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eip | title | description | author | discussions-to | status | type | category | created | requires |
---|---|---|---|---|---|---|---|---|---|
5173 | NFT Future Rewards (nFR) | A multigenerational reward mechanism that rewards all owners of non-fungible tokens (NFT). | Yale ReiSoleil (@longnshort), dRadiant (@dRadiant), D Wang, PhD <david@iob.fi> | https://ethereum-magicians.org/t/non-fungible-future-rewards-token-standard/9203 | Draft | Standards Track | ERC | 2022-05-08 | 165, 721 |
Abstract
In this EIP, we propose the implementation of a Future Rewards (FR) extension which will enable owners of EIP-721 tokens (NFTs) to participate in future price increases after they sell their tokens.
Through the implementation of this nFR proposal, the creators, buyers and sellers create a giving circle in trading practice. A giving circle is formed when all participants work in a framework to build greater wealth through each other's success. One does not expect the same amount of return from the same person when they give someone a portion of their profits. There is no quid pro quo. Rather, they are confident that someone else in the same circle will give them the same benefits, with a smaller or greater monetary value, from other participants in the same circle later on.
Owners of nFR compliant tokens can benefit in two ways from such a gift economic framework:
- An increase in price during their holding period;
- They continue to receive Future Rewards (FRs) after the token is sold.
The realized profits from the sale of nFR compliant tokens will be shared across the chain of historical ownership if the seller is not the original Minter and therefore not the very first seller. Through the NFT Future Rewards (nFR) framework, the same seller, as well as every other seller, will receive the same FR distributions. Everybody pays it forward, forming a giving circle.
Giving circles are groups of people who work together to improve a situation that is typically much larger than it is at the moment. Some of the characteristics of a giving circle are community interdependence and delayed reciprocity.
In a well-designed circle of giving, givers may be able to receive more than they give over time, so giving is not the only thing involved. As a result, the traditional model of platform versus user and user vs. user relationships has been fundamentally altered into one, shared objective: if others succeed, I succeed more.
Motivation
Not limited to NFT trading, it is common for an average trader to fall victim to spoofing, insider trading, front running, wash trading, and pump and dump, among a number of other techniques used by various actors. The current system guarantees that most traders will lose money because of their emotions, the constant oscillation between greed and fear. Under the current system, a trader has no advantage over many of the more sophisticated techniques used by various actors.
Although this historical precedent has been followed in today's markets, just as crypto has revolutionized traditional trading, we now have the opportunity to transform this historic trail of unequal value distribution by tracking every transaction of every distinguishable token through the emergence of the non-fungible token standard.
There needs to be a change in historical unfair trading practices so that:
- With a success-based model, everyone is on the same page;
- A mutually beneficial economic rule benefits both buyers and sellers.
NFTs, in contrast to physical art and collectibles in the physical world, are not currently reflecting the contributions of their owners to their value. Since each EIP-721 token can be tracked individually, and may be modified to record every change in the price of any specific NFT token, there is no reason that a Future Rewards program of this type should not be established.
This nFR proposal establishes a standard interface for a profit sharing framework in all stages of the token's ownership history desired by all market participants. In a giving circle, art buyers/owners are compensated for their participation in the instrument’s trading price discovery process.
We embrace and promote a new gift economic model, which is similar to the Copyleft and open-source spirit as opposed to traditional copyrights. The advancement of technology has enabled such implementation in trading for the first time. In the same way that open-source software has changed the software industry and society, we can also change the financial industry.
As in trading, most traders lose money, but the proposed Future Rewards framework is designed to help average traders do better.
Additionally, as we will explain later, it discourages any "under-the-table" deals that may circumvent the rules set forth by artists and marketplaces.
Is This Just a Ponzi Scheme?
No, it is not. Ponzi schemes promise profits that are impossible to keep.
As opposed to fixed-yield schemes, our proposal only distributes future profits when those profits are achieved rather than guaranteeing them. Should later holders fail to make a profit, future return shares will not be distributed.
The early participants in price discovery will receive a share of profits as part of the FR implementation only and if a later owner has accumulated profits during their holdings of the token.
Specification
The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in this document are to be interpreted as described in RFC 2119.
The following is an extension of the EIP-721 standard.
EIP-721-compliant contracts MAY implement this EIP for rewards to provide a standard method of rewarding future buyers and previous owners with realized profits in the future.
Implementers of this standard MUST have all of the following functions:
pragma solidity ^0.8.0;
import "@openzeppelin/contracts/utils/introspection/IERC165.sol";
/*
*
* @dev Interface for the Future Rewards Token Standard.
