Datasets:

Zellic
/

smart-contract-fiesta

	// This contract is part of Zellic’s smart contract dataset, which is a collection of publicly available contract code gathered as of March 2023.

	// SPDX-License-Identifier: MIT
	pragma solidity ^0.8.4;

	/// @notice Contract helper for Kali DAO extensions.
	abstract contract KaliExtension {
	function setExtension(bytes calldata extensionData) public payable virtual;
	}

	/// @notice Contract that enables a single call to call multiple methods on itself.
	/// @author Modified from Solady (https://github.com/vectorized/solady/blob/main/src/utils/Multicallable.sol)
	/// @dev WARNING!
	/// Multicallable is NOT SAFE for use in contracts with checks / requires on `msg.value`
	/// (e.g. in NFT minting / auction contracts) without a suitable nonce mechanism.
	/// It WILL open up your contract to double-spend vulnerabilities / exploits.
	/// See: (https://www.paradigm.xyz/2021/08/two-rights-might-make-a-wrong/)
	abstract contract Multicallable {
	/// @dev Apply `DELEGATECALL` with the current contract to each calldata in `data`,
	/// and store the `abi.encode` formatted results of each `DELEGATECALL` into `results`.
	/// If any of the `DELEGATECALL`s reverts, the entire transaction is reverted,
	/// and the error is bubbled up.
	function multicall(
	bytes[] calldata data
	) public payable virtual returns (bytes[] memory) {
	assembly {
	mstore(0x00, 0x20)
	mstore(0x20, data.length) // Store `data.length` into `results`.
	// Early return if no data.
	if iszero(data.length) {
	return(0x00, 0x40)
	}

	let results := 0x40
	// `shl` 5 is equivalent to multiplying by 0x20.
	let end := shl(5, data.length)
	// Copy the offsets from calldata into memory.
	calldatacopy(0x40, data.offset, end)
	// Pointer to the top of the memory (i.e. start of the free memory).
	let resultsOffset := end

	for {
	end := add(results, end)
	} 1 {

	} {
	// The offset of the current bytes in the calldata.
	let o := add(data.offset, mload(results))
	let memPtr := add(resultsOffset, 0x40)
	// Copy the current bytes from calldata to the memory.
	calldatacopy(
	memPtr,
	add(o, 0x20), // The offset of the current bytes' bytes.
	calldataload(o) // The length of the current bytes.
	)
	if iszero(
	delegatecall(
	gas(),
	address(),
	memPtr,
	calldataload(o),
	0x00,
	0x00
	)
	) {
	// Bubble up the revert if the delegatecall reverts.
	returndatacopy(0x00, 0x00, returndatasize())
	revert(0x00, returndatasize())
	}
	// Append the current `resultsOffset` into `results`.
	mstore(results, resultsOffset)
	results := add(results, 0x20)
	// Append the `returndatasize()`, and the return data.
	mstore(memPtr, returndatasize())
	returndatacopy(add(memPtr, 0x20), 0x00, returndatasize())
	// Advance the `resultsOffset` by `returndatasize() + 0x20`,
	// rounded up to the next multiple of 32.
	resultsOffset := and(
	add(add(resultsOffset, returndatasize()), 0x3f),
	0xffffffffffffffe0
	)
	if iszero(lt(results, end)) {
	break
	}
	}
	return(0x00, add(resultsOffset, 0x40))
	}
	}
	}

	/// @notice Reentrancy protection for contracts.
	/// @author Modified from Solbase (https://github.com/Sol-DAO/solbase/blob/main/src/utils/ReentrancyGuard.sol)
	abstract contract ReentrancyGuard {
	error Reentrancy();

	uint256 internal locked = 1;

	modifier nonReentrant() virtual {
	if (locked == 2) revert Reentrancy();

	locked = 2;

	_;

	locked = 1;
	}
	}

	/// @notice Contract helper for Keep token management.
	abstract contract KeepTokenManager {
	function balanceOf(
	address account,
	uint256 id
	) public view virtual returns (uint256);

	function totalSupply(uint256 id) public view virtual returns (uint256);

	function transferable(uint256 id) public view virtual returns (bool);

	function getPriorVotes(
	address account,
	uint256 id,
	uint256 timestamp
	) public view virtual returns (uint256);

	function mint(
	address to,
	uint256 id,
	uint256 amount,
	bytes calldata data
	) public payable virtual;

	function burn(
	address from,
	uint256 id,
	uint256 amount
	) public payable virtual;

