Drillx is a proof-of-work algorithm for smart contract based cryptocurrency mining.
Drillx builds upon Equix, the CPU-friendly client puzzle designed to protect Tor from DOS attacks. Equix itself is a variation of Equihash, an asymmetric proof-of-work function with cheap verifications. Drillx adds a Keccak hashing step on top of Equix to guarantee a difficulty distribution of p(Z) = 2^-Z
where Z
is the number of leading zeros on the hash. A challenge C
is assumed to be a securely generated 256-bit hash, seeded by a recent Solana blockhash. Miners compete to find a 64-bit nonce N
that produces a hash of their target difficulty. Solutions must be presented in the form (E, N)
where E = Equix(C, N)
. The difficulty is calculated from Keccak(E', N)
where E'
is the Equix proof, sorted lexographically to prevent malleability. Since E
can be efficiently verified on-chain and Keccak is available as a Solana syscall, Drillx solutions can easily fit into a single Solana transaction.
Miners can iterate through nonces to find a hash that satisfies their target difficulty.
use drillx::{equix::SolverMemory, Solution};
fn main() {
let challenge = [255; 32]; // Should be provided by a program
let target = 8;
let mut memory = SolverMemory::new();
for nonce in 0..u64::MAX {
let hx = drillx::hash_with_memory(&mut memory, &challenge, &nonce.to_le_bytes());
if hx.difficuty() >= target {
println!("Solution: {:?}", Solution::new(hx.d, nonce));
return
}
}
}
Smart contracts can verify the solution and use the difficulty to issue token rewards.
use drillx::Solution;
fn verify(solution: Solution) {
let challenge = [255; 32]; // Fetch from state
let target = 8;
assert!(solution.is_valid(&challenge));
assert!(solution.to_hash().difficulty() >= target);
}