grassrootseconomics
/
openethereum
5
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

Merge pull request #613 from ethcore/jdb_option1 

JournalDB option 1 fix
This commit is contained in:
Gav Wood 2016-03-07 09:38:50 +01:00
parent 7e9f13750f 4d1effb008
commit 318e7e9e04
4 changed files with 262 additions and 97 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

8
ethcore/src/client.rs
View File

@ -190,6 +190,8 @@ pub struct ClientReport {
pub transactions_applied: usize,
/// How much gas has been processed so far.
pub gas_processed: U256,
/// Memory used by state DB
pub state_db_mem: usize,
}
impl ClientReport {
@ -222,7 +224,7 @@ pub struct Client<V = CanonVerifier> where V: Verifier {
}
const HISTORY: u64 = 1000;
const CLIENT_DB_VER_STR: &'static str = "4.0";
const CLIENT_DB_VER_STR: &'static str = "5.1";
impl Client<CanonVerifier> {
/// Create a new client with given spec and DB path.
@ -432,7 +434,9 @@ impl<V> Client<V> where V: Verifier {
/// Get the report.
pub fn report(&self) -> ClientReport {
self.report.read().unwrap().clone()
let mut report = self.report.read().unwrap().clone();
report.state_db_mem = self.state_db.lock().unwrap().mem_used();
report
}
/// Tick the client.

3
parity/main.rs
View File

@ -395,7 +395,7 @@ impl Informant {
let sync_info = sync.status();
if let (_, _, &Some(ref last_report)) = (self.chain_info.read().unwrap().deref(), self.cache_info.read().unwrap().deref(), self.report.read().unwrap().deref()) {
println!("[ #{} {} ]---[ {} blk/s | {} tx/s | {} gas/s //··· {}/{} peers, #{}, {}+{} queued ···// mem: {} chain, {} queue, {} sync ]",
println!("[ #{} {} ]---[ {} blk/s | {} tx/s | {} gas/s //··· {}/{} peers, #{}, {}+{} queued ···// mem: {} db, {} chain, {} queue, {} sync ]",
chain_info.best_block_number,
chain_info.best_block_hash,
(report.blocks_imported - last_report.blocks_imported) / dur,
@ -408,6 +408,7 @@ impl Informant {
queue_info.unverified_queue_size,
queue_info.verified_queue_size,
Informant::format_bytes(report.state_db_mem),
Informant::format_bytes(cache_info.total()),
Informant::format_bytes(queue_info.mem_used),
Informant::format_bytes(sync_info.mem_used),