	function setTransferability(uint256 id, bool on) public payable virtual;
	}

	/// @notice ERC1155 interface to receive tokens.
	/// @author Modified from Solbase (https://github.com/Sol-DAO/solbase/blob/main/src/tokens/ERC1155/ERC1155.sol)
	abstract contract ERC1155TokenReceiver {
	function onERC1155Received(
	address,
	address,
	uint256,
	uint256,
	bytes calldata
	) public payable virtual returns (bytes4) {
	return this.onERC1155Received.selector;
	}

	function onERC1155BatchReceived(
	address,
	address,
	uint256[] calldata,
	uint256[] calldata,
	bytes calldata
	) public payable virtual returns (bytes4) {
	return this.onERC1155BatchReceived.selector;
	}
	}

	enum Operation {
	call,
	delegatecall,
	create
	}

	struct Call {
	Operation op;
	address to;
	uint256 value;
	bytes data;
	}

	struct Signature {
	address user;
	uint8 v;
	bytes32 r;
	bytes32 s;
	}

	/// @title Kali
	/// @notice Kali DAO core for on-chain governance.
	/// @author z0r0z.eth

	enum ProposalType {
	MINT, // Add to membership.
	BURN, // Revoke membership.
	CALL, // Call to external code.
	VPERIOD, // Set `votingPeriod`.
	GPERIOD, // Set `gracePeriod`.
	QUORUM, // Set `quorum`.
	SUPERMAJORITY, // Set `supermajority`.
	TYPE, // Set `VoteType` `ProposalType`.
	PAUSE, // Flip membership transferability.
	EXTENSION, // Flip `extensions` permission.
	ESCAPE, // Delete pending proposal in queue.
	URI // Amend root documentation for the DAO.
	}

	enum VoteType {
	SIMPLE_MAJORITY_QUORUM_REQUIRED,
	SIMPLE_MAJORITY,
	SUPERMAJORITY_QUORUM_REQUIRED,
	SUPERMAJORITY
	}

	struct Proposal {
	uint256 prevProposal;
	bytes32 proposalHash;
	address proposer;
	uint40 creationTime;
	uint216 yesVotes;
	uint216 noVotes;
	}

	struct ProposalState {
	bool passed;
	bool processed;
	}

	contract Kali is ERC1155TokenReceiver, Multicallable, ReentrancyGuard {
	/// -----------------------------------------------------------------------
	/// Events
	/// -----------------------------------------------------------------------

	event NewProposal(
	address indexed proposer,
	uint256 indexed proposal,
	Call[] calls,
	ProposalType setting,
	string details,
	uint256 creationTime,
	bool sponsored
	);

	event ProposalCancelled(address indexed proposer, uint256 indexed proposal);

	event ProposalSponsored(address indexed sponsor, uint256 indexed proposal);

	event VoteCast(
	address indexed voter,
	uint256 indexed proposal,
	bool approve,
	uint256 weight,
	string details
	);

	event ProposalProcessed(uint256 indexed proposal, bool passed);

	event ExtensionSet(address indexed extension, bool on);

	event URISet(string daoURI);

	event GovSettingsUpdated(
	uint256 votingPeriod,
	uint256 gracePeriod,
	uint256 quorum,
	uint256 supermajority,
	uint256[2] typeSetting
	);

	event Executed(
	Operation op,
	address to,
	uint256 value,
	bytes data,
	bool success
	);

	/// -----------------------------------------------------------------------
	/// Custom Errors
	/// -----------------------------------------------------------------------

	error Initialized();

	error PeriodBounds();

	error QuorumMax();

	error SupermajorityBounds();

	error TypeBounds();

	error Unauthorized();

	error Sponsored();

	error InvalidProposal();

	error AlreadyVoted();

	error InvalidHash();

	error PrevNotProcessed();

	error VotingNotEnded();

	error InvalidSig();

	error Overflow();

	/// -----------------------------------------------------------------------
	/// DAO Storage/Logic
	/// -----------------------------------------------------------------------

	bytes32 internal constant MALLEABILITY_THRESHOLD =
	0x7fffffffffffffffffffffffffffffff5d576e7357a4501ddfe92f46681b20a0;

	uint256 internal currentSponsoredProposal;

	uint256 public proposalCount;

	string public daoURI;

	uint120 public votingPeriod;

	uint120 public gracePeriod;

	uint8 public quorum; // 1-100.

	uint8 public supermajority; // 1-100.

