583 lines
18 KiB
Rust
583 lines
18 KiB
Rust
// Copyright 2015-2019 Parity Technologies (UK) Ltd.
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// This file is part of Parity.
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// Parity is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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// Parity is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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// You should have received a copy of the GNU General Public License
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// along with Parity. If not, see <http://www.gnu.org/licenses/>.
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use compute::{calculate_dag_item, FNV_PRIME};
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use keccak::H256;
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use shared::{get_data_size, Node, ETHASH_ACCESSES, ETHASH_MIX_BYTES};
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const PROGPOW_CACHE_BYTES: usize = 16 * 1024;
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const PROGPOW_CACHE_WORDS: usize = PROGPOW_CACHE_BYTES / 4;
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const PROGPOW_CNT_CACHE: usize = 12;
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const PROGPOW_CNT_MATH: usize = 20;
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const PROGPOW_CNT_DAG: usize = ETHASH_ACCESSES;
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const PROGPOW_DAG_LOADS: usize = 4;
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const PROGPOW_MIX_BYTES: usize = 2 * ETHASH_MIX_BYTES;
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const PROGPOW_PERIOD_LENGTH: usize = 50; // blocks per progpow epoch (N)
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const PROGPOW_LANES: usize = 16;
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const PROGPOW_REGS: usize = 32;
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const FNV_HASH: u32 = 0x811c9dc5;
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const KECCAKF_RNDC: [u32; 24] = [
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0x00000001, 0x00008082, 0x0000808a, 0x80008000, 0x0000808b, 0x80000001, 0x80008081, 0x00008009,
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0x0000008a, 0x00000088, 0x80008009, 0x8000000a, 0x8000808b, 0x0000008b, 0x00008089, 0x00008003,
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0x00008002, 0x00000080, 0x0000800a, 0x8000000a, 0x80008081, 0x00008080, 0x80000001, 0x80008008,
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];
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const KECCAKF_ROTC: [u32; 24] = [
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1, 3, 6, 10, 15, 21, 28, 36, 45, 55, 2, 14, 27, 41, 56, 8, 25, 43, 62, 18, 39, 61, 20, 44,
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];
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const KECCAKF_PILN: [usize; 24] = [
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10, 7, 11, 17, 18, 3, 5, 16, 8, 21, 24, 4, 15, 23, 19, 13, 12, 2, 20, 14, 22, 9, 6, 1,
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];
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fn keccak_f800_round(st: &mut [u32; 25], r: usize) {
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// Theta
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let mut bc = [0u32; 5];
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for i in 0..bc.len() {
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bc[i] = st[i] ^ st[i + 5] ^ st[i + 10] ^ st[i + 15] ^ st[i + 20];
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}
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for i in 0..bc.len() {
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let t = bc[(i + 4) % 5] ^ bc[(i + 1) % 5].rotate_left(1);
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for j in (0..st.len()).step_by(5) {
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st[j + i] ^= t;
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}
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}
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// Rho Pi
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let mut t = st[1];
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debug_assert_eq!(KECCAKF_ROTC.len(), 24);
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for i in 0..24 {
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let j = KECCAKF_PILN[i];
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bc[0] = st[j];
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st[j] = t.rotate_left(KECCAKF_ROTC[i]);
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t = bc[0];
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}
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// Chi
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for j in (0..st.len()).step_by(5) {
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for i in 0..bc.len() {
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bc[i] = st[j + i];
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}
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for i in 0..bc.len() {
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st[j + i] ^= (!bc[(i + 1) % 5]) & bc[(i + 2) % 5];
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}
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}
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// Iota
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debug_assert!(r < KECCAKF_RNDC.len());
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st[0] ^= KECCAKF_RNDC[r];
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}
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fn keccak_f800(header_hash: H256, nonce: u64, result: [u32; 8], st: &mut [u32; 25]) {
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for i in 0..8 {
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st[i] = (header_hash[4 * i] as u32)
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+ ((header_hash[4 * i + 1] as u32) << 8)
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+ ((header_hash[4 * i + 2] as u32) << 16)
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+ ((header_hash[4 * i + 3] as u32) << 24);
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}
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st[8] = nonce as u32;
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st[9] = (nonce >> 32) as u32;
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for i in 0..8 {
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st[10 + i] = result[i];
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}
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for r in 0..22 {
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keccak_f800_round(st, r);
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}
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}
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pub fn keccak_f800_short(header_hash: H256, nonce: u64, result: [u32; 8]) -> u64 {
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let mut st = [0u32; 25];
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keccak_f800(header_hash, nonce, result, &mut st);
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(st[0].swap_bytes() as u64) << 32 | st[1].swap_bytes() as u64
