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Detector Documentation

alpharush edited this page Apr 7, 2024 · 32 revisions

Public Detectors

List of public detectors

Storage ABIEncoderV2 Array

Configuration

  • Check: abiencoderv2-array
  • Severity: High
  • Confidence: High

Description

solc versions 0.4.7-0.5.9 contain a compiler bug leading to incorrect ABI encoder usage.

Exploit Scenario:

contract A {
    uint[2][3] bad_arr = [[1, 2], [3, 4], [5, 6]];
    
    /* Array of arrays passed to abi.encode is vulnerable */
    function bad() public {                                                                                          
        bytes memory b = abi.encode(bad_arr);
    }
}

abi.encode(bad_arr) in a call to bad() will incorrectly encode the array as [[1, 2], [2, 3], [3, 4]] and lead to unintended behavior.

Recommendation

Use a compiler >= 0.5.10.

Arbitrary from in transferFrom

Configuration

  • Check: arbitrary-send-erc20
  • Severity: High
  • Confidence: High

Description

Detect when msg.sender is not used as from in transferFrom.

Exploit Scenario:

    function a(address from, address to, uint256 amount) public {
        erc20.transferFrom(from, to, am);
    }

Alice approves this contract to spend her ERC20 tokens. Bob can call a and specify Alice's address as the from parameter in transferFrom, allowing him to transfer Alice's tokens to himself.

Recommendation

Use msg.sender as from in transferFrom.

Modifying storage array by value

Configuration

  • Check: array-by-reference
  • Severity: High
  • Confidence: High

Description

Detect arrays passed to a function that expects reference to a storage array

Exploit Scenario:

contract Memory {
    uint[1] public x; // storage

    function f() public {
        f1(x); // update x
        f2(x); // do not update x
    }

    function f1(uint[1] storage arr) internal { // by reference
        arr[0] = 1;
    }

    function f2(uint[1] arr) internal { // by value
        arr[0] = 2;
    }
}

Bob calls f(). Bob assumes that at the end of the call x[0] is 2, but it is 1. As a result, Bob's usage of the contract is incorrect.

Recommendation

Ensure the correct usage of memory and storage in the function parameters. Make all the locations explicit.

ABI encodePacked Collision

Configuration

  • Check: encode-packed-collision
  • Severity: High
  • Confidence: High

Description

Detect collision due to dynamic type usages in abi.encodePacked

Exploit Scenario:

contract Sign {
    function get_hash_for_signature(string name, string doc) external returns(bytes32) {
        return keccak256(abi.encodePacked(name, doc));
    }
}

Bob calls get_hash_for_signature with (bob, This is the content). The hash returned is used as an ID. Eve creates a collision with the ID using (bo, bThis is the content) and compromises the system.

Recommendation

Do not use more than one dynamic type in abi.encodePacked() (see the Solidity documentation). Use abi.encode(), preferably.

Incorrect shift in assembly.

Configuration

  • Check: incorrect-shift
  • Severity: High
  • Confidence: High

Description

Detect if the values in a shift operation are reversed

Exploit Scenario:

contract C {
    function f() internal returns (uint a) {
        assembly {
            a := shr(a, 8)
        }
    }
}

The shift statement will right-shift the constant 8 by a bits

Recommendation

Swap the order of parameters.

Multiple constructor schemes

Configuration

  • Check: multiple-constructors
  • Severity: High
  • Confidence: High

Description

Detect multiple constructor definitions in the same contract (using new and old schemes).

Exploit Scenario:

contract A {
    uint x;
    constructor() public {
        x = 0;
    }
    function A() public {
        x = 1;
    }
    
    function test() public returns(uint) {
        return x;
    }
}

In Solidity 0.4.22, a contract with both constructor schemes will compile. The first constructor will take precedence over the second, which may be unintended.

Recommendation

Only declare one constructor, preferably using the new scheme constructor(...) instead of function <contractName>(...).

Name reused

Configuration

  • Check: name-reused
  • Severity: High
  • Confidence: High

Description

If a codebase has two contracts the similar names, the compilation artifacts will not contain one of the contracts with the duplicate name.

Exploit Scenario:

Bob's truffle codebase has two contracts named ERC20. When truffle compile runs, only one of the two contracts will generate artifacts in build/contracts. As a result, the second contract cannot be analyzed.

Recommendation

Rename the contract.

Protected Variables

Configuration

  • Check: protected-vars
  • Severity: High
  • Confidence: High

Description

Detect unprotected variable that are marked protected

Exploit Scenario:

contract Buggy{

    /// @custom:security write-protection="onlyOwner()"
    address owner;

    function set_protected() public onlyOwner(){
        owner = msg.sender;
    }

    function set_not_protected() public{
        owner = msg.sender;
    }
}    

owner must be always written by function using onlyOwner (write-protection="onlyOwner()"), however anyone can call set_not_protected.

Recommendation

Add access controls to the vulnerable function

Public mappings with nested variables

Configuration

  • Check: public-mappings-nested
  • Severity: High
  • Confidence: High

Description

Prior to Solidity 0.5, a public mapping with nested structures returned incorrect values.

Exploit Scenario:

Bob interacts with a contract that has a public mapping with nested structures. The values returned by the mapping are incorrect, breaking Bob's usage

Recommendation

Do not use public mapping with nested structures.

Right-to-Left-Override character

Configuration

  • Check: rtlo
  • Severity: High
  • Confidence: High

Description

An attacker can manipulate the logic of the contract by using a right-to-left-override character (U+202E).

Exploit Scenario:

contract Token
{

    address payable o; // owner
    mapping(address => uint) tokens;

    function withdraw() external returns(uint)
    {
        uint amount = tokens[msg.sender];
        address payable d = msg.sender;
        tokens[msg.sender] = 0;
        _withdraw(/*owner‮/*noitanitsed*/ d, o/*‭
		        /*value */, amount);
    }

    function _withdraw(address payable fee_receiver, address payable destination, uint value) internal
    {
		fee_receiver.transfer(1);
		destination.transfer(value);
    }
}

Token uses the right-to-left-override character when calling _withdraw. As a result, the fee is incorrectly sent to msg.sender, and the token balance is sent to the owner.

Recommendation

Special control characters must not be allowed.

State variable shadowing

Configuration

  • Check: shadowing-state
  • Severity: High
  • Confidence: High

Description

Detection of state variables shadowed.

Exploit Scenario:

contract BaseContract{
    address owner;

    modifier isOwner(){
        require(owner == msg.sender);
        _;
    }

}

contract DerivedContract is BaseContract{
    address owner;

    constructor(){
        owner = msg.sender;
    }

    function withdraw() isOwner() external{
        msg.sender.transfer(this.balance);
    }
}

owner of BaseContract is never assigned and the modifier isOwner does not work.

Recommendation

Remove the state variable shadowing.