	mapping(address => bool) public extensions;

	mapping(uint256 => Proposal) public proposals;

	mapping(uint256 => ProposalState) public proposalStates;

	mapping(ProposalType => VoteType) public proposalVoteTypes;

	mapping(uint256 => mapping(address => bool)) public voted;

	mapping(address => uint256) public lastYesVote;

	function token() public pure virtual returns (KeepTokenManager tkn) {
	uint256 placeholder;

	assembly {
	placeholder := sub(
	calldatasize(),
	add(shr(240, calldataload(sub(calldatasize(), 2))), 2)
	)

	tkn := shr(0x60, calldataload(add(placeholder, 2)))
	}
	}

	function tokenId() public pure virtual returns (uint256 id) {
	return _fetchImmutable(22);
	}

	function name() public pure virtual returns (string memory) {
	return string(abi.encodePacked(_fetchImmutable(54)));
	}

	function _fetchImmutable(
	uint256 place
	) internal pure virtual returns (uint256 ref) {
	uint256 placeholder;

	assembly {
	placeholder := sub(
	calldatasize(),
	add(shr(240, calldataload(sub(calldatasize(), 2))), 2)
	)

	ref := calldataload(add(placeholder, place))
	}
	}

	/// -----------------------------------------------------------------------
	/// ERC165 Logic
	/// -----------------------------------------------------------------------

	function supportsInterface(
	bytes4 interfaceId
	) public view virtual returns (bool) {
	return
	// ERC165 interface ID for ERC165.
	interfaceId == this.supportsInterface.selector \|\|
	// ERC165 Interface ID for ERC721TokenReceiver.
	interfaceId == this.onERC721Received.selector \|\|
	// ERC165 Interface ID for ERC1155TokenReceiver.
	interfaceId == type(ERC1155TokenReceiver).interfaceId;
	}

	/// -----------------------------------------------------------------------
	/// ERC721 Receiver Logic
	/// -----------------------------------------------------------------------

	function onERC721Received(
	address,
	address,
	uint256,
	bytes calldata
	) public payable virtual returns (bytes4) {
	return this.onERC721Received.selector;
	}

	/// -----------------------------------------------------------------------
	/// Initialization Logic
	/// -----------------------------------------------------------------------

	constructor() payable {
	// Deploy as singleton.
	votingPeriod = 1;
	}

	function initialize(
	Call[] calldata _calls,
	string calldata _daoURI,
	uint120[4] calldata _govSettings
	) public payable virtual {
	if (votingPeriod != 0) revert Initialized();

	if (_govSettings[0] == 0) revert PeriodBounds();

	if (_govSettings[0] > 365 days) revert PeriodBounds();

	if (_govSettings[1] > 365 days) revert PeriodBounds();

	if (_govSettings[2] > 100) revert QuorumMax();

	if (_govSettings[3] <= 51) revert SupermajorityBounds();

	if (_govSettings[3] > 100) revert SupermajorityBounds();

	if (_calls.length != 0) {
	for (uint256 i; i < _calls.length; ) {
	extensions[_calls[i].to] = true;

	if (_calls[i].data.length > 3)
	_execute(
	_calls[i].op,
	_calls[i].to,
	_calls[i].value,
	_calls[i].data
	);

	// An array can't have a total length
	// larger than the max uint256 value.
	unchecked {
	++i;
	}
	}
	}

	daoURI = _daoURI;

	votingPeriod = uint120(_govSettings[0]);

	gracePeriod = uint120(_govSettings[1]);

	quorum = uint8(_govSettings[2]);

	supermajority = uint8(_govSettings[3]);
	}

	/// -----------------------------------------------------------------------
	/// EIP-712 Logic
	/// -----------------------------------------------------------------------

	function DOMAIN_SEPARATOR() public view virtual returns (bytes32) {
	return
	keccak256(
	abi.encode(
	// `keccak256(
	// "EIP712Domain(string name,string version,uint256 chainId,address verifyingContract)"
	// )`
	0x8b73c3c69bb8fe3d512ecc4cf759cc79239f7b179b0ffacaa9a75d522b39400f,
	// `keccak256(bytes("Kali"))`
	0xd321353274be6f42cf7b550879ff1a1c924e1e8f469054b23c7354e7f1737c64,
	// `keccak256("1")`
	0xc89efdaa54c0f20c7adf612882df0950f5a951637e0307cdcb4c672f298b8bc6,
	block.chainid,
	address(this)
	)
	);
	}

	/// -----------------------------------------------------------------------
	/// Proposal Logic
	/// -----------------------------------------------------------------------

	function propose(
	Call[] calldata calls,
	ProposalType setting,
	string calldata details
	) public payable virtual returns (uint256 proposal, uint40 creationTime) {
	if (setting != ProposalType.MINT)
	if (setting != ProposalType.BURN)
	if (setting != ProposalType.CALL)
	if (setting == ProposalType.VPERIOD)
	if (calls[0].value == 0 \|\| calls[0].value > 365 days)
	revert PeriodBounds();
	else if (setting == ProposalType.GPERIOD)
	if (calls[0].value > 365 days)
	revert PeriodBounds();
	else if (setting == ProposalType.QUORUM)
	if (calls[0].value > 100) revert QuorumMax();
	else if (setting == ProposalType.SUPERMAJORITY)
	if (
	calls[0].value <= 51 \|\|
	calls[0].value > 100
	) revert SupermajorityBounds();
	else if (setting == ProposalType.TYPE)
	if (
	calls[0].value > 11 \|\|
	calls[1].value > 3
	) revert TypeBounds();
	bool sponsored;