*
* A standardized way to receive future rewards for non-fungible tokens (NFTs.)
*
*/
interface IERC5173 is IERC165 {
event FRClaimed(address indexed account, uint256 indexed amount);
event FRDistributed(uint256 indexed tokenId, uint256 indexed soldPrice, uint256 indexed allocatedFR);
function list(uint256 tokenId, uint256 salePrice) external;
function unlist(uint256 tokenId) external;
function buy(uint256 tokenId) payable external;
function releaseFR(address payable account) external;
function retrieveFRInfo(uint256 tokenId) external returns(uint8, uint256, uint256, uint256, uint256, address[] memory);
function retrieveAllottedFR(address account) external returns(uint256);
function retrieveListInfo(uint256 tokenId) external returns(uint256, address, bool);
}
An nFR contract MUST implement and update for each Token ID. The data in the FRInfo
struct MAY either be stored wholly in a single mapping, or MAY be broken down into several mappings. The struct MUST either be exposed in a public mapping or mappings, or MUST have public functions that access the private data. This is for client-side data fetching and verification.
struct FRInfo {
uint8 numGenerations; // Number of generations corresponding to that Token ID
uint256 percentOfProfit; // Percent of profit allocated for FR, scaled by 1e18
uint256 successiveRatio; // The common ratio of successive in the geometric sequence, used for distribution calculation
uint256 lastSoldPrice; // Last sale price in ETH mantissa
uint256 ownerAmount; // Amount of owners the Token ID has seen
address[] addressesInFR; // The addresses currently in the FR cycle
}
struct ListInfo {
uint256 salePrice; // ETH mantissa of the listed selling price
address lister; // Owner/Lister of the Token
bool isListed; // Boolean indicating whether the Token is listed or not
}
Additionally, an nFR smart contract MUST store the corresponding ListInfo
for each Token ID in a mapping. A method to retrieve a Token ID’s corresponding ListInfo
MUST also be accessible publicly.
An nFR smart contract MUST also store and update the amount of Ether allocated to a specific address using the _allotedFR
mapping. The _allottedFR
mapping MUST either be public or have a function to fetch the FR payment allotted to a specific address.
Percent Fixed Point
The allocatedFR
MUST be calculated using a percentage fixed point with a scaling factor of 1e18 (X/1e18) - such as "5e16" - for 5%. This is REQUIRED to maintain uniformity across the standard. The max and min values would be - 1e18 - 1.
Default FR Info
A default FRInfo
MUST be stored in order to be backward compatible with EIP-721 mint functions. It MAY also have a function to update the FRInfo
, assuming it has not been hard-coded.
EIP-721 Overrides
An nFR-compliant smart contract MUST override the EIP-721 _mint
, _transfer
, and _burn
functions. When overriding the _mint
function, a default FR model is REQUIRED to be established if the mint is to succeed when calling the EIP-721 _mint
function and not the nFR _mint
function. It is also to update the owner amount and directly add the recipient address to the FR cycle. When overriding the _transfer
function, the smart contract SHALL consider the NFT as sold for 0 ETH, and update the state accordingly after a successful transfer. This is to prevent FR circumvention. Additionally, the _transfer
function SHALL prevent the caller from transferring the token to themselves, this can be done through a require statement that ensures the sender is not the recipient, otherwise, it’d be possible to fill up the FR sequence with one’s own address. Finally, when overriding the _burn
function, the smart contract SHALL delete the FRInfo
corresponding to that Token ID after a successful burn.
Additionally, the EIP-721 _checkOnERC721Received
function MAY be explicitly called after mints and transfers if the smart contract aims to have safe transfers and mints.
Safe Transfers
If the wallet/broker/auction application will accept safe transfers, then it MUST implement the EIP-721 wallet interface.
Listing, Unlisting, and Buying
The list
, unlist
, and buy
functions MUST be implemented, as they provide the capability to sell a token.
function list(uint256 tokenId, uint256 salePrice) public virtual override {
//...
}
function unlist(uint256 tokenId) public virtual override {
//...
}
function buy(uint256 tokenId) public virtual override payable {
//...
}
The list
function accepts a tokenId
and a salePrice
and updates the corresponding ListInfo
for that given tokenId
after ensuring that the msg.sender
is either approved or the owner of the token. The function signifies that the token is listed and at what price it is listed for.
The unlist
function accepts a tokenId
and it deletes the corresponding ListInfo
after the owner verifications have been met.
