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CowSwapBurner.vy

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The source code of the CoWSwapBurner.vy contract can be found on GitHub.

The CowSwapBurner is an essential component of the fee burning architecture, designed to facilitate the efficient and automated exchange of admin fees using conditional orders of the CoWSwap protocol.

This system simplifies fee burning by requiring only a single burner contract. A simple function call can create an order that sells a accrued fee token into the target token.

The old system used various kinds of burners with hardcoded routes, which often did not result in the most efficient fee burning mechanism, thereby "losing" fees that could be distributed among veCRV holders.

To learn more about the CoW-Protocol, make sure to check out their official documentation.


Conditional Orders

Conditional CowSwap orders are automatically created for each token to be burned using the burn function. This function is not directly externally callable by users through this contract; instead, it is called when the collect function within the FeeCollector contract is invoked. Additionally, there is a caller fee to incentivize this contract call.

struct ConditionalOrderParams:
    # The contract implementing the conditional order logic
    handler: address  # self
    # Allows for multiple conditional orders of the same type and data
    salt: bytes32  # Not used for now
    # Data available to ALL discrete orders created by the conditional order
    staticData: Bytes[STATIC_DATA_LEN]  # Using coin address

composable_cow.create(ConditionalOrderParams({
                            handler: self,
                            salt: empty(bytes32),
                            staticData: concat(b"", convert(coin.address, bytes20)),
                        }), True)

created

CowSwapBurner.created(arg0: address) -> bool: view

Getter method to check if a conditional order for coin arg0 has been created. If there is not an existing order, a new order will be created when the burn function is called.1

Returns: true or false (bool).

Input Type Description
arg0 address Address of coin to check.
Source code
created: public(HashMap[ERC20, bool])

@external
def burn(_coins: DynArray[ERC20, MAX_COINS_LEN], _receiver: address):
    """
    @notice Post hook after collect to register coins for burn
    @dev Registers new orders in ComposableCow
    @param _coins Which coins to burn
    @param _receiver Receiver of profit
    """
    assert msg.sender == fee_collector.address, "Only FeeCollector"

    fee: uint256 = fee_collector.fee(Epoch.COLLECT)
    fee_payouts: DynArray[Transfer, MAX_COINS_LEN] = []
    self_transfers: DynArray[Transfer, MAX_COINS_LEN] = []
    for coin in _coins:
        if not self.created[coin]:
            composable_cow.create(ConditionalOrderParams({
                handler: self,
                salt: empty(bytes32),
                staticData: concat(b"", convert(coin.address, bytes20)),
            }), True)
            coin.approve(vault_relayer, max_value(uint256))
            self.created[coin] = True
        amount: uint256 = coin.balanceOf(fee_collector.address) * fee / ONE
        fee_payouts.append(Transfer({coin: coin, to: _receiver, amount: amount}))
        self_transfers.append(Transfer({coin: coin, to: self, amount: max_value(uint256)}))

    fee_collector.transfer(fee_payouts)
    fee_collector.transfer(self_transfers)
>>> CowSwapBurner.created('0xDDAfbb505ad214D7b80b1f830fcCc89B60fb7A83')
'true'

get_current_order

CowSwapBurner.get_current_order(sell_token: address=empty(address)) -> GPv2Order_Data

Getter for the current order parameters of a token.

Returns: GPv2Order_Data consisting of:

  • sellToken: ERC20
  • buyToken: ERC20
  • receiver: address
  • sellAmount: uint256
  • buyAmount: uint256
  • validTo: uint32
  • appData: bytes32
  • feeAmount: uint256
  • kind: bytes32
  • partiallyFillable: bool
  • sellTokenBalance: bytes32
  • buyTokenBalance: bytes32
Input Type Description
sell_token address Token address to check parameters for.
Source code
@view
@external
def get_current_order(sell_token: address=empty(address)) -> GPv2Order_Data:
    """
    @notice Get current order parameters
    @param sell_token Address of possible sell token
    @return Order parameters
    """
    return self._get_order(ERC20(sell_token))