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}
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pub fn keccak_f800_long(header_hash: H256, nonce: u64, result: [u32; 8]) -> H256 {
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let mut st = [0u32; 25];
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keccak_f800(header_hash, nonce, result, &mut st);
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// NOTE: transmute from `[u32; 8]` to `[u8; 32]`
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unsafe { std::mem::transmute([st[0], st[1], st[2], st[3], st[4], st[5], st[6], st[7]]) }
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}
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#[inline]
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fn fnv1a_hash(h: u32, d: u32) -> u32 {
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(h ^ d).wrapping_mul(FNV_PRIME)
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}
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#[derive(Clone)]
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struct Kiss99 {
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z: u32,
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w: u32,
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jsr: u32,
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jcong: u32,
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}
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impl Kiss99 {
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fn new(z: u32, w: u32, jsr: u32, jcong: u32) -> Kiss99 {
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Kiss99 { z, w, jsr, jcong }
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}
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#[inline]
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fn next_u32(&mut self) -> u32 {
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self.z = 36969u32
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.wrapping_mul(self.z & 65535)
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.wrapping_add(self.z >> 16);
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self.w = 18000u32
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.wrapping_mul(self.w & 65535)
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.wrapping_add(self.w >> 16);
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let mwc = (self.z << 16).wrapping_add(self.w);
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self.jsr ^= self.jsr << 17;
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self.jsr ^= self.jsr >> 13;
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self.jsr ^= self.jsr << 5;
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self.jcong = 69069u32.wrapping_mul(self.jcong).wrapping_add(1234567);
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(mwc ^ self.jcong).wrapping_add(self.jsr)
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}
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}
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fn fill_mix(seed: u64, lane_id: u32) -> [u32; PROGPOW_REGS] {
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// Use FNV to expand the per-warp seed to per-lane
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// Use KISS to expand the per-lane seed to fill mix
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let z = fnv1a_hash(FNV_HASH, seed as u32);
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let w = fnv1a_hash(z, (seed >> 32) as u32);
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let jsr = fnv1a_hash(w, lane_id);
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let jcong = fnv1a_hash(jsr, lane_id);
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let mut rnd = Kiss99::new(z, w, jsr, jcong);
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let mut mix = [0; PROGPOW_REGS];
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debug_assert_eq!(PROGPOW_REGS, 32);
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for i in 0..32 {
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mix[i] = rnd.next_u32();
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}
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mix
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}
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// Merge new data from b into the value in a. Assuming A has high entropy only
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// do ops that retain entropy even if B is low entropy (IE don't do A&B)
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fn merge(a: u32, b: u32, r: u32) -> u32 {
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match r % 4 {
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0 => a.wrapping_mul(33).wrapping_add(b),
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1 => (a ^ b).wrapping_mul(33),
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2 => a.rotate_left(((r >> 16) % 31) + 1) ^ b,
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_ => a.rotate_right(((r >> 16) % 31) + 1) ^ b,
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}
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}
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fn math(a: u32, b: u32, r: u32) -> u32 {
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match r % 11 {
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0 => a.wrapping_add(b),
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1 => a.wrapping_mul(b),
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2 => ((a as u64).wrapping_mul(b as u64) >> 32) as u32,
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3 => a.min(b),
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4 => a.rotate_left(b),
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5 => a.rotate_right(b),
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6 => a & b,
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7 => a | b,
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8 => a ^ b,
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9 => a.leading_zeros() + b.leading_zeros(),
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_ => a.count_ones() + b.count_ones(),
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}
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}
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fn progpow_init(seed: u64) -> (Kiss99, [u32; PROGPOW_REGS], [u32; PROGPOW_REGS]) {
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let z = fnv1a_hash(FNV_HASH, seed as u32);
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let w = fnv1a_hash(z, (seed >> 32) as u32);
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let jsr = fnv1a_hash(w, seed as u32);
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let jcong = fnv1a_hash(jsr, (seed >> 32) as u32);
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let mut rnd = Kiss99::new(z, w, jsr, jcong);
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// Create a random sequence of mix destinations for merge() and mix sources
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// for cache reads guarantees every destination merged once and guarantees
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// no duplicate cache reads, which could be optimized away. Uses
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// Fisher-Yates shuffle.
