default();
    context.prepare_wallet(specific_cost_context)?;

    // Check that enforcing the wallet values succeeded.
    for (idx, value) in enforced_wallet_values.iter() {
        if context.wallet_at_ex(idx, false).value != *value {
            return Err(CostError::EnforceWalletValueFailed(*idx));
        }
    }

    let mut variable_values = VariableValues::default();
    for i in 0..program.statements.len() {
        analyze_gas_statements(
            &context,
            specific_cost_context,
            &StatementIdx(i),
            &mut variable_values,
        )?;
    }

    let function_costs = program
        .funcs
        .iter()
        .map(|func| {
            let res = SpecificCostContext::to_cost_map(context.wallet_at(&func.entry_point).value);
            (func.id.clone(), res)
        })
        .collect();

    Ok(GasInfo { variable_values, function_costs })
}

/// Returns the statements whose wallet value is needed by
/// [get_branch_requirements].
fn get_branch_requirements_dependencies(
    idx: &StatementIdx,
    invocation: &Invocation,
    libfunc_cost: &[BranchCost],
) -> OrderedHashSet<StatementIdx> {
    let mut res: OrderedHashSet<StatementIdx> = Default::default();
    for (branch_info, branch_cost) in zip_eq(&invocation.branches, libfunc_cost) {
        match branch_cost {
            BranchCost::FunctionCost { const_cost: _, function, sign: _ } => {
                res.insert(function.entry_point);
            }
            BranchCost::WithdrawGas(WithdrawGasBranchInfo {
                success: true,
                with_builtin_costs: _,
            }) => {
                // If withdraw_gas succeeds, we don't need to take future_wallet_value into account,
                // so we simply return.
                continue;
            }
            _ => {}
        }
        res.insert(idx.next(&branch_info.target));
    }

    res
}

/// Returns the required value for the wallet for each branch.
///
/// Rectify (see [CostTypeTrait::rectify]) is needed in case the branch cost is negative
/// (e.g., in `coupon_refund`).
fn get_branch_requirements<
    CostType: CostTypeTrait,
    SpecificCostContext: SpecificCostContextTrait<CostType>,
>(
    specific_context: &SpecificCostContext,
    wallet_at_fn: &dyn Fn(&StatementIdx) -> WalletInfo<CostType>,
    idx: &StatementIdx,
    invocation: &Invocation,
    libfunc_cost: &[BranchCost],
    rectify: bool,
) -> Vec<WalletInfo<CostType>> {
    zip_eq(&invocation.branches, libfunc_cost)
        .map(|(branch_info, branch_cost)| {
            let res = specific_context.get_branch_requirement(
                wallet_at_fn,
                idx,
                branch_info,
                branch_cost,
            );
            if rectify { res.rectify() } else { res }
        })
        .collect()
}

/// For every `branch_align`, `withdraw_gas`, `redeposit_gas` and `coupon_refund` statements,
/// computes the required variables.
///
/// * For `branch_align` this is the amount of cost *reduced* from the wallet.
/// * For `withdraw_gas` this is the amount that should be withdrawn and added to the wallet.
/// * For `redeposit_gas` this is the amount that should be redeposited and removed from the wallet.
/// * For `coupon_refund` this is the amount that should be refunded and removed from the wallet.
fn analyze_gas_statements<
    CostType: CostTypeTrait,
    SpecificCostContext: SpecificCostContextTrait<CostType>,
>(
    context: &CostContext<'_, CostType>,
    specific_context: &SpecificCostContext,
    idx: &StatementIdx,
    variable_values: &mut VariableValues,
) -> Result<(), CostError> {
    let Statement::Invocation(invocation) = &context.program.get_statement(idx).unwrap() else {
        return Ok(());
    };
    let libfunc_cost: Vec<BranchCost> = context.get_cost(&invocation.libfunc_id);
    let branch_requirements: Vec<WalletInfo<CostType>> = get_branch_requirements(
        specific_context,
        &|statement_idx| context.wallet_at(statement_idx),
        idx,
        invocation,
        &libfunc_cost,
        false,
    );

