// Copyright 2020 The Grin Developers
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! core consensus mainnet tests (separated to de-clutter consensus_mainnet)
//! Setting global::mining_mode() changes global shared state so automated tests should only use one
//! mining mode/chain type per test file to avoid non-deterministic behaviour.
use grin_core as core;
use self::core::consensus::*;
use self::core::core::block::HeaderVersion;
use self::core::global;
use self::core::pow::Difficulty;
use chrono::prelude::Utc;
use std::fmt::{self, Display};
/// Last n blocks for difficulty calculation purposes
/// (copied from stats in server crate)
#[derive(Clone, Debug)]
pub struct DiffBlock {
/// Block number (can be negative for a new chain)
pub block_number: i64,
/// Block network difficulty
pub difficulty: u64,
/// Time block was found (epoch seconds)
pub time: u64,
/// Duration since previous block (epoch seconds)
pub duration: u64,
}
/// Stats on the last WINDOW blocks and the difficulty calculation
/// (Copied from stats in server crate)
#[derive(Clone)]
pub struct DiffStats {
/// latest height
pub height: u64,
/// Last WINDOW block data
pub last_blocks: Vec<DiffBlock>,
/// Average block time for last WINDOW blocks
pub average_block_time: u64,
/// Average WINDOW difficulty
pub average_difficulty: u64,
/// WINDOW size
pub window_size: u64,
/// Block time sum
pub block_time_sum: u64,
/// Block diff sum
pub block_diff_sum: u64,
/// latest ts
pub latest_ts: u64,
/// earliest ts
pub earliest_ts: u64,
/// ts delta
pub ts_delta: u64,
}
impl Display for DiffBlock {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let output = format!(
"Block Number: {} Difficulty: {}, Time: {}, Duration: {}",
self.block_number, self.difficulty, self.time, self.duration
);
Display::fmt(&output, f)
}
}
// Creates a new chain with a genesis at a simulated difficulty
fn create_chain_sim(diff: u64) -> Vec<(HeaderInfo, DiffStats)> {
println!(
"adding create: {}, {}",
Utc::now().timestamp(),
Difficulty::from_num(diff)
);
let return_vec = vec![HeaderInfo::from_ts_diff(
Utc::now().timestamp() as u64,
Difficulty::from_num(diff),
)];
let diff_stats = get_diff_stats(&return_vec);
vec![(
HeaderInfo::from_ts_diff(Utc::now().timestamp() as u64, Difficulty::from_num(diff)),
diff_stats,
)]
}
fn get_diff_stats(chain_sim: &[HeaderInfo]) -> DiffStats {
// Fill out some difficulty stats for convenience
let diff_iter = chain_sim.to_vec();
let last_blocks: Vec<HeaderInfo> = global::difficulty_data_to_vector(diff_iter.iter().cloned());
let mut last_time = last_blocks[0].timestamp;
let tip_height = chain_sim.len();
let earliest_block_height = tip_height as i64 - last_blocks.len() as i64;
let earliest_ts = last_blocks[0].timestamp;
let latest_ts = last_blocks[last_blocks.len() - 1].timestamp;
let mut i = 1;
let sum_blocks: Vec<HeaderInfo> = global::difficulty_data_to_vector(diff_iter.iter().cloned())
.into_iter()
.take(DMA_WINDOW as usize)
.collect();
let sum_entries: Vec<DiffBlock> = sum_blocks
.iter()
//.skip(1)
.map(|n| {
let dur = n.timestamp - last_time;
let height = earliest_block_height + i + 1;
i += 1;
last_time = n.timestamp;
DiffBlock {
block_number: height,
difficulty: n.difficulty.to_num(),
time: n.timestamp,
duration: dur,
}
})
.collect();
let block_time_sum = sum_entries.iter().fold(0, |sum, t| sum + t.duration);
let block_diff_sum = sum_entries.iter().fold(0, |sum, d| sum + d.difficulty);
i = 1;
last_time = last_blocks[0].clone().timestamp;
let diff_entries: Vec<DiffBlock> = last_blocks
.iter()
