Files
pezkuwi-subxt/substrate/frame/contracts/src/storage.rs
T
Bastian Köcher 68390d4085 Init RuntimeLogger automatically for each runtime api call (#8128)
* Init `RuntimeLogger` automatically for each runtime api call

This pr change the runtime api in such a way to always and automatically
enable the `RuntimeLogger`. This enables the user to use `log` or
`tracing` from inside the runtime to create log messages. As logging
introduces some extra code and especially increases the size of the wasm
blob. It is advised to disable all logging completely with
`sp-api/disable-logging` when doing the wasm builds for the on-chain
wasm runtime.

Besides these changes, the pr also brings most of the logging found in
frame to the same format "runtime::*".

* Update frame/im-online/src/lib.rs

Co-authored-by: Guillaume Thiolliere <gui.thiolliere@gmail.com>

* Update test-utils/runtime/Cargo.toml

* Fix test

* Don't use tracing in the runtime, as we don't support it :D

* Fixes

Co-authored-by: Guillaume Thiolliere <gui.thiolliere@gmail.com>
2021-03-01 15:29:17 +01:00

328 lines
11 KiB
Rust

// This file is part of Substrate.
// Copyright (C) 2019-2021 Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// 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.
//! This module contains routines for accessing and altering a contract related state.
use crate::{
exec::{AccountIdOf, StorageKey},
AliveContractInfo, BalanceOf, CodeHash, ContractInfo, ContractInfoOf, Config, TrieId,
AccountCounter, DeletionQueue, Error,
weights::WeightInfo,
};
use codec::{Encode, Decode};
use sp_std::prelude::*;
use sp_std::marker::PhantomData;
use sp_io::hashing::blake2_256;
use sp_runtime::traits::{Bounded, Saturating, Zero};
use sp_core::crypto::UncheckedFrom;
use frame_support::{
dispatch::DispatchResult,
storage::child::{self, KillChildStorageResult},
traits::Get,
weights::Weight,
};
/// An error that means that the account requested either doesn't exist or represents a tombstone
/// account.
#[cfg_attr(test, derive(PartialEq, Eq, Debug))]
pub struct ContractAbsentError;
#[derive(Encode, Decode)]
pub struct DeletedContract {
pair_count: u32,
trie_id: TrieId,
}
pub struct Storage<T>(PhantomData<T>);
impl<T> Storage<T>
where
T: Config,
T::AccountId: UncheckedFrom<T::Hash> + AsRef<[u8]>
{
/// Reads a storage kv pair of a contract.
///
/// The read is performed from the `trie_id` only. The `address` is not necessary. If the contract
/// doesn't store under the given `key` `None` is returned.
pub fn read(trie_id: &TrieId, key: &StorageKey) -> Option<Vec<u8>> {
child::get_raw(&crate::child_trie_info(&trie_id), &blake2_256(key))
}
/// Update a storage entry into a contract's kv storage.
///
/// If the `opt_new_value` is `None` then the kv pair is removed.
///
/// This function also updates the bookkeeping info such as: number of total non-empty pairs a
/// contract owns, the last block the storage was written to, etc. That's why, in contrast to
/// `read`, this function also requires the `account` ID.
///
/// If the contract specified by the id `account` doesn't exist `Err` is returned.`
///
/// # Panics
///
/// Panics iff the `account` specified is not alive and in storage.
pub fn write(
account: &AccountIdOf<T>,
trie_id: &TrieId,
key: &StorageKey,
opt_new_value: Option<Vec<u8>>,
) -> DispatchResult {
let mut new_info = match <ContractInfoOf<T>>::get(account) {
Some(ContractInfo::Alive(alive)) => alive,
None | Some(ContractInfo::Tombstone(_)) => panic!("Contract not found"),
};
let hashed_key = blake2_256(key);
let child_trie_info = &crate::child_trie_info(&trie_id);
let opt_prev_len = child::len(&child_trie_info, &hashed_key);
// Update the total number of KV pairs and the number of empty pairs.