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let mut mix_seq_dst = [0u32; PROGPOW_REGS];
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let mut mix_seq_cache = [0u32; PROGPOW_REGS];
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for i in 0..mix_seq_dst.len() {
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mix_seq_dst[i] = i as u32;
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mix_seq_cache[i] = i as u32;
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}
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for i in (1..mix_seq_dst.len()).rev() {
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let j = rnd.next_u32() as usize % (i + 1);
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mix_seq_dst.swap(i, j);
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let j = rnd.next_u32() as usize % (i + 1);
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mix_seq_cache.swap(i, j);
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}
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(rnd, mix_seq_dst, mix_seq_cache)
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}
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pub type CDag = [u32; PROGPOW_CACHE_WORDS];
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fn progpow_loop(
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seed: u64,
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loop_: usize,
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mix: &mut [[u32; PROGPOW_REGS]; PROGPOW_LANES],
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cache: &[Node],
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c_dag: &CDag,
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data_size: usize,
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) {
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// All lanes share a base address for the global load. Global offset uses
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// mix[0] to guarantee it depends on the load result.
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let g_offset = mix[loop_ % PROGPOW_LANES][0] as usize
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% (64 * data_size / (PROGPOW_LANES * PROGPOW_DAG_LOADS));
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// 256 bytes of dag data
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let mut dag_item = [0u32; 64];
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// Fetch DAG nodes (64 bytes each)
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for l in 0..PROGPOW_DAG_LOADS {
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let index = g_offset * PROGPOW_LANES * PROGPOW_DAG_LOADS + l * 16;
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let node = calculate_dag_item(index as u32 / 16, cache);
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dag_item[l * 16..(l + 1) * 16].clone_from_slice(node.as_words());
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}
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let (rnd, mix_seq_dst, mix_seq_cache) = progpow_init(seed);
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// Lanes can execute in parallel and will be convergent
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for l in 0..mix.len() {
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let mut rnd = rnd.clone();
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// Initialize the seed and mix destination sequence
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let mut mix_seq_dst_cnt = 0;
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let mut mix_seq_cache_cnt = 0;
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let mut mix_dst = || {
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let res = mix_seq_dst[mix_seq_dst_cnt % PROGPOW_REGS] as usize;
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mix_seq_dst_cnt += 1;
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res
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};
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let mut mix_cache = || {
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let res = mix_seq_cache[mix_seq_cache_cnt % PROGPOW_REGS] as usize;
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mix_seq_cache_cnt += 1;
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res
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};
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for i in 0..PROGPOW_CNT_CACHE.max(PROGPOW_CNT_MATH) {
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if i < PROGPOW_CNT_CACHE {
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// Cached memory access, lanes access random 32-bit locations
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// within the first portion of the DAG
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let offset = mix[l][mix_cache()] as usize % PROGPOW_CACHE_WORDS;
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let data = c_dag[offset];
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let dst = mix_dst();
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mix[l][dst] = merge(mix[l][dst], data, rnd.next_u32());
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}
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if i < PROGPOW_CNT_MATH {
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// Random math
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// Generate 2 unique sources
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let src_rnd = rnd.next_u32() % (PROGPOW_REGS * (PROGPOW_REGS - 1)) as u32;
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let src1 = src_rnd % PROGPOW_REGS as u32; // 0 <= src1 < PROGPOW_REGS
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let mut src2 = src_rnd / PROGPOW_REGS as u32; // 0 <= src2 < PROGPOW_REGS - 1
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if src2 >= src1 {
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src2 += 1; // src2 is now any reg other than src1
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}
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let data = math(mix[l][src1 as usize], mix[l][src2 as usize], rnd.next_u32());
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let dst = mix_dst();
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mix[l][dst] = merge(mix[l][dst], data, rnd.next_u32());
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}
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}
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// Global load to sequential locations
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let mut data_g = [0u32; PROGPOW_DAG_LOADS];
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let index = ((l ^ loop_) % PROGPOW_LANES) * PROGPOW_DAG_LOADS;
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for i in 0..PROGPOW_DAG_LOADS {
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data_g[i] = dag_item[index + i];
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}
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// Consume the global load data at the very end of the loop to allow
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// full latency hiding. Always merge into `mix[0]` to feed the offset
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// calculation.
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mix[l][0] = merge(mix[l][0], data_g[0], rnd.next_u32());
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for i in 1..PROGPOW_DAG_LOADS {
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let dst = mix_dst();
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mix[l][dst] = merge(mix[l][dst], data_g[i], rnd.next_u32());
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}
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}
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}
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pub fn progpow(
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header_hash: H256,
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nonce: u64,
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block_number: u64,
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cache: &[Node],
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c_dag: &CDag,
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) -> (H256, H256) {
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let mut mix = [[0u32; PROGPOW_REGS]; PROGPOW_LANES];
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let mut lane_results = [0u32; PROGPOW_LANES];
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let mut result = [0u32; 8];
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let data_size = get_data_size(block_number) / PROGPOW_MIX_BYTES;
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// NOTE: This assert is required to aid the optimizer elide the non-zero
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// remainder check in `progpow_loop`.