342
util/src/journaldb.rs
View File

@ -25,10 +25,7 @@ use kvdb::{Database, DBTransaction, DatabaseConfig};
use std::env;
/// Implementation of the HashDB trait for a disk-backed database with a memory overlay
/// and, possibly, latent-removal semantics.
///
/// If `counters` is `None`, then it behaves exactly like OverlayDB. If not it behaves
/// differently:
/// and latent-removal semantics.
///
/// Like OverlayDB, there is a memory overlay; `commit()` must be called in order to
/// write operations out to disk. Unlike OverlayDB, `remove()` operations do not take effect
@ -60,7 +57,6 @@ const DB_VERSION_NO_JOURNAL : u32 = 3 + 256;
const PADDING : [u8; 10] = [ 0u8; 10 ];
impl JournalDB {
/// Create a new instance from file
pub fn new(path: &str) -> JournalDB {
Self::from_prefs(path, true)
@ -149,6 +145,87 @@ impl JournalDB {
Ok(ret as u32)
}
fn morph_key(key: &H256, index: u8) -> Bytes {
let mut ret = key.bytes().to_owned();
ret.push(index);
ret
}
// The next three are valid only as long as there is an insert operation of `key` in the journal.
fn set_already_in(batch: &DBTransaction, key: &H256) { batch.put(&Self::morph_key(key, 0), &[1u8]).expect("Low-level database error. Some issue with your hard disk?"); }
fn reset_already_in(batch: &DBTransaction, key: &H256) { batch.delete(&Self::morph_key(key, 0)).expect("Low-level database error. Some issue with your hard disk?"); }
fn is_already_in(backing: &Database, key: &H256) -> bool {
backing.get(&Self::morph_key(key, 0)).expect("Low-level database error. Some issue with your hard disk?").is_some()
}
fn insert_keys(inserts: &Vec<(H256, Bytes)>, backing: &Database, counters: &mut HashMap<H256, i32>, batch: &DBTransaction) {
for &(ref h, ref d) in inserts {
if let Some(c) = counters.get_mut(h) {
// already counting. increment.
*c += 1;
continue;
}
// this is the first entry for this node in the journal.
if backing.get(&h.bytes()).expect("Low-level database error. Some issue with your hard disk?").is_some() {
// already in the backing DB. start counting, and remember it was already in.
Self::set_already_in(batch, &h);
counters.insert(h.clone(), 1);
continue;
}
// Gets removed when a key leaves the journal, so should never be set when we're placing a new key.
//Self::reset_already_in(&h);
assert!(!Self::is_already_in(backing, &h));
batch.put(&h.bytes(), d).expect("Low-level database error. Some issue with your hard disk?");
}
}
fn replay_keys(inserts: &Vec<H256>, backing: &Database, counters: &mut HashMap<H256, i32>) {
println!("replay_keys: inserts={:?}, counters={:?}", inserts, counters);
for h in inserts {
if let Some(c) = counters.get_mut(h) {
// already counting. increment.
*c += 1;
continue;
}
// this is the first entry for this node in the journal.
// it is initialised to 1 if it was already in.
if Self::is_already_in(backing, h) {
println!("replace_keys: Key {} was already in!", h);
counters.insert(h.clone(), 1);
}
}
println!("replay_keys: (end) counters={:?}", counters);
}
fn kill_keys(deletes: Vec<H256>, counters: &mut HashMap<H256, i32>, batch: &DBTransaction) {
for h in deletes.into_iter() {
let mut n: Option<i32> = None;
if let Some(c) = counters.get_mut(&h) {
if *c > 1 {
*c -= 1;
continue;
} else {
n = Some(*c);
}
}
match &n {
&Some(i) if i == 1 => {
counters.remove(&h);
Self::reset_already_in(batch, &h);
}
&None => {
// Gets removed when moving from 1 to 0 additional refs. Should never be here at 0 additional refs.
//assert!(!Self::is_already_in(db, &h));
batch.delete(&h.bytes()).expect("Low-level database error. Some issue with your hard disk?");
}
_ => panic!("Invalid value in counters: {:?}", n),
}
}
}
/// Commit all recent insert operations and historical removals from the old era
/// to the backing database.
fn commit_with_counters(&mut self, now: u64, id: &H256, end: Option<(u64, H256)>) -> Result<u32, UtilError> {
@ -159,60 +236,85 @@ impl JournalDB {
// TODO: store reclaim_period.