	// If member or extension is making proposal, include sponsorship.
	if (
	token().balanceOf(msg.sender, tokenId()) != 0 \|\|
	extensions[msg.sender]
	) sponsored = true;

	// Proposal count cannot realistically overflow on human timescales.
	unchecked {
	proposals[proposal = ++proposalCount] = Proposal({
	prevProposal: sponsored ? currentSponsoredProposal : 0,
	proposalHash: keccak256(abi.encode(calls, setting, details)),
	proposer: msg.sender,
	creationTime: creationTime = sponsored
	? _safeCastTo40(block.timestamp)
	: 0,
	yesVotes: 0,
	noVotes: 0
	});
	}

	if (sponsored) currentSponsoredProposal = proposal;

	emit NewProposal(
	msg.sender,
	proposal,
	calls,
	setting,
	details,
	creationTime,
	sponsored
	);
	}

	function cancelProposal(uint256 proposal) public payable virtual {
	Proposal storage prop = proposals[proposal];

	if (msg.sender != prop.proposer)
	if (!extensions[msg.sender]) revert Unauthorized();

	if (prop.creationTime != 0) revert Sponsored();

	delete proposals[proposal];

	emit ProposalCancelled(msg.sender, proposal);
	}

	function sponsorProposal(uint256 proposal) public payable virtual {
	Proposal storage prop = proposals[proposal];

	if (token().balanceOf(msg.sender, tokenId()) == 0)
	if (!extensions[msg.sender]) revert Unauthorized();

	if (prop.proposer == address(0)) revert InvalidProposal();

	if (prop.creationTime != 0) revert Sponsored();

	prop.prevProposal = currentSponsoredProposal;

	currentSponsoredProposal = proposal;

	prop.creationTime = _safeCastTo40(block.timestamp);

	emit ProposalSponsored(msg.sender, proposal);
	}

	/// -----------------------------------------------------------------------
	/// Voting Logic
	/// -----------------------------------------------------------------------

	function vote(
	uint256 proposal,
	bool approve,
	string calldata details
	) public payable virtual {
	_vote(msg.sender, proposal, approve, details);
	}

	function voteBySig(
	uint256 proposal,
	bool approve,
	string calldata details,
	Signature calldata sig
	) public payable virtual {
	bytes32 hash = keccak256(
	abi.encodePacked(
	"\x19\x01",
	DOMAIN_SEPARATOR(),
	keccak256(
	abi.encode(
	keccak256(
	"SignVote(uint256 proposal,bool approve,string details)"
	),
	proposal,
	approve,
	details
	)
	)
	)
	);

	// Check signature recovery.
	_recoverSig(hash, sig.user, sig.v, sig.r, sig.s);

	_vote(sig.user, proposal, approve, details);
	}

	function _vote(
	address user,
	uint256 proposal,
	bool approve,
	string calldata details
	) internal virtual {
	Proposal storage prop = proposals[proposal];

	if (voted[proposal][user]) revert AlreadyVoted();

	voted[proposal][user] = true;

	// This is safe from overflow because `votingPeriod`
	// is capped so it will not combine with unix time
	// to exceed the max uint256 value.
	unchecked {
	if (block.timestamp > prop.creationTime + votingPeriod)
	revert InvalidProposal();
	}

	uint216 weight = uint216(
	token().getPriorVotes(user, tokenId(), prop.creationTime)
	);

	// This is safe from overflow because `yesVotes`
	// and `noVotes` are capped by `totalSupply`
	// which is checked for overflow in `token` contract.
	unchecked {
	if (approve) {
	prop.yesVotes += weight;

	lastYesVote[user] = proposal;
	} else {
	prop.noVotes += weight;
	}
	}

	emit VoteCast(user, proposal, approve, weight, details);
	}

	/// -----------------------------------------------------------------------
	/// Processing Logic
	/// -----------------------------------------------------------------------

	function processProposal(
	uint256 proposal,
	Call[] calldata calls,
	ProposalType setting,
	string calldata details
	) public payable virtual nonReentrant returns (bool passed) {
	Proposal storage prop = proposals[proposal];

	if (prop.creationTime == 0) revert InvalidProposal();

	if (keccak256(abi.encode(calls, setting, details)) != prop.proposalHash)
	revert InvalidHash();

