ApeX
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About
ApeX Pro is a non-custodial trading platform that delivers limitless cross-margined perpetual contracts trading.
Badges
About
ApeX Pro is a non-custodial trading platform that delivers limitless cross-margined perpetual contracts trading.
ApeX Pro public beta launched
2022 Nov 21st
ApeX Pro beta is launched, with incentives program for users.
ApeX Pro live on Mainnet
2022 Aug 31st
ApeX Pro, a non-custodial decentralized exchange is now live on Mainnet.
ApeX Pro is a non-custodial trading platform that delivers limitless cross-margined perpetual contracts trading.
ApeX Pro is running two independent StarkEx instances, one for USDC and one for USDT, but that technical distinction is not visible to the user.
Funds can be stolen if
Funds can be lost if
Users can be censored if
MEV can be extracted if
Sequencer failure
Force via L1State validation
ZK proofs (ST)STARKs are zero knowledge proofs that ensure state correctness.
Data availability
External (DAC)Proof construction relies fully on data that is NOT published onchain. There exists a Data Availability Committee (DAC) with a threshold of 3/5 that is tasked with protecting and supplying the data.
Exit window
NoneThere is no window for users to exit in case of an unwanted regular upgrade since contracts are instantly upgradable.
Proposer failure
Use escape hatchUsers are able to trustlessly exit by submitting a Merkle proof of funds. Positions will be closed using the average price from the last batch state update.
Validity proofs ensure state correctness
Each update to the system state must be accompanied by a ZK proof that ensures that the new state was derived by correctly applying a series of valid user transactions to the previous state. These proofs are then verified on Ethereum by a smart contract. The system state is represented using Merkle roots.
Zero knowledge STARK cryptography is used
Despite their production use zkSTARKs proof systems are still relatively new, complex and they rely on the proper implementation of the polynomial constraints used to check validity of the Execution Trace.
Funds can be lost if the proof system is implemented incorrectly.
Data is not stored on chain
The balances of the users are not published on-chain, but rather sent to external trusted parties, also known as committee members. A state update is valid and accepted on-chain only if at least a quorum of the committee members sign a state update.
Funds can be lost if the external data becomes unavailable (CRITICAL).
Users can be censored if the committee restricts their access to the external data.
The system has a centralized operator
The operator is the only entity that can propose blocks. A live and trustworthy operator is vital to the health of the system. Typically, the Operator is the hot wallet of the StarkEx service submitting state updates for which proofs have been already submitted and verified.
MEV can be extracted if the operator exploits their centralized position and frontruns user transactions.
Users can force exit the system
Force exit allows the users to escape censorship by withdrawing their funds. The system allows users to force the withdrawal of funds by submitting a request directly to the contract on-chain. The request must be served within 7d. If this does not happen, the system will halt regular operation and permit trustless withdrawal of funds. Perpetual positions can also be force closed before withdrawing, however this requires the user to find the counterparty for the trade themselves.
Users can be censored if the operator refuses to include their transactions. However, there exists a mechanism to independently exit the system.
Funds can be lost if the user is unable to find the counterparty for the force trade.
Regular exit
Forced exit
If the user experiences censorship from the operator with regular exit they can submit their withdrawal requests directly on L1. The system is then obliged to service this request. Once the force operation is submitted and if the request is serviced, the operation follows the flow of a regular exit.
Emergency exit
If the enough time deadline passes and the forced exit is still ignored the user can put the system into a frozen state, disallowing further state updates. In that case everybody can withdraw by submitting a merkle proof of their funds with their L1 transaction.
The system uses the following set of permissioned addresses:
Allowed to upgrade the implementation of the StarkExchange (USDC) contract, potentially maliciously gaining control over the system or stealing funds.Currently there is 14d delay before the upgrade.
Allowed to upgrade the implementation of the StarkExchange (USDT) contract, potentially maliciously gaining control over the system or stealing funds.Currently there is 14d delay before the upgrade.
Allowed to update state of the system and verify DA proofs for USDC StarkEx instance. When Operator is down the state cannot be updated.
Allowed to update state of the system and verify DA proofs for USDT StarkEx instance. When Operator is down the state cannot be updated.
Validity proof must be signed by at least 3 of these addresses to approve state update.
Validity proof must be signed by at least 3 of these addresses to approve state update.
Can upgrade implementation of SHARP Verifier, potentially with code approving fraudulent state. Currently there is 0s delay before the upgrade.
This is a Gnosis Safe with 2 / 4 threshold. SHARP Verifier Governor.
Used in:
Those are the participants of the SHARPVerifierGovernorMultisig.
The system consists of the following smart contracts on the host chain (Ethereum):
Data Availability Committee (DAC) contract for USDC StarkEx instance, verifying data availability claim from DAC Members (via multisig check).
Data Availability Committee (DAC) contract for USDT StarkEx instance, verifying data availability claim from DAC Members (via multisig check).
Allows deposits in different tokens and swaps them to USDC. Allows fast withdrawals after the agreement of at least 2 designated signers.
Allows deposits in different tokens and swaps them to USDT. Allows fast withdrawals after the agreement of at least 2 designated signers.
Contract responsible for validating force withdrawal requests. Used by both USDC and USDT StarkEx instances.
CallProxy for GpsStatementVerifier.
Proxy used in:
Starkware SHARP verifier used collectively by Starknet, Sorare, ImmutableX, Apex, Myria, rhino.fi and Canvas Connect. It receives STARK proofs from the Prover attesting to the integrity of the Execution Trace of these Programs including correctly computed state root which is part of the Program Output.
Implementation used in:
MemoryPageFactRegistry is one of the many contracts used by SHARP verifier. This one is important as it registers all necessary on-chain data.
Implementation used in:
Same as MemoryPageFactRegistry but stores facts proved by the old SHARP Verifier, used as a fallback.
Implementation used in:
Value Locked is calculated based on these smart contracts and tokens:
The current deployment carries some associated risks:
Funds can be stolen if a contract receives a malicious code upgrade. There is no delay on code upgrades (CRITICAL).
