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// This file is part of Substrate.
// Copyright (C) Parity Technologies (UK) Ltd.
// 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.
//! # Contract Pallet
//! The Contract module provides functionality for the runtime to deploy and execute WebAssembly
//! smart-contracts.
//! This module extends accounts based on the [`Currency`] trait to have smart-contract
//! functionality. It can be used with other modules that implement accounts based on [`Currency`].
//! These "smart-contract accounts" have the ability to instantiate smart-contracts and make calls
//! to other contract and non-contract accounts.
//! The smart-contract code is stored once in a code cache, and later retrievable via its hash.
//! This means that multiple smart-contracts can be instantiated from the same hash, without
//! replicating the code each time.
//! When a smart-contract is called, its associated code is retrieved via the code hash and gets
//! executed. This call can alter the storage entries of the smart-contract account, instantiate new
//! smart-contracts, or call other smart-contracts.
//! Finally, when an account is reaped, its associated code and storage of the smart-contract
//! account will also be deleted.
//! Senders must specify a gas limit with every call, as all instructions invoked by the
//! smart-contract require gas. Unused gas is refunded after the call, regardless of the execution
//! outcome.
//! If the gas limit is reached, then all calls and state changes (including balance transfers) are
//! only reverted at the current call's contract level. For example, if contract A calls B and B
//! runs out of gas mid-call, then all of B's calls are reverted. Assuming correct error handling by
//! contract A, A's other calls and state changes still persist.
//! Contract call failures are not always cascading. When failures occur in a sub-call, they do not
//! "bubble up", and the call will only revert at the specific contract level. For example, if
//! contract A calls contract B, and B fails, A can decide how to handle that failure, either
//! proceeding or reverting A's changes.
//! * [`Pallet::instantiate_with_code`] - Deploys a new contract from the supplied wasm binary,
//! optionally transferring
//! some balance. This instantiates a new smart contract account with the supplied code and
//! calls its constructor to initialize the contract.
//! * [`Pallet::instantiate`] - The same as `instantiate_with_code` but instead of uploading new
//! code an existing `code_hash` is supplied.
//! * [`Pallet::call`] - Makes a call to an account, optionally transferring some balance.
//! The Contract module is a work in progress. The following examples show how this Contract module
//! can be used to instantiate and call contracts.
//! * [`ink`](https://github.com/paritytech/ink) is
//! an [`eDSL`](https://wiki.haskell.org/Embedded_domain_specific_language) that enables writing
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//! WebAssembly based smart contracts in the Rust programming language.
#![cfg_attr(not(feature = "std"), no_std)]
#![cfg_attr(feature = "runtime-benchmarks", recursion_limit = "1024")]
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mod address;
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mod migration;
mod schedule;
pub mod chain_extension;
pub mod weights;
#[cfg(test)]
mod tests;
use crate::{
exec::{AccountIdOf, ErrorOrigin, ExecError, Executable, Key, Stack as ExecStack},
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storage::{meter::Meter as StorageMeter, ContractInfo, DeletedContract},
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wasm::{OwnerInfo, PrefabWasmModule, TryInstantiate},
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use codec::{Codec, Encode, HasCompact};
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use environmental::*;
dispatch::{Dispatchable, GetDispatchInfo, Pays, PostDispatchInfo},
ensure,
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traits::{
tokens::fungible::Inspect, ConstU32, Contains, Currency, Get, Randomness,
ReservableCurrency, Time,
},
weights::{OldWeight, Weight},
BoundedVec, WeakBoundedVec,
use frame_system::Pallet as System;
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use pallet_contracts_primitives::{
Code, CodeUploadResult, CodeUploadReturnValue, ContractAccessError, ContractExecResult,
ContractInstantiateResult, ExecReturnValue, GetStorageResult, InstantiateReturnValue,
StorageDeposit,
use smallvec::Array;
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use sp_runtime::traits::{Convert, Hash, Saturating, StaticLookup};
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use sp_std::{fmt::Debug, marker::PhantomData, prelude::*};
pub use crate::{
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address::{AddressGenerator, DefaultAddressGenerator},
exec::Frame,
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migration::Migration,
pallet::*,
schedule::{HostFnWeights, InstructionWeights, Limits, Schedule},
wasm::Determinism,
};
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#[cfg(doc)]
pub use crate::wasm::api_doc;
type CodeHash<T> = <T as frame_system::Config>::Hash;
type TrieId = BoundedVec<u8, ConstU32<128>>;
<<T as Config>::Currency as Currency<<T as frame_system::Config>::AccountId>>::Balance;
type CodeVec<T> = BoundedVec<u8, <T as Config>::MaxCodeLen>;
type RelaxedCodeVec<T> = WeakBoundedVec<u8, <T as Config>::MaxCodeLen>;
type AccountIdLookupOf<T> = <<T as frame_system::Config>::Lookup as StaticLookup>::Source;
type DebugBufferVec<T> = BoundedVec<u8, <T as Config>::MaxDebugBufferLen>;
/// Used as a sentinel value when reading and writing contract memory.