The buy
function accepts a tokenId
and MUST be payable. It MUST verify that the msg.value
matches the token’s salePrice
and that the token is listed, before proceeding and calling the FR _transferFrom
function. This is to ensure the values are valid and will also allow for the necessary FR to be held in the contract.
Future Rewards _transferFrom
Function
The FR _transferFrom
function MUST be called by all nFR-supporting smart contracts, though the accommodations for non-nFR-supporting contracts MAY also be implemented to ensure backwards compatibility.
function transferFrom(address from, address to, uint256 tokenId, uint256 soldPrice) public virtual override payable {
//...
}
Based on the stored lastSoldPrice
, the smart contract will determine whether the sale was profitable after calling the EIP-721 transfer function and transferring the NFT. If it was not profitable, the smart contract SHALL update the last sold price for the corresponding Token ID, increment the owner amount, shift the generations, and transfer all of the msg.value
to the lister
depending on the implementation. Otherwise, if the transaction was profitable, the smart contract SHALL call the _distributeFR
function, then update the lastSoldPrice
, increment the owner amount, and finally shift generations. The _distributeFR
function MUST return the difference between the allocated FR that is to be distributed amongst the _addressesInFR
and the msg.value
to the lister
. Once the operations have completed, the function MUST clear the corresponding ListInfo
. Similarly to the _transfer
override, the FR _transferFrom
SHALL ensure that the recipient is not the sender of the token.
Future Rewards Calculation
Marketplaces that support this standard MAY implement various methods of calculating or transferring Future Rewards to the previous owners.
function _calculateFR(uint256 totalProfit, uint256 buyerReward, uint256 successiveRatio, uint256 ownerAmount, uint256 windowSize) pure internal virtual returns(uint256[] memory) {
//...
}
In this example (Figure 1), a seller is REQUIRED to share a portion of their net profit with 10 previous holders of the token. Future Rewards will also be paid to the same seller as the value of the token increases from up to 10 subsequent owners.
When an owner loses money during their holding period, they MUST NOT be obligated to share Future Rewards distributions, since there is no profit to share. However, he SHALL still receive a share of Future Rewards distributions from future generations of owners, if they are profitable.
Figure 1: Geometric sequence distribution
The buyers/owners receive a portion ( r ) of the realized profit (P ) from an NFT transaction. The remaining proceeds go to the seller.
As a result of defining a sliding window mechanism ( n ), we can determine which previous owners will receive distributions. The owners are arranged in a queue, starting with the earliest owner and ending with the owner immediately before the current owner (the Last Generation). The First Generation is the last of the next n generations. There is a fixed-size profit distribution window from the First Generation to the Last Generation.
The profit distribution SHALL be only available to previous owners who fall within the window.
In this example, there SHALL be a portion of the proceeds awarded to the Last Generation owner (the owner immediately prior to the current seller) based on the geometric sequence in which profits are distributed. The larger portion of the proceeds SHALL go to the Mid-Gen owners, the earlier the greater, until the last eligible owner is determined by the sliding window, the First Generation. Owners who purchase earlier SHALL receive a greater reward, with first-generation owners receiving the greatest reward.
Future Rewards Distribution
Figure 2: NFT Owners' Future Rewards (nFR)
Figure 2 illustrates an example of a five-generation Future Rewards Distribution program based on an owner's realized profit.
function _distributeFR(uint256 tokenId, uint256 soldPrice) internal virtual {
//...
emit FRDistributed(tokenId, soldPrice, allocatedFR);
}
The _distributeFR
function MUST be called in the FR transferFrom
function if there is a profitable sale. The function SHALL calculate the difference between the current sale price and the lastSoldPrice
, then it SHALL call the _calculateFR
function to receive the proper distribution of FR. Then it SHALL distribute the FR accordingly, making order adjustments as necessary. Then, the contract SHALL calculate the total amount of FR that was distributed (allocatedFR
), in order to return the difference of the soldPrice
and allocatedFR
to the lister
. Finally, it SHALL emit the FRDistributed
event.
Future Rewards Claiming
The future Rewards payments SHOULD utilize a pull-payment model, similar to that demonstrated by OpenZeppelin with their PaymentSplitter contract. The event FRClaimed would be triggered after a successful claim has been made.
function releaseFR(address payable account) public virtual override {
//...