@view
@internal
def _get_order(sell_token: ERC20) -> GPv2Order_Data:
    buy_token: ERC20 = fee_collector.target()
    return GPv2Order_Data({
        sellToken: sell_token,  # token to sell
        buyToken: buy_token,  # token to buy
        receiver: fee_collector.address,  # receiver of the token to buy
        sellAmount: 0,  # Set later
        buyAmount: self.target_threshold,
        validTo: convert(fee_collector.epoch_time_frame(Epoch.EXCHANGE)[1], uint32),  # timestamp until order is valid
        appData: ADD_DATA,  # extra info about the order
        feeAmount: 0,  # amount of fees in sellToken
        kind: SELL_KIND,  # buy or sell
        partiallyFillable: True,  # partially fillable (True) or fill-or-kill (False)
        sellTokenBalance: TOKEN_BALANCE,  # From where the sellToken balance is withdrawn
        buyTokenBalance: TOKEN_BALANCE,  # Where the buyToken is deposited
    })
>>> CowSwapBurner.get_current_order('0xDDAfbb505ad214D7b80b1f830fcCc89B60fb7A83')
0xDDAfbb505ad214D7b80b1f830fcCc89B60fb7A83, 0xaBEf652195F98A91E490f047A5006B71c85f058d, 0xBb7404F9965487a9DdE721B3A5F0F3CcfA9aa4C5, 0, 1000000000000000000, 1718755200, 0x058315b749613051abcbf50cf2d605b4fa4a41554ec35d73fd058fc530da559f, 0,0xf3b277728b3fee749481eb3e0b3b48980dbbab78658fc419025cb16eee346775, true, 0x5a28e9363bb942b639270062aa6bb295f434bcdfc42c97267bf003f272060dc9, 0x5a28e9363bb942b639270062aa6bb295f434bcdfc42c97267bf003f272060dc9

burn

CowSwapBurner.burn(_coins: DynArray[ERC20, MAX_COINS_LEN], _receiver: address)

Guarded Method

This function is only callable by the FeeCollector contract via the collect function.

Function to create a conditional CowSwap order for coins.

Input Type Description
_coins DynArray[ERC20, MAX_COINS_LEN] Coins to burn.
_receiver address Receiver of the keeper fee specified in when calling collect within the FeeCollector.
Source code
interface FeeCollector:
    def fee(_epoch: Epoch=empty(Epoch), _ts: uint256=block.timestamp) -> uint256: view
    def target() -> ERC20: view
    def owner() -> address: view
    def emergency_owner() -> address: view
    def epoch_time_frame(epoch: Epoch, ts: uint256=block.timestamp) -> (uint256, uint256): view
    def can_exchange(_coins: DynArray[ERC20, MAX_COINS_LEN]) -> bool: view
    def transfer(_transfers: DynArray[Transfer, MAX_COINS_LEN]): nonpayable

struct ConditionalOrderParams:
    # The contract implementing the conditional order logic
    handler: address  # self
    # Allows for multiple conditional orders of the same type and data
    salt: bytes32  # Not used for now
    # Data available to ALL discrete orders created by the conditional order
    staticData: Bytes[STATIC_DATA_LEN]  # Using coin address

interface ComposableCow:
    def create(params: ConditionalOrderParams, dispatch: bool): nonpayable
    def domainSeparator() -> bytes32: view
    def isValidSafeSignature(
        safe: address, sender: address, _hash: bytes32, _domainSeparator: bytes32, typeHash: bytes32,
        encodeData: Bytes[15 * 32],
        payload: Bytes[(32 + 3 + 1 + 8) * 32],
    ) -> bytes4: view

@external
def burn(_coins: DynArray[ERC20, MAX_COINS_LEN], _receiver: address):
    """
    @notice Post hook after collect to register coins for burn
    @dev Registers new orders in ComposableCow
    @param _coins Which coins to burn
    @param _receiver Receiver of profit
    """
    assert msg.sender == fee_collector.address, "Only FeeCollector"