match (&opt_prev_len, &opt_new_value) {
(Some(_), None) => {
new_info.pair_count = new_info.pair_count.checked_sub(1)
.ok_or_else(|| Error::<T>::StorageExhausted)?;
},
(None, Some(_)) => {
new_info.pair_count = new_info.pair_count.checked_add(1)
.ok_or_else(|| Error::<T>::StorageExhausted)?;
},
(Some(_), Some(_)) => {},
(None, None) => {},
}
// Update the total storage size.
let prev_value_len = opt_prev_len.unwrap_or(0);
let new_value_len = opt_new_value
.as_ref()
.map(|new_value| new_value.len() as u32)
.unwrap_or(0);
new_info.storage_size = new_info
.storage_size
.checked_sub(prev_value_len)
.and_then(|val| val.checked_add(new_value_len))
.ok_or_else(|| Error::<T>::StorageExhausted)?;
new_info.last_write = Some(<frame_system::Module<T>>::block_number());
<ContractInfoOf<T>>::insert(&account, ContractInfo::Alive(new_info));
// Finally, perform the change on the storage.
match opt_new_value {
Some(new_value) => child::put_raw(&child_trie_info, &hashed_key, &new_value[..]),
None => child::kill(&child_trie_info, &hashed_key),
}
Ok(())
}
/// Returns the rent allowance set for the contract give by the account id.
pub fn rent_allowance(
account: &AccountIdOf<T>,
) -> Result<BalanceOf<T>, ContractAbsentError>
{
<ContractInfoOf<T>>::get(account)
.and_then(|i| i.as_alive().map(|i| i.rent_allowance))
.ok_or(ContractAbsentError)
}
/// Set the rent allowance for the contract given by the account id.
///
/// Returns `Err` if the contract doesn't exist or is a tombstone.
pub fn set_rent_allowance(
account: &AccountIdOf<T>,
rent_allowance: BalanceOf<T>,
) -> Result<(), ContractAbsentError> {
<ContractInfoOf<T>>::mutate(account, |maybe_contract_info| match maybe_contract_info {
Some(ContractInfo::Alive(ref mut alive_info)) => {
alive_info.rent_allowance = rent_allowance;
Ok(())
}
_ => Err(ContractAbsentError),
})
}
/// Creates a new contract descriptor in the storage with the given code hash at the given address.
///
/// Returns `Err` if there is already a contract (or a tombstone) exists at the given address.
pub fn place_contract(
account: &AccountIdOf<T>,
trie_id: TrieId,
ch: CodeHash<T>,
) -> DispatchResult {
<ContractInfoOf<T>>::try_mutate(account, |existing| {
if existing.is_some() {
return Err(Error::<T>::DuplicateContract.into());
}
let contract = AliveContractInfo::<T> {
code_hash: ch,
storage_size: 0,
trie_id,
deduct_block:
// We want to charge rent for the first block in advance. Therefore we
// treat the contract as if it was created in the last block and then
// charge rent for it during instantiation.
<frame_system::Module<T>>::block_number().saturating_sub(1u32.into()),
rent_allowance: <BalanceOf<T>>::max_value(),
rent_payed: <BalanceOf<T>>::zero(),
pair_count: 0,
last_write: None,
_reserved: None,
};
*existing = Some(contract.into());
Ok(())
})
}
/// Push a contract's trie to the deletion queue for lazy removal.
///
/// You must make sure that the contract is also removed or converted into a tombstone
/// when queuing the trie for deletion.
pub fn queue_trie_for_deletion(contract: &AliveContractInfo<T>) -> DispatchResult {
if <DeletionQueue<T>>::decode_len().unwrap_or(0) >= T::DeletionQueueDepth::get() as usize {
Err(Error::<T>::DeletionQueueFull.into())
} else {
<DeletionQueue<T>>::append(DeletedContract {
pair_count: contract.pair_count,
trie_id: contract.trie_id.clone(),
});
Ok(())
}
}
/// Calculates the weight that is necessary to remove one key from the trie and how many
/// of those keys can be deleted from the deletion queue given the supplied queue length
/// and weight limit.
pub fn deletion_budget(queue_len: usize, weight_limit: Weight) -> (u64, u32) {
let base_weight = T::WeightInfo::on_initialize();