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assert!(data_size > 0);
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// Initialize mix for all lanes
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let seed = keccak_f800_short(header_hash, nonce, result);
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for l in 0..mix.len() {
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mix[l] = fill_mix(seed, l as u32);
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}
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// Execute the randomly generated inner loop
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let period = block_number / PROGPOW_PERIOD_LENGTH as u64;
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for i in 0..PROGPOW_CNT_DAG {
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progpow_loop(period, i, &mut mix, cache, c_dag, data_size);
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}
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// Reduce mix data to a single per-lane result
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for l in 0..lane_results.len() {
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lane_results[l] = FNV_HASH;
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for i in 0..PROGPOW_REGS {
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lane_results[l] = fnv1a_hash(lane_results[l], mix[l][i]);
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}
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}
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// Reduce all lanes to a single 128-bit result
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result = [FNV_HASH; 8];
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for l in 0..PROGPOW_LANES {
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result[l % 8] = fnv1a_hash(result[l % 8], lane_results[l]);
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}
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let digest = keccak_f800_long(header_hash, seed, result);
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// NOTE: transmute from `[u32; 8]` to `[u8; 32]`
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let result = unsafe { ::std::mem::transmute(result) };
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(digest, result)
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}
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pub fn generate_cdag(cache: &[Node]) -> CDag {
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let mut c_dag = [0u32; PROGPOW_CACHE_WORDS];
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for i in 0..PROGPOW_CACHE_WORDS / 16 {
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let node = calculate_dag_item(i as u32, cache);
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for j in 0..16 {
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c_dag[i * 16 + j] = node.as_words()[j];
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}
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}
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c_dag
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}
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#[cfg(test)]
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mod test {
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use tempdir::TempDir;
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use super::*;
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use cache::{NodeCacheBuilder, OptimizeFor};
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use keccak::H256;
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use rustc_hex::FromHex;
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use serde_json::{self, Value};
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use std::collections::VecDeque;
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fn h256(hex: &str) -> H256 {
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let bytes = FromHex::from_hex(hex).unwrap();
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let mut res = [0; 32];
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res.copy_from_slice(&bytes);
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res
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}
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#[test]
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fn test_cdag() {
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let builder = NodeCacheBuilder::new(OptimizeFor::Memory, u64::max_value());
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let tempdir = TempDir::new("").unwrap();
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let cache = builder.new_cache(tempdir.into_path(), 0);
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let c_dag = generate_cdag(cache.as_ref());
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let expected = vec![
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690150178u32,
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1181503948,
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2248155602,
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2118233073,
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2193871115,
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1791778428,
