# How to generate a random number in solidity?

I have a couple of keccaks, which could be reduced to one if I would find a cheap way to get parts of the created uint.

``````pragma solidity ^0.4.19;

contract test {
function test() {

}

function sup() returns (uint test) {
uint _test = uint(keccak256("wow"));
return _test;
}
}
``````

This returns me a sweet random number: 13483274892375982735325

Now the plan is that instead of calling keccak 5 times with different "seeds", I could take that number apart and get something like: 1348, 3274, 8923 etc. which I then use for my random number e.g.: 1348 % 10

But solidity can't just do that. Is there anything cheap that could work?

Solidity contracts are deterministic. Anyone who figures out how your contract produces randomness can anticipate its results and use this information to exploit your application.

One option is to produce randomness off-chain (where it cannot be predicted) and use it in your smart contract. Chainlink VRF is an easy-to-implement solution for using random data in smart contracts. Here's an example snippet to request & receive random data:

``````requestRandomness(keyHash, fee, seed);
``````

Your contract's request is fulfilled in a callback function:

``````function fulfillRandomness(bytes32 requestId, uint256 randomness) external override {
// Do something with randomness
}
``````

An example of a full contract that implements a random number would be:

``````pragma solidity 0.6.2;

contract Verifiable6SidedDiceRoll is VRFConsumerBase {
using SafeMath for uint;

bytes32 internal keyHash;
uint256 internal fee;

event RequestRandomness(
bytes32 indexed requestId,
bytes32 keyHash,
uint256 seed
);

event RequestRandomnessFulfilled(
bytes32 indexed requestId,
uint256 randomness
);

/**
* @notice Constructor inherits VRFConsumerBase
* @dev Ropsten deployment params:
* @dev   _vrfCoordinator: 0xf720CF1B963e0e7bE9F58fd471EFa67e7bF00cfb
*/
{
vrfCoordinator = _vrfCoordinator;
keyHash = 0xced103054e349b8dfb51352f0f8fa9b5d20dde3d06f9f43cb2b85bc64b238205; // hard-coded for Ropsten
fee = 10 ** 18; // 1 LINK hard-coded for Ropsten
}

/**
* @notice Requests randomness from a user-provided seed
* @dev The user-provided seed is hashed with the current blockhash as an additional precaution.
* @dev   1. In case of block re-orgs, the revealed answers will not be re-used again.
* @dev   2. In case of predictable user-provided seeds, the seed is mixed with the less predictable blockhash.
* @dev This is only an example implementation and not necessarily suitable for mainnet.
* @dev You must review your implementation details with extreme care.
*/
function rollDice(uint256 userProvidedSeed) public returns (bytes32 requestId) {
uint256 seed = uint256(keccak256(abi.encode(userProvidedSeed, blockhash(block.number)))); // Hash user seed and blockhash
bytes32 _requestId = requestRandomness(keyHash, fee, seed);
emit RequestRandomness(_requestId, keyHash, seed);
return _requestId;
}

function fulfillRandomness(bytes32 requestId, uint256 randomness) external override {
emit RequestRandomnessFulfilled(requestId, randomness);
}

}
``````
• Keep in mind that generating a random number this way has a fee (paid in LINK). Commented Nov 6, 2021 at 20:39
• You will cost 10 LINK per request on Ethereum. 1 LINK = \$22.5 today. If your project is an NFT project with 1000 NFTs and you want to make sure you used the 'can not be predicted random number' in every mint. You can do the math. Commented Dec 24, 2021 at 3:56
• Although solidity contracts are deterministic, there is still a way to generate a Pseudo-random number. The answer should cover that first and then show options such as chainlink. Commented Dec 12, 2022 at 9:27

You cannot create truly random numbers but you can pseudo-random numbers. Blockchain is a deterministic system so we have to make sure that each node must give the same random number. Determinism, is very important because it is vital that regardless of where the smart contract code executes, it produces the same result every time and everywhere.

Getting truly numbers in a deterministic system is impossible because global variables are being used is predictable or can be somehow get manipulated.

For example, Timestamp vulnerability is quite common. Usually, the timestamp of a block is accessed via `block.timestamp` but this timestamp can be manipulated by miners, leading to influencing the outcome of some function that relies on timestamps. The timestamp is used as a source of randomness in lottery games to select the next winner. Thus, it might be possible for a miner to modify the timestamp in such a way that its chances of becoming the next winner increase.