let weight_per_queue_item = T::WeightInfo::on_initialize_per_queue_item(1) -
T::WeightInfo::on_initialize_per_queue_item(0);
let weight_per_key = T::WeightInfo::on_initialize_per_trie_key(1) -
T::WeightInfo::on_initialize_per_trie_key(0);
let decoding_weight = weight_per_queue_item.saturating_mul(queue_len as Weight);
// `weight_per_key` being zero makes no sense and would constitute a failure to
// benchmark properly. We opt for not removing any keys at all in this case.
let key_budget = weight_limit
.saturating_sub(base_weight)
.saturating_sub(decoding_weight)
.checked_div(weight_per_key)
.unwrap_or(0) as u32;
(weight_per_key, key_budget)
}
/// Delete as many items from the deletion queue possible within the supplied weight limit.
///
/// It returns the amount of weight used for that task or `None` when no weight was used
/// apart from the base weight.
pub fn process_deletion_queue_batch(weight_limit: Weight) -> Weight {
let queue_len = <DeletionQueue<T>>::decode_len().unwrap_or(0);
if queue_len == 0 {
return weight_limit;
}
let (weight_per_key, mut remaining_key_budget) = Self::deletion_budget(
queue_len,
weight_limit,
);
// We want to check whether we have enough weight to decode the queue before
// proceeding. Too little weight for decoding might happen during runtime upgrades
// which consume the whole block before the other `on_initialize` blocks are called.
if remaining_key_budget == 0 {
return weight_limit;
}
let mut queue = <DeletionQueue<T>>::get();
while !queue.is_empty() && remaining_key_budget > 0 {
// Cannot panic due to loop condition
let trie = &mut queue[0];
let pair_count = trie.pair_count;
let outcome = child::kill_storage(
&crate::child_trie_info(&trie.trie_id),
Some(remaining_key_budget),
);
if pair_count > remaining_key_budget {
// Cannot underflow because of the if condition
trie.pair_count -= remaining_key_budget;
} else {
// We do not care to preserve order. The contract is deleted already and
// noone waits for the trie to be deleted.
let removed = queue.swap_remove(0);
match outcome {
// This should not happen as our budget was large enough to remove all keys.
KillChildStorageResult::SomeRemaining(_) => {
log::error!(
target: "runtime::contracts",
"After deletion keys are remaining in this child trie: {:?}",
removed.trie_id,
);
},
KillChildStorageResult::AllRemoved(_) => (),
}
}
remaining_key_budget = remaining_key_budget
.saturating_sub(remaining_key_budget.min(pair_count));
}
<DeletionQueue<T>>::put(queue);
weight_limit.saturating_sub(weight_per_key.saturating_mul(remaining_key_budget as Weight))
}
/// This generator uses inner counter for account id and applies the hash over `AccountId +
/// accountid_counter`.
pub fn generate_trie_id(account_id: &AccountIdOf<T>) -> TrieId {
use sp_runtime::traits::Hash;
// Note that skipping a value due to error is not an issue here.
// We only need uniqueness, not sequence.
let new_seed = <AccountCounter<T>>::mutate(|v| {
*v = v.wrapping_add(1);
*v
});
let buf: Vec<_> = account_id.as_ref().iter()
.chain(&new_seed.to_le_bytes())
.cloned()
.collect();
T::Hashing::hash(&buf).as_ref().into()
}
/// Returns the code hash of the contract specified by `account` ID.
#[cfg(test)]
pub fn code_hash(account: &AccountIdOf<T>) -> Result<CodeHash<T>, ContractAbsentError>
{
<ContractInfoOf<T>>::get(account)
.and_then(|i| i.as_alive().map(|i| i.code_hash))
.ok_or(ContractAbsentError)
}
/// Fill up the queue in order to exercise the limits during testing.
#[cfg(test)]
pub fn fill_queue_with_dummies() {
let queue: Vec<_> = (0..T::DeletionQueueDepth::get()).map(|_| DeletedContract {
pair_count: 0,
trie_id: vec![],
})
.collect();
<DeletionQueue<T>>::put(queue);
}
}