// when we make a new commit, we journal the inserts and removes.
// for each end_era that we journaled that we are no passing by,
// we remove all of its removes assuming it is canonical and all
// of its inserts otherwise.
// When we make a new commit, we make a journal of all blocks in the recent history and record
// all keys that were inserted and deleted. The journal is ordered by era; multiple commits can
// share the same era. This forms a data structure similar to a queue but whose items are tuples.
// By the time comes to remove a tuple from the queue (i.e. then the era passes from recent history
// into ancient history) then only one commit from the tuple is considered canonical. This commit
// is kept in the main backing database, whereas any others from the same era are reverted.
//
// It is possible that a key, properly available in the backing database be deleted and re-inserted
// in the recent history queue, yet have both operations in commits that are eventually non-canonical.
// To avoid the original, and still required, key from being deleted, we maintain a reference count
// which includes an original key, if any.
//
// The semantics of the `counter` are:
// insert key k:
// counter already contains k: count += 1
// counter doesn't contain k:
// backing db contains k: count = 1
// backing db doesn't contain k: insert into backing db, count = 0
// delete key k:
// counter contains k (count is asserted to be non-zero):
// count > 1: counter -= 1
// count == 1: remove counter
// count == 0: remove key from backing db
// counter doesn't contain k: remove key from backing db
//
// We also keep reference counters for each key inserted in the journal to handle
// the following cases where key K must not be deleted from the DB when processing removals :
// Given H is the journal size in eras, 0 <= C <= H.
// Key K is removed in era A(N) and re-inserted in canonical era B(N + C).
// Key K is removed in era A(N) and re-inserted in non-canonical era B`(N + C).
// Key K is added in non-canonical era A'(N) canonical B(N + C).
// Practically, this means that for each commit block turning from recent to ancient we do the
// following:
// is_canonical:
// inserts: Ignored (left alone in the backing database).
// deletes: Enacted; however, recent history queue is checked for ongoing references. This is
// reduced as a preference to deletion from the backing database.
// !is_canonical:
// inserts: Reverted; however, recent history queue is checked for ongoing references. This is
// reduced as a preference to deletion from the backing database.
// deletes: Ignored (they were never inserted).
//
// The counter is encreased each time a key is inserted in the journal in the commit. The list of insertions
// is saved with the era record. When the era becomes end_era and goes out of journal the counter is decreased
// and the key is safe to delete.
// record new commit's details.
trace!("commit: #{} ({}), end era: {:?}", now, id, end);
trace!("commit: #{} ({}), end era: {:?}", now, id, end);
let mut counters = self.counters.as_ref().unwrap().write().unwrap();
let batch = DBTransaction::new();
{
let mut index = 0usize;
let mut last;
while {
let record = try!(self.backing.get({
let mut r = RlpStream::new_list(3);
r.append(&now);
r.append(&index);
r.append(&&PADDING[..]);
last = r.drain();
&last
}));
match record {
Some(r) => {
assert!(&Rlp::new(&r).val_at::<H256>(0) != id);
true
},
None => false,
}
} {
while try!(self.backing.get({
let mut r = RlpStream::new_list(3);
r.append(&now);
r.append(&index);
r.append(&&PADDING[..]);
last = r.drain();
&last
})).is_some() {
index += 1;
}
let drained = self.overlay.drain();
let removes: Vec<H256> = drained
.iter()
.filter_map(|(ref k, &(_, ref c))| if *c < 0 {Some(k.clone())} else {None}).cloned()
.collect();
let inserts: Vec<(H256, Bytes)> = drained
.into_iter()
.filter_map(|(k, (v, r))| if r > 0 { assert!(r == 1); Some((k, v)) } else { assert!(r >= -1); None })