.skip(1)
.map(|n| {
let dur = n.timestamp - last_time;
let height = earliest_block_height + i;
i += 1;
last_time = n.timestamp;
DiffBlock {
block_number: height,
difficulty: n.difficulty.to_num(),
time: n.timestamp,
duration: dur,
}
})
.collect();
DiffStats {
height: tip_height as u64,
last_blocks: diff_entries,
average_block_time: block_time_sum / DMA_WINDOW,
average_difficulty: block_diff_sum / DMA_WINDOW,
window_size: DMA_WINDOW,
block_time_sum: block_time_sum,
block_diff_sum: block_diff_sum,
latest_ts: latest_ts,
earliest_ts: earliest_ts,
ts_delta: latest_ts - earliest_ts,
}
}
// Adds another 'block' to the iterator, so to speak, with difficulty calculated
// from the difficulty adjustment at interval seconds from the previous block
fn add_block(
interval: u64,
chain_sim: Vec<(HeaderInfo, DiffStats)>,
) -> Vec<(HeaderInfo, DiffStats)> {
let mut ret_chain_sim = chain_sim.clone();
let mut return_chain: Vec<HeaderInfo> = chain_sim.clone().iter().map(|e| e.0.clone()).collect();
// get last interval
let diff = next_difficulty(1, return_chain.clone());
let last_elem = chain_sim.first().unwrap().clone().0;
let time = last_elem.timestamp + interval;
return_chain.insert(0, HeaderInfo::from_ts_diff(time, diff.difficulty));
let diff_stats = get_diff_stats(&return_chain);
ret_chain_sim.insert(
0,
(HeaderInfo::from_ts_diff(time, diff.difficulty), diff_stats),
);
ret_chain_sim
}
// Adds another n 'blocks' to the iterator, with difficulty calculated
fn add_block_repeated(
interval: u64,
chain_sim: Vec<(HeaderInfo, DiffStats)>,
iterations: usize,
) -> Vec<(HeaderInfo, DiffStats)> {
let mut return_chain = chain_sim;
for _ in 0..iterations {
return_chain = add_block(interval, return_chain.clone());
}
return_chain
}
// Prints the contents of the iterator and its difficulties.. useful for
// tweaking
fn print_chain_sim(chain_sim: Vec<(HeaderInfo, DiffStats)>) {
let mut chain_sim = chain_sim;
chain_sim.reverse();
let mut last_time = 0;
let mut first = true;
println!("Constants");
println!("DIFFICULTY_ADJUST_WINDOW: {}", DMA_WINDOW);
println!("BLOCK_TIME_WINDOW: {}", BLOCK_TIME_WINDOW);
println!("CLAMP_FACTOR: {}", CLAMP_FACTOR);
println!("DAMP_FACTOR: {}", DMA_DAMP_FACTOR);
chain_sim.iter().enumerate().for_each(|(i, b)| {
let block = b.0.clone();
let stats = b.1.clone();
if first {
last_time = block.timestamp;
first = false;
}
println!(
"Height: {}, Time: {}, Interval: {}, Network difficulty:{}, Average Block Time: {}, Average Difficulty {}, Block Time Sum: {}, Block Diff Sum: {}, Latest Timestamp: {}, Earliest Timestamp: {}, Timestamp Delta: {}",
i,
block.timestamp,
block.timestamp - last_time,
block.difficulty,
stats.average_block_time,
stats.average_difficulty,
stats.block_time_sum,
stats.block_diff_sum,
stats.latest_ts,
stats.earliest_ts,
stats.ts_delta,
);
let mut sb = stats.last_blocks;
sb.reverse();
for i in sb {
println!(" {}", i);
}
last_time = block.timestamp;
});
}
/// Checks different next_target adjustments and difficulty boundaries
#[test]
fn adjustment_scenarios() {
global::set_local_chain_type(global::ChainTypes::Mainnet);
// Genesis block with initial diff
let chain_sim = create_chain_sim(global::initial_block_difficulty());
// Scenario 1) Hash power is massively over estimated, first block takes an hour
let chain_sim = add_block_repeated(3600, chain_sim, 2);
let chain_sim = add_block_repeated(1800, chain_sim, 2);
let chain_sim = add_block_repeated(900, chain_sim, 10);
let chain_sim = add_block_repeated(450, chain_sim, 30);
let chain_sim = add_block_repeated(400, chain_sim, 30);
