7c335e8764
* misc: bump license header to 2019 * misc: remove_duplicate_empty_lines.sh * misc: run license header script * commit cargo lock
214 lines
6.6 KiB
Rust
214 lines
6.6 KiB
Rust
// Copyright 2015-2019 Parity Technologies (UK) Ltd.
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// This file is part of Parity Ethereum.
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// Parity Ethereum 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 Ethereum 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 Ethereum. If not, see <http://www.gnu.org/licenses/>.
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//! Canonical hash trie definitions and helper functions.
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//!
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//! Each CHT is a trie mapping block numbers to canonical hashes and total difficulty.
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//! One is generated for every `SIZE` blocks, allowing us to discard those blocks in
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//! favor of the trie root. When the "ancient" blocks need to be accessed, we simply
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//! request an inclusion proof of a specific block number against the trie with the
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//! root has. A correct proof implies that the claimed block is identical to the one
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//! we discarded.
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use common_types::ids::BlockId;
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use ethereum_types::{H256, U256};
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use hashdb::HashDB;
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use keccak_hasher::KeccakHasher;
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use kvdb::DBValue;
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use memorydb::MemoryDB;
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use bytes::Bytes;
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use trie::{TrieMut, Trie, Recorder};
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use ethtrie::{self, TrieDB, TrieDBMut};
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use rlp::{RlpStream, Rlp};
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// encode a key.
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macro_rules! key {
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($num: expr) => { ::rlp::encode(&$num) }
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}
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macro_rules! val {
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($hash: expr, $td: expr) => {{
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let mut stream = RlpStream::new_list(2);
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stream.append(&$hash).append(&$td);
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stream.drain()
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}}
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}
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/// The size of each CHT.
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pub const SIZE: u64 = 2048;
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/// A canonical hash trie. This is generic over any database it can query.
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/// See module docs for more details.
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#[derive(Debug, Clone)]
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pub struct CHT<DB: HashDB<KeccakHasher, DBValue>> {
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db: DB,
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root: H256, // the root of this CHT.
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number: u64,
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}
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impl<DB: HashDB<KeccakHasher, DBValue>> CHT<DB> {
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/// Query the root of the CHT.
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pub fn root(&self) -> H256 { self.root }
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/// Query the number of the CHT.
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pub fn number(&self) -> u64 { self.number }
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/// Generate an inclusion proof for the entry at a specific block.
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/// Nodes before level `from_level` will be omitted.
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/// Returns an error on an incomplete trie, and `Ok(None)` on an unprovable request.
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pub fn prove(&self, num: u64, from_level: u32) -> ethtrie::Result<Option<Vec<Bytes>>> {
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if block_to_cht_number(num) != Some(self.number) { return Ok(None) }
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let mut recorder = Recorder::with_depth(from_level);
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let t = TrieDB::new(&self.db, &self.root)?;
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t.get_with(&key!(num), &mut recorder)?;
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Ok(Some(recorder.drain().into_iter().map(|x| x.data).collect()))
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}
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}
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/// Block information necessary to build a CHT.
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pub struct BlockInfo {
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/// The block's hash.
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pub hash: H256,
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/// The block's parent's hash.
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pub parent_hash: H256,
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/// The block's total difficulty.
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pub total_difficulty: U256,
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}
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/// Build an in-memory CHT from a closure which provides necessary information
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/// about blocks. If the fetcher ever fails to provide the info, the CHT
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/// will not be generated.
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pub fn build<F>(cht_num: u64, mut fetcher: F) -> Option<CHT<MemoryDB<KeccakHasher, DBValue>>>
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where F: FnMut(BlockId) -> Option<BlockInfo>
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{
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let mut db = MemoryDB::<KeccakHasher, DBValue>::new();
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// start from the last block by number and work backwards.
