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Soroban Contracts 101 : Liquidity Pool

Hi there! Welcome to last post of my series called "Soroban Contracts 101", where I'll be explaining the basics of Soroban contracts, such as data storage, authentication, custom types, and more. All the code that we're gonna explain throughout this series will mostly come from soroban-contracts-101 github repository.

In this post, i will explain Soroban Liquidity Pool example contract. This contract enables decentralized exchange functionality between two token types by maintaining a constant product invariant. It accomplishes this through the use of a third token type, called pool shares, which represent ownership in the liquidity pool.

The Contract Code

#![no_std]

mod test;
mod token;

use num_integer::Roots;
use soroban_sdk::{contractimpl, Address, Bytes, BytesN, ConversionError, Env, RawVal, TryFromVal};
use token::create_contract;

#[derive(Clone, Copy)]
#[repr(u32)]
pub enum DataKey {
    TokenA = 0,
    TokenB = 1,
    TokenShare = 2,
    TotalShares = 3,
    ReserveA = 4,
    ReserveB = 5,
}

impl TryFromVal<Env, DataKey> for RawVal {
    type Error = ConversionError;

    fn try_from_val(_env: &Env, v: &DataKey) -> Result<Self, Self::Error> {
        Ok((*v as u32).into())
    }
}

fn get_token_a(e: &Env) -> BytesN<32> {
    e.storage().get_unchecked(&DataKey::TokenA).unwrap()
}

fn get_token_b(e: &Env) -> BytesN<32> {
    e.storage().get_unchecked(&DataKey::TokenB).unwrap()
}

fn get_token_share(e: &Env) -> BytesN<32> {
    e.storage().get_unchecked(&DataKey::TokenShare).unwrap()
}

fn get_total_shares(e: &Env) -> i128 {
    e.storage().get_unchecked(&DataKey::TotalShares).unwrap()
}

fn get_reserve_a(e: &Env) -> i128 {
    e.storage().get_unchecked(&DataKey::ReserveA).unwrap()
}

fn get_reserve_b(e: &Env) -> i128 {
    e.storage().get_unchecked(&DataKey::ReserveB).unwrap()
}

fn get_balance(e: &Env, contract_id: BytesN<32>) -> i128 {
    token::Client::new(e, &contract_id).balance(&e.current_contract_address())
}

fn get_balance_a(e: &Env) -> i128 {
    get_balance(e, get_token_a(e))
}

fn get_balance_b(e: &Env) -> i128 {
    get_balance(e, get_token_b(e))
}

fn get_balance_shares(e: &Env) -> i128 {
    get_balance(e, get_token_share(e))
}

fn put_token_a(e: &Env, contract_id: BytesN<32>) {
    e.storage().set(&DataKey::TokenA, &contract_id);
}

fn put_token_b(e: &Env, contract_id: BytesN<32>) {
    e.storage().set(&DataKey::TokenB, &contract_id);
}

fn put_token_share(e: &Env, contract_id: BytesN<32>) {
    e.storage().set(&DataKey::TokenShare, &contract_id);
}

fn put_total_shares(e: &Env, amount: i128) {
    e.storage().set(&DataKey::TotalShares, &amount)
}

fn put_reserve_a(e: &Env, amount: i128) {
    e.storage().set(&DataKey::ReserveA, &amount)
}

fn put_reserve_b(e: &Env, amount: i128) {
    e.storage().set(&DataKey::ReserveB, &amount)
}

fn burn_shares(e: &Env, amount: i128) {
    let total = get_total_shares(e);
    let share_contract_id = get_token_share(e);

    token::Client::new(e, &share_contract_id).burn(&e.current_contract_address(), &amount);
    put_total_shares(e, total - amount);
}

fn mint_shares(e: &Env, to: Address, amount: i128) {
    let total = get_total_shares(e);
    let share_contract_id = get_token_share(e);