    let wallet_value = context.wallet_at(idx).value;

    for (branch_info, branch_cost, branch_requirement) in
        zip_eq3(&invocation.branches, &libfunc_cost, &branch_requirements)
    {
        if let BranchCost::WithdrawGas(WithdrawGasBranchInfo { success: true, .. }) = branch_cost {
            // Note that `idx.next(&branch_info.target)` is indeed branch align due to
            // `ProgramRegistry::validate`.
            let branch_align_idx = idx.next(&branch_info.target);
            let withdrawal = specific_context.get_gas_withdrawal(
                idx,
                branch_cost,
                &wallet_value,
                context.wallet_at(&branch_align_idx).value,
            )?;
            for (token_type, amount) in SpecificCostContext::into_full_cost_iter(withdrawal) {
                assert_eq!(
                    variable_values.insert((*idx, token_type), std::cmp::max(amount, 0)),
                    None
                );

                assert_eq!(
                    variable_values
                        .insert((branch_align_idx, token_type), std::cmp::max(-amount, 0)),
                    None
                );
            }
        } else if let BranchCost::RedepositGas = branch_cost {
            let cost = wallet_value.clone() - branch_requirement.value.clone();
            for (token_type, amount) in SpecificCostContext::into_full_cost_iter(cost) {
                assert_eq!(variable_values.insert((*idx, token_type), amount), None);
            }
        } else if let BranchCost::FunctionCost { sign: BranchCostSign::Add, .. } = branch_cost {
            // If the refund can be fully used, the wallet value will be the same as
            // `branch_requirement`. Otherwise, wallet value will be zero and the difference
            // should be registered in the refund variables.
            let cost = wallet_value.clone() - branch_requirement.value.clone();
            for (token_type, amount) in SpecificCostContext::into_full_cost_iter(cost) {
                assert_eq!(variable_values.insert((*idx, token_type), amount), None);
            }
        } else if invocation.branches.len() > 1 {
            let cost = wallet_value.clone() - branch_requirement.value.clone();
            for (token_type, amount) in SpecificCostContext::into_full_cost_iter(cost) {
                assert_eq!(
                    variable_values.insert((idx.next(&branch_info.target), token_type), amount),
                    None
                );
            }
        }
    }
    Ok(())
}

pub trait SpecificCostContextTrait<CostType: CostTypeTrait> {
    /// Converts a `CostType` to a [OrderedHashMap] from [CostTokenType] to i64.
    fn to_cost_map(cost: CostType) -> OrderedHashMap<CostTokenType, i64>;

    /// Converts a `CostType` to a [OrderedHashMap] from [CostTokenType] to i64.
    /// All relevant [CostTokenType] are included (even if their value is 0).
    fn into_full_cost_iter(cost: CostType) -> impl Iterator<Item = (CostTokenType, i64)>;

    /// Computes the value that should be withdrawn and added to the wallet.
    fn get_gas_withdrawal(
        &self,
        idx: &StatementIdx,
        branch_cost: &BranchCost,
        wallet_value: &CostType,
        future_wallet_value: CostType,
    ) -> Result<CostType, CostError>;

    /// Returns the required value for the wallet for a single branch.
    fn get_branch_requirement(
        &self,
        wallet_at_fn: &dyn Fn(&StatementIdx) -> WalletInfo<CostType>,
        idx: &StatementIdx,
        branch_info: &BranchInfo,
        branch_cost: &BranchCost,
    ) -> WalletInfo<CostType>;
}

/// The information about the wallet value at a given statement.
#[derive(Clone, Debug, Default)]
pub struct WalletInfo<CostType: CostTypeTrait> {
    /// The minimum wallet value before executing the statement.
    value: CostType,
}

impl<CostType: CostTypeTrait> WalletInfo<CostType> {
    /// Computes the wallet value of a statement, given the wallet values of its branches.
    ///
    /// `target_value` is the target value for this statement. See [CostContext::target_values].
    fn merge(
        branch_costs: &[BranchCost],
        branches: Vec<Self>,
        target_value: Option<&CostType>,
    ) -> Self {
        let n_branches = branches.len();
        let mut max_value =
            CostType::max(branches.iter().map(|wallet_info| wallet_info.value.clone()));