	// Skip previous proposal processing requirement
	// in case of escape hatch.
	if (setting != ProposalType.ESCAPE)
	if (proposals[prop.prevProposal].creationTime != 0)
	revert PrevNotProcessed();

	VoteType voteType = proposalVoteTypes[setting];

	passed = _countVotes(voteType, prop.yesVotes, prop.noVotes);

	// If quorum and approval threshold are met,
	// skip voting period for fast processing.
	// If a grace period has been set,
	// or if quorum is set to nothing,
	// maintain voting period check.
	if (
	!passed \|\|
	gracePeriod != 0 \|\|
	quorum == 0 \|\|
	voteType == VoteType.SIMPLE_MAJORITY \|\|
	voteType == VoteType.SUPERMAJORITY
	) {
	// This is safe from overflow because `votingPeriod`
	// and `gracePeriod` are capped so they will not combine
	// with unix time to exceed the max uint256 value.
	unchecked {
	if (
	block.timestamp <=
	prop.creationTime + votingPeriod + gracePeriod
	) revert VotingNotEnded();
	}
	}

	if (passed) {
	// An array can't have a total length
	// larger than the max uint256 value.
	unchecked {
	if (setting == ProposalType.MINT) {
	for (uint256 i; i < calls.length; ++i) {
	token().mint(
	calls[i].to,
	tokenId(),
	calls[i].value,
	calls[i].data
	);
	}
	} else if (setting == ProposalType.BURN) {
	for (uint256 i; i < calls.length; ++i) {
	token().burn(calls[i].to, tokenId(), calls[i].value);
	}
	} else if (setting == ProposalType.CALL) {
	for (uint256 i; i < calls.length; ++i) {
	_execute(
	calls[i].op,
	calls[i].to,
	calls[i].value,
	calls[i].data
	);
	}
	} else if (setting == ProposalType.VPERIOD) {
	votingPeriod = uint120(calls[0].value);
	} else if (setting == ProposalType.GPERIOD) {
	gracePeriod = uint120(calls[0].value);
	} else if (setting == ProposalType.QUORUM) {
	quorum = uint8(calls[0].value);
	} else if (setting == ProposalType.SUPERMAJORITY) {
	supermajority = uint8(calls[0].value);
	} else if (setting == ProposalType.TYPE) {
	proposalVoteTypes[ProposalType(calls[0].value)] = VoteType(
	calls[1].value
	);
	} else if (setting == ProposalType.PAUSE) {
	token().setTransferability(
	tokenId(),
	!token().transferable(tokenId())
	);
	} else if (setting == ProposalType.EXTENSION) {
	for (uint256 i; i < calls.length; ++i) {
	if (calls[i].value != 0)
	extensions[calls[i].to] = !extensions[calls[i].to];

	if (calls[i].data.length > 3)
	KaliExtension(calls[i].to).setExtension(
	calls[i].data
	);
	}
	} else if (setting == ProposalType.ESCAPE) {
	delete proposals[calls[0].value];
	} else if (setting == ProposalType.URI) {
	daoURI = details;
	}

	proposalStates[proposal].passed = true;
	}
	}

	delete proposals[proposal];

	proposalStates[proposal].processed = true;

	emit ProposalProcessed(proposal, passed);
	}

	function _countVotes(
	VoteType voteType,
	uint256 yesVotes,
	uint256 noVotes
	) internal view virtual returns (bool passed) {
	// Fail proposal if no participation.
	if (yesVotes == 0)
	if (noVotes == 0) return false;

	// Rule out any failed quorums.
	if (
	voteType == VoteType.SIMPLE_MAJORITY_QUORUM_REQUIRED \|\|
	voteType == VoteType.SUPERMAJORITY_QUORUM_REQUIRED
	) {
	// This is safe from overflow because `yesVotes`
	// and `noVotes` supply are checked
	// in `token` contract.
	unchecked {
	if (
	(yesVotes + noVotes) <
	((token().totalSupply(tokenId()) * quorum) / 100)
	) return false;
	}
	}

	if (
	// Simple majority check.
	voteType == VoteType.SIMPLE_MAJORITY \|\|
	voteType == VoteType.SIMPLE_MAJORITY_QUORUM_REQUIRED
	) {
	if (yesVotes > noVotes) return true;
	} else {
	// Supermajority check.
	// Example: 7 yes, 2 no, supermajority = 66
	// ((7+2) * 66) / 100 = 5.94; 7 yes will pass.
	// This is safe from overflow because `yesVotes`
	// and `noVotes` supply are checked
	// in `token` contract.
	unchecked {
	if (yesVotes >= ((yesVotes + noVotes) * supermajority) / 100)
	return true;
	}
	}
	}