    token::Client::new(e, &share_contract_id).mint(&to, &amount);

    put_total_shares(e, total + amount);
}

fn transfer(e: &Env, contract_id: BytesN<32>, to: Address, amount: i128) {
    token::Client::new(e, &contract_id).transfer(&e.current_contract_address(), &to, &amount);
}

fn transfer_a(e: &Env, to: Address, amount: i128) {
    transfer(e, get_token_a(e), to, amount);
}

fn transfer_b(e: &Env, to: Address, amount: i128) {
    transfer(e, get_token_b(e), to, amount);
}

fn get_deposit_amounts(
    desired_a: i128,
    min_a: i128,
    desired_b: i128,
    min_b: i128,
    reserve_a: i128,
    reserve_b: i128,
) -> (i128, i128) {
    if reserve_a == 0 && reserve_b == 0 {
        return (desired_a, desired_b);
    }

    let amount_b = desired_a * reserve_b / reserve_a;
    if amount_b <= desired_b {
        if amount_b < min_b {
            panic!("amount_b less than min")
        }
        (desired_a, amount_b)
    } else {
        let amount_a = desired_b * reserve_a / reserve_b;
        if amount_a > desired_a || desired_a < min_a {
            panic!("amount_a invalid")
        }
        (amount_a, desired_b)
    }
}

pub trait LiquidityPoolTrait {
    // Sets the token contract addresses for this pool
    fn initialize(e: Env, token_wasm_hash: BytesN<32>, token_a: BytesN<32>, token_b: BytesN<32>);

    // Returns the token contract address for the pool share token
    fn share_id(e: Env) -> BytesN<32>;

    // Deposits token_a and token_b. Also mints pool shares for the "to" Identifier. The amount minted
    // is determined based on the difference between the reserves stored by this contract, and
    // the actual balance of token_a and token_b for this contract.
    fn deposit(e: Env, to: Address, desired_a: i128, min_a: i128, desired_b: i128, min_b: i128);

    // If "buy_a" is true, the swap will buy token_a and sell token_b. This is flipped if "buy_a" is false.
    // "out" is the amount being bought, with in_max being a safety to make sure you receive at least that amount.
    // swap will transfer the selling token "to" to this contract, and then the contract will transfer the buying token to "to".
    fn swap(e: Env, to: Address, buy_a: bool, out: i128, in_max: i128);

    // transfers share_amount of pool share tokens to this contract, burns all pools share tokens in this contracts, and sends the
    // corresponding amount of token_a and token_b to "to".
    // Returns amount of both tokens withdrawn
    fn withdraw(e: Env, to: Address, share_amount: i128, min_a: i128, min_b: i128) -> (i128, i128);

    fn get_rsrvs(e: Env) -> (i128, i128);
}

struct LiquidityPool;

#[contractimpl]
impl LiquidityPoolTrait for LiquidityPool {
    fn initialize(e: Env, token_wasm_hash: BytesN<32>, token_a: BytesN<32>, token_b: BytesN<32>) {
        if token_a >= token_b {
            panic!("token_a must be less than token_b");
        }

        let share_contract_id = create_contract(&e, &token_wasm_hash, &token_a, &token_b);
        token::Client::new(&e, &share_contract_id).initialize(
            &e.current_contract_address(),
            &7u32,
            &Bytes::from_slice(&e, b"Pool Share Token"),
            &Bytes::from_slice(&e, b"POOL"),
        );

        put_token_a(&e, token_a);
        put_token_b(&e, token_b);
        put_token_share(&e, share_contract_id.try_into().unwrap());
        put_total_shares(&e, 0);
        put_reserve_a(&e, 0);
        put_reserve_b(&e, 0);
    }

    fn share_id(e: Env) -> BytesN<32> {
        get_token_share(&e)
    }

    fn deposit(e: Env, to: Address, desired_a: i128, min_a: i128, desired_b: i128, min_b: i128) {
        // Depositor needs to authorize the deposit
        to.require_auth();

        let (reserve_a, reserve_b) = (get_reserve_a(&e), get_reserve_b(&e));