    fee: uint256 = fee_collector.fee(Epoch.COLLECT)
    fee_payouts: DynArray[Transfer, MAX_COINS_LEN] = []
    self_transfers: DynArray[Transfer, MAX_COINS_LEN] = []
    for coin in _coins:
        if not self.created[coin]:
            composable_cow.create(ConditionalOrderParams({
                handler: self,
                salt: empty(bytes32),
                staticData: concat(b"", convert(coin.address, bytes20)),
            }), True)
            coin.approve(vault_relayer, max_value(uint256))
            self.created[coin] = True
        amount: uint256 = coin.balanceOf(fee_collector.address) * fee / ONE
        fee_payouts.append(Transfer({coin: coin, to: _receiver, amount: amount}))
        self_transfers.append(Transfer({coin: coin, to: self, amount: max_value(uint256)}))

    fee_collector.transfer(fee_payouts)
    fee_collector.transfer(self_transfers)
>>> soon

getTradableOrder

CowSwapBurner.getTradeableOrder(_owner: address, _sender: address, _ctx: bytes32, _static_input: Bytes[STATIC_DATA_LEN], _offchain_input: Bytes[OFFCHAIN_DATA_LEN]) -> GPv2Order_Data

Function to generate a order for the WatchTower.

Returns: order parameters (GPv2Order_Data).

Input Type Description
_owner address Owner of the order.
_sender address msg.sender context calling isValidSignature
_ctx bytes32 Execution context.
_static_input Bytes[STATIC_DATA_LEN] sellToken encoded as bytes(Bytes[20]).
_offchain_input Bxtes[OFFCHAIN_DATA_LEN] Not used, zero-length bytes.
Source code
struct GPv2Order_Data:
    sellToken: ERC20  # token to sell
    buyToken: ERC20  # token to buy
    receiver: address  # receiver of the token to buy
    sellAmount: uint256
    buyAmount: uint256
    validTo: uint32  # timestamp until order is valid
    appData: bytes32  # extra info about the order
    feeAmount: uint256  # amount of fees in sellToken
    kind: bytes32  # buy or sell
    partiallyFillable: bool  # partially fillable (True) or fill-or-kill (False)
    sellTokenBalance: bytes32  # From where the sellToken balance is withdrawn
    buyTokenBalance: bytes32  # Where the buyToken is deposited

STATIC_DATA_LEN: constant(uint256) = 20
OFFCHAIN_DATA_LEN: constant(uint256) = 1

@view
@external
def getTradeableOrder(_owner: address, _sender: address, _ctx: bytes32, _static_input: Bytes[STATIC_DATA_LEN], _offchain_input: Bytes[OFFCHAIN_DATA_LEN]) -> GPv2Order_Data:
    """
    @notice Generate order for WatchTower
    @dev _owner, _sender, _ctx, _offchain_input are ignored
    @param _owner Owner of order (self)
    @param _sender `msg.sender` context calling `isValidSignature`
    @param _ctx Execution context
    @param _static_input sellToken encoded as bytes(Bytes[20])
    @param _offchain_input Not used, zero-length bytes
    @return Order parameters
    """
    sell_token: ERC20 = ERC20(convert(convert(_static_input, bytes20), address))
    order: GPv2Order_Data = self._get_order(sell_token)
    order.sellAmount = sell_token.balanceOf(self)

    if order.sellAmount == 0 or not fee_collector.can_exchange([sell_token]):
        start: uint256 = 0
        end: uint256 = 0
        start, end = fee_collector.epoch_time_frame(Epoch.EXCHANGE)
        if block.timestamp >= start:
            start, end = fee_collector.epoch_time_frame(Epoch.EXCHANGE, block.timestamp + 7 * 24 * 3600)
        reason: String[11] = "ZeroBalance"
        if order.sellAmount != 0:  # FeeCollector reject
            reason = "NotAllowed"
        raw_revert(_abi_encode(start, reason, method_id=method_id("PollTryAtEpoch(uint256,string)")))