Suicidal

Configuration

  • Check: suicidal
  • Severity: High
  • Confidence: High

Description

Unprotected call to a function executing selfdestruct/suicide.

Exploit Scenario:

contract Suicidal{
    function kill() public{
        selfdestruct(msg.sender);
    }
}

Bob calls kill and destructs the contract.

Recommendation

Protect access to all sensitive functions.

Uninitialized state variables

Configuration

  • Check: uninitialized-state
  • Severity: High
  • Confidence: High

Description

Uninitialized state variables.

Exploit Scenario:

contract Uninitialized{
    address destination;

    function transfer() payable public{
        destination.transfer(msg.value);
    }
}

Bob calls transfer. As a result, the Ether are sent to the address 0x0 and are lost.

Recommendation

Initialize all the variables. If a variable is meant to be initialized to zero, explicitly set it to zero to improve code readability.

Uninitialized storage variables

Configuration

  • Check: uninitialized-storage
  • Severity: High
  • Confidence: High

Description

An uninitialized storage variable will act as a reference to the first state variable, and can override a critical variable.

Exploit Scenario:

contract Uninitialized{
    address owner = msg.sender;

    struct St{
        uint a;
    }

    function func() {
        St st;
        st.a = 0x0;
    }
}

Bob calls func. As a result, owner is overridden to 0.

Recommendation

Initialize all storage variables.

Unprotected upgradeable contract

Configuration

  • Check: unprotected-upgrade
  • Severity: High
  • Confidence: High

Description

Detects logic contract that can be destructed.

Exploit Scenario:

contract Buggy is Initializable{
    address payable owner;

    function initialize() external initializer{
        require(owner == address(0));
        owner = msg.sender;
    }
    function kill() external{
        require(msg.sender == owner);
        selfdestruct(owner);
    }
}

Buggy is an upgradeable contract. Anyone can call initialize on the logic contract, and destruct the contract.

Recommendation

Add a constructor to ensure initialize cannot be called on the logic contract.

Arbitrary from in transferFrom used with permit

Configuration

  • Check: arbitrary-send-erc20-permit
  • Severity: High
  • Confidence: Medium

Description

Detect when msg.sender is not used as from in transferFrom and permit is used.

Exploit Scenario:

    function bad(address from, uint256 value, uint256 deadline, uint8 v, bytes32 r, bytes32 s, address to) public {
        erc20.permit(from, address(this), value, deadline, v, r, s);
        erc20.transferFrom(from, to, value);
    }

If an ERC20 token does not implement permit and has a fallback function e.g. WETH, transferFrom allows an attacker to transfer all tokens approved for this contract.

Recommendation

Ensure that the underlying ERC20 token correctly implements a permit function.

Functions that send Ether to arbitrary destinations

Configuration

  • Check: arbitrary-send-eth
  • Severity: High
  • Confidence: Medium

Description

Unprotected call to a function sending Ether to an arbitrary address.

Exploit Scenario:

contract ArbitrarySendEth{
    address destination;
    function setDestination(){
        destination = msg.sender;
    }

    function withdraw() public{
        destination.transfer(this.balance);
    }
}

Bob calls setDestination and withdraw. As a result he withdraws the contract's balance.

Recommendation

Ensure that an arbitrary user cannot withdraw unauthorized funds.

Array Length Assignment

Configuration

  • Check: controlled-array-length
  • Severity: High
  • Confidence: Medium

Description

Detects the direct assignment of an array's length.

Exploit Scenario:

contract A {
	uint[] testArray; // dynamic size array

	function f(uint usersCount) public {
		// ...
		testArray.length = usersCount;
		// ...
	}

	function g(uint userIndex, uint val) public {
		// ...
		testArray[userIndex] = val;
		// ...
	}
}

Contract storage/state-variables are indexed by a 256-bit integer. The user can set the array length to 2**256-1 in order to index all storage slots. In the example above, one could call the function f to set the array length, then call the function g to control any storage slot desired. Note that storage slots here are indexed via a hash of the indexers; nonetheless, all storage will still be accessible and could be controlled by the attacker.

Recommendation

Do not allow array lengths to be set directly set; instead, opt to add values as needed. Otherwise, thoroughly review the contract to ensure a user-controlled variable cannot reach an array length assignment.

Controlled Delegatecall

Configuration

  • Check: controlled-delegatecall
  • Severity: High
  • Confidence: Medium

Description

Delegatecall or callcode to an address controlled by the user.

Exploit Scenario:

contract Delegatecall{
    function delegate(address to, bytes data){
        to.delegatecall(data);
    }
}

Bob calls delegate and delegates the execution to his malicious contract. As a result, Bob withdraws the funds of the contract and destructs it.

Recommendation

Avoid using delegatecall. Use only trusted destinations.

Payable functions using delegatecall inside a loop

Configuration

  • Check: delegatecall-loop
  • Severity: High
  • Confidence: Medium

Description

Detect the use of delegatecall inside a loop in a payable function.

Exploit Scenario:

contract DelegatecallInLoop{

    mapping (address => uint256) balances;

    function bad(address[] memory receivers) public payable {
        for (uint256 i = 0; i < receivers.length; i++) {
            address(this).delegatecall(abi.encodeWithSignature("addBalance(address)", receivers[i]));
        }
    }

    function addBalance(address a) public payable {
        balances[a] += msg.value;
    } 

}

When calling bad the same msg.value amount will be accredited multiple times.

Recommendation

Carefully check that the function called by delegatecall is not payable/doesn't use msg.value.

Incorrect exponentiation

Configuration

  • Check: incorrect-exp
  • Severity: High
  • Confidence: Medium

Description

Detect use of bitwise xor ^ instead of exponential **

Exploit Scenario:

contract Bug{
    uint UINT_MAX = 2^256 - 1;
    ...
}

Alice deploys a contract in which UINT_MAX incorrectly uses ^ operator instead of ** for exponentiation

Recommendation

Use the correct operator ** for exponentiation.

Incorrect return in assembly

Configuration

  • Check: incorrect-return
  • Severity: High
  • Confidence: Medium

Description

Detect if return in an assembly block halts unexpectedly the execution.

Exploit Scenario:

contract C {
    function f() internal returns (uint a, uint b) {
        assembly {
            return (5, 6)
        }
    }

    function g() returns (bool){
        f();
        return true;
    }
}

The return statement in f will cause execution in g to halt. The function will return 6 bytes starting from offset 5, instead of returning a boolean.

Recommendation

Use the leave statement.

msg.value inside a loop

Configuration

  • Check: msg-value-loop
  • Severity: High
  • Confidence: Medium

Description

Detect the use of msg.value inside a loop.

Exploit Scenario:

contract MsgValueInLoop{

    mapping (address => uint256) balances;

    function bad(address[] memory receivers) public payable {
        for (uint256 i=0; i < receivers.length; i++) {
            balances[receivers[i]] += msg.value;
        }
    }

}

Recommendation

Provide an explicit array of amounts alongside the receivers array, and check that the sum of all amounts matches msg.value.