In order to get the true random number we have to look at outside the blockchain. We need to use oracle services to get the true random number. If you do not have your true random number in your smart contract, your smart contract can get hacked. You can read about 2 cases:

since solidity evolving very fast, other answers are outdated. This answer will be outdated one day but as of now you can implement a pseudo number generator like this:

``````  // I realized if you call the random() in for loop, you get same result. So I had to add another changing variable
// https://stackoverflow.com/questions/73555009/how-to-generate-random-words-in-solidity-based-based-on-a-string-of-letters/73557284#73557284
uint counter =1;
function random() private view returns (uint) {
counter++;
// sha3 and now have been deprecated
return uint(keccak256(abi.encodePacked(block.difficulty, block.timestamp, players,counter)));
// convert hash to integer
// players is an array of entrants

}
``````

this will return very very big number. But we use modulo operator.

``````random() % players.length
``````

this will return a number between 0 and players.length. we write a function for this:

``````function pickWinner() public {
uint index=random()%players.length;
}
``````

## Get random Number with Chainlink

After you deploy this contract, you have to send Link tokens to this contract and press on `getRandomNumber`. Wait about a minute and then click on `result`

`````` import "https://github.com/smartcontractkit/chainlink/blob/develop/contracts/src/v0.8/VRFConsumerBase.sol";

contract Test is VRFConsumerBase {
bytes32 public keyHash;
uint256 public fee;
uint256 public ticketPrice;
uint256 public result;

// key hash 0x0476f9a745b61ea5c0ab224d3a6e4c99f0b02fce4da01143a4f70aa80ae76e8a
constructor(
uint256 _ticketPrice
fee = 0.1 * 10 ** 18;
ticketPrice = _ticketPrice;
}

function getRandomNumber() public payable returns (bytes32 requestId) {
require(
"YOU HAVE TO SEND LINK TOKEN TO THIS CONTRACT"
);
return requestRandomness(keyHash, fee);
}

// this is callback, it will be called by the vrf coordinator
function fulfillRandomness(
bytes32 requestId,
uint256 randomness
) internal override {
result = randomness;
}

}
``````

• how likely is it that if this function were called several times in rapid succession that the same number would be returned because block.difficult and block.timestamp haven't changed in the intervening calls? Commented Sep 5, 2021 at 21:46
• @GGizmos as I mentioned "You cannot create truly random number but you can pseudo random number". u can change the params Commented Sep 8, 2021 at 15:44
• You could add reference to one of your state variables that will change between each call. Simplest example is `uint randomCallCount` Commented Dec 19, 2021 at 20:53

To generate a pseudo-random number you could do something like

``````function random() private view returns (uint) {
return uint(keccak256(block.difficulty, now));
}
``````

If you need a random number in a specific range you can e.g. use modulo. For instance to get a random number between 0 and 999 (both incl.) you can do it as follows:

``````function random() private view returns (uint) {
uint randomHash = uint(keccak256(block.difficulty, now));
return randomHash % 1000;
}
``````

If you have e.g. another field of type array available, you could pass its length to the `keccak256` function as an additional argument.

(All code was compiled with v0.4.17).

• Can anyone tell if this safe? Commented Aug 7, 2023 at 15:27
• @RenanCoelho This method generates a pseudo-random number using values like `block.difficulty` and `now`, which can be influenced by miners. Therefore, it's not safe for production environments where true randomness is required, as it could be predicted or manipulated by malicious actors. Commented Aug 9, 2023 at 11:29
• Thanks for the info! Maybe the safest way to do it is using Chainlink VRF. chain.link/vrf Commented Aug 18, 2023 at 14:48
``````// Generate a random number between 1 and 100:
uint randNonce = 0;
uint random = uint(keccak256(abi.encodePacked(now, msg.sender, randNonce))) % 100;
randNonce++;
uint random2 = uint(keccak256(abi.encodePacked(now, msg.sender, randNonce))) % 100;
``````

In order to prevent a manipulation you need a more than pseudorandom number.

Have a look at the randao smart contract. It provides actual random numbers that an attacker can not easily manipulate.

Generating a random number in solidity is pretty complicated. Because blockchain is a deterministic system.

For generating a random number in solidity you have to generator this number from outside the blocks.

For this you have to learn about the VRFConsumerBase. This is a package which help us to generator the fully random number without disturbing our blockchain blocks. For more help you can checkout from this link: https://docs.chain.link/docs/get-a-random-number/

Here is the simple example generating a random number in solidity.

``````pragma solidity ^0.6.6;
import "@openzeppelin/contracts/access/Ownable.sol";

contract Lottery is VRFConsumerBase, Ownable {
uint256 public usdEntryFee;
AggregatorV3Interface internal ethUSDPriceFeed;
enum LOTTERY_STATE {
OPEN,
CLOSED,
CALCULATING_WINNER
}
LOTTERY_STATE public lottery_state;
uint256 public fee;
bytes32 public keyHash;
uint256 public randomness;

constructor(
uint256 _fee,
bytes32 _keyHash
usdEntryFee = 50 * (10**18);
lottery_state = LOTTERY_STATE.CLOSED;
fee = _fee;
keyHash = _keyHash;
}

function enter() public payable {
//\$50 minimum
require(lottery_state == LOTTERY_STATE.OPEN, "LOTTERY IS CLOSED!");
require(msg.value >= getEntranceFee(), "Not Enough ETH!");
players.push(msg.sender);
}

function getEntranceFee() public view returns (uint256) {
(, int256 price, , , ) = ethUSDPriceFeed.latestRoundData();
uint256 adjustedPrice = uint256(price) * 10**10;
uint256 costToEnter = (usdEntryFee * 10**18) / adjustedPrice;
return costToEnter;
}

function startLottery() public onlyOwner {
require(
lottery_state == LOTTERY_STATE.CLOSED,
"Can't start a new lottery yet!"
);
lottery_state = LOTTERY_STATE.OPEN;
}

function endLottery() public onlyOwner {

lottery_state = LOTTERY_STATE.CALCULATING_WINNER;
bytes32 requestId = requestRandomness(keyHash, fee);
}

function fulfillRandomness(bytes32 _requestId, uint256 _randomness)
internal
override
{
require(
lottery_state == LOTTERY_STATE.CALCULATING_WINNER,
"You aren't there yet!"
);
require(_randomness > 0, "random-not-found");
uint256 indexOfWinner = _randomness % players.length;
recentWinner = players[indexOfWinner];
lottery_state = LOTTERY_STATE.CLOSED;
randomness = _randomness;
}
}
``````