    return order

@view
@internal
def _get_order(sell_token: ERC20) -> GPv2Order_Data:
    buy_token: ERC20 = fee_collector.target()
    return GPv2Order_Data({
        sellToken: sell_token,  # token to sell
        buyToken: buy_token,  # token to buy
        receiver: fee_collector.address,  # receiver of the token to buy
        sellAmount: 0,  # Set later
        buyAmount: self.target_threshold,
        validTo: convert(fee_collector.epoch_time_frame(Epoch.EXCHANGE)[1], uint32),  # timestamp until order is valid
        appData: ADD_DATA,  # extra info about the order
        feeAmount: 0,  # amount of fees in sellToken
        kind: SELL_KIND,  # buy or sell
        partiallyFillable: True,  # partially fillable (True) or fill-or-kill (False)
        sellTokenBalance: TOKEN_BALANCE,  # From where the sellToken balance is withdrawn
        buyTokenBalance: TOKEN_BALANCE,  # Where the buyToken is deposited
    })
>>> CowSwapBurner.
''

verify

CowSwapBurner.verify(_owner: address, _sender: address, _hash: bytes32, _domain_separator: bytes32, _ctx: bytes32, _static_input: Bytes[STATIC_DATA_LEN], _offchain_input: Bytes[OFFCHAIN_DATA_LEN], _order: GPv2Order_Data)

Function to verify CowSwap orders to ensure that the order adheres to the conditions set by the contract and can be executed properly.

Input Type Description
_owner address Owner of conditional order (self).
_sender address msg.sender context calling isValidSignature.
_hash bytes32 EIP-712 order digest.
_domain_seperator bytes32 EIP-712 domain separator.
_ctx bytes32 Execution context.
_static_input Bytes[STATIC_DATA_LEN] ConditionalOrder's staticData (coin address).
_offchain_input Bytes[OFFCHAIN_DATA_LEN] Conditional order type-specific data NOT known at time of creation for a specific discrete order (or zero-length bytes if not applicable).
_order GPv2Order_Data The proposed discrete order's GPv2Order.Data struct.
Source code
struct GPv2Order_Data:
    sellToken: ERC20  # token to sell
    buyToken: ERC20  # token to buy
    receiver: address  # receiver of the token to buy
    sellAmount: uint256
    buyAmount: uint256
    validTo: uint32  # timestamp until order is valid
    appData: bytes32  # extra info about the order
    feeAmount: uint256  # amount of fees in sellToken
    kind: bytes32  # buy or sell
    partiallyFillable: bool  # partially fillable (True) or fill-or-kill (False)
    sellTokenBalance: bytes32  # From where the sellToken balance is withdrawn
    buyTokenBalance: bytes32  # Where the buyToken is deposited

@view
@external
def verify(
    _owner: address,
    _sender: address,
    _hash: bytes32,
    _domain_separator: bytes32,
    _ctx: bytes32,
    _static_input: Bytes[STATIC_DATA_LEN],
    _offchain_input: Bytes[OFFCHAIN_DATA_LEN],
    _order: GPv2Order_Data,
):
    """
    @notice Verify order
    @dev Called from ComposableCow. _owner, _sender, _hash, _domain_separator, _ctx are ignored.
    @param _owner Owner of conditional order (self)
    @param _sender `msg.sender` context calling `isValidSignature`
    @param _hash `EIP-712` order digest
    @param _domain_separator `EIP-712` domain separator
    @param _ctx Execution context
    @param _static_input ConditionalOrder's staticData (coin address)
    @param _offchain_input Conditional order type-specific data NOT known at time of creation for a specific discrete order (or zero-length bytes if not applicable)
    @param _order The proposed discrete order's `GPv2Order.Data` struct
    """
    sell_token: ERC20 = ERC20(convert(convert(_static_input, bytes20), address))
    if not fee_collector.can_exchange([sell_token]):
        raw_revert(_abi_encode("NotAllowed", method_id=method_id("OrderNotValid(string)")))
    if _offchain_input != b"":
        raw_revert(_abi_encode("NonZeroOffchainInput", method_id=method_id("OrderNotValid(string)")))
    order: GPv2Order_Data = self._get_order(sell_token)
    order.sellAmount = _order.sellAmount  # Any amount allowed
    order.buyAmount = max(_order.buyAmount, order.buyAmount)  # Price is discovered within CowSwap competition
    if _abi_encode(order) != _abi_encode(_order):
        raw_revert(_abi_encode("BadOrder", method_id=method_id("OrderNotValid(string)")))
>>> soon

isValidSignature

CowSwapBurner.isValidSignature(_hash: bytes32, signature: Bytes[1792]) -> bytes4

Function to verify a ERC-1271 signature for a given hash.