        // If there are multiple branches, there must be a branch_align in each of them, which
        // can be used to increase the wallet value up to the target value.
        let is_branch_align = n_branches > 1;
        // If this is `redeposit_gas`, the wallet value can be increased up to the target value,
        // by redepositing the difference.
        let is_redeposit = matches!(branch_costs[..], [BranchCost::RedepositGas]);

        if is_branch_align || is_redeposit {
            if let Some(target_value) = target_value {
                // If the target value is greater than the maximum value of the branches, use
                // the target value.
                max_value = CostType::max([max_value, target_value.clone()].into_iter());
            }
        }

        WalletInfo { value: max_value }
    }

    /// See [CostTypeTrait::rectify].
    fn rectify(&self) -> Self {
        Self { value: CostType::rectify(&self.value) }
    }
}

/// Implements a cast from CostType to WalletInfo.
impl<CostType: CostTypeTrait> From<CostType> for WalletInfo<CostType> {
    fn from(value: CostType) -> Self {
        WalletInfo { value }
    }
}

/// Implements addition of WalletInfo.
impl<CostType: CostTypeTrait> std::ops::Add for WalletInfo<CostType> {
    type Output = Self;

    fn add(self, other: Self) -> Self {
        WalletInfo { value: self.value + other.value }
    }
}

/// Helper struct for computing the wallet value at each statement.
struct CostContext<'a, CostType: CostTypeTrait> {
    /// The Sierra program.
    program: &'a Program,
    /// A callback function returning the cost of a libfunc for every output branch.
    get_cost_fn: &'a dyn Fn(&ConcreteLibfuncId) -> Vec<BranchCost>,
    /// A map from statement index to an enforced wallet value. For example, some functions
    /// may have a required cost, in this case the functions entry points should have a predefined
    /// wallet value.
    enforced_wallet_values: &'a OrderedHashMap<StatementIdx, CostType>,
    /// The cost before executing a Sierra statement.
    costs: UnorderedHashMap<StatementIdx, WalletInfo<CostType>>,
    /// A partial map from StatementIdx to a requested lower bound on the wallet value.
    target_values: UnorderedHashMap<StatementIdx, CostType>,
}
impl<CostType: CostTypeTrait> CostContext<'_, CostType> {
    /// Returns the cost of a libfunc for every output branch.
    fn get_cost(&self, libfunc_id: &ConcreteLibfuncId) -> Vec<BranchCost> {
        (self.get_cost_fn)(libfunc_id)
    }

    /// Returns the required value in the wallet before executing statement `idx`.
    ///
    /// Assumes that [Self::prepare_wallet] was called before.
    ///
    /// For `branch_align` the function returns the result as if the alignment is zero (since the
    /// alignment is not know at this point).
    fn wallet_at(&self, idx: &StatementIdx) -> WalletInfo<CostType> {
        self.wallet_at_ex(idx, true)
    }

    /// Extended version of [Self::wallet_at].
    ///
    /// If `with_enforced_values` is `true`, the enforced wallet values are used if set.
    fn wallet_at_ex(&self, idx: &StatementIdx, with_enforced_values: bool) -> WalletInfo<CostType> {
        if with_enforced_values {
            if let Some(enforced_wallet_value) = self.enforced_wallet_values.get(idx) {
                // If there is an enforced value, use it.
                return WalletInfo::from(enforced_wallet_value.clone());
            }
        }

        self.costs
            .get(idx)
            .unwrap_or_else(|| panic!("Wallet value for statement {idx} was not yet computed."))
            .clone()
    }

    /// Prepares the values for [Self::wallet_at].
    fn prepare_wallet<SpecificCostContext: SpecificCostContextTrait<CostType>>(
        &mut self,
        specific_cost_context: &SpecificCostContext,
    ) -> Result<(), CostError> {
        let rev_topological_order = compute_reverse_topological_order(
            self.program.statements.len(),
            true,
            |current_idx| {
                match &self.program.get_statement(current_idx).unwrap() {
                    Statement::Return(_) => {
                        // Return has no dependencies.
                        vec![]
                    }
                    Statement::Invocation(invocation) => {
                        let libfunc_cost: Vec<BranchCost> = self.get_cost(&invocation.libfunc_id);