	/// -----------------------------------------------------------------------
	/// Execution Logic
	/// -----------------------------------------------------------------------

	function _execute(
	Operation op,
	address to,
	uint256 value,
	bytes memory data
	) internal virtual {
	bool success;

	if (op == Operation.call) {
	assembly {
	success := call(
	gas(),
	to,
	value,
	add(data, 0x20),
	mload(data),
	0,
	0
	)
	}

	emit Executed(op, to, value, data, success);
	} else if (op == Operation.delegatecall) {
	assembly {
	success := delegatecall(
	gas(),
	to,
	add(data, 0x20),
	mload(data),
	0,
	0
	)
	}

	emit Executed(op, to, value, data, success);
	} else {
	assembly {
	success := create(value, add(data, 0x20), mload(data))
	}

	emit Executed(op, to, value, data, success);
	}
	}

	/// -----------------------------------------------------------------------
	/// Signature Recovery Logic
	/// -----------------------------------------------------------------------

	function _recoverSig(
	bytes32 hash,
	address signer,
	uint8 v,
	bytes32 r,
	bytes32 s
	) internal view virtual {
	if (signer == address(0)) revert InvalidSig();

	bool isValid;

	/// @solidity memory-safe-assembly
	assembly {
	// Clean the upper 96 bits of `signer` in case they are dirty.
	for {
	signer := shr(96, shl(96, signer))
	} signer {

	} {
	// Load the free memory pointer.
	// Simply using the free memory usually costs less if many slots are needed.
	let m := mload(0x40)

	// Clean the excess bits of `v` in case they are dirty.
	v := and(v, 0xff)
	// If `s` in lower half order, such that the signature is not malleable.
	if iszero(gt(s, MALLEABILITY_THRESHOLD)) {
	mstore(m, hash)
	mstore(add(m, 0x20), v)
	mstore(add(m, 0x40), r)
	mstore(add(m, 0x60), s)
	pop(
	staticcall(
	gas(), // Amount of gas left for the transaction.
	0x01, // Address of `ecrecover`.
	m, // Start of input.
	0x80, // Size of input.
	m, // Start of output.
	0x20 // Size of output.
	)
	)
	// `returndatasize()` will be `0x20` upon success, and `0x00` otherwise.
	if mul(eq(mload(m), signer), returndatasize()) {
	isValid := 1
	break
	}
	}

	// `bytes4(keccak256("isValidSignature(bytes32,bytes)"))`.
	let f := shl(224, 0x1626ba7e)
	// Write the abi-encoded calldata into memory, beginning with the function selector.
	mstore(m, f) // `bytes4(keccak256("isValidSignature(bytes32,bytes)"))`.
	mstore(add(m, 0x04), hash)
	mstore(add(m, 0x24), 0x40) // The offset of the `signature` in the calldata.
	mstore(add(m, 0x44), 65) // Store the length of the signature.
	mstore(add(m, 0x64), r) // Store `r` of the signature.
	mstore(add(m, 0x84), s) // Store `s` of the signature.
	mstore8(add(m, 0xa4), v) // Store `v` of the signature.

	isValid := and(
	and(
	// Whether the returndata is the magic value `0x1626ba7e` (left-aligned).
	eq(mload(0x00), f),
	// Whether the returndata is exactly 0x20 bytes (1 word) long.
	eq(returndatasize(), 0x20)
	),
	// Whether the staticcall does not revert.
	// This must be placed at the end of the `and` clause,
	// as the arguments are evaluated from right to left.
	staticcall(
	gas(), // Remaining gas.
	signer, // The `signer` address.
	m, // Offset of calldata in memory.
	0xa5, // Length of calldata in memory.
	0x00, // Offset of returndata.
	0x20 // Length of returndata to write.
	)
	)
	break
	}
	}

	if (!isValid) revert InvalidSig();
	}

	/// -----------------------------------------------------------------------
	/// Safecast Logic
	/// -----------------------------------------------------------------------

	function _safeCastTo40(uint256 x) internal pure virtual returns (uint40) {
	if (x >= (1 << 40)) revert Overflow();

	return uint40(x);
	}

	/// -----------------------------------------------------------------------
	/// Extension Logic
	/// -----------------------------------------------------------------------

	modifier onlyExtension() {
	if (!extensions[msg.sender]) revert Unauthorized();