Reentrancy vulnerabilities

Configuration

  • Check: reentrancy-eth
  • Severity: High
  • Confidence: Medium

Description

Detection of the reentrancy bug. Do not report reentrancies that don't involve Ether (see reentrancy-no-eth)

Exploit Scenario:

    function withdrawBalance(){
        // send userBalance[msg.sender] Ether to msg.sender
        // if msg.sender is a contract, it will call its fallback function
        if( ! (msg.sender.call.value(userBalance[msg.sender])() ) ){
            throw;
        }
        userBalance[msg.sender] = 0;
    }

Bob uses the re-entrancy bug to call withdrawBalance two times, and withdraw more than its initial deposit to the contract.

Recommendation

Apply the check-effects-interactions pattern.

Return instead of leave in assembly

Configuration

  • Check: return-leave
  • Severity: High
  • Confidence: Medium

Description

Detect if a return is used where a leave should be used.

Exploit Scenario:

contract C {
    function f() internal returns (uint a, uint b) {
        assembly {
            return (5, 6)
        }
    }

}

The function will halt the execution, instead of returning a two uint.

Recommendation

Use the leave statement.

Storage Signed Integer Array

Configuration

  • Check: storage-array
  • Severity: High
  • Confidence: Medium

Description

solc versions 0.4.7-0.5.9 contain a compiler bug leading to incorrect values in signed integer arrays.

Exploit Scenario:

contract A {
	int[3] ether_balances; // storage signed integer array
	function bad0() private {
		// ...
		ether_balances = [-1, -1, -1];
		// ...
	}
}

bad0() uses a (storage-allocated) signed integer array state variable to store the ether balances of three accounts.
-1 is supposed to indicate uninitialized values but the Solidity bug makes these as 1, which could be exploited by the accounts.

Recommendation

Use a compiler version >= 0.5.10.

Unchecked transfer

Configuration

  • Check: unchecked-transfer
  • Severity: High
  • Confidence: Medium

Description

The return value of an external transfer/transferFrom call is not checked

Exploit Scenario:

contract Token {
    function transferFrom(address _from, address _to, uint256 _value) public returns (bool success);
}
contract MyBank{  
    mapping(address => uint) balances;
    Token token;
    function deposit(uint amount) public{
        token.transferFrom(msg.sender, address(this), amount);
        balances[msg.sender] += amount;
    }
}

Several tokens do not revert in case of failure and return false. If one of these tokens is used in MyBank, deposit will not revert if the transfer fails, and an attacker can call deposit for free..

Recommendation

Use SafeERC20, or ensure that the transfer/transferFrom return value is checked.

Weak PRNG

Configuration

  • Check: weak-prng
  • Severity: High
  • Confidence: Medium

Description

Weak PRNG due to a modulo on block.timestamp, now or blockhash. These can be influenced by miners to some extent so they should be avoided.

Exploit Scenario:

contract Game {

    uint reward_determining_number;

    function guessing() external{
      reward_determining_number = uint256(block.blockhash(10000)) % 10;
    }
}

Eve is a miner. Eve calls guessing and re-orders the block containing the transaction. As a result, Eve wins the game.

Recommendation

Do not use block.timestamp, now or blockhash as a source of randomness

Codex

Configuration

  • Check: codex
  • Severity: High
  • Confidence: Low

Description

Use codex to find vulnerabilities

Exploit Scenario:

N/A

Recommendation

Review codex's message.

Domain separator collision

Configuration

  • Check: domain-separator-collision
  • Severity: Medium
  • Confidence: High

Description

An ERC20 token has a function whose signature collides with EIP-2612's DOMAIN_SEPARATOR(), causing unanticipated behavior for contracts using permit functionality.

Exploit Scenario:

contract Contract{
    function some_collisions() external() {}
}

some_collision clashes with EIP-2612's DOMAIN_SEPARATOR() and will interfere with contract's using permit.

Recommendation

Remove or rename the function that collides with DOMAIN_SEPARATOR().

Dangerous enum conversion

Configuration

  • Check: enum-conversion
  • Severity: Medium
  • Confidence: High

Description

Detect out-of-range enum conversion (solc < 0.4.5).

Exploit Scenario:

    pragma solidity 0.4.2;
    contract Test{

    enum E{a}

    function bug(uint a) public returns(E){
        return E(a);
    }
}

Attackers can trigger unexpected behaviour by calling bug(1).

Recommendation

Use a recent compiler version. If solc <0.4.5 is required, check the enum conversion range.

Incorrect erc20 interface

Configuration

  • Check: erc20-interface
  • Severity: Medium
  • Confidence: High

Description

Incorrect return values for ERC20 functions. A contract compiled with Solidity > 0.4.22 interacting with these functions will fail to execute them, as the return value is missing.

Exploit Scenario:

contract Token{
    function transfer(address to, uint value) external;
    //...
}

Token.transfer does not return a boolean. Bob deploys the token. Alice creates a contract that interacts with it but assumes a correct ERC20 interface implementation. Alice's contract is unable to interact with Bob's contract.

Recommendation

Set the appropriate return values and types for the defined ERC20 functions.

Incorrect erc721 interface

Configuration

  • Check: erc721-interface
  • Severity: Medium
  • Confidence: High

Description

Incorrect return values for ERC721 functions. A contract compiled with solidity > 0.4.22 interacting with these functions will fail to execute them, as the return value is missing.

Exploit Scenario:

contract Token{
    function ownerOf(uint256 _tokenId) external view returns (bool);
    //...
}

Token.ownerOf does not return an address like ERC721 expects. Bob deploys the token. Alice creates a contract that interacts with it but assumes a correct ERC721 interface implementation. Alice's contract is unable to interact with Bob's contract.

Recommendation

Set the appropriate return values and vtypes for the defined ERC721 functions.

Dangerous strict equalities

Configuration

  • Check: incorrect-equality
  • Severity: Medium
  • Confidence: High

Description

Use of strict equalities that can be easily manipulated by an attacker.

Exploit Scenario:

contract Crowdsale{
    function fund_reached() public returns(bool){
        return this.balance == 100 ether;
    }

Crowdsale relies on fund_reached to know when to stop the sale of tokens. Crowdsale reaches 100 Ether. Bob sends 0.1 Ether. As a result, fund_reached is always false and the crowdsale never ends.

Recommendation

Don't use strict equality to determine if an account has enough Ether or tokens.

Contracts that lock Ether

Configuration

  • Check: locked-ether
  • Severity: Medium
  • Confidence: High

Description

Contract with a payable function, but without a withdrawal capacity.

Exploit Scenario:

pragma solidity 0.4.24;
contract Locked{
    function receive() payable public{
    }
}

Every Ether sent to Locked will be lost.

Recommendation

Remove the payable attribute or add a withdraw function.