        // Calculate deposit amounts
        let amounts = get_deposit_amounts(desired_a, min_a, desired_b, min_b, reserve_a, reserve_b);

        let token_a_client = token::Client::new(&e, &get_token_a(&e));
        let token_b_client = token::Client::new(&e, &get_token_b(&e));

        token_a_client.transfer(&to, &e.current_contract_address(), &amounts.0);
        token_b_client.transfer(&to, &e.current_contract_address(), &amounts.1);

        // Now calculate how many new pool shares to mint
        let (balance_a, balance_b) = (get_balance_a(&e), get_balance_b(&e));
        let total_shares = get_total_shares(&e);

        let zero = 0;
        let new_total_shares = if reserve_a > zero && reserve_b > zero {
            let shares_a = (balance_a * total_shares) / reserve_a;
            let shares_b = (balance_b * total_shares) / reserve_b;
            shares_a.min(shares_b)
        } else {
            (balance_a * balance_b).sqrt()
        };

        mint_shares(&e, to, new_total_shares - total_shares);
        put_reserve_a(&e, balance_a);
        put_reserve_b(&e, balance_b);
    }

    fn swap(e: Env, to: Address, buy_a: bool, out: i128, in_max: i128) {
        to.require_auth();

        let (reserve_a, reserve_b) = (get_reserve_a(&e), get_reserve_b(&e));
        let (reserve_sell, reserve_buy) = if buy_a {
            (reserve_b, reserve_a)
        } else {
            (reserve_a, reserve_b)
        };

        // First calculate how much needs to be sold to buy amount out from the pool
        let n = reserve_sell * out * 1000;
        let d = (reserve_buy - out) * 997;
        let sell_amount = (n / d) + 1;
        if sell_amount > in_max {
            panic!("in amount is over max")
        }

        // Transfer the amount being sold to the contract
        let sell_token = if buy_a {
            get_token_b(&e)
        } else {
            get_token_a(&e)
        };
        let sell_token_client = token::Client::new(&e, &sell_token);
        sell_token_client.transfer(&to, &e.current_contract_address(), &sell_amount);

        let (balance_a, balance_b) = (get_balance_a(&e), get_balance_b(&e));

        // residue_numerator and residue_denominator are the amount that the invariant considers after
        // deducting the fee, scaled up by 1000 to avoid fractions
        let residue_numerator = 997;
        let residue_denominator = 1000;
        let zero = 0;

        let new_invariant_factor = |balance: i128, reserve: i128, out: i128| {
            let delta = balance - reserve - out;
            let adj_delta = if delta > zero {
                residue_numerator * delta
            } else {
                residue_denominator * delta
            };
            residue_denominator * reserve + adj_delta
        };

        let (out_a, out_b) = if buy_a { (out, 0) } else { (0, out) };

        let new_inv_a = new_invariant_factor(balance_a, reserve_a, out_a);
        let new_inv_b = new_invariant_factor(balance_b, reserve_b, out_b);
        let old_inv_a = residue_denominator * reserve_a;
        let old_inv_b = residue_denominator * reserve_b;

        if new_inv_a * new_inv_b < old_inv_a * old_inv_b {
            panic!("constant product invariant does not hold");
        }

        if buy_a {
            transfer_a(&e, to, out_a);
        } else {
            transfer_b(&e, to, out_b);
        }

        put_reserve_a(&e, balance_a - out_a);
        put_reserve_b(&e, balance_b - out_b);
    }

    fn withdraw(e: Env, to: Address, share_amount: i128, min_a: i128, min_b: i128) -> (i128, i128) {
        to.require_auth();

