// Copyright 2018 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.
extern crate env_logger;
extern crate grin_chain as chain;
extern crate grin_core as core;
extern crate grin_keychain as keychain;
extern crate grin_util as util;
extern crate grin_wallet as wallet;
extern crate rand;
extern crate time;
use std::fs;
use std::sync::Arc;
use chain::types::NoopAdapter;
use chain::Chain;
use core::core::hash::Hashed;
use core::core::target::Difficulty;
use core::core::{Block, BlockHeader, OutputFeatures, OutputIdentifier, Transaction};
use core::global::ChainTypes;
use core::{consensus, global, pow};
use keychain::{ExtKeychain, Keychain};
use wallet::libtx::{self, build};
fn clean_output_dir(dir_name: &str) {
let _ = fs::remove_dir_all(dir_name);
}
fn setup(dir_name: &str) -> Chain {
let _ = env_logger::init();
clean_output_dir(dir_name);
global::set_mining_mode(ChainTypes::AutomatedTesting);
let genesis_block = pow::mine_genesis_block().unwrap();
chain::Chain::init(
dir_name.to_string(),
Arc::new(NoopAdapter {}),
genesis_block,
pow::verify_size,
).unwrap()
}
#[test]
fn mine_empty_chain() {
let chain = setup(".grin");
let keychain = ExtKeychain::from_random_seed().unwrap();
for n in 1..4 {
let prev = chain.head_header().unwrap();
let difficulty = consensus::next_difficulty(chain.difficulty_iter()).unwrap();
let pk = keychain.derive_key_id(n as u32).unwrap();
let reward = libtx::reward::output(&keychain, &pk, 0, prev.height).unwrap();
let mut b = core::core::Block::new(&prev, vec![], difficulty.clone(), reward).unwrap();
b.header.timestamp = prev.timestamp + time::Duration::seconds(60);
chain.set_txhashset_roots(&mut b, false).unwrap();
pow::pow_size(
&mut b.header,
difficulty,
global::proofsize(),
global::sizeshift(),
).unwrap();
let bhash = b.hash();
chain.process_block(b, chain::Options::MINE).unwrap();
// checking our new head
let head = chain.head().unwrap();
assert_eq!(head.height, n);
assert_eq!(head.last_block_h, bhash);
// now check the block_header of the head
let header = chain.head_header().unwrap();
assert_eq!(header.height, n);
assert_eq!(header.hash(), bhash);
// now check the block itself
let block = chain.get_block(&header.hash()).unwrap();
assert_eq!(block.header.height, n);
assert_eq!(block.hash(), bhash);
assert_eq!(block.outputs.len(), 1);
// now check the block height index
let header_by_height = chain.get_header_by_height(n).unwrap();
assert_eq!(header_by_height.hash(), bhash);
chain.validate(false).unwrap();
}
}
#[test]
fn mine_forks() {
let chain = setup(".grin2");
let kc = ExtKeychain::from_random_seed().unwrap();
// add a first block to not fork genesis
let prev = chain.head_header().unwrap();
let b = prepare_block(&kc, &prev, &chain, 2);
chain.process_block(b, chain::Options::SKIP_POW).unwrap();
// mine and add a few blocks
for n in 1..4 {
// first block for one branch
let prev = chain.head_header().unwrap();
let b1 = prepare_block(&kc, &prev, &chain, 3 * n);
// 2nd block with higher difficulty for other branch
let b2 = prepare_block(&kc, &prev, &chain, 3 * n + 1);
// process the first block to extend the chain
let bhash = b1.hash();
chain.process_block(b1, chain::Options::SKIP_POW).unwrap();
// checking our new head
let head = chain.head().unwrap();
assert_eq!(head.height, (n + 1) as u64);
assert_eq!(head.last_block_h, bhash);
assert_eq!(head.prev_block_h, prev.hash());
// process the 2nd block to build a fork with more work
let bhash = b2.hash();
chain.process_block(b2, chain::Options::SKIP_POW).unwrap();
// checking head switch
let head = chain.head().unwrap();
assert_eq!(head.height, (n + 1) as u64);
assert_eq!(head.last_block_h, bhash);
assert_eq!(head.prev_block_h, prev.hash());
}
}
#[test]
fn mine_losing_fork() {
let kc = ExtKeychain::from_random_seed().unwrap();
let chain = setup(".grin3");
// add a first block we'll be forking from
let prev = chain.head_header().unwrap();
let b1 = prepare_block(&kc, &prev, &chain, 2);