                        get_branch_requirements_dependencies(current_idx, invocation, &libfunc_cost)
                            .into_iter()
                            .collect()
                    }
                }
            },
        )?;

        for current_idx in rev_topological_order {
            // The computation of the dependencies was completed.
            let res = self.no_cache_compute_wallet_at(&current_idx, specific_cost_context);
            // Update the cache with the result.
            self.costs.insert(current_idx, res.clone());
        }

        Ok(())
    }

    /// Helper function for `prepare_wallet()`.
    ///
    /// Assumes that the values was already computed for the dependencies.
    fn no_cache_compute_wallet_at<SpecificCostContext: SpecificCostContextTrait<CostType>>(
        &mut self,
        idx: &StatementIdx,
        specific_cost_context: &SpecificCostContext,
    ) -> WalletInfo<CostType> {
        match &self.program.get_statement(idx).unwrap() {
            Statement::Return(_) => Default::default(),
            Statement::Invocation(invocation) => {
                let libfunc_cost: Vec<BranchCost> = self.get_cost(&invocation.libfunc_id);

                // For each branch, compute the required value for the wallet.
                let branch_requirements: Vec<WalletInfo<CostType>> = get_branch_requirements(
                    specific_cost_context,
                    &|statement_idx| self.wallet_at(statement_idx),
                    idx,
                    invocation,
                    &libfunc_cost,
                    true,
                );

                // The wallet value at the beginning of the statement is the maximal value
                // required by all the branches.
                WalletInfo::merge(&libfunc_cost, branch_requirements, self.target_values.get(idx))
            }
        }
    }

    /// Computes the target value for each statement. Rerunning `prepare_wallet` with these
    /// target values will try to set the values of statements such as `branch_align`,
    /// `withdraw_gas` and `redeposit_gas` to achieve these targets.
    fn compute_target_values<SpecificCostContext: SpecificCostContextTrait<CostType>>(
        &self,
        specific_cost_context: &SpecificCostContext,
    ) -> Result<UnorderedHashMap<StatementIdx, CostType>, CostError> {
        // Compute a reverse topological order of the statements.
        // Unlike `prepare_wallet`:
        // * function calls are not treated as edges and
        // * the success branches of `withdraw_gas` are treated as edges.
        //
        // Note, that we allow cycles, but the result may not be optimal in such a case.
        let rev_topological_order = compute_reverse_topological_order(
            self.program.statements.len(),
            false,
            |current_idx| {
                match self.program.get_statement(current_idx).unwrap() {
                    Statement::Return(_) => {
                        // Return has no dependencies.
                        vec![]
                    }
                    Statement::Invocation(invocation) => invocation
                        .branches
                        .iter()
                        .map(|branch_info| current_idx.next(&branch_info.target))
                        .collect(),
                }
            },
        )?;

        // Compute the excess mapping - additional amount of cost that, if possible, should be
        // added to the wallet value.
        let mut excess = UnorderedHashMap::<StatementIdx, CostType>::default();
        // The set of statements for which the excess value was already finalized.
        let mut finalized_excess_statements = UnorderedHashSet::<StatementIdx>::default();

        for idx in rev_topological_order.iter().rev() {
            self.handle_excess_at(
                idx,
                specific_cost_context,
                &mut excess,
                &mut finalized_excess_statements,
            )?;
        }

        // Compute the target value for each statement by adding the excess to the wallet value.
        Ok((0..self.program.statements.len())
            .map(|i| {
                let idx = StatementIdx(i);
                let original_wallet_value = self.wallet_at_ex(&idx, false).value;
                (idx, original_wallet_value + excess.get(&idx).cloned().unwrap_or_default())
            })
            .collect())
    }