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1067701239,
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724807309,
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530799275,
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3480325829,
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3899029234,
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1998124059,
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2541974622,
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1100859971,
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1297211151,
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3268320000,
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2217813733,
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2690422980,
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3172863319,
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2651064309,
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];
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assert_eq!(c_dag.iter().take(20).cloned().collect::<Vec<_>>(), expected,);
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}
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#[test]
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fn test_random_merge() {
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let tests = [
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(1000000u32, 101u32, 33000101u32),
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(2000000, 102, 66003366),
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(3000000, 103, 6000103),
|
|
(4000000, 104, 2000104),
|
|
(1000000, 0, 33000000),
|
|
(2000000, 0, 66000000),
|
|
(3000000, 0, 6000000),
|
|
(4000000, 0, 2000000),
|
|
];
|
|
|
|
for (i, &(a, b, expected)) in tests.iter().enumerate() {
|
|
assert_eq!(merge(a, b, i as u32), expected,);
|
|
}
|
|
}
|
|
|
|
#[test]
|
|
fn test_random_math() {
|
|
let tests = [
|
|
(20u32, 22u32, 42u32),
|
|
(70000, 80000, 1305032704),
|
|
(70000, 80000, 1),
|
|
(1, 2, 1),
|
|
(3, 10000, 196608),
|
|
(3, 0, 3),
|
|
(3, 6, 2),
|
|
(3, 6, 7),
|
|
(3, 6, 5),
|
|
(0, 0xffffffff, 32),
|
|
(3 << 13, 1 << 5, 3),
|
|
(22, 20, 42),
|
|
(80000, 70000, 1305032704),
|
|
(80000, 70000, 1),
|
|
(2, 1, 1),
|
|
(10000, 3, 80000),
|
|
(0, 3, 0),
|
|
(6, 3, 2),
|
|
(6, 3, 7),
|
|
(6, 3, 5),
|
|
(0, 0xffffffff, 32),
|
|
(3 << 13, 1 << 5, 3),
|
|
];
|
|
|
|
for (i, &(a, b, expected)) in tests.iter().enumerate() {
|
|
assert_eq!(math(a, b, i as u32), expected,);
|
|
}
|
|
}
|
|
|
|
#[test]
|
|
fn test_keccak_256() {
|
|
let expected = "5dd431e5fbc604f499bfa0232f45f8f142d0ff5178f539e5a7800bf0643697af";
|
|
assert_eq!(keccak_f800_long([0; 32], 0, [0; 8]), h256(expected),);
|
|
}
|
|
|
|
#[test]
|
|
fn test_keccak_64() {
|
|
let expected: u64 = 0x5dd431e5fbc604f4;
|
|
assert_eq!(keccak_f800_short([0; 32], 0, [0; 8]), expected,);
|
|
}
|
|
|
|
#[test]
|
|
fn test_progpow_hash() {
|
|
let builder = NodeCacheBuilder::new(OptimizeFor::Memory, u64::max_value());
|
|
let tempdir = TempDir::new("").unwrap();
|
|
let cache = builder.new_cache(tempdir.into_path(), 0);
|
|
let c_dag = generate_cdag(cache.as_ref());
|
|
|
|
let header_hash = [0; 32];
|
|
|
|
let (digest, result) = progpow(header_hash, 0, 0, cache.as_ref(), &c_dag);
|
|
|
|
let expected_digest =
|
|
FromHex::from_hex("63155f732f2bf556967f906155b510c917e48e99685ead76ea83f4eca03ab12b")
|
|
.unwrap();
|
|
let expected_result =
|
|
FromHex::from_hex("faeb1be51075b03a4ff44b335067951ead07a3b078539ace76fd56fc410557a3")
|
|
.unwrap();
|
|
|
|
assert_eq!(digest.to_vec(), expected_digest,);
|
|
|
|
assert_eq!(result.to_vec(), expected_result,);
|
|
}
|
|
|
|
#[test]
|
|
fn test_progpow_testvectors() {
|
|
struct ProgpowTest {
|
|
block_number: u64,
|
|
header_hash: H256,
|
|
nonce: u64,
|
|
mix_hash: H256,
|
|
final_hash: H256,
|
|
}
|
|
|
|
let tests: Vec<VecDeque<Value>> =
|
|
serde_json::from_slice(include_bytes!("../res/progpow_testvectors.json")).unwrap();
|
|
|
|
let tests: Vec<ProgpowTest> = tests
|
|
.into_iter()
|
|
.map(|mut test: VecDeque<Value>| {
|
|
assert!(test.len() == 5);
|
|
|
|
let block_number: u64 = serde_json::from_value(test.pop_front().unwrap()).unwrap();
|
|
let header_hash: String =
|
|
serde_json::from_value(test.pop_front().unwrap()).unwrap();
|
|
let nonce: String = serde_json::from_value(test.pop_front().unwrap()).unwrap();
|
|
let mix_hash: String = serde_json::from_value(test.pop_front().unwrap()).unwrap();
|
|
let final_hash: String = serde_json::from_value(test.pop_front().unwrap()).unwrap();
|
|
|
|
ProgpowTest {
|
|
block_number,
|
|
header_hash: h256(&header_hash),
|
|
nonce: u64::from_str_radix(&nonce, 16).unwrap(),
|
|
mix_hash: h256(&mix_hash),
|
|
final_hash: h256(&final_hash),
|
|
}
|
|
})
|
|
.collect();
|
|
|
|
for test in tests {
|
|
let builder = NodeCacheBuilder::new(OptimizeFor::Memory, u64::max_value());
|
|
let tempdir = TempDir::new("").unwrap();
|
|
let cache = builder.new_cache(tempdir.path().to_owned(), test.block_number);
|
|
let c_dag = generate_cdag(cache.as_ref());
|
|
|
|
let (digest, result) = progpow(
|
|
test.header_hash,
|
|
test.nonce,
|
|
test.block_number,
|
|
cache.as_ref(),
|
|
&c_dag,
|
|
);
|
|
|
|
assert_eq!(digest, test.final_hash);
|
|
assert_eq!(result, test.mix_hash);
|
|
}
|
|
}
|
|
}
|