let chain_sim = add_block_repeated(300, chain_sim, 30);
println!("*********************************************************");
println!("Scenario 1) Grossly over-estimated genesis difficulty ");
println!("*********************************************************");
print_chain_sim(chain_sim);
println!("*********************************************************");
// Under-estimated difficulty
let chain_sim = create_chain_sim(global::initial_block_difficulty());
let chain_sim = add_block_repeated(1, chain_sim, 5);
let chain_sim = add_block_repeated(20, chain_sim, 5);
let chain_sim = add_block_repeated(30, chain_sim, 20);
println!("*********************************************************");
println!("Scenario 2) Grossly under-estimated genesis difficulty ");
println!("*********************************************************");
print_chain_sim(chain_sim);
println!("*********************************************************");
let just_enough = DMA_WINDOW as usize;
// Steady difficulty for a good while, then a sudden drop
let chain_sim = create_chain_sim(global::initial_block_difficulty());
let chain_sim = add_block_repeated(60, chain_sim, just_enough as usize);
let chain_sim = add_block_repeated(600, chain_sim, 60);
println!();
println!("*********************************************************");
println!("Scenario 3) Sudden drop in hashpower");
println!("*********************************************************");
print_chain_sim(chain_sim);
println!("*********************************************************");
// Sudden increase
let chain_sim = create_chain_sim(global::initial_block_difficulty());
let chain_sim = add_block_repeated(60, chain_sim, just_enough as usize);
let chain_sim = add_block_repeated(10, chain_sim, 10);
println!();
println!("*********************************************************");
println!("Scenario 4) Sudden increase in hashpower");
println!("*********************************************************");
print_chain_sim(chain_sim);
println!("*********************************************************");
// Oscillations
let chain_sim = create_chain_sim(global::initial_block_difficulty());
let chain_sim = add_block_repeated(60, chain_sim, just_enough as usize);
let chain_sim = add_block_repeated(10, chain_sim, 10);
let chain_sim = add_block_repeated(60, chain_sim, 20);
let chain_sim = add_block_repeated(10, chain_sim, 10);
println!();
println!("*********************************************************");
println!("Scenario 5) Oscillations in hashpower");
println!("*********************************************************");
print_chain_sim(chain_sim);
println!("*********************************************************");
}
#[test]
fn test_secondary_pow_ratio() {
global::set_local_chain_type(global::ChainTypes::Mainnet);
assert_eq!(secondary_pow_ratio(1), 90);
assert_eq!(secondary_pow_ratio(89), 90);
assert_eq!(secondary_pow_ratio(90), 90);
assert_eq!(secondary_pow_ratio(91), 90);
assert_eq!(secondary_pow_ratio(179), 90);
assert_eq!(secondary_pow_ratio(180), 90);
assert_eq!(secondary_pow_ratio(181), 90);
let one_week = 60 * 24 * 7;
assert_eq!(secondary_pow_ratio(one_week - 1), 90);
assert_eq!(secondary_pow_ratio(one_week), 90);
assert_eq!(secondary_pow_ratio(one_week + 1), 90);
let two_weeks = one_week * 2;
assert_eq!(secondary_pow_ratio(two_weeks - 1), 89);
assert_eq!(secondary_pow_ratio(two_weeks), 89);
assert_eq!(secondary_pow_ratio(two_weeks + 1), 89);
let t4_fork_height = 64_000;
assert_eq!(secondary_pow_ratio(t4_fork_height - 1), 85);