        // First transfer the pool shares that need to be redeemed
        let share_token_client = token::Client::new(&e, &get_token_share(&e));
        share_token_client.transfer(&to, &e.current_contract_address(), &share_amount);

        let (balance_a, balance_b) = (get_balance_a(&e), get_balance_b(&e));
        let balance_shares = get_balance_shares(&e);

        let total_shares = get_total_shares(&e);

        // Now calculate the withdraw amounts
        let out_a = (balance_a * balance_shares) / total_shares;
        let out_b = (balance_b * balance_shares) / total_shares;

        if out_a < min_a || out_b < min_b {
            panic!("min not satisfied");
        }

        burn_shares(&e, balance_shares);
        transfer_a(&e, to.clone(), out_a);
        transfer_b(&e, to, out_b);
        put_reserve_a(&e, balance_a - out_a);
        put_reserve_b(&e, balance_b - out_b);

        (out_a, out_b)
    }

    fn get_rsrvs(e: Env) -> (i128, i128) {
        (get_reserve_a(&e), get_reserve_b(&e))
    }
}
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This LiquidityPool contract enables decentralized exchange functionality between two token types (called token_a and token_b) by maintaining a constant product invariant. It accomplishes this through the use of a third token type, called pool shares, which represent ownership in the liquidity pool.

The contract is initialized by calling the initialize() function, passing in the token_a, token_b, and pool share token contract IDs (created using the create_contract() helper function). This function sets up the necessary storage for tracking the pool's reserves and shares, and initializes the pool share token.

Users can deposit token_a and token_b into the pool by calling the deposit() function. This function first ensures the depositor has authorized the transaction, then calculates how much of each token type should be deposited to maintain the constant product invariant (based on the pool's current reserves). It transfers in these amounts, mints new pool shares for the depositor based on the size of their deposit relative to the pool's total reserves, and updates the reserve storage.

Swaps between the two token types can be performed by calling the swap() function, specifying which token type to buy (token_a or token_b) and the amount to buy. The function calculates how much of the selling token needs to be provided to buy the desired amount while maintaining the constant product invariant, ensures this amount is less than or equal to the specified maximum, transfers in the selling token and transfers out the buying token. It also updates the reserve storage to account for the swap.

Finally, the withdraw() function allows pool share owners to redeem their shares for the underlying tokens. It burns the redeemed pool shares, calculates how much of each token type should be withdrawn based on the pool's reserves and the amount of shares redeemed, and transfers out the token amounts (ensuring minimum withdrawal requirements are met). It also updates the reserve storage.

The get_rsrvs() view function can be called to get the current reserve amounts for token_a and token_b. This allows users to check the state of the liquidity pool and inform decisions to deposit, withdraw, or swap.

Contract Usage

Here's the usage flow for the LiquidityPool contract:

Here's the usage flow for the LiquidityPool contract:

  1. The contract owner calls initialize(), passing in the token wasm hash and token_a/token_b/pool share token contract IDs. This sets up the storage and initializes the pool share token.
  2. Users call deposit(), passing in the amount of each token type they want to deposit and the address to mint pool shares to. This brings liquidity into the pool and mints shares to the depositors representing their ownership.
  3. When users want to trade between token_a and token_b, they call swap(), specifying which token they want to buy and the amounts. The pool calculates the exchange rate that maintains the invariant and performs the swap, transferring tokens.
  4. When users want to withdraw their liquidity, they call withdraw(), passing in the amount of pool shares they want to redeem. This burns the shares and transfers the corresponding amounts of token_a and token_b to the user according to the current exchange rate.
  5. At any time, users can call get_rsrvs() to get the current reserve amounts and get an idea of the pool's exchange rates and state. This helps inform decisions to deposit, withdraw, or swap.

Conclusion

Overall, the contract enables decentralized exchange between the two tokens through use of the pool share token to maintain consistent exchange rates and pool shareholder ownership. Users can provide/remove liquidity and perform swaps, and monitor the pool's state to utilize it efficiently.

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