Returns: ERC1271_MAGIC_VALUE if signature is OK (bytes4).

Input Type Description
_hash bytes32 Hash of a signed data.
signature Bytes[1792] Signature for the object. (GPv2Order.Data, PayloadStruct) in this case.
Source code
ERC1271_MAGIC_VALUE: constant(bytes4) = 0x1626ba7e

@view
@external
def isValidSignature(_hash: bytes32, signature: Bytes[1792]) -> bytes4:
    """
    @notice ERC1271 signature verifier method
    @dev Forwards query to ComposableCow
    @param _hash Hash of signed object. Ignored here
    @param signature Signature for the object. (GPv2Order.Data, PayloadStruct) here
    @return `ERC1271_MAGIC_VALUE` if signature is OK
    """
    order: GPv2Order_Data = empty(GPv2Order_Data)
    payload: PayloadStruct = empty(PayloadStruct)
    order, payload = _abi_decode(signature, (GPv2Order_Data, PayloadStruct))

    return composable_cow.isValidSafeSignature(self, msg.sender, _hash, composable_cow.domainSeparator(), empty(bytes32),
        _abi_encode(order),
        _abi_encode(payload),
    )
>>> soon

target_threshold

CowSwapBurner.target_threshold() -> uint256: view

Getter for the minimum amount of target token to be bought in an order. This value ensure that each executed order meets a certain minimum value. This variable can be changed by the owner of the FeeCollector using the set_target_threshold function. Due to the gas efficiency of L2's, the value can be set much lower e.g. on Gnosis than on Ethereum.1

Returns: target threshold (uint256).

Source code
target_threshold: public(uint256)  # min amount to exchange

@external
def __init__(_fee_collector: FeeCollector,
    _composable_cow: ComposableCow, _vault_relayer: address, _target_threshold: uint256):
    """
    @notice Contract constructor
    @param _fee_collector FeeCollector to anchor to
    @param _composable_cow Address of ComposableCow contract
    @param _vault_relayer CowSwap's VaultRelayer contract address, all approves go there
    @param _target_threshold Minimum amount of target to buy per order
    """
    ...
    assert _target_threshold > 0, "Bad target threshold"
    self.target_threshold = _target_threshold
>>> CowSwapBurner.target_threshold()
50000000000000000000

set_target_threshold

CowSwapBurner.set_target_threshold(_target_threshold: uint256)

Guarded Method

This function is only callable by the owner of the FeeCollector contract.

Function to set the a new target_threshold value.

Input Type Description
_target_threshold uint256 New target threshold value.
Source code
target_threshold: public(uint256)  # min amount to exchange

@external
def set_target_threshold(_target_threshold: uint256):
    """
    @dev Callable only by owner
    @param _target_threshold Minimum amount of target to receive, with base=10**18
    """
    assert msg.sender == fee_collector.owner(), "Only owner"
    assert _target_threshold > 0, "Bad target threshold"

    self.target_threshold = _target_threshold
>>> soon

Pushing and Recovering Coins

The push_target function is used to transfer any leftover target coins from the burner to the FeeCollector.

Additionally, there is a recover function which lets the owner or emergency_owner of the FeeCollector to recover ERC20 or ETH.

push_target

CowSwapBurner.push_target() -> uint256

Function to push the entire balance of the target coin to the FeeCollector. This function can be called externally, but is also called directly by the FeeCollector before the target coins are forwarded to the hooker contract using the forward function.

Returns: amout of target coins pushed (uint256).

Source code
@external
def push_target() -> uint256:
    """
    @notice In case target coin is left in contract can be pushed to forward
    @return Amount of coin pushed further
    """
    target: ERC20 = fee_collector.target()
    amount: uint256 = target.balanceOf(self)
    if amount > 0:
        target.transfer(fee_collector.address, amount)
    return amount
>>> soon

recover

CowSwapBurner.recover(_coins: DynArray[ERC20, MAX_COINS_LEN])

Guarded Method

This function is only callable by the owner or emergency_owner of the FeeCollector.vy contract.