    /// Handles the excess at the given statement by pushing it to the next statement(s).
    ///
    /// * `redeposit_gas` - consumes all the excess, as it can be redeposited.
    /// * `branch_align` - adds the difference to the excess, so that it will be possible by a
    ///   future `redeposit_gas`.
    /// * `withdraw_gas` - removes the planned withdrawal from the excess, so that the excess will
    ///   be used instead of a withdrawal.
    fn handle_excess_at<SpecificCostContext: SpecificCostContextTrait<CostType>>(
        &self,
        idx: &StatementIdx,
        specific_cost_context: &SpecificCostContext,
        excess: &mut UnorderedHashMap<StatementIdx, CostType>,
        finalized_excess_statements: &mut UnorderedHashSet<StatementIdx>,
    ) -> Result<(), CostError> {
        let wallet_value = self.wallet_at_ex(idx, false).value;

        if let Some(enforced_wallet_value) = self.enforced_wallet_values.get(idx) {
            // No excess is expected at statement with enforced wallet value.
            // If there is one, we ignore it.
            excess.insert(
                *idx,
                CostType::rectify(&(enforced_wallet_value.clone() - wallet_value.clone())),
            );
        }

        finalized_excess_statements.insert(*idx);

        let current_excess = excess.get(idx).cloned().unwrap_or_default();

        let invocation = match &self.program.get_statement(idx).unwrap() {
            Statement::Invocation(invocation) => invocation,
            Statement::Return(_) => {
                // Excess cannot be handled, simply drop it.
                return Ok(());
            }
        };

        let libfunc_cost: Vec<BranchCost> = self.get_cost(&invocation.libfunc_id);

        let branch_requirements = get_branch_requirements(
            specific_cost_context,
            &|statement_idx| self.wallet_at(statement_idx),
            idx,
            invocation,
            &libfunc_cost,
            false,
        );

        // Pass the excess to the branches.
        for (branch_info, branch_cost, branch_requirement) in
            zip_eq3(&invocation.branches, &libfunc_cost, branch_requirements)
        {
            let branch_statement = idx.next(&branch_info.target);
            if finalized_excess_statements.contains(&branch_statement) {
                // Don't update statements which were already visited.
                return Ok(());
            }

            let future_wallet_value = self.wallet_at(&branch_statement).value;
            let mut actual_excess = current_excess.clone();

            if invocation.branches.len() > 1 {
                if let BranchCost::WithdrawGas(WithdrawGasBranchInfo { success: true, .. }) =
                    branch_cost
                {
                    let planned_withdrawal = specific_cost_context.get_gas_withdrawal(
                        idx,
                        branch_cost,
                        &wallet_value,
                        future_wallet_value,
                    )?;

                    // Note that planned_withdrawal may be either positive (where there is an actual
                    // withdrawal) or negative (where we do not need to withdraw and the failing
                    // branch is more expensive than the success branch).
                    actual_excess = CostType::rectify(&(actual_excess - planned_withdrawal));
                } else {
                    // Branch align of a non-withdraw-gas statement.
                    // If there are branch align, increase the excess by the current difference,
                    // so that future statements will be able to use it (e.g., `redeposit_gas`).
                    let additional_excess = wallet_value.clone() - branch_requirement.value;
                    actual_excess = actual_excess + CostType::rectify(&additional_excess);
                }
            } else if let BranchCost::RedepositGas = branch_cost {
                // All the excess can be redeposited.
                actual_excess = Default::default();
            } else if let BranchCost::FunctionCost { sign: BranchCostSign::Add, .. } = branch_cost {
                // The difference between `wallet_value` and `branch_requirement.value` is the
                // amount of "wasted" refund (refund that could not be used in the first
                // iteration) - this amount can be added to the excess.
                let additional_excess = wallet_value.clone() - branch_requirement.value;
                actual_excess = actual_excess + CostType::rectify(&additional_excess);
            }

            // Update the excess for `branch_statement` using the minimum of the existing excess and
            // `actual_excess`.
            match excess.entry(branch_statement) {
                Entry::Occupied(mut entry) => {
                    let current_value = entry.get();
                    entry.insert(CostType::min2(current_value, &actual_excess));
                }
                Entry::Vacant(entry) => {
                    entry.insert(actual_excess);
                }
            }
        }
        Ok(())
    }
}

