use core::ops::Bound; use core::ptr::NonNull; use std::collections::HashMap; use std::convert::TryInto; use std::sync::{Arc, RwLock}; use heed::types::ByteSlice; use heed::{BytesDecode, Env, RoTxn, RwTxn, UntypedDatabase as Database}; use crate::{ Db, Error, IDb, ITx, ITxFn, Result, TxError, TxFnResult, TxOpError, TxOpResult, TxResult, TxValueIter, Value, ValueIter, }; pub use heed; // -- err impl From<heed::Error> for Error { fn from(e: heed::Error) -> Error { Error(format!("LMDB: {}", e).into()) } } impl From<heed::Error> for TxOpError { fn from(e: heed::Error) -> TxOpError { TxOpError(e.into()) } } // -- db pub struct LmdbDb { db: heed::Env, trees: RwLock<(Vec<Database>, HashMap<String, usize>)>, } impl LmdbDb { pub fn init(db: Env) -> Db { let s = Self { db, trees: RwLock::new((Vec::new(), HashMap::new())), }; Db(Arc::new(s)) } fn get_tree(&self, i: usize) -> Result<Database> { self.trees .read() .unwrap() .0 .get(i) .cloned() .ok_or_else(|| Error("invalid tree id".into())) } } impl IDb for LmdbDb { fn engine(&self) -> String { "LMDB (using Heed crate)".into() } fn open_tree(&self, name: &str) -> Result<usize> { let mut trees = self.trees.write().unwrap(); if let Some(i) = trees.1.get(name) { Ok(*i) } else { let tree = self.db.create_database(Some(name))?; let i = trees.0.len(); trees.0.push(tree); trees.1.insert(name.to_string(), i); Ok(i) } } fn list_trees(&self) -> Result<Vec<String>> { let tree0 = match self.db.open_database::<heed::types::Str, ByteSlice>(None)? { Some(x) => x, None => return Ok(vec![]), }; let mut ret = vec![]; let tx = self.db.read_txn()?; for item in tree0.iter(&tx)? { let (tree_name, _) = item?; ret.push(tree_name.to_string()); } drop(tx); let mut ret2 = vec![]; for tree_name in ret { if self .db .open_database::<ByteSlice, ByteSlice>(Some(&tree_name))? .is_some() { ret2.push(tree_name); } } Ok(ret2) } // ---- fn get(&self, tree: usize, key: &[u8]) -> Result<Option<Value>> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; let val = tree.get(&tx, key)?; match val { None => Ok(None), Some(v) => Ok(Some(v.to_vec())), } } fn len(&self, tree: usize) -> Result<usize> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; Ok(tree.len(&tx)?.try_into().unwrap()) } fn insert(&self, tree: usize, key: &[u8], value: &[u8]) -> Result<Option<Value>> { let tree = self.get_tree(tree)?; let mut tx = self.db.write_txn()?; let old_val = tree.get(&tx, key)?.map(Vec::from); tree.put(&mut tx, key, value)?; tx.commit()?; Ok(old_val) } fn remove(&self, tree: usize, key: &[u8]) -> Result<Option<Value>> { let tree = self.get_tree(tree)?; let mut tx = self.db.write_txn()?; let old_val = tree.get(&tx, key)?.map(Vec::from); tree.delete(&mut tx, key)?; tx.commit()?; Ok(old_val) } fn clear(&self, tree: usize) -> Result<()> { let tree = self.get_tree(tree)?; let mut tx = self.db.write_txn()?; tree.clear(&mut tx)?; tx.commit()?; Ok(()) } fn iter(&self, tree: usize) -> Result<ValueIter<'_>> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; TxAndIterator::make(tx, |tx| Ok(tree.iter(tx)?)) } fn iter_rev(&self, tree: usize) -> Result<ValueIter<'_>> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; TxAndIterator::make(tx, |tx| Ok(tree.rev_iter(tx)?)) } fn range<'r>( &self, tree: usize, low: Bound<&'r [u8]>, high: Bound<&'r [u8]>, ) -> Result<ValueIter<'_>> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; TxAndIterator::make(tx, |tx| Ok(tree.range(tx, &(low, high))?)) } fn range_rev<'r>( &self, tree: usize, low: Bound<&'r [u8]>, high: Bound<&'r [u8]>, ) -> Result<ValueIter<'_>> { let tree = self.get_tree(tree)?; let tx = self.db.read_txn()?; TxAndIterator::make(tx, |tx| Ok(tree.rev_range(tx, &(low, high))?)) } // ---- fn transaction(&self, f: &dyn ITxFn) -> TxResult<(), ()> { let trees = self.trees.read().unwrap(); let mut tx = LmdbTx { trees: &trees.0[..], tx: self .db .write_txn() .map_err(Error::from) .map_err(TxError::Db)?, }; let res = f.try_on(&mut tx); match res { TxFnResult::Ok => { tx.tx.commit().map_err(Error::from).map_err(TxError::Db)?; Ok(()) } TxFnResult::Abort => { tx.tx.abort().map_err(Error::from).map_err(TxError::Db)?; Err(TxError::Abort(())) } TxFnResult::DbErr => { tx.tx.abort().map_err(Error::from).map_err(TxError::Db)?; Err(TxError::Db(Error( "(this message will be discarded)".into(), ))) } } } } // ---- struct LmdbTx<'a> { trees: &'a [Database], tx: RwTxn<'a, 'a>, } impl<'a> LmdbTx<'a> { fn get_tree(&self, i: usize) -> TxOpResult<&Database> { self.trees.get(i).ok_or_else(|| { TxOpError(Error( "invalid tree id (it might have been openned after the transaction started)".into(), )) }) } } impl<'a> ITx for LmdbTx<'a> { fn get(&self, tree: usize, key: &[u8]) -> TxOpResult<Option<Value>> { let tree = self.get_tree(tree)?; match tree.get(&self.tx, key)? { Some(v) => Ok(Some(v.to_vec())), None => Ok(None), } } fn len(&self, _tree: usize) -> TxOpResult<usize> { unimplemented!(".len() in transaction not supported with LMDB backend") } fn insert(&mut self, tree: usize, key: &[u8], value: &[u8]) -> TxOpResult<Option<Value>> { let tree = *self.get_tree(tree)?; let old_val = tree.get(&self.tx, key)?.map(Vec::from); tree.put(&mut self.tx, key, value)?; Ok(old_val) } fn remove(&mut self, tree: usize, key: &[u8]) -> TxOpResult<Option<Value>> { let tree = *self.get_tree(tree)?; let old_val = tree.get(&self.tx, key)?.map(Vec::from); tree.delete(&mut self.tx, key)?; Ok(old_val) } fn iter(&self, _tree: usize) -> TxOpResult<TxValueIter<'_>> { unimplemented!("Iterators in transactions not supported with LMDB backend"); } fn iter_rev(&self, _tree: usize) -> TxOpResult<TxValueIter<'_>> { unimplemented!("Iterators in transactions not supported with LMDB backend"); } fn range<'r>( &self, _tree: usize, _low: Bound<&'r [u8]>, _high: Bound<&'r [u8]>, ) -> TxOpResult<TxValueIter<'_>> { unimplemented!("Iterators in transactions not supported with LMDB backend"); } fn range_rev<'r>( &self, _tree: usize, _low: Bound<&'r [u8]>, _high: Bound<&'r [u8]>, ) -> TxOpResult<TxValueIter<'_>> { unimplemented!("Iterators in transactions not supported with LMDB backend"); } } // ---- type IteratorItem<'a> = heed::Result<( <ByteSlice as BytesDecode<'a>>::DItem, <ByteSlice as BytesDecode<'a>>::DItem, )>; struct TxAndIterator<'a, I> where I: Iterator<Item = IteratorItem<'a>> + 'a, { tx: RoTxn<'a>, iter: Option<I>, } impl<'a, I> TxAndIterator<'a, I> where I: Iterator<Item = IteratorItem<'a>> + 'a, { fn make<F>(tx: RoTxn<'a>, iterfun: F) -> Result<ValueIter<'a>> where F: FnOnce(&'a RoTxn<'a>) -> Result<I>, { let mut res = TxAndIterator { tx, iter: None }; let tx = unsafe { NonNull::from(&res.tx).as_ref() }; res.iter = Some(iterfun(tx)?); Ok(Box::new(res)) } } impl<'a, I> Drop for TxAndIterator<'a, I> where I: Iterator<Item = IteratorItem<'a>> + 'a, { fn drop(&mut self) { drop(self.iter.take()); } } impl<'a, I> Iterator for TxAndIterator<'a, I> where I: Iterator<Item = IteratorItem<'a>> + 'a, { type Item = Result<(Value, Value)>; fn next(&mut self) -> Option<Self::Item> { match self.iter.as_mut().unwrap().next() { None => None, Some(Err(e)) => Some(Err(e.into())), Some(Ok((k, v))) => Some(Ok((k.to_vec(), v.to_vec()))), } } } // ---- #[cfg(target_pointer_width = "64")] pub fn recommended_map_size() -> usize { 1usize << 40 } #[cfg(target_pointer_width = "32")] pub fn recommended_map_size() -> usize { warn!("LMDB is not recommended on 32-bit systems, database size will be limited"); 1usize << 30 }