Function to recover ERC20 tokens or ETH from this contract. Calling this function will transfer _coins to the FeeCollector.

Input Type Description
_coins DynArray[ERC20, MAX_COINS_LEN] Dynamic array of the token addresses to recover.
Source code
@external
def recover(_coins: DynArray[ERC20, MAX_COINS_LEN]):
    """
    @notice Recover ERC20 tokens or Ether from this contract
    @dev Callable only by owner and emergency owner
    @param _coins Token addresses
    """
    assert msg.sender in [fee_collector.owner(), fee_collector.emergency_owner()], "Only owner"

    for coin in _coins:
        if coin.address == ETH_ADDRESS:
            raw_call(fee_collector.address, b"", value=self.balance)
        else:
            coin.transfer(fee_collector.address, coin.balanceOf(self))  # do not need safe transfer
>>> soon

Valid Interface a la ERC-165

In order for the burner contract to be fully compatible with the FeeCollector, a specific interface needs to hold up as per ERC-165:

SUPPORTED_INTERFACES: constant(bytes4[4]) = [
    # ERC165: method_id("supportsInterface(bytes4)") == 0x01ffc9a7
    0x01ffc9a7,
    # Burner:
    #   method_id("burn(address[],address)") == 0x72a436a8
    #   method_id("push_target()") == 0x2eb078cd
    #   method_id("VERSION()") == 0xffa1ad74
    0xa3b5e311,
    # Interface corresponding to IConditionalOrderGenerator:
    #   method_id("getTradeableOrder(address,address,bytes32,bytes,bytes)") == 0xb8296fc4
    0xb8296fc4,
    # ERC1271 interface:
    #   method_id("isValidSignature(bytes32,bytes)") == 0x1626ba7e
    ERC1271_MAGIC_VALUE,
]

supportsInterface

CowSwapBurner.supportsInterface(_interface_id: bytes4) -> bool

Function to check if the burner supports the correct interface, as specified by the ERC-165 standard. This method makes sure the contract is compatible with the FeeCollector contract.

Returns: true or false (bool)

Input Type Description
_interface_id bytes4 ID of the interface.
Source code
SIGNATURE_VERIFIER_MUXER_INTERFACE: constant(bytes4) = 0x62af8dc2
ERC1271_MAGIC_VALUE: constant(bytes4) = 0x1626ba7e
SUPPORTED_INTERFACES: constant(bytes4[4]) = [
    # ERC165: method_id("supportsInterface(bytes4)") == 0x01ffc9a7
    0x01ffc9a7,
    # Burner:
    #   method_id("burn(address[],address)") == 0x72a436a8
    #   method_id("push_target()") == 0x2eb078cd
    #   method_id("VERSION()") == 0xffa1ad74
    0xa3b5e311,
    # Interface corresponding to IConditionalOrderGenerator:
    #   method_id("getTradeableOrder(address,address,bytes32,bytes,bytes)") == 0xb8296fc4
    0xb8296fc4,
    # ERC1271 interface:
    #   method_id("isValidSignature(bytes32,bytes)") == 0x1626ba7e
    ERC1271_MAGIC_VALUE,
]

@pure
@external
def supportsInterface(_interface_id: bytes4) -> bool:
    """
    @dev Interface identification is specified in ERC-165.
    Fails on SignatureVerifierMuxer for compatability with ComposableCow.
    @param _interface_id Id of the interface
    """
    assert _interface_id != SIGNATURE_VERIFIER_MUXER_INTERFACE
    return _interface_id in SUPPORTED_INTERFACES
>>> soon

Contract Info Methods

fee_collector

CowSwapBurner.fee_collector() -> address: view

Getter for the Fee Collector address to anchor to.

Returns: fee collector (address).