}
Owner Generation Shifting
The _shiftGenerations
function MUST be called regardless of whether the sale was profitable or not. As a result, it will be called in the _transfer
EIP-721 override function and the FR transferFrom
function. The function SHALL remove the oldest account from the corresponding _addressesInFR
array. This calculation will take into account the current length of the array versus the total number of generations for a given token ID.
Rationale
Fixed Percentage to 10^18
Considering Fixed-Point Arithmetic is to be enforced, it is logical to have 1e18 represent 100% and 1e16 represent 1% for Fixed-Point operations. This method of handling percents is also commonly seen in many Solidity libraries for Fixed-Point operations.
Emitting Event for Payment
Since each NFT contract is independent, and while a marketplace contract can emit events when an item is sold, choosing to emit an event for payment is important. As the royalty and FR recipient may not be aware of/watching for a secondary sale of their NFT, they would never know that they received a payment except that their ETH wallet has been increased randomly.
The recipient of the secondary sale will therefore be able to verify that the payment has been received by calling the parent contract of the NFT being sold, as implemented in EIP-2981.
Number of Generations of All Owners ( n ) vs Number of Generations of Only Profitable Owners
It is the number of generations of all owners, not just those who are profitable, that determines the number of owners from which the subsequent owners' profits will be shared, see Figure 3. As part of the effort to discourage "ownership hoarding," Future Rewards distributions will not be made to the current owner/purchaser if all the owners lose money holding the NFT. Further information can be found under Security Considerations.
Figure 3: Losing owners
Single vs Multigenerations
In a single generation reward, the new buyer/owner receives a share of the next single generation's realized profit only. In a multigenerational reward system, buyers will have future rewards years after their purchase. The NFT should have a long-term growth potential and a substantial dividend payout would be possible in this case.
We propose that the marketplace operator can choose between a single generational distribution system and a multigenerational distribution system.
Direct FR Payout by the Seller vs Smart Contract-managed Payout
FR payouts directly derived from the sale proceeds are immediate and final. As part of the fraud detection detailed later in the Security Considerations section, we selected a method in which the smart contract calculates all the FR amounts for each generation of previous owners, and handles payout according to other criteria set by the marketplace, such as reduced or delayed payments for wallet addresses with low scores, or a series of consecutive orders detected using a time-heuristic analysis.
Equal vs Linear Reward Distributions
Equal FR Payout
Figure 4: Equal, linear reward distribution
FR distributions from the realization of profits by later owners are distributed equally to all eligible owners (Figure 4). The exponential reward curve, however, may be more desirable, as it gives a slightly larger share to the newest buyer. Additionally, this distribution gives the earliest generations the largest portions as their FR distributions near the end, so they receive higher rewards for their early involvement, but the distribution is not nearly as extreme as one based on arithmetic sequences (Figure 5).
This system does not discriminate against any buyer because each buyer will go through the same distribution curve.
Straight line arithmetic sequence FR payout
Figure 5: Arithmetic sequence distribution
The profit is distributed according to the arithmetic sequence, which is 1, 2, 3, ... and so on. The first owner will receive 1 portion, the second owner will receive 2 portions, the third owner will receive 3 portions, etc.
Backwards Compatibility
This proposal is fully compatible with current EIP-721 standards and EIP-2981. It can also be easily adapted to work with EIP-1155.
Test Cases
This contract contains the reference implementation for this proposal.
Here is a visualization of the test case.
Reference Implementation
This implementation uses OpenZeppelin contracts and the PRB Math library created by Paul R Berg for fixed-point arithmetic. It demonstrates the interface for the nFR standard, an nFR standard-compliant extension, and an EIP-721 implementation using the extension.
The code for the reference implementation is here.
Distribution of NFT Royalties to Artists and Creators
We agree that artists’ royalties should be uniform and on-chain. We support EIP-2981 NFT royalty Standard proposal.
All platforms can support royalty rewards for the same NFT based on on-chain parameters and functions:
- No profit, no profit sharing, no cost;
- The question of "who owned it" is often crucial to the provenance and value of a collectible;
- The previous owner should be re-compensated for their ownership;
- And the buyer/owner incentive in FR eliminates any motive to circumvent the royalty payout schemes;
Distribution of NFT Owners’ Future Rewards (FRs)
Future Rewards calculation
Any realized profits (P) when an NFT is sold are distributed among the buyers/owners. The previous owners will take a fixed portion of the profix (P), and this portion is called Future Rewards (FRs). The seller takes the rest of the profits.
We define a sliding window mechanism to decide which previous owners will be involved in the profit distribution. Let's imagine the owners as a queue starting from the first hand owner to the current owner. The profit distribution window starts from the previous owner immediately to the current owner and extends towards the first owner, and the size of the windows is fixed. Only previous owners located inside the window will join the profit distribution.