///
/// It is usually used to signal `None` to a contract when only a primitive is allowed
/// and we don't want to go through encoding a full Rust type. Using `u32::Max` is a safe
/// sentinel because contracts are never allowed to use such a large amount of resources
/// that this value makes sense for a memory location or length.
const SENTINEL: u32 = u32::MAX;
#[frame_support::pallet]
pub mod pallet {
use frame_support::pallet_prelude::*;
use frame_system::pallet_prelude::*;
/// The current storage version.
const STORAGE_VERSION: StorageVersion = StorageVersion::new(9);
#[pallet::pallet]
#[pallet::storage_version(STORAGE_VERSION)]
pub struct Pallet<T>(PhantomData<T>);
#[pallet::config]
pub trait Config: frame_system::Config {
/// The time implementation used to supply timestamps to contracts through `seal_now`.
/// The generator used to supply randomness to contracts through `seal_random`.
///
/// # Deprecated
///
/// Codes using the randomness functionality cannot be uploaded. Neither can contracts
/// be instantiated from existing codes that use this deprecated functionality. It will
/// be removed eventually. Hence for new `pallet-contracts` deployments it is okay
/// to supply a dummy implementation for this type (because it is never used).
type Randomness: Randomness<Self::Hash, Self::BlockNumber>;
/// The currency in which fees are paid and contract balances are held.
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type Currency: ReservableCurrency<Self::AccountId>
+ Inspect<Self::AccountId, Balance = BalanceOf<Self>>;
/// The overarching event type.
type RuntimeEvent: From<Event<Self>> + IsType<<Self as frame_system::Config>::RuntimeEvent>;
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/// The overarching call type.
type RuntimeCall: Dispatchable<RuntimeOrigin = Self::RuntimeOrigin, PostInfo = PostDispatchInfo>
+ GetDispatchInfo
+ codec::Decode
+ IsType<<Self as frame_system::Config>::RuntimeCall>;
/// Filter that is applied to calls dispatched by contracts.
///
/// Use this filter to control which dispatchables are callable by contracts.
/// This is applied in **addition** to [`frame_system::Config::BaseCallFilter`].
/// It is recommended to treat this as a whitelist.
///
/// # Stability
///
/// The runtime **must** make sure that all dispatchables that are callable by
/// contracts remain stable. In addition [`Self::RuntimeCall`] itself must remain stable.
/// This means that no existing variants are allowed to switch their positions.
///
/// # Note
///
/// Note that dispatchables that are called via contracts do not spawn their
/// own wasm instance for each call (as opposed to when called via a transaction).
/// Therefore please make sure to be restrictive about which dispatchables are allowed
/// in order to not introduce a new DoS vector like memory allocation patterns that can
/// be exploited to drive the runtime into a panic.
type CallFilter: Contains<<Self as frame_system::Config>::RuntimeCall>;
/// Used to answer contracts' queries regarding the current weight price. This is **not**
/// used to calculate the actual fee and is only for informational purposes.
type WeightPrice: Convert<Weight, BalanceOf<Self>>;
/// Describes the weights of the dispatchables of this module and is also used to
/// construct a default cost schedule.
type WeightInfo: WeightInfo;
/// Type that allows the runtime authors to add new host functions for a contract to call.
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type ChainExtension: chain_extension::ChainExtension<Self> + Default;
/// Cost schedule and limits.
#[pallet::constant]
type Schedule: Get<Schedule<Self>>;
/// The type of the call stack determines the maximum nesting depth of contract calls.
///
/// The allowed depth is `CallStack::size() + 1`.
/// Therefore a size of `0` means that a contract cannot use call or instantiate.
/// In other words only the origin called "root contract" is allowed to execute then.
///
/// This setting along with [`MaxCodeLen`](#associatedtype.MaxCodeLen) directly affects
/// memory usage of your runtime.
type CallStack: Array<Item = Frame<Self>>;
/// The maximum number of contracts that can be pending for deletion.
///
/// When a contract is deleted by calling `seal_terminate` it becomes inaccessible
/// immediately, but the deletion of the storage items it has accumulated is performed
/// later. The contract is put into the deletion queue. This defines how many
/// contracts can be queued up at the same time. If that limit is reached `seal_terminate`
/// will fail. The action must be retried in a later block in that case.
///
/// The reasons for limiting the queue depth are:
///
/// 1. The queue is in storage in order to be persistent between blocks. We want to limit
/// the amount of storage that can be consumed.