Source code
interface FeeCollector:
    def fee(_epoch: Epoch=empty(Epoch), _ts: uint256=block.timestamp) -> uint256: view
    def target() -> ERC20: view
    def owner() -> address: view
    def emergency_owner() -> address: view
    def epoch_time_frame(epoch: Epoch, ts: uint256=block.timestamp) -> (uint256, uint256): view
    def can_exchange(_coins: DynArray[ERC20, MAX_COINS_LEN]) -> bool: view
    def transfer(_transfers: DynArray[Transfer, MAX_COINS_LEN]): nonpayable

fee_collector: public(immutable(FeeCollector))

@external
def __init__(_fee_collector: FeeCollector,
    _composable_cow: ComposableCow, _vault_relayer: address, _target_threshold: uint256):
    """
    @notice Contract constructor
    @param _fee_collector FeeCollector to anchor to
    @param _composable_cow Address of ComposableCow contract
    @param _vault_relayer CowSwap's VaultRelayer contract address, all approves go there
    @param _target_threshold Minimum amount of target to buy per order
    """
    fee_collector = _fee_collector
    ...
>>> CowSwapBurner.fee_collector()
'0xa2Bcd1a4Efbd04B63cd03f5aFf2561106ebCCE00'

composable_cow

CowSwapBurner.composable_cow() -> address: view

Getter for the ComposableCow contract. ComposableCow is a framework for smoothing developer experience when building conditional orders on the CoW Protocol. For the official documentation, see here.

Returns: ComposableCow contract (address).

Source code
interface ComposableCow:
    def create(params: ConditionalOrderParams, dispatch: bool): nonpayable
    def domainSeparator() -> bytes32: view
    def isValidSafeSignature(
        safe: address, sender: address, _hash: bytes32, _domainSeparator: bytes32, typeHash: bytes32,
        encodeData: Bytes[15 * 32],
        payload: Bytes[(32 + 3 + 1 + 8) * 32],
    ) -> bytes4: view

composable_cow: public(immutable(ComposableCow))

@external
def __init__(_fee_collector: FeeCollector,
    _composable_cow: ComposableCow, _vault_relayer: address, _target_threshold: uint256):
    """
    @notice Contract constructor
    @param _fee_collector FeeCollector to anchor to
    @param _composable_cow Address of ComposableCow contract
    @param _vault_relayer CowSwap's VaultRelayer contract address, all approves go there
    @param _target_threshold Minimum amount of target to buy per order
    """
    ...
    composable_cow = _composable_cow
    ...
>>> CowSwapBurner.composable_cow()
'0xfdaFc9d1902f4e0b84f65F49f244b32b31013b74'

vault_relayer

CowSwapBurner.vault_relayer() -> address: view

Getter for CoW Protocols Vault Relayer contract. This is the contract where all approvals go to. For the official documentation, see here.

Returns: Vault Relayer (address).

Source code
vault_relayer: public(immutable(address))

@external
def __init__(_fee_collector: FeeCollector,
    _composable_cow: ComposableCow, _vault_relayer: address, _target_threshold: uint256):
    """
    @notice Contract constructor
    @param _fee_collector FeeCollector to anchor to
    @param _composable_cow Address of ComposableCow contract
    @param _vault_relayer CowSwap's VaultRelayer contract address, all approves go there
    @param _target_threshold Minimum amount of target to buy per order
    """
    ...
    vault_relayer = _vault_relayer
    ...
>>> CowSwapBurner.vault_relayer()
'0xC92E8bdf79f0507f65a392b0ab4667716BFE0110'

ADD_DATA

CowSwapBurner.ADD_DATA() -> bytes32: view

Getter for the additional data applied in the internal _get_order function. The data is shown as metadata on the CowSwap explorer and allows distinguishing Curve orders (e.g., see this transaction).

Returns: additional data (bytes32).

Source code
ADD_DATA: public(constant(bytes32)) = 0x058315b749613051abcbf50cf2d605b4fa4a41554ec35d73fd058fc530da559f
>>> CowSwapBurner.ADD_DATA()
'0x058315b749613051abcbf50cf2d605b4fa4a41554ec35d73fd058fc530da559f'

VERSION

CowSwapBurner.VERSION() -> String[20]: view

Getter for the burner version.

Returns: version (String[20])

Source code
VERSION: public(constant(String[20])) = "CowSwap"
>>> CowSwapBurner.VERSION()
'CowSwap'

  1. The minimum target threshold value on Gnosis is 1 (1e18), on Ethereum 50 (50 * 1e18)