In this equation:
- P is the total profit, the difference between the selling price minus the buying price;
- r is buyer reward ratio of the total P;
- g is the common ratio of successive in the geometric sequence;
- n is the actual number of owners eligible and participating in the future rewards sharing. To calculate n, we have n = min(m, w), where m is the current number of owners for a token, and w is the window size of the profit distribution sliding window algorithm
Converting into Code
pragma solidity ^0.8.0;
//...
/* Assumes usage of a Fixed Point Arithmetic library (prb-math) for both int256 and uint256, and OpenZeppelin Math utils for Math.min. */
function _calculateFR(uint256 P, uint256 r, uint256 g, uint256 m, uint256 w) pure internal virtual returns(uint256[] memory) {
uint256 n = Math.min(m, w);
uint256[] memory FR = new uint256[](n);
for (uint256 i = 1; i < n + 1; i++) {
uint256 pi = 0;
if (successiveRatio != 1e18) {
int256 v1 = 1e18 - int256(g).powu(n);
int256 v2 = int256(g).powu(i - 1);
int256 v3 = int256(P).mul(int256(r));
int256 v4 = v3.mul(1e18 - int256(g));
pi = uint256(v4 * v2 / v1);
} else {
pi = P.mul(r).div(n);
}
FR[i - 1] = pi;
}
return FR;
}
The complete implementation code can be found here.
Security Considerations
Payment Attacks
As this EIP introduces royalty and realized profit rewards collection, distribution, and payouts to the EIP-721 standard, the attack vectors increase. As discussed by Andreas Freund regarding mitigations to phishing attacks, we recommend reentrancy protection for all payment functions to reduce the most significant attack vectors for payments and payouts.
Royalty Circumventing
Many methods are being used to avoid paying royalties to creators under the current EIP-721 standard. Through an under-the-table transaction, the new buyer's cost basis will be reduced to zero, increasing their FR liability to the full selling price. Everyone, either the buyer or seller, would pay a portion of the previous owner's net realized profits ( P x r ). Acting in his or her own interests, the buyer rejects any loyalty circumventing proposal.
FR Hoarding through Wash Sales
Quantexa blog and beincrypto articles have reported widespread wash trading on all unregulated cryptocurrency trading platforms and NFT marketplaces. The use of wash trading by dishonest actors can lead to an unfair advantage, as well as inflated prices and money laundering. When a single entity becomes multiple generations of owners to accumulate more rewards in the future, the validity of the system is undermined.
Wash trading by users
Using a different wallet address, an attacker can "sell" the NFT to themselves at a loss. It is possible to repeat this process n times in order to maximize their share of the subsequent FR distributions (Figure 6). A wallet ranking score can partially alleviate this problem. It is evident that a brand new wallet is a red flag, and the marketplace may withhold FR distribution from it if it has a short transaction history (i.e. fewer than a certain number of transactions).
We do not want a large portion of future rewards to go to a small number of wash traders. Making such practices less profitable is one way to discourage wash trading and award hoarding. It can be partially mitigated, for example, by implementing a wallet-score and holding period-based incentive system. The rewards for both parties are reduced if a new wallet is used or if a holding period is less than a certain period.
Figure 6: Same owner using different wallets
Wash trading by the marketplace operator
However, the biggest offender appears to be the marketplace, which engages heavily in wash trading, or simply does not care about it, according to Decrypt. The authors have personally experienced this phenomenon. A senior executive of a top-5 cryptocurrency exchange boasted during a mid-night drinking session in 2018, that they had "brushed" (wash-traded) certain newly listed tokens, which they called "marketmaking." The exchange is still ranked among the top five crypto exchanges today.
Many of these companies engage in wash trading on their own or collude with certain users, and royalties and FR payments are reimbursed under the table. It is crucial that all exchanges have robust features to prevent self-trading. Users should be able to observe watchers transparently. Marketplaces should provide their customers with free access to an on-chain transaction monitoring service like Chainalysis Reactor.
Long/Cyclical FR-Entitled Owner Generations
In most cases, malicious actors will create excessively long or cyclical Future Rewards Owner Generations that will result in applications that attempt to distribute FR or shift generations running out of gas and not functioning. Therefore, clients are responsible for verifying that the contract with which they interact has an appropriate number of generations, so that looping over will not deplete the gas.
Copyright
Copyright and related rights waived via CC0.