let b1head = b1.header.clone();
chain.process_block(b1, chain::Options::SKIP_POW).unwrap();
// prepare the 2 successor, sibling blocks, one with lower diff
let b2 = prepare_block(&kc, &b1head, &chain, 4);
let b2head = b2.header.clone();
let bfork = prepare_block(&kc, &b1head, &chain, 3);
// add higher difficulty first, prepare its successor, then fork
// with lower diff
chain.process_block(b2, chain::Options::SKIP_POW).unwrap();
assert_eq!(chain.head_header().unwrap().hash(), b2head.hash());
let b3 = prepare_block(&kc, &b2head, &chain, 5);
chain
.process_block(bfork, chain::Options::SKIP_POW)
.unwrap();
// adding the successor
let b3head = b3.header.clone();
chain.process_block(b3, chain::Options::SKIP_POW).unwrap();
assert_eq!(chain.head_header().unwrap().hash(), b3head.hash());
}
#[test]
fn longer_fork() {
let kc = ExtKeychain::from_random_seed().unwrap();
// to make it easier to compute the txhashset roots in the test, we
// prepare 2 chains, the 2nd will be have the forked blocks we can
// then send back on the 1st
let chain = setup(".grin4");
let chain_fork = setup(".grin5");
// add blocks to both chains, 20 on the main one, only the first 5
// for the forked chain
let mut prev = chain.head_header().unwrap();
for n in 0..10 {
let b = prepare_block(&kc, &prev, &chain, 2 * n + 2);
let bh = b.header.clone();
if n < 5 {
let b_fork = b.clone();
chain_fork
.process_block(b_fork, chain::Options::SKIP_POW)
.unwrap();
}
chain.process_block(b, chain::Options::SKIP_POW).unwrap();
prev = bh;
}
// check both chains are in the expected state
let head = chain.head_header().unwrap();
assert_eq!(head.height, 10);
assert_eq!(head.hash(), prev.hash());
let head_fork = chain_fork.head_header().unwrap();
assert_eq!(head_fork.height, 5);
let mut prev_fork = head_fork.clone();
for n in 0..7 {
let b_fork = prepare_block(&kc, &prev_fork, &chain_fork, 2 * n + 11);
let bh_fork = b_fork.header.clone();
let b = b_fork.clone();
chain.process_block(b, chain::Options::SKIP_POW).unwrap();
chain_fork
.process_block(b_fork, chain::Options::SKIP_POW)
.unwrap();
prev_fork = bh_fork;
}
}
#[test]
fn spend_in_fork_and_compact() {
util::init_test_logger();
let chain = setup(".grin6");
let prev = chain.head_header().unwrap();
let kc = ExtKeychain::from_random_seed().unwrap();
let mut fork_head = prev;
// mine the first block and keep track of the block_hash
// so we can spend the coinbase later
let b = prepare_block(&kc, &fork_head, &chain, 2);
let block_hash = b.hash();
let out_id = OutputIdentifier::from_output(&b.outputs[0]);
assert!(out_id.features.contains(OutputFeatures::COINBASE_OUTPUT));
fork_head = b.header.clone();
chain
.process_block(b.clone(), chain::Options::SKIP_POW)
.unwrap();
let merkle_proof = chain.get_merkle_proof(&out_id, &b.header).unwrap();
// now mine three further blocks
for n in 3..6 {
let b = prepare_block(&kc, &fork_head, &chain, n);
fork_head = b.header.clone();
chain.process_block(b, chain::Options::SKIP_POW).unwrap();
}
// Check the height of the "fork block".
assert_eq!(fork_head.height, 4);
let tx1 = build::transaction(
vec![
build::coinbase_input(
consensus::REWARD,
block_hash,
merkle_proof,
kc.derive_key_id(2).unwrap(),
),
build::output(consensus::REWARD - 20000, kc.derive_key_id(30).unwrap()),
build::with_fee(20000),
],
&kc,
).unwrap();
let next = prepare_block_tx(&kc, &fork_head, &chain, 7, vec![&tx1]);
let prev_main = next.header.clone();
chain
.process_block(next.clone(), chain::Options::SKIP_POW)
.unwrap();
chain.validate(false).unwrap();
let tx2 = build::transaction(
vec![
build::input(consensus::REWARD - 20000, kc.derive_key_id(30).unwrap()),
build::output(consensus::REWARD - 40000, kc.derive_key_id(31).unwrap()),
build::with_fee(20000),
],
&kc,
).unwrap();
let next = prepare_block_tx(&kc, &prev_main, &chain, 9, vec![&tx2]);
let prev_main = next.header.clone();
chain.process_block(next, chain::Options::SKIP_POW).unwrap();
// Full chain validation for completeness.