Deletion on mapping containing a structure

Configuration

  • Check: mapping-deletion
  • Severity: Medium
  • Confidence: High

Description

A deletion in a structure containing a mapping will not delete the mapping (see the Solidity documentation). The remaining data may be used to compromise the contract.

Exploit Scenario:

    struct BalancesStruct{
        address owner;
        mapping(address => uint) balances;
    }
    mapping(address => BalancesStruct) public stackBalance;

    function remove() internal{
         delete stackBalance[msg.sender];
    }

remove deletes an item of stackBalance. The mapping balances is never deleted, so remove does not work as intended.

Recommendation

Use a lock mechanism instead of a deletion to disable structure containing a mapping.

State variable shadowing from abstract contracts

Configuration

  • Check: shadowing-abstract
  • Severity: Medium
  • Confidence: High

Description

Detection of state variables shadowed from abstract contracts.

Exploit Scenario:

contract BaseContract{
    address owner;
}

contract DerivedContract is BaseContract{
    address owner;
}

owner of BaseContract is shadowed in DerivedContract.

Recommendation

Remove the state variable shadowing.

Tautological compare

Configuration

  • Check: tautological-compare
  • Severity: Medium
  • Confidence: High

Description

A variable compared to itself is probably an error as it will always return true for ==, >=, <= and always false for <, > and !=.

Exploit Scenario:

    function check(uint a) external returns(bool){
        return (a >= a);
    }

check always return true.

Recommendation

Remove comparison or compare to different value.

Tautology or contradiction

Configuration

  • Check: tautology
  • Severity: Medium
  • Confidence: High

Description

Detects expressions that are tautologies or contradictions.

Exploit Scenario:

contract A {
	function f(uint x) public {
		// ...
        if (x >= 0) { // bad -- always true
           // ...
        }
		// ...
	}

	function g(uint8 y) public returns (bool) {
		// ...
        return (y < 512); // bad!
		// ...
	}
}

x is a uint256, so x >= 0 will be always true. y is a uint8, so y <512 will be always true.

Recommendation

Fix the incorrect comparison by changing the value type or the comparison.

Write after write

Configuration

  • Check: write-after-write
  • Severity: Medium
  • Confidence: High

Description

Detects variables that are written but never read and written again.

Exploit Scenario:

```solidity
contract Buggy{
    function my_func() external initializer{
        // ...
        a = b;
        a = c;
        // ..
    }
}
```
`a` is first asigned to `b`, and then to `c`. As a result the first write does nothing.

Recommendation

Fix or remove the writes.

Misuse of a Boolean constant

Configuration

  • Check: boolean-cst
  • Severity: Medium
  • Confidence: Medium

Description

Detects the misuse of a Boolean constant.

Exploit Scenario:

contract A {
	function f(uint x) public {
		// ...
        if (false) { // bad!
           // ...
        }
		// ...
	}

	function g(bool b) public returns (bool) {
		// ...
        return (b || true); // bad!
		// ...
	}
}

Boolean constants in code have only a few legitimate uses. Other uses (in complex expressions, as conditionals) indicate either an error or, most likely, the persistence of faulty code.

Recommendation

Verify and simplify the condition.

Constant functions using assembly code

Configuration

  • Check: constant-function-asm
  • Severity: Medium
  • Confidence: Medium

Description

Functions declared as constant/pure/view using assembly code.

constant/pure/view was not enforced prior to Solidity 0.5. Starting from Solidity 0.5, a call to a constant/pure/view function uses the STATICCALL opcode, which reverts in case of state modification.

As a result, a call to an incorrectly labeled function may trap a contract compiled with Solidity 0.5.

Exploit Scenario:

contract Constant{
    uint counter;
    function get() public view returns(uint){
       counter = counter +1;
       return counter
    }
}

Constant was deployed with Solidity 0.4.25. Bob writes a smart contract that interacts with Constant in Solidity 0.5.0. All the calls to get revert, breaking Bob's smart contract execution.

Recommendation

Ensure the attributes of contracts compiled prior to Solidity 0.5.0 are correct.

Constant functions changing the state

Configuration

  • Check: constant-function-state
  • Severity: Medium
  • Confidence: Medium

Description

Functions declared as constant/pure/view change the state.

constant/pure/view was not enforced prior to Solidity 0.5. Starting from Solidity 0.5, a call to a constant/pure/view function uses the STATICCALL opcode, which reverts in case of state modification.

As a result, a call to an incorrectly labeled function may trap a contract compiled with Solidity 0.5.

Exploit Scenario:

contract Constant{
    uint counter;
    function get() public view returns(uint){
       counter = counter +1;
       return counter
    }
}

Constant was deployed with Solidity 0.4.25. Bob writes a smart contract that interacts with Constant in Solidity 0.5.0. All the calls to get revert, breaking Bob's smart contract execution.

Recommendation

Ensure that attributes of contracts compiled prior to Solidity 0.5.0 are correct.

Divide before multiply

Configuration

  • Check: divide-before-multiply
  • Severity: Medium
  • Confidence: Medium

Description

Solidity's integer division truncates. Thus, performing division before multiplication can lead to precision loss.

Exploit Scenario:

contract A {
	function f(uint n) public {
        coins = (oldSupply / n) * interest;
    }
}

If n is greater than oldSupply, coins will be zero. For example, with oldSupply = 5; n = 10, interest = 2, coins will be zero.
If (oldSupply * interest / n) was used, coins would have been 1.
In general, it's usually a good idea to re-arrange arithmetic to perform multiplication before division, unless the limit of a smaller type makes this dangerous.

Recommendation

Consider ordering multiplication before division.

Out-of-order retryable transactions

Configuration

  • Check: out-of-order-retryable
  • Severity: Medium
  • Confidence: Medium

Description

Out-of-order retryable transactions

Exploit Scenario:

contract L1 {
    function doStuffOnL2() external {
        // Retryable A
        IInbox(inbox).createRetryableTicket({
            to: l2contract,
            l2CallValue: 0,
            maxSubmissionCost: maxSubmissionCost,
            excessFeeRefundAddress: msg.sender,
            callValueRefundAddress: msg.sender,
            gasLimit: gasLimit,
            maxFeePerGas: maxFeePerGas,
            data: abi.encodeCall(l2contract.claim_rewards, ())
        });
        // Retryable B
        IInbox(inbox).createRetryableTicket({
            to: l2contract,
            l2CallValue: 0,
            maxSubmissionCost: maxSubmissionCost,
            excessFeeRefundAddress: msg.sender,
            callValueRefundAddress: msg.sender,
            gasLimit: gas,
            maxFeePerGas: maxFeePerGas,
            data: abi.encodeCall(l2contract.unstake, ())
        });
    }
}

contract L2 {
    function claim_rewards() public {
        // rewards is computed based on balance and staking period
        uint unclaimed_rewards = _compute_and_update_rewards();
        token.safeTransfer(msg.sender, unclaimed_rewards);
    }

    // Call claim_rewards before unstaking, otherwise you lose your rewards
    function unstake() public {
        _free_rewards(); // clean up rewards related variables
        balance = balance[msg.sender];
        balance[msg.sender] = 0;
        staked_token.safeTransfer(msg.sender, balance);
    }
}

Bob calls doStuffOnL2 but the first retryable ticket calling claim_rewards fails. The second retryable ticket calling unstake is executed successfully. As a result, Bob loses his rewards.