.collect();
let mut r = RlpStream::new_list(3);
let inserts: Vec<H256> = self.overlay.keys().iter().filter(|&(_, &c)| c > 0).map(|(key, _)| key.clone()).collect();
// Increase counter for each inserted key no matter if the block is canonical or not.
for i in &inserts {
*counters.entry(i.clone()).or_insert(0) += 1;
}
let removes: Vec<H256> = self.overlay.keys().iter().filter(|&(_, &c)| c < 0).map(|(key, _)| key.clone()).collect();
r.append(id);
r.append(&inserts);
// Process the new inserts.
// We use the inserts for three things. For each:
// - we place into the backing DB or increment the counter if already in;
// - we note in the backing db that it was already in;
// - we write the key into our journal for this block;
r.begin_list(inserts.len());
inserts.iter().foreach(|&(k, _)| {r.append(&k);});
r.append(&removes);
Self::insert_keys(&inserts, &self.backing, &mut counters, &batch);
try!(batch.put(&last, r.as_raw()));
try!(batch.put(&LATEST_ERA_KEY, &encode(&now)));
}
@ -221,8 +323,6 @@ impl JournalDB {
if let Some((end_era, canon_id)) = end {
let mut index = 0usize;
let mut last;
let mut to_remove: Vec<H256> = Vec::new();
let mut canon_inserts: Vec<H256> = Vec::new();
while let Some(rlp_data) = try!(self.backing.get({
let mut r = RlpStream::new_list(3);
r.append(&end_era);
@ -232,54 +332,19 @@ impl JournalDB {
&last
})) {
let rlp = Rlp::new(&rlp_data);
let mut inserts: Vec<H256> = rlp.val_at(1);
JournalDB::decrease_counters(&inserts, &mut counters);
let inserts: Vec<H256> = rlp.val_at(1);
let deletes: Vec<H256> = rlp.val_at(2);
// Collect keys to be removed. These are removed keys for canonical block, inserted for non-canonical
if canon_id == rlp.val_at(0) {
let mut canon_deletes: Vec<H256> = rlp.val_at(2);
trace!("Purging nodes deleted from canon: {:?}", canon_deletes);
to_remove.append(&mut canon_deletes);
canon_inserts = inserts;
}
else {
trace!("Purging nodes inserted in non-canon: {:?}", inserts);
to_remove.append(&mut inserts);
}
trace!("commit: Delete journal for time #{}.{}: {}, (canon was {}): {} entries", end_era, index, rlp.val_at::<H256>(0), canon_id, to_remove.len());
Self::kill_keys(if canon_id == rlp.val_at(0) {deletes} else {inserts}, &mut counters, &batch);
try!(batch.delete(&last));
index += 1;
}
let canon_inserts = canon_inserts.drain(..).collect::<HashSet<_>>();
// Purge removed keys if they are not referenced and not re-inserted in the canon commit
let mut deletes = 0;
trace!("Purging filtered nodes: {:?}", to_remove.iter().filter(|h| !counters.contains_key(h) && !canon_inserts.contains(h)).collect::<Vec<_>>());
for h in to_remove.iter().filter(|h| !counters.contains_key(h) && !canon_inserts.contains(h)) {
try!(batch.delete(&h));
deletes += 1;
}
trace!("Total nodes purged: {}", deletes);
trace!("JournalDB: delete journal for time #{}.{}, (canon was {})", end_era, index, canon_id);
}
// Commit overlay insertions
let ret = Self::batch_overlay_insertions(&mut self.overlay, &batch);
try!(self.backing.write(batch));
Ok(ret as u32)
}
// Decrease counters for given keys. Deletes obsolete counters
fn decrease_counters(keys: &[H256], counters: &mut HashMap<H256, i32>) {
for i in keys.iter() {
let delete_counter = {
let cnt = counters.get_mut(i).expect("Missing key counter");
*cnt -= 1;
*cnt == 0
};
if delete_counter {
counters.remove(i);
}
}
// trace!("JournalDB::commit() deleted {} nodes", deletes);
Ok(0)
}
fn payload(&self, key: &H256) -> Option<Bytes> {
@ -287,7 +352,7 @@ impl JournalDB {
}
fn read_counters(db: &Database) -> HashMap<H256, i32> {
let mut res = HashMap::new();
let mut counters = HashMap::new();
if let Some(val) = db.get(&LATEST_ERA_KEY).expect("Low-level database error.") {
let mut era = decode::<u64>(&val);
loop {
@ -299,11 +364,10 @@ impl JournalDB {
r.append(&&PADDING[..]);
&r.drain()
}).expect("Low-level database error.") {
println!("read_counters: era={}, index={}", era, index);
let rlp = Rlp::new(&rlp_data);