/// Generates a topological ordering of the statements according to the given dependencies_callback.
///
/// Each statement appears in the ordering after its dependencies.
fn compute_reverse_topological_order(
    n_statements: usize,
    detect_cycles: bool,
    dependencies_callback: impl Fn(&StatementIdx) -> Vec<StatementIdx>,
) -> Result<Vec<StatementIdx>, CostError> {
    reverse_topological_ordering(
        detect_cycles,
        (0..n_statements).map(StatementIdx),
        n_statements,
        |idx| Ok(dependencies_callback(&idx)),
        |_| CostError::UnexpectedCycle,
    )
}

pub struct PreCostContext {}

impl SpecificCostContextTrait<PreCost> for PreCostContext {
    fn to_cost_map(cost: PreCost) -> OrderedHashMap<CostTokenType, i64> {
        cost.0.into_iter().map(|(token_type, val)| (token_type, val as i64)).collect()
    }

    fn into_full_cost_iter(cost: PreCost) -> impl Iterator<Item = (CostTokenType, i64)> {
        CostTokenType::iter_precost().map(move |token_type| {
            (*token_type, cost.0.get(token_type).copied().unwrap_or_default().into())
        })
    }

    fn get_gas_withdrawal(
        &self,
        _idx: &StatementIdx,
        _branch_cost: &BranchCost,
        wallet_value: &PreCost,
        future_wallet_value: PreCost,
    ) -> Result<PreCost, CostError> {
        Ok(future_wallet_value - wallet_value.clone())
    }

    fn get_branch_requirement(
        &self,
        wallet_at_fn: &dyn Fn(&StatementIdx) -> WalletInfo<PreCost>,
        idx: &StatementIdx,
        branch_info: &BranchInfo,
        branch_cost: &BranchCost,
    ) -> WalletInfo<PreCost> {
        let branch_cost = match branch_cost {
            BranchCost::Regular { const_cost: _, pre_cost } => pre_cost.clone(),
            BranchCost::BranchAlign | BranchCost::RedepositGas => Default::default(),
            BranchCost::FunctionCost { const_cost: _, function, sign } => {
                let func_cost = wallet_at_fn(&function.entry_point).value;
                match sign {
                    BranchCostSign::Add => PreCost::default() - func_cost,
                    BranchCostSign::Subtract => func_cost,
                }
            }
            BranchCost::WithdrawGas(info) => {
                if info.success {
                    // If withdraw_gas succeeds, we don't need to take
                    // future_wallet_value into account, so we simply return.
                    return Default::default();
                } else {
                    Default::default()
                }
            }
        };
        let future_wallet_value = wallet_at_fn(&idx.next(&branch_info.target));
        WalletInfo::from(branch_cost) + future_wallet_value
    }
}

/// Extension of [CostTypeTrait] that can be used in post-cost computation [PostcostContext].
pub trait PostCostTypeEx: CostTypeTrait + Copy {
    /// Constructor from [ConstCost].
    fn from_const_cost(const_cost: &ConstCost) -> Self;

    /// See [SpecificCostContextTrait::into_full_cost_iter].
    fn into_full_cost_iter(self) -> impl Iterator<Item = (CostTokenType, i64)>;
}

impl PostCostTypeEx for i32 {
    fn from_const_cost(const_cost: &ConstCost) -> Self {
        const_cost.cost()
    }

    fn into_full_cost_iter(self) -> impl Iterator<Item = (CostTokenType, i64)> {
        [(CostTokenType::Const, self.into())].into_iter()
    }
}

impl PostCostTypeEx for ConstCost {
    fn from_const_cost(const_cost: &ConstCost) -> Self {
        *const_cost
    }

    fn into_full_cost_iter(self) -> impl Iterator<Item = (CostTokenType, i64)> {
        [
            (CostTokenType::Step, self.steps.into()),
            (CostTokenType::Hole, self.holes.into()),
            (CostTokenType::RangeCheck, self.range_checks.into()),
        ]
        .into_iter()
    }
}