Recommendation

Do not rely on the order or successful execution of retryable tickets.

Reentrancy vulnerabilities

Configuration

  • Check: reentrancy-no-eth
  • Severity: Medium
  • Confidence: Medium

Description

Detection of the reentrancy bug. Do not report reentrancies that involve Ether (see reentrancy-eth).

Exploit Scenario:

    function bug(){
        require(not_called);
        if( ! (msg.sender.call() ) ){
            throw;
        }
        not_called = False;
    }   

Recommendation

Apply the check-effects-interactions pattern.

Reused base constructors

Configuration

  • Check: reused-constructor
  • Severity: Medium
  • Confidence: Medium

Description

Detects if the same base constructor is called with arguments from two different locations in the same inheritance hierarchy.

Exploit Scenario:

pragma solidity ^0.4.0;

contract A{
    uint num = 5;
    constructor(uint x) public{
        num += x;
    }
}

contract B is A{
    constructor() A(2) public { /* ... */ }
}

contract C is A {
    constructor() A(3) public { /* ... */ }
}

contract D is B, C {
    constructor() public { /* ... */ }
}

contract E is B {
    constructor() A(1) public { /* ... */ }
}

The constructor of A is called multiple times in D and E:

  • D inherits from B and C, both of which construct A.
  • E only inherits from B, but B and E construct A. .

Recommendation

Remove the duplicate constructor call.

Dangerous usage of tx.origin

Configuration

  • Check: tx-origin
  • Severity: Medium
  • Confidence: Medium

Description

tx.origin-based protection can be abused by a malicious contract if a legitimate user interacts with the malicious contract.

Exploit Scenario:

contract TxOrigin {
    address owner = msg.sender;

    function bug() {
        require(tx.origin == owner);
    }

Bob is the owner of TxOrigin. Bob calls Eve's contract. Eve's contract calls TxOrigin and bypasses the tx.origin protection.

Recommendation

Do not use tx.origin for authorization.

Unchecked low-level calls

Configuration

  • Check: unchecked-lowlevel
  • Severity: Medium
  • Confidence: Medium

Description

The return value of a low-level call is not checked.

Exploit Scenario:

contract MyConc{
    function my_func(address payable dst) public payable{
        dst.call.value(msg.value)("");
    }
}

The return value of the low-level call is not checked, so if the call fails, the Ether will be locked in the contract. If the low level is used to prevent blocking operations, consider logging failed calls.

Recommendation

Ensure that the return value of a low-level call is checked or logged.

Unchecked Send

Configuration

  • Check: unchecked-send
  • Severity: Medium
  • Confidence: Medium

Description

The return value of a send is not checked.

Exploit Scenario:

contract MyConc{
    function my_func(address payable dst) public payable{
        dst.send(msg.value);
    }
}

The return value of send is not checked, so if the send fails, the Ether will be locked in the contract. If send is used to prevent blocking operations, consider logging the failed send.

Recommendation

Ensure that the return value of send is checked or logged.

Uninitialized local variables

Configuration

  • Check: uninitialized-local
  • Severity: Medium
  • Confidence: Medium

Description

Uninitialized local variables.

Exploit Scenario:

contract Uninitialized is Owner{
    function withdraw() payable public onlyOwner{
        address to;
        to.transfer(this.balance)
    }
}

Bob calls transfer. As a result, all Ether is sent to the address 0x0 and is lost.

Recommendation

Initialize all the variables. If a variable is meant to be initialized to zero, explicitly set it to zero to improve code readability.

Unused return

Configuration

  • Check: unused-return
  • Severity: Medium
  • Confidence: Medium

Description

The return value of an external call is not stored in a local or state variable.

Exploit Scenario:

contract MyConc{
    using SafeMath for uint;   
    function my_func(uint a, uint b) public{
        a.add(b);
    }
}

MyConc calls add of SafeMath, but does not store the result in a. As a result, the computation has no effect.

Recommendation

Ensure that all the return values of the function calls are used.

Incorrect modifier

Configuration

  • Check: incorrect-modifier
  • Severity: Low
  • Confidence: High

Description

If a modifier does not execute _ or revert, the execution of the function will return the default value, which can be misleading for the caller.

Exploit Scenario:

    modidfier myModif(){
        if(..){
           _;
        }
    }
    function get() myModif returns(uint){

    }

If the condition in myModif is false, the execution of get() will return 0.

Recommendation

All the paths in a modifier must execute _ or revert.

Builtin Symbol Shadowing

Configuration

  • Check: shadowing-builtin
  • Severity: Low
  • Confidence: High

Description

Detection of shadowing built-in symbols using local variables, state variables, functions, modifiers, or events.

Exploit Scenario:

pragma solidity ^0.4.24;

contract Bug {
    uint now; // Overshadows current time stamp.

    function assert(bool condition) public {
        // Overshadows built-in symbol for providing assertions.
    }

    function get_next_expiration(uint earlier_time) private returns (uint) {
        return now + 259200; // References overshadowed timestamp.
    }
}

now is defined as a state variable, and shadows with the built-in symbol now. The function assert overshadows the built-in assert function. Any use of either of these built-in symbols may lead to unexpected results.

Recommendation

Rename the local variables, state variables, functions, modifiers, and events that shadow a builtin symbol.

Local variable shadowing

Configuration

  • Check: shadowing-local
  • Severity: Low
  • Confidence: High

Description

Detection of shadowing using local variables.

Exploit Scenario:

pragma solidity ^0.4.24;

contract Bug {
    uint owner;

    function sensitive_function(address owner) public {
        // ...
        require(owner == msg.sender);
    }

    function alternate_sensitive_function() public {
        address owner = msg.sender;
        // ...
        require(owner == msg.sender);
    }
}

sensitive_function.owner shadows Bug.owner. As a result, the use of owner in sensitive_function might be incorrect.

Recommendation

Rename the local variables that shadow another component.

Uninitialized function pointers in constructors

Configuration

  • Check: uninitialized-fptr-cst
  • Severity: Low
  • Confidence: High

Description

solc versions 0.4.5-0.4.26 and 0.5.0-0.5.8 contain a compiler bug leading to unexpected behavior when calling uninitialized function pointers in constructors.

Exploit Scenario:

contract bad0 {

  constructor() public {
    /* Uninitialized function pointer */
    function(uint256) internal returns(uint256) a;
    a(10);
  }

}

The call to a(10) will lead to unexpected behavior because function pointer a is not initialized in the constructor.