let to_add: Vec<H256> = rlp.val_at(1);
for h in to_add {
*res.entry(h).or_insert(0) += 1;
}
let inserts: Vec<H256> = rlp.val_at(1);
Self::replay_keys(&inserts, db, &mut counters);
index += 1;
};
if index == 0 || era == 0 {
@ -312,10 +376,15 @@ impl JournalDB {
era -= 1;
}
}
trace!("Recovered {} counters", res.len());
res
trace!("Recovered {} counters", counters.len());
counters
}
}
/// Returns heap memory size used
pub fn mem_used(&self) -> usize {
self.overlay.mem_used() + match &self.counters { &Some(ref c) => c.read().unwrap().heap_size_of_children(), &None => 0 }
}
}
impl HashDB for JournalDB {
fn keys(&self) -> HashMap<H256, i32> {
@ -368,6 +437,28 @@ mod tests {
use super::*;
use hashdb::*;
#[test]
fn insert_same_in_fork() {
// history is 1
let mut jdb = JournalDB::new_temp();
let x = jdb.insert(b"X");
jdb.commit(1, &b"1".sha3(), None).unwrap();
jdb.commit(2, &b"2".sha3(), None).unwrap();
jdb.commit(3, &b"1002a".sha3(), Some((1, b"1".sha3()))).unwrap();
jdb.commit(4, &b"1003a".sha3(), Some((2, b"2".sha3()))).unwrap();
jdb.remove(&x);
jdb.commit(3, &b"1002b".sha3(), Some((1, b"1".sha3()))).unwrap();
let x = jdb.insert(b"X");
jdb.commit(4, &b"1003b".sha3(), Some((2, b"2".sha3()))).unwrap();
jdb.commit(5, &b"1004a".sha3(), Some((3, b"1002a".sha3()))).unwrap();
jdb.commit(6, &b"1005a".sha3(), Some((4, b"1003a".sha3()))).unwrap();
assert!(jdb.exists(&x));
}
#[test]
fn long_history() {
// history is 3
@ -488,15 +579,18 @@ mod tests {
assert!(jdb.exists(&foo));
}
#[test]
fn reopen() {
let mut dir = ::std::env::temp_dir();
dir.push(H32::random().hex());
let bar = H256::random();
let foo = {
let mut jdb = JournalDB::new(dir.to_str().unwrap());
// history is 1
let foo = jdb.insert(b"foo");
jdb.emplace(bar.clone(), b"bar".to_vec());
jdb.commit(0, &b"0".sha3(), None).unwrap();
foo
};
@ -510,8 +604,68 @@ mod tests {
{
let mut jdb = JournalDB::new(dir.to_str().unwrap());
assert!(jdb.exists(&foo));
assert!(jdb.exists(&bar));
jdb.commit(2, &b"2".sha3(), Some((1, b"1".sha3()))).unwrap();
assert!(!jdb.exists(&foo));
}
}
#[test]
fn reopen_remove() {
let mut dir = ::std::env::temp_dir();
dir.push(H32::random().hex());
let bar = H256::random();
let foo = {
let mut jdb = JournalDB::new(dir.to_str().unwrap());
// history is 1
let foo = jdb.insert(b"foo");
jdb.commit(0, &b"0".sha3(), None).unwrap();
jdb.commit(1, &b"1".sha3(), Some((0, b"0".sha3()))).unwrap();
// foo is ancient history.
jdb.insert(b"foo");
jdb.commit(2, &b"2".sha3(), Some((1, b"1".sha3()))).unwrap();
foo
};
{
let mut jdb = JournalDB::new(dir.to_str().unwrap());
jdb.remove(&foo);
jdb.commit(3, &b"3".sha3(), Some((2, b"2".sha3()))).unwrap();
assert!(jdb.exists(&foo));
jdb.remove(&foo);
jdb.commit(4, &b"4".sha3(), Some((3, b"3".sha3()))).unwrap();
jdb.commit(5, &b"5".sha3(), Some((4, b"4".sha3()))).unwrap();
assert!(!jdb.exists(&foo));
}
}
#[test]
fn reopen_fork() {
let mut dir = ::std::env::temp_dir();
dir.push(H32::random().hex());
let (foo, bar, baz) = {
let mut jdb = JournalDB::new(dir.to_str().unwrap());
// history is 1
let foo = jdb.insert(b"foo");
let bar = jdb.insert(b"bar");
jdb.commit(0, &b"0".sha3(), None).unwrap();
jdb.remove(&foo);
let baz = jdb.insert(b"baz");
jdb.commit(1, &b"1a".sha3(), Some((0, b"0".sha3()))).unwrap();
jdb.remove(&bar);
jdb.commit(1, &b"1b".sha3(), Some((0, b"0".sha3()))).unwrap();
(foo, bar, baz)
};
{
let mut jdb = JournalDB::new(dir.to_str().unwrap());
jdb.commit(2, &b"2b".sha3(), Some((1, b"1b".sha3()))).unwrap();
assert!(jdb.exists(&foo));
assert!(!jdb.exists(&baz));
assert!(!jdb.exists(&bar));
}
}
}

6
util/src/memorydb.rs
View File

@ -21,6 +21,7 @@ use bytes::*;
use rlp::*;
use sha3::*;
use hashdb::*;
use heapsize::*;
use std::mem;
use std::collections::HashMap;
@ -143,6 +144,11 @@ impl MemoryDB {
}
self.raw(key).unwrap()
}
/// Returns the size of allocated heap memory
pub fn mem_used(&self) -> usize {
self.data.heap_size_of_children()
}
}
static NULL_RLP_STATIC: [u8; 1] = [0x80; 1];