assert_eq!(secondary_pow_ratio(t4_fork_height), 85);
assert_eq!(secondary_pow_ratio(t4_fork_height + 1), 85);
let one_year = one_week * 52;
assert_eq!(secondary_pow_ratio(one_year), 45);
let ninety_one_weeks = one_week * 91;
assert_eq!(secondary_pow_ratio(ninety_one_weeks - 1), 12);
assert_eq!(secondary_pow_ratio(ninety_one_weeks), 12);
assert_eq!(secondary_pow_ratio(ninety_one_weeks + 1), 12);
let two_year = one_year * 2;
assert_eq!(secondary_pow_ratio(two_year - 1), 1);
assert_eq!(secondary_pow_ratio(two_year), 0);
assert_eq!(secondary_pow_ratio(two_year + 1), 0);
}
#[test]
fn test_secondary_pow_scale() {
global::set_local_chain_type(global::ChainTypes::Mainnet);
let window = DMA_WINDOW;
let mut hi = HeaderInfo::from_diff_scaling(Difficulty::from_num(10), 100);
// all primary, factor should increase so it becomes easier to find a high
// difficulty block
hi.is_secondary = false;
assert_eq!(
secondary_pow_scaling(1, &(0..window).map(|_| hi.clone()).collect::<Vec<_>>()),
108
);
// all secondary on 90%, factor should go down a bit
hi.is_secondary = true;
assert_eq!(
secondary_pow_scaling(1, &(0..window).map(|_| hi.clone()).collect::<Vec<_>>()),
99
);
// all secondary on 1%, factor should go down to bound (divide by 2)
assert_eq!(
secondary_pow_scaling(
2 * YEAR_HEIGHT * 83 / 90,
&(0..window).map(|_| hi.clone()).collect::<Vec<_>>()
),
50
);
// same as above, testing lowest bound
let mut low_hi = HeaderInfo::from_diff_scaling(Difficulty::from_num(10), MIN_AR_SCALE as u32);
low_hi.is_secondary = true;
assert_eq!(
secondary_pow_scaling(
2 * YEAR_HEIGHT,
&(0..window).map(|_| low_hi.clone()).collect::<Vec<_>>()
),
MIN_AR_SCALE as u32
);
// the right ratio of 95% secondary
let mut primary_hi = HeaderInfo::from_diff_scaling(Difficulty::from_num(10), 50);
primary_hi.is_secondary = false;
assert_eq!(
secondary_pow_scaling(
1,
&(0..(window / 10))
.map(|_| primary_hi.clone())
.chain((0..(window * 9 / 10)).map(|_| hi.clone()))
.collect::<Vec<_>>()
),
95, // avg ar_scale of 10% * 50 + 90% * 100
);
// 95% secondary, should come down based on 97.5 average
assert_eq!(
secondary_pow_scaling(
1,
&(0..(window / 20))
.map(|_| primary_hi.clone())
.chain((0..(window * 95 / 100)).map(|_| hi.clone()))
.collect::<Vec<_>>()
),
97
);
// 40% secondary, should come up based on 70 average
assert_eq!(
secondary_pow_scaling(
1,
&(0..(window * 6 / 10))
.map(|_| primary_hi.clone())
.chain((0..(window * 4 / 10)).map(|_| hi.clone()))
.collect::<Vec<_>>()
),
73
);
}
#[test]
fn hard_forks() {
global::set_local_chain_type(global::ChainTypes::Mainnet);
assert_eq!(header_version(0), HeaderVersion(1));
assert_eq!(header_version(10), HeaderVersion(1));
assert_eq!(header_version(HARD_FORK_INTERVAL - 1), HeaderVersion(1));
assert_eq!(header_version(HARD_FORK_INTERVAL), HeaderVersion(2));
assert_eq!(header_version(HARD_FORK_INTERVAL + 1), HeaderVersion(2));
assert_eq!(header_version(HARD_FORK_INTERVAL * 2 - 1), HeaderVersion(2));
assert_eq!(header_version(HARD_FORK_INTERVAL * 2), HeaderVersion(3));
assert_eq!(header_version(HARD_FORK_INTERVAL * 2 + 1), HeaderVersion(3));
assert_eq!(header_version(HARD_FORK_INTERVAL * 3 - 1), HeaderVersion(3));
assert_eq!(header_version(HARD_FORK_INTERVAL * 3), HeaderVersion(4));
assert_eq!(header_version(HARD_FORK_INTERVAL * 3 + 1), HeaderVersion(4));
assert_eq!(header_version(HARD_FORK_INTERVAL * 4 - 1), HeaderVersion(4));
assert_eq!(header_version(HARD_FORK_INTERVAL * 4), HeaderVersion(5));
assert_eq!(header_version(HARD_FORK_INTERVAL * 4 + 1), HeaderVersion(5));
}