pub struct PostcostContext<'a> {
    pub get_ap_change_fn: &'a dyn Fn(&StatementIdx) -> usize,
    pub precost_gas_info: &'a GasInfo,
}

impl<CostType: PostCostTypeEx> SpecificCostContextTrait<CostType> for PostcostContext<'_> {
    fn to_cost_map(cost: CostType) -> OrderedHashMap<CostTokenType, i64> {
        if cost == CostType::default() {
            Default::default()
        } else {
            Self::into_full_cost_iter(cost).collect()
        }
    }

    fn into_full_cost_iter(cost: CostType) -> impl Iterator<Item = (CostTokenType, i64)> {
        cost.into_full_cost_iter()
    }

    fn get_gas_withdrawal(
        &self,
        idx: &StatementIdx,
        branch_cost: &BranchCost,
        wallet_value: &CostType,
        future_wallet_value: CostType,
    ) -> Result<CostType, CostError> {
        let BranchCost::WithdrawGas(info) = branch_cost else {
            panic!("Unexpected BranchCost: {branch_cost:?}.");
        };
        assert!(info.success, "Unexpected BranchCost: Expected `success == true`, got {info:?}.");

        let withdraw_gas_cost =
            CostType::from_const_cost(&self.compute_withdraw_gas_cost(idx, info));
        Ok(future_wallet_value + withdraw_gas_cost - *wallet_value)
    }

    fn get_branch_requirement(
        &self,
        wallet_at_fn: &dyn Fn(&StatementIdx) -> WalletInfo<CostType>,
        idx: &StatementIdx,
        branch_info: &BranchInfo,
        branch_cost: &BranchCost,
    ) -> WalletInfo<CostType> {
        let branch_cost_val = match branch_cost {
            BranchCost::Regular { const_cost, pre_cost: _ } => {
                CostType::from_const_cost(const_cost)
            }
            BranchCost::BranchAlign => {
                let ap_change = (self.get_ap_change_fn)(idx);
                let res = if ap_change == 0 {
                    ConstCost::default()
                } else {
                    ConstCost {
                        steps: 1,
                        holes: ap_change as i32,
                        range_checks: 0,
                        range_checks96: 0,
                    }
                };
                CostType::from_const_cost(&res)
            }
            BranchCost::FunctionCost { const_cost, function, sign } => {
                let cost = wallet_at_fn(&function.entry_point).value
                    + CostType::from_const_cost(const_cost);
                match sign {
                    BranchCostSign::Add => CostType::default() - cost,
                    BranchCostSign::Subtract => cost,
                }
            }
            BranchCost::WithdrawGas(info) => {
                let cost = CostType::from_const_cost(&self.compute_withdraw_gas_cost(idx, info));

                // If withdraw_gas succeeds, we don't need to take
                // future_wallet_value into account, so we simply return.
                if info.success {
                    return WalletInfo::from(cost);
                }
                cost
            }
            BranchCost::RedepositGas => {
                CostType::from_const_cost(&self.compute_redeposit_gas_cost(idx))
            }
        };
        let future_wallet_value = wallet_at_fn(&idx.next(&branch_info.target));
        WalletInfo { value: branch_cost_val } + future_wallet_value
    }
}

impl PostcostContext<'_> {
    /// Computes the cost of the withdraw_gas libfunc.
    fn compute_withdraw_gas_cost(
        &self,
        idx: &StatementIdx,
        info: &WithdrawGasBranchInfo,
    ) -> ConstCost {
        info.const_cost(|token_type| {
            self.precost_gas_info.variable_values[&(*idx, token_type)].into_or_panic()
        })
    }

    /// Computes the cost of the redeposit_gas libfunc.
    fn compute_redeposit_gas_cost(&self, idx: &StatementIdx) -> ConstCost {
        ConstCost::steps(
            BuiltinCostsType::cost_computation_steps(false, |token_type| {
                self.precost_gas_info.variable_values[&(*idx, token_type)].into_or_panic()
            })
            .into_or_panic(),
        )
    }
}