	_;
	}

	function relay(
	Call calldata call
	) public payable virtual onlyExtension nonReentrant {
	_execute(call.op, call.to, call.value, call.data);
	}

	function mint(
	KeepTokenManager source,
	address to,
	uint256 id,
	uint256 amount,
	bytes calldata data
	) public payable virtual onlyExtension nonReentrant {
	source.mint(to, id, amount, data);
	}

	function burn(
	KeepTokenManager source,
	address from,
	uint256 id,
	uint256 amount
	) public payable virtual onlyExtension nonReentrant {
	source.burn(from, id, amount);
	}

	function setTransferability(
	KeepTokenManager source,
	uint256 id,
	bool on
	) public payable virtual onlyExtension nonReentrant {
	source.setTransferability(id, on);
	}

	function setExtension(address extension, bool on) public payable virtual {
	if (!extensions[msg.sender])
	if (msg.sender != address(this)) revert Unauthorized();

	extensions[extension] = on;

	emit ExtensionSet(extension, on);
	}

	function setURI(
	string calldata _daoURI
	) public payable virtual onlyExtension {
	daoURI = _daoURI;

	emit URISet(_daoURI);
	}

	function deleteProposal(uint256 proposal) public payable virtual {
	if (!extensions[msg.sender])
	if (msg.sender != address(this)) revert Unauthorized();

	if (proposals[proposal].creationTime == 0) revert InvalidProposal();

	delete proposals[proposal];

	proposalStates[proposal].processed = true;
	}

	function updateGovSettings(
	uint256 _votingPeriod,
	uint256 _gracePeriod,
	uint256 _quorum,
	uint256 _supermajority,
	uint256[2] calldata _typeSetting
	) public payable virtual {
	if (!extensions[msg.sender])
	if (msg.sender != address(this)) revert Unauthorized();

	if (_votingPeriod != 0)
	if (_votingPeriod <= 365 days)
	votingPeriod = uint120(_votingPeriod);

	if (_gracePeriod <= 365 days) gracePeriod = uint120(_gracePeriod);

	if (_quorum <= 100) quorum = uint8(_quorum);

	if (_supermajority > 51)
	if (_supermajority <= 100) supermajority = uint8(_supermajority);

	if (_typeSetting[0] <= 11)
	if (_typeSetting[1] <= 3)
	proposalVoteTypes[ProposalType(_typeSetting[0])] = VoteType(
	_typeSetting[1]
	);

	emit GovSettingsUpdated(
	_votingPeriod,
	_gracePeriod,
	_quorum,
	_supermajority,
	_typeSetting
	);
	}
	}

	/// @notice Minimal proxy library with immutable args operations.
	/// @author Modified from Solady (https://github.com/Vectorized/solady/blob/main/src/utils/LibClone.sol)
	library LibClone {
	/// -----------------------------------------------------------------------
	/// Custom Errors
	/// -----------------------------------------------------------------------

	/// @dev Unable to deploy the clone.
	error DeploymentFailed();

	/// -----------------------------------------------------------------------
	/// Clone Operations
	/// -----------------------------------------------------------------------

	/// @dev Deploys a deterministic clone of `implementation`,
	/// using immutable arguments encoded in `data`, with `salt`.
	function cloneDeterministic(
	address implementation,
	bytes memory data,
	bytes32 salt
	) internal returns (address instance) {
	assembly {
	// Compute the boundaries of the data and cache the memory slots around it.
	let mBefore3 := mload(sub(data, 0x60))
	let mBefore2 := mload(sub(data, 0x40))
	let mBefore1 := mload(sub(data, 0x20))
	let dataLength := mload(data)
	let dataEnd := add(add(data, 0x20), dataLength)
	let mAfter1 := mload(dataEnd)

	// +2 bytes for telling how much data there is appended to the call.
	let extraLength := add(dataLength, 2)

	// Write the bytecode before the data.
	mstore(data, 0x5af43d3d93803e606057fd5bf3)
	// Write the address of the implementation.
	mstore(sub(data, 0x0d), implementation)
	// Write the rest of the bytecode.
	mstore(
	sub(data, 0x21),
	or(
	shl(0x48, extraLength),
	0x593da1005b363d3d373d3d3d3d610000806062363936013d73
	)
	)
	// `keccak256("ReceiveETH(uint256)")`.
	mstore(
	sub(data, 0x3a),
	0x9e4ac34f21c619cefc926c8bd93b54bf5a39c7ab2127a895af1cc0691d7e3dff
	)
	mstore(
	sub(data, 0x5a),
	or(
	shl(0x78, add(extraLength, 0x62)),
	0x6100003d81600a3d39f336602c57343d527f
	)
	)
	mstore(dataEnd, shl(0xf0, extraLength))

	// Create the instance.
	instance := create2(
	0,
	sub(data, 0x4c),
	add(extraLength, 0x6c),
	salt
	)

	// If `instance` is zero, revert.
	if iszero(instance) {
	// Store the function selector of `DeploymentFailed()`.
	mstore(0x00, 0x30116425)
	// Revert with (offset, size).
	revert(0x1c, 0x04)
	}