chain.validate(false).unwrap();
// mine 2 forked blocks from the first
let fork = prepare_fork_block_tx(&kc, &fork_head, &chain, 6, vec![&tx1]);
let prev_fork = fork.header.clone();
chain.process_block(fork, chain::Options::SKIP_POW).unwrap();
let fork_next = prepare_fork_block_tx(&kc, &prev_fork, &chain, 8, vec![&tx2]);
let prev_fork = fork_next.header.clone();
chain
.process_block(fork_next, chain::Options::SKIP_POW)
.unwrap();
chain.validate(false).unwrap();
// check state
let head = chain.head_header().unwrap();
assert_eq!(head.height, 6);
assert_eq!(head.hash(), prev_main.hash());
assert!(
chain
.is_unspent(&OutputIdentifier::from_output(&tx2.outputs[0]))
.is_ok()
);
assert!(
chain
.is_unspent(&OutputIdentifier::from_output(&tx1.outputs[0]))
.is_err()
);
// make the fork win
let fork_next = prepare_fork_block(&kc, &prev_fork, &chain, 10);
let prev_fork = fork_next.header.clone();
chain
.process_block(fork_next, chain::Options::SKIP_POW)
.unwrap();
chain.validate(false).unwrap();
// check state
let head = chain.head_header().unwrap();
assert_eq!(head.height, 7);
assert_eq!(head.hash(), prev_fork.hash());
assert!(
chain
.is_unspent(&OutputIdentifier::from_output(&tx2.outputs[0]))
.is_ok()
);
assert!(
chain
.is_unspent(&OutputIdentifier::from_output(&tx1.outputs[0]))
.is_err()
);
// add 20 blocks to go past the test horizon
let mut prev = prev_fork;
for n in 0..20 {
let next = prepare_block(&kc, &prev, &chain, 11 + n);
prev = next.header.clone();
chain.process_block(next, chain::Options::SKIP_POW).unwrap();
}
chain.validate(false).unwrap();
chain.compact().unwrap();
chain.validate(false).unwrap();
}
fn prepare_block<K>(kc: &K, prev: &BlockHeader, chain: &Chain, diff: u64) -> Block
where
K: Keychain,
{
let mut b = prepare_block_nosum(kc, prev, diff, vec![]);
chain.set_txhashset_roots(&mut b, false).unwrap();
b
}
fn prepare_block_tx<K>(
kc: &K,
prev: &BlockHeader,
chain: &Chain,
diff: u64,
txs: Vec<&Transaction>,
) -> Block
where
K: Keychain,
{
let mut b = prepare_block_nosum(kc, prev, diff, txs);
chain.set_txhashset_roots(&mut b, false).unwrap();
b
}
fn prepare_fork_block<K>(kc: &K, prev: &BlockHeader, chain: &Chain, diff: u64) -> Block
where
K: Keychain,
{
let mut b = prepare_block_nosum(kc, prev, diff, vec![]);
chain.set_txhashset_roots(&mut b, true).unwrap();
b
}
fn prepare_fork_block_tx<K>(
kc: &K,
prev: &BlockHeader,
chain: &Chain,
diff: u64,
txs: Vec<&Transaction>,
) -> Block
where
K: Keychain,
{
let mut b = prepare_block_nosum(kc, prev, diff, txs);
chain.set_txhashset_roots(&mut b, true).unwrap();
b
}
fn prepare_block_nosum<K>(kc: &K, prev: &BlockHeader, diff: u64, txs: Vec<&Transaction>) -> Block
where
K: Keychain,
{
let proof_size = global::proofsize();
let key_id = kc.derive_key_id(diff as u32).unwrap();
let fees = txs.iter().map(|tx| tx.fee()).sum();
let reward = libtx::reward::output(kc, &key_id, fees, prev.height).unwrap();
let mut b = match core::core::Block::new(
prev,
txs.into_iter().cloned().collect(),
Difficulty::from_num(diff),
reward,
) {
Err(e) => panic!("{:?}", e),
Ok(b) => b,
};
b.header.timestamp = prev.timestamp + time::Duration::seconds(60);
b.header.total_difficulty = prev.total_difficulty.clone() + Difficulty::from_num(diff);
b.header.pow = core::core::Proof::random(proof_size);
b
}
#[test]
#[ignore]
fn actual_diff_iter_output() {
global::set_mining_mode(ChainTypes::AutomatedTesting);
let genesis_block = pow::mine_genesis_block().unwrap();
let chain = chain::Chain::init(
"../.grin".to_string(),
Arc::new(NoopAdapter {}),
genesis_block,
pow::verify_size,
).unwrap();
let iter = chain.difficulty_iter();
let mut last_time = 0;
let mut first = true;
for i in iter.into_iter() {
let elem = i.unwrap();
if first {
last_time = elem.0;
first = false;
}
println!(
"next_difficulty time: {}, diff: {}, duration: {} ",
elem.0,
elem.1.to_num(),
last_time - elem.0
);
last_time = elem.0;
}
}