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let last_num = start_number(cht_num + 1) - 1;
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let mut id = BlockId::Number(last_num);
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let mut root = H256::default();
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{
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let mut t = TrieDBMut::new(&mut db, &mut root);
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for blk_num in (0..SIZE).map(|n| last_num - n) {
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let info = match fetcher(id) {
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Some(info) => info,
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None => return None,
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};
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id = BlockId::Hash(info.parent_hash);
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t.insert(&key!(blk_num), &val!(info.hash, info.total_difficulty))
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.expect("fresh in-memory database is infallible; qed");
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}
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}
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Some(CHT {
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db,
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root,
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number: cht_num,
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})
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}
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/// Compute a CHT root from an iterator of (hash, td) pairs. Fails if shorter than
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/// SIZE items. The items are assumed to proceed sequentially from `start_number(cht_num)`.
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/// Discards the trie's nodes.
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pub fn compute_root<I>(cht_num: u64, iterable: I) -> Option<H256>
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where I: IntoIterator<Item=(H256, U256)>
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{
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let mut v = Vec::with_capacity(SIZE as usize);
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let start_num = start_number(cht_num) as usize;
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for (i, (h, td)) in iterable.into_iter().take(SIZE as usize).enumerate() {
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v.push((key!(i + start_num), val!(h, td)))
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}
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if v.len() == SIZE as usize {
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Some(::triehash::trie_root(v))
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} else {
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None
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}
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}
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/// Check a proof for a CHT.
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/// Given a set of a trie nodes, a number to query, and a trie root,
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/// verify the given trie branch and extract the canonical hash and total difficulty.
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// TODO: better support for partially-checked queries.
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pub fn check_proof(proof: &[Bytes], num: u64, root: H256) -> Option<(H256, U256)> {
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let mut db = MemoryDB::<KeccakHasher, DBValue>::new();
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for node in proof { db.insert(&node[..]); }
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let res = match TrieDB::new(&db, &root) {
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Err(_) => return None,
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Ok(trie) => trie.get_with(&key!(num), |val: &[u8]| {
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let rlp = Rlp::new(val);
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rlp.val_at::<H256>(0)
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.and_then(|h| rlp.val_at::<U256>(1).map(|td| (h, td)))
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.ok()
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})
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};
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match res {
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Ok(Some(Some((hash, td)))) => Some((hash, td)),
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_ => None,
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}
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}
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/// Convert a block number to a CHT number.
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/// Returns `None` for `block_num` == 0, `Some` otherwise.
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pub fn block_to_cht_number(block_num: u64) -> Option<u64> {
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match block_num {
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0 => None,
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n => Some((n - 1) / SIZE),
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}
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}
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/// Get the starting block of a given CHT.
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/// CHT 0 includes block 1...SIZE,
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/// CHT 1 includes block SIZE + 1 ... 2*SIZE
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/// More generally: CHT N includes block (1 + N*SIZE)...((N+1)*SIZE).
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/// This is because the genesis hash is assumed to be known
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/// and including it would be redundant.
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pub fn start_number(cht_num: u64) -> u64 {
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(cht_num * SIZE) + 1
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}
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#[cfg(test)]
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mod tests {
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#[test]
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fn size_is_lt_usize() {
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// to ensure safe casting on the target platform.
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assert!(::cht::SIZE < usize::max_value() as u64)
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}
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#[test]
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fn block_to_cht_number() {
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assert!(::cht::block_to_cht_number(0).is_none());
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assert_eq!(::cht::block_to_cht_number(1).unwrap(), 0);
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assert_eq!(::cht::block_to_cht_number(::cht::SIZE + 1).unwrap(), 1);
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assert_eq!(::cht::block_to_cht_number(::cht::SIZE).unwrap(), 0);
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}
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#[test]
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fn start_number() {
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assert_eq!(::cht::start_number(0), 1);
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assert_eq!(::cht::start_number(1), ::cht::SIZE + 1);
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assert_eq!(::cht::start_number(2), ::cht::SIZE * 2 + 1);
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}
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}
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