	// Restore the overwritten memory surrounding `data`.
	mstore(dataEnd, mAfter1)
	mstore(data, dataLength)
	mstore(sub(data, 0x20), mBefore1)
	mstore(sub(data, 0x40), mBefore2)
	mstore(sub(data, 0x60), mBefore3)
	}
	}

	/// @dev Returns the address of the deterministic clone of
	/// `implementation` using immutable arguments encoded in `data`, with `salt`, by `deployer`.
	function predictDeterministicAddress(
	address implementation,
	bytes memory data,
	bytes32 salt,
	address deployer
	) internal pure returns (address predicted) {
	assembly {
	// Compute the boundaries of the data and cache the memory slots around it.
	let mBefore3 := mload(sub(data, 0x60))
	let mBefore2 := mload(sub(data, 0x40))
	let mBefore1 := mload(sub(data, 0x20))
	let dataLength := mload(data)
	let dataEnd := add(add(data, 0x20), dataLength)
	let mAfter1 := mload(dataEnd)

	// +2 bytes for telling how much data there is appended to the call.
	let extraLength := add(dataLength, 2)

	// Write the bytecode before the data.
	mstore(data, 0x5af43d3d93803e606057fd5bf3)
	// Write the address of the implementation.
	mstore(sub(data, 0x0d), implementation)
	// Write the rest of the bytecode.
	mstore(
	sub(data, 0x21),
	or(
	shl(0x48, extraLength),
	0x593da1005b363d3d373d3d3d3d610000806062363936013d73
	)
	)
	// `keccak256("ReceiveETH(uint256)")`.
	mstore(
	sub(data, 0x3a),
	0x9e4ac34f21c619cefc926c8bd93b54bf5a39c7ab2127a895af1cc0691d7e3dff
	)
	mstore(
	sub(data, 0x5a),
	or(
	shl(0x78, add(extraLength, 0x62)),
	0x6100003d81600a3d39f336602c57343d527f
	)
	)
	mstore(dataEnd, shl(0xf0, extraLength))

	// Compute and store the bytecode hash.
	mstore(0x35, keccak256(sub(data, 0x4c), add(extraLength, 0x6c)))
	mstore8(0x00, 0xff) // Write the prefix.
	mstore(0x01, shl(96, deployer))
	mstore(0x15, salt)
	predicted := keccak256(0x00, 0x55)
	// Restore the part of the free memory pointer that has been overwritten.
	mstore(0x35, 0)

	// Restore the overwritten memory surrounding `data`.
	mstore(dataEnd, mAfter1)
	mstore(data, dataLength)
	mstore(sub(data, 0x20), mBefore1)
	mstore(sub(data, 0x40), mBefore2)
	mstore(sub(data, 0x60), mBefore3)
	}
	}
	}

	/// @notice Kali Factory.
	contract KaliFactory is Multicallable {
	/// -----------------------------------------------------------------------
	/// Library Usage
	/// -----------------------------------------------------------------------

	using LibClone for address;

	/// -----------------------------------------------------------------------
	/// Events
	/// -----------------------------------------------------------------------

	event Deployed(
	Kali indexed kali,
	KeepTokenManager token,
	uint256 tokenId,
	bytes32 name,
	Call[] calls,
	string daoURI,
	uint120[4] govSettings
	);

	/// -----------------------------------------------------------------------
	/// Immutables
	/// -----------------------------------------------------------------------

	address internal immutable kaliTemplate;

	/// -----------------------------------------------------------------------
	/// Constructor
	/// -----------------------------------------------------------------------

	constructor(address _kaliTemplate) payable {
	kaliTemplate = _kaliTemplate;
	}

	/// -----------------------------------------------------------------------
	/// Deployment Logic
	/// -----------------------------------------------------------------------

	function determineKali(
	KeepTokenManager token,
	uint256 tokenId,
	bytes32 name
	) public view virtual returns (address) {
	return
	kaliTemplate.predictDeterministicAddress(
	abi.encodePacked(token, tokenId, name),
	name,
	address(this)
	);
	}

	function deployKali(
	KeepTokenManager _token,
	uint256 _tokenId,
	bytes32 _name, // create2 salt.
	Call[] calldata _calls,
	string calldata _daoURI,
	uint120[4] calldata _govSettings
	) public payable virtual {
	Kali kali = Kali(
	kaliTemplate.cloneDeterministic(
	abi.encodePacked(_token, _tokenId, _name),
	_name
	)
	);

	kali.initialize{value: msg.value}(_calls, _daoURI, _govSettings);

	emit Deployed(
	kali,
	_token,
	_tokenId,
	_name,
	_calls,
	_daoURI,
	_govSettings
	);
	}
	}