Recommendation

Initialize function pointers before calling. Avoid function pointers if possible.

Pre-declaration usage of local variables

Configuration

  • Check: variable-scope
  • Severity: Low
  • Confidence: High

Description

Detects the possible usage of a variable before the declaration is stepped over (either because it is later declared, or declared in another scope).

Exploit Scenario:

contract C {
    function f(uint z) public returns (uint) {
        uint y = x + 9 + z; // 'x' is used pre-declaration
        uint x = 7;

        if (z % 2 == 0) {
            uint max = 5;
            // ...
        }

        // 'max' was intended to be 5, but it was mistakenly declared in a scope and not assigned (so it is zero).
        for (uint i = 0; i < max; i++) {
            x += 1;
        }

        return x;
    }
}

In the case above, the variable x is used before its declaration, which may result in unintended consequences. Additionally, the for-loop uses the variable max, which is declared in a previous scope that may not always be reached. This could lead to unintended consequences if the user mistakenly uses a variable prior to any intended declaration assignment. It also may indicate that the user intended to reference a different variable.

Recommendation

Move all variable declarations prior to any usage of the variable, and ensure that reaching a variable declaration does not depend on some conditional if it is used unconditionally.

Void constructor

Configuration

  • Check: void-cst
  • Severity: Low
  • Confidence: High

Description

Detect the call to a constructor that is not implemented

Exploit Scenario:

contract A{}
contract B is A{
    constructor() public A(){}
}

When reading B's constructor definition, we might assume that A() initiates the contract, but no code is executed.

Recommendation

Remove the constructor call.

Calls inside a loop

Configuration

  • Check: calls-loop
  • Severity: Low
  • Confidence: Medium

Description

Calls inside a loop might lead to a denial-of-service attack.

Exploit Scenario:

contract CallsInLoop{

    address[] destinations;

    constructor(address[] newDestinations) public{
        destinations = newDestinations;
    }

    function bad() external{
        for (uint i=0; i < destinations.length; i++){
            destinations[i].transfer(i);
        }
    }

}

If one of the destinations has a fallback function that reverts, bad will always revert.

Recommendation

Favor pull over push strategy for external calls.

Missing events access control

Configuration

  • Check: events-access
  • Severity: Low
  • Confidence: Medium

Description

Detect missing events for critical access control parameters

Exploit Scenario:

contract C {

  modifier onlyAdmin {
    if (msg.sender != owner) throw;
    _;
  }

  function updateOwner(address newOwner) onlyAdmin external {
    owner = newOwner;
  }
}

updateOwner() has no event, so it is difficult to track off-chain owner changes.

Recommendation

Emit an event for critical parameter changes.

Missing events arithmetic

Configuration

  • Check: events-maths
  • Severity: Low
  • Confidence: Medium

Description

Detect missing events for critical arithmetic parameters.

Exploit Scenario:

contract C {

    modifier onlyOwner {
        if (msg.sender != owner) throw;
        _;
    }

    function setBuyPrice(uint256 newBuyPrice) onlyOwner public {
        buyPrice = newBuyPrice;
    }

    function buy() external {
     ... // buyPrice is used to determine the number of tokens purchased
    }    
}

setBuyPrice() does not emit an event, so it is difficult to track changes in the value of buyPrice off-chain.

Recommendation

Emit an event for critical parameter changes.

Dangerous unary expressions

Configuration

  • Check: incorrect-unary
  • Severity: Low
  • Confidence: Medium

Description

Unary expressions such as x=+1 probably typos.

Exploit Scenario:

contract Bug{
    uint public counter;

    function increase() public returns(uint){
        counter=+1;
        return counter;
    }
}

increase() uses =+ instead of +=, so counter will never exceed 1.

Recommendation

Remove the unary expression.

Missing zero address validation

Configuration

  • Check: missing-zero-check
  • Severity: Low
  • Confidence: Medium

Description

Detect missing zero address validation.

Exploit Scenario:

contract C {

  modifier onlyAdmin {
    if (msg.sender != owner) throw;
    _;
  }

  function updateOwner(address newOwner) onlyAdmin external {
    owner = newOwner;
  }
}

Bob calls updateOwner without specifying the newOwner, so Bob loses ownership of the contract.

Recommendation

Check that the address is not zero.

Reentrancy vulnerabilities

Configuration

  • Check: reentrancy-benign
  • Severity: Low
  • Confidence: Medium

Description

Detection of the reentrancy bug. Only report reentrancy that acts as a double call (see reentrancy-eth, reentrancy-no-eth).

Exploit Scenario:

    function callme(){
        if( ! (msg.sender.call()() ) ){
            throw;
        }
        counter += 1
    }   

callme contains a reentrancy. The reentrancy is benign because it's exploitation would have the same effect as two consecutive calls.

Recommendation

Apply the check-effects-interactions pattern.

Reentrancy vulnerabilities

Configuration

  • Check: reentrancy-events
  • Severity: Low
  • Confidence: Medium

Description

Detects reentrancies that allow manipulation of the order or value of events.

Exploit Scenario:

contract ReentrantContract {
	function f() external {
		if (BugReentrancyEvents(msg.sender).counter() == 1) {
			BugReentrancyEvents(msg.sender).count(this);
		}
	}
}
contract Counter {
	uint public counter;
	event Counter(uint);

}
contract BugReentrancyEvents is Counter {
    function count(ReentrantContract d) external {
        counter += 1;
        d.f();
        emit Counter(counter);
    }
}
contract NoReentrancyEvents is Counter {
	function count(ReentrantContract d) external {
        counter += 1;
        emit Counter(counter);
        d.f();
    }
}

If the external call d.f() re-enters BugReentrancyEvents, the Counter events will be incorrect (Counter(2), Counter(2)) whereas NoReentrancyEvents will correctly emit (Counter(1), Counter(2)). This may cause issues for offchain components that rely on the values of events e.g. checking for the amount deposited to a bridge.

Recommendation

Apply the check-effects-interactions pattern.

Return Bomb

Configuration

  • Check: return-bomb
  • Severity: Low
  • Confidence: Medium

Description

A low level callee may consume all callers gas unexpectedly.

Exploit Scenario:

//Modified from https://github.com/nomad-xyz/ExcessivelySafeCall
contract BadGuy {
    function youveActivateMyTrapCard() external pure returns (bytes memory) {
        assembly{
            revert(0, 1000000)
        }
    }
}

contract Mark {
    function oops(address badGuy) public{
        bool success;
        bytes memory ret;

        // Mark pays a lot of gas for this copy
        //(success, ret) = badGuy.call{gas:10000}(
        (success, ret) = badGuy.call(
            abi.encodeWithSelector(
                BadGuy.youveActivateMyTrapCard.selector
            )
        );

        // Mark may OOG here, preventing local state changes
        //importantCleanup();
    }
}

After Mark calls BadGuy bytes are copied from returndata to memory, the memory expansion cost is paid. This means that when using a standard solidity call, the callee can "returnbomb" the caller, imposing an arbitrary gas cost. Callee unexpectedly makes the caller OOG.