Just let me know if you have any other question.

First, let's see how a random number is generated on your computer. It needs a source of randomness, like - the temperature of CPU, how many times you pressed the letter "B", the speed of your fan at a time `t` etc.

But in blockchain, there is `nearly no source of randomness`. Everything the contract sees, the public sees. And someone could game the system just by looking a the smart contract, aka seeing its `source of randomness`.

Given you take the above into consideration, you can use this simple random generator solidity program to generate random numbers between 0 to 100. Bare in mind that someone can still game the system. We're just making it hard for them.

``````contract Random {
uint256 private seed;

constructor() {
seed = (block.timestamp + block.difficulty) % 100;
}

function getRandomNumber() public returns (uint256) {
seed = (seed + block.timestamp + block.difficulty) % 100;
return seed;
}
``````

}

`block.difficulty` and `block.timestamp` are pretty random and we're taking advantage of that.

`block.difficulty` is a indicates how difficult a block is to mine for miners. So we can generally say the more transactions a block has the more difficult it is to mine.

`block.timestamp` is Unix time of block when it is mined.

So, we're seeding at the creation of the smart contract and even to make it hard when we call `getRandomNumber` we're changing the `seed`, by adding another source of randomness, i.e the previous `seed`. Hope this helps.

Here my best attempt. Based on a different problem I can't find anymore. If I do I'll link it.

``````pragma solidity ^0.4.19;

contract test {

event randomNumbers(uint[8] numbers, uint[8] randomNumbers);

function testa() public returns (uint[8] bla) {

//uint something = 12345678123456781234567812345678;
uint something = uint(keccak256("rockandroll"));

uint[8] memory array;
uint[8] memory random;

for(uint i=0; i<8; i++) {
uint digit = something % 10000;
// do something with digit
array[i] = digit;
something /= 10000;
random[i] =digit % 10;
}

randomNumbers(array,random);

return array;
}
``````

You can generate randomness on chain by taking some data at a given time, mixing it and form a number.

``````unchecked {
randomTokenId = uint256(
keccak256(
abi.encode(
keccak256(
abi.encodePacked(
msg.sender,
tx.origin,
gasleft(),
block.timestamp,
block.number,
blockhash(block.number),
blockhash(block.number - 100)
)
)
)
)
) % 100;
}
``````

Problem with this approach is all data is available at the time and user control the data.

It uses a future commit and reveal. You mint a token, for example, on block 16723029. But the mint function will only generate your `tokenId` or random id when 16723029 + 5 (a future block). When after 5 blocks this functions is called, your randomness is revealed and you get your random `tokenId` or random id. Genius and simple.

If you are minting the last token, you can call it arbitrary call the function.

You can't do that using only Solidity, otherwise it's unsafe. You need an oracle.

If you don't, the random number is more or less predictable.

For example, you could use the block timestamp and difficulty to create a random number but it's pseudo-random:

``````function createRandomNumber(uint256 max) external view returns (uint256)
{
return
uint256(
keccak256(
abi.encodePacked(
block.timestamp,
block.difficulty,
msg.sender
)
)
) % max;
}
``````

So you need to use ChainLink's VRF V2 contract (verifiable random number):

``````contract SomeContract is VRFV2WrapperConsumerBase {

// fee given to the oracle for fulfilling the request (LINK tokens)
uint256 internal fee;

uint32 callbackGasLimit = 100000;

uint16 confirmations = 3;

fee = 0.25 * 10**18;
}

// Requests a random number from ChainLink
function generateRandomNumber() public returns (uint256) {
require(
);

// Request a random number from chainlink
uint256 requestId = requestRandomness(
callbackGasLimit,
confirmations,
1
);

return requestId;
}

// will be executed when chainlink is done generating the number
function fulfillRandomWords(
uint256 _requestId,
uint256[] memory _randomWords
) internal override {
uint256 number = _randomWords[0];

// Do something with the random number
}
}
``````

SKALE supports true random generation and it is free to use chain. They have a speical arrangement where 11/16 nodes have to sign to get a random value.

https://docs.skale.network/tools/skale-specific/random-number-generator