Recommendation

Avoid unlimited implicit decoding of returndata.

Block timestamp

Configuration

  • Check: timestamp
  • Severity: Low
  • Confidence: Medium

Description

Dangerous usage of block.timestamp. block.timestamp can be manipulated by miners.

Exploit Scenario:

"Bob's contract relies on block.timestamp for its randomness. Eve is a miner and manipulates block.timestamp to exploit Bob's contract.

Recommendation

Avoid relying on block.timestamp.

Assembly usage

Configuration

  • Check: assembly
  • Severity: Informational
  • Confidence: High

Description

The use of assembly is error-prone and should be avoided.

Recommendation

Do not use evm assembly.

Assert state change

Configuration

  • Check: assert-state-change
  • Severity: Informational
  • Confidence: High

Description

Incorrect use of assert(). See Solidity best practices.

Exploit Scenario:

contract A {

  uint s_a;

  function bad() public {
    assert((s_a += 1) > 10);
  }
}

The assert in bad() increments the state variable s_a while checking for the condition.

Recommendation

Use require for invariants modifying the state.

Boolean equality

Configuration

  • Check: boolean-equal
  • Severity: Informational
  • Confidence: High

Description

Detects the comparison to boolean constants.

Exploit Scenario:

contract A {
	function f(bool x) public {
		// ...
        if (x == true) { // bad!
           // ...
        }
		// ...
	}
}

Boolean constants can be used directly and do not need to be compare to true or false.

Recommendation

Remove the equality to the boolean constant.

Cyclomatic complexity

Configuration

  • Check: cyclomatic-complexity
  • Severity: Informational
  • Confidence: High

Description

Detects functions with high (> 11) cyclomatic complexity.

Recommendation

Reduce cyclomatic complexity by splitting the function into several smaller subroutines.

Deprecated standards

Configuration

  • Check: deprecated-standards
  • Severity: Informational
  • Confidence: High

Description

Detect the usage of deprecated standards.

Exploit Scenario:

contract ContractWithDeprecatedReferences {
    // Deprecated: Change block.blockhash() -> blockhash()
    bytes32 globalBlockHash = block.blockhash(0);

    // Deprecated: Change constant -> view
    function functionWithDeprecatedThrow() public constant {
        // Deprecated: Change msg.gas -> gasleft()
        if(msg.gas == msg.value) {
            // Deprecated: Change throw -> revert()
            throw;
        }
    }

    // Deprecated: Change constant -> view
    function functionWithDeprecatedReferences() public constant {
        // Deprecated: Change sha3() -> keccak256()
        bytes32 sha3Result = sha3("test deprecated sha3 usage");

        // Deprecated: Change callcode() -> delegatecall()
        address(this).callcode();

        // Deprecated: Change suicide() -> selfdestruct()
        suicide(address(0));
    }
}

Recommendation

Replace all uses of deprecated symbols.

Unindexed ERC20 event parameters

Configuration

  • Check: erc20-indexed
  • Severity: Informational
  • Confidence: High

Description

Detects whether events defined by the ERC20 specification that should have some parameters as indexed are missing the indexed keyword.

Exploit Scenario:

contract ERC20Bad {
    // ...
    event Transfer(address from, address to, uint value);
    event Approval(address owner, address spender, uint value);

    // ...
}

Transfer and Approval events should have the 'indexed' keyword on their two first parameters, as defined by the ERC20 specification. Failure to include these keywords will exclude the parameter data in the transaction/block's bloom filter, so external tooling searching for these parameters may overlook them and fail to index logs from this token contract.

Recommendation

Add the indexed keyword to event parameters that should include it, according to the ERC20 specification.

Function Initializing State

Configuration

  • Check: function-init-state
  • Severity: Informational
  • Confidence: High

Description

Detects the immediate initialization of state variables through function calls that are not pure/constant, or that use non-constant state variable.

Exploit Scenario:

contract StateVarInitFromFunction {

    uint public v = set(); // Initialize from function (sets to 77)
    uint public w = 5;
    uint public x = set(); // Initialize from function (sets to 88)
    address public shouldntBeReported = address(8);

    constructor(){
        // The constructor is run after all state variables are initialized.
    }

    function set() public  returns(uint)  {
        // If this function is being used to initialize a state variable declared
        // before w, w will be zero. If it is declared after w, w will be set.
        if(w == 0) {
            return 77;
        }

        return 88;
    }
}

In this case, users might intend a function to return a value a state variable can initialize with, without realizing the context for the contract is not fully initialized. In the example above, the same function sets two different values for state variables because it checks a state variable that is not yet initialized in one case, and is initialized in the other. Special care must be taken when initializing state variables from an immediate function call so as not to incorrectly assume the state is initialized.

Recommendation

Remove any initialization of state variables via non-constant state variables or function calls. If variables must be set upon contract deployment, locate initialization in the constructor instead.

Incorrect usage of using-for statement

Configuration

  • Check: incorrect-using-for
  • Severity: Informational
  • Confidence: High

Description

In Solidity, it is possible to use libraries for certain types, by the using-for statement (using <library> for <type>). However, the Solidity compiler doesn't check whether a given library has at least one function matching a given type. If it doesn't, such a statement has no effect and may be confusing.

Exploit Scenario:

```solidity
library L {
    function f(bool) public pure {}
}

using L for uint;
```
Such a code will compile despite the fact that `L` has no function with `uint` as its first argument.

Recommendation

Make sure that the libraries used in using-for statements have at least one function matching a type used in these statements.

Low-level calls

Configuration

  • Check: low-level-calls
  • Severity: Informational
  • Confidence: High

Description

The use of low-level calls is error-prone. Low-level calls do not check for code existence or call success.

Recommendation

Avoid low-level calls. Check the call success. If the call is meant for a contract, check for code existence.

Missing inheritance

Configuration

  • Check: missing-inheritance
  • Severity: Informational
  • Confidence: High

Description

Detect missing inheritance.

Exploit Scenario:

interface ISomething {
    function f1() external returns(uint);
}

contract Something {
    function f1() external returns(uint){
        return 42;
    }
}

Something should inherit from ISomething.

Recommendation

Inherit from the missing interface or contract.

Conformance to Solidity naming conventions

Configuration

  • Check: naming-convention
  • Severity: Informational
  • Confidence: High

Description

Solidity defines a naming convention that should be followed.

Rule exceptions

  • Allow constant variable name/symbol/decimals to be lowercase (ERC20).
  • Allow _ at the beginning of the mixed_case match for private variables and unused parameters.

Recommendation

Follow the Solidity naming convention.

Different pragma directives are used

Configuration

  • Check: pragma
  • Severity: Informational
  • Confidence: High

Description

Detect whether different Solidity versions are used.

Recommendation

Use one Solidity version.

Redundant Statements

Configuration

  • Check: redundant-statements
  • Severity: Informational
  • Confidence: High

Description

Detect the usage of redundant statements that have no effect.

Exploit Scenario:

contract RedundantStatementsContract {

    constructor() public {
        uint; // Elementary Type Name
        bool; // Elementary Type Name
        RedundantStatementsContract; // Identifier
    }

    function test() public returns (uint) {
        uint; // Elementary Type Name
        assert; // Identifier
        test; // Identifier
        return 777;
    }
}

Each commented line references types/identifiers, but performs no action with them, so no code will be generated for such statements and they can be removed.

Recommendation

Remove redundant statements if they congest code but offer no value.

Incorrect versions of Solidity

Configuration

  • Check: solc-version
  • Severity: Informational
  • Confidence: High

Description

solc frequently releases new compiler versions. Using an old version prevents access to new Solidity security checks. We also recommend avoiding complex pragma statement.

Recommendation

Deploy with a recent version of Solidity (at least 0.8.0) with no known severe issues.

Use a simple pragma version that allows any of these versions. Consider using the latest version of Solidity for testing.

Unimplemented functions

Configuration

  • Check: unimplemented-functions
  • Severity: Informational
  • Confidence: High

Description

Detect functions that are not implemented on derived-most contracts.

Exploit Scenario:

interface BaseInterface {
    function f1() external returns(uint);
    function f2() external returns(uint);
}

interface BaseInterface2 {
    function f3() external returns(uint);
}

contract DerivedContract is BaseInterface, BaseInterface2 {
    function f1() external returns(uint){
        return 42;
    }
}

DerivedContract does not implement BaseInterface.f2 or BaseInterface2.f3. As a result, the contract will not properly compile. All unimplemented functions must be implemented on a contract that is meant to be used.

Recommendation

Implement all unimplemented functions in any contract you intend to use directly (not simply inherit from).

Unused Imports

Configuration

  • Check: unused-import
  • Severity: Informational
  • Confidence: High

Description

Importing a file that is not used in the contract likely indicates a mistake. The import should be removed until it is needed.

Exploit Scenario:

```solidity
import {A} from "./A.sol";
contract B {}
```
B either should import from A and it was forgotten or the import is not needed and should be removed.

Recommendation

Remove the unused import. If the import is needed later, it can be added back.

Unused state variable

Configuration

  • Check: unused-state
  • Severity: Informational
  • Confidence: High

Description

Unused state variable.

Recommendation

Remove unused state variables.

Costly operations inside a loop

Configuration

  • Check: costly-loop
  • Severity: Informational
  • Confidence: Medium

Description

Costly operations inside a loop might waste gas, so optimizations are justified.

Exploit Scenario:

contract CostlyOperationsInLoop{

    uint loop_count = 100;
    uint state_variable=0;

    function bad() external{
        for (uint i=0; i < loop_count; i++){
            state_variable++;
        }
    }

    function good() external{
      uint local_variable = state_variable;
      for (uint i=0; i < loop_count; i++){
        local_variable++;
      }
      state_variable = local_variable;
    }
}

Incrementing state_variable in a loop incurs a lot of gas because of expensive SSTOREs, which might lead to an out-of-gas.

Recommendation

Use a local variable to hold the loop computation result.

Dead-code

Configuration

  • Check: dead-code
  • Severity: Informational
  • Confidence: Medium

Description

Functions that are not sued.

Exploit Scenario:

contract Contract{
    function dead_code() internal() {}
}

dead_code is not used in the contract, and make the code's review more difficult.

Recommendation

Remove unused functions.

Reentrancy vulnerabilities

Configuration

  • Check: reentrancy-unlimited-gas
  • Severity: Informational
  • Confidence: Medium

Description

Detection of the reentrancy bug. Only report reentrancy that is based on transfer or send.

Exploit Scenario:

    function callme(){
        msg.sender.transfer(balances[msg.sender]):
        balances[msg.sender] = 0;
    }   

send and transfer do not protect from reentrancies in case of gas price changes.

Recommendation

Apply the check-effects-interactions pattern.

Variable names too similar

Configuration

  • Check: similar-names
  • Severity: Informational
  • Confidence: Medium

Description

Detect variables with names that are too similar.

Exploit Scenario:

Bob uses several variables with similar names. As a result, his code is difficult to review.

Recommendation

Prevent variables from having similar names.

Too many digits

Configuration

  • Check: too-many-digits
  • Severity: Informational
  • Confidence: Medium

Description

Literals with many digits are difficult to read and review. Use scientific notation or suffixes to make the code more readable.

Exploit Scenario:

contract MyContract{
    uint 1_ether = 10000000000000000000; 
}

While 1_ether looks like 1 ether, it is 10 ether. As a result, it's likely to be used incorrectly.

Recommendation

Use:

Cache array length

Configuration

  • Check: cache-array-length
  • Severity: Optimization
  • Confidence: High

Description

Detects for loops that use length member of some storage array in their loop condition and don't modify it.

Exploit Scenario:

contract C
{
    uint[] array;
    
    function f() public 
    {
        for (uint i = 0; i < array.length; i++)
        {
            // code that does not modify length of `array`
        }
    }
}

Since the for loop in f doesn't modify array.length, it is more gas efficient to cache it in some local variable and use that variable instead, like in the following example:

contract C
{
    uint[] array;
    
    function f() public 
    {
        uint array_length = array.length;
        for (uint i = 0; i < array_length; i++)
        {
            // code that does not modify length of `array`
        }
    }
}

Recommendation

Cache the lengths of storage arrays if they are used and not modified in for loops.

State variables that could be declared constant

Configuration

  • Check: constable-states
  • Severity: Optimization
  • Confidence: High

Description

State variables that are not updated following deployment should be declared constant to save gas.

Recommendation

Add the constant attribute to state variables that never change.

Public function that could be declared external

Configuration

  • Check: external-function
  • Severity: Optimization
  • Confidence: High

Description

public functions that are never called by the contract should be declared external, and its immutable parameters should be located in calldata to save gas.

Recommendation

Use the external attribute for functions never called from the contract, and change the location of immutable parameters to calldata to save gas.

State variables that could be declared immutable

Configuration

  • Check: immutable-states
  • Severity: Optimization
  • Confidence: High

Description

State variables that are not updated following deployment should be declared immutable to save gas.

Recommendation

Add the immutable attribute to state variables that never change or are set only in the constructor.

Public variable read in external context

Configuration

  • Check: var-read-using-this
  • Severity: Optimization
  • Confidence: High

Description

The contract reads its own variable using this, adding overhead of an unnecessary STATICCALL.

Exploit Scenario:

contract C {
    mapping(uint => address) public myMap;
    function test(uint x) external returns(address) {
        return this.myMap(x);
    }
}

Recommendation

Read the variable directly from storage instead of calling the contract.

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