/// 2. The queue is stored in a vector and needs to be decoded as a whole when reading
/// it at the end of each block. Longer queues take more weight to decode and hence
/// limit the amount of items that can be deleted per block.
#[pallet::constant]
type DeletionQueueDepth: Get<u32>;
/// The maximum amount of weight that can be consumed per block for lazy trie removal.
///
/// The amount of weight that is dedicated per block to work on the deletion queue. Larger
/// values allow more trie keys to be deleted in each block but reduce the amount of
/// weight that is left for transactions. See [`Self::DeletionQueueDepth`] for more
/// information about the deletion queue.
#[pallet::constant]
type DeletionWeightLimit: Get<Weight>;
/// The amount of balance a caller has to pay for each byte of storage.
///
/// # Note
///
/// Changing this value for an existing chain might need a storage migration.
#[pallet::constant]
type DepositPerByte: Get<BalanceOf<Self>>;
/// The amount of balance a caller has to pay for each storage item.
///
/// # Note
///
/// Changing this value for an existing chain might need a storage migration.
#[pallet::constant]
type DepositPerItem: Get<BalanceOf<Self>>;
/// The address generator used to generate the addresses of contracts.
type AddressGenerator: AddressGenerator<Self>;
/// The maximum length of a contract code in bytes. This limit applies to the instrumented
/// version of the code. Therefore `instantiate_with_code` can fail even when supplying
/// a wasm binary below this maximum size.
///
/// The value should be chosen carefully taking into the account the overall memory limit
/// your runtime has, as well as the [maximum allowed callstack
/// depth](#associatedtype.CallStack). Look into the `integrity_test()` for some insights.
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#[pallet::constant]
type MaxCodeLen: Get<u32>;
/// The maximum allowable length in bytes for storage keys.
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#[pallet::constant]
type MaxStorageKeyLen: Get<u32>;
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/// Make contract callable functions marked as `#[unstable]` available.
///
/// Contracts that use `#[unstable]` functions won't be able to be uploaded unless
/// this is set to `true`. This is only meant for testnets and dev nodes in order to
/// experiment with new features.
///
/// # Warning
///
/// Do **not** set to `true` on productions chains.
#[pallet::constant]
type UnsafeUnstableInterface: Get<bool>;
/// The maximum length of the debug buffer in bytes.
#[pallet::constant]
type MaxDebugBufferLen: Get<u32>;
impl<T: Config> Hooks<BlockNumberFor<T>> for Pallet<T> {
fn on_idle(_block: T::BlockNumber, remaining_weight: Weight) -> Weight {
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ContractInfo::<T>::process_deletion_queue_batch(remaining_weight)
.saturating_add(T::WeightInfo::on_process_deletion_queue_batch())
}
fn on_initialize(_block: T::BlockNumber) -> Weight {
// We want to process the deletion_queue in the on_idle hook. Only in the case
// that the queue length has reached its maximal depth, we process it here.
let max_len = T::DeletionQueueDepth::get() as usize;
let queue_len = <DeletionQueue<T>>::decode_len().unwrap_or(0);
if queue_len >= max_len {
// We do not want to go above the block limit and rather avoid lazy deletion
// in that case. This should only happen on runtime upgrades.
let weight_limit = T::BlockWeights::get()
.max_block
.saturating_sub(System::<T>::block_weight().total())
.min(T::DeletionWeightLimit::get());
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ContractInfo::<T>::process_deletion_queue_batch(weight_limit)
.saturating_add(T::WeightInfo::on_process_deletion_queue_batch())
} else {
T::WeightInfo::on_process_deletion_queue_batch()
}
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fn integrity_test() {
// Total runtime memory is expected to have 128Mb upper limit
const MAX_RUNTIME_MEM: u32 = 1024 * 1024 * 128;
// Memory limits for a single contract:
// Value stack size: 1Mb per contract, default defined in wasmi
const MAX_STACK_SIZE: u32 = 1024 * 1024;
// Heap limit is normally 16 mempages of 64kb each = 1Mb per contract
let max_heap_size = T::Schedule::get().limits.max_memory_size();
// Max call depth is CallStack::size() + 1
let max_call_depth = u32::try_from(T::CallStack::size().saturating_add(1))
.expect("CallStack size is too big");
// Check that given configured `MaxCodeLen`, runtime heap memory limit can't be broken.
//
// In worst case, the decoded wasm contract code would be `x16` times larger than the
// encoded one. This is because even a single-byte wasm instruction has 16-byte size in
// wasmi. This gives us `MaxCodeLen*16` safety margin.
//
// Next, the pallet keeps both the original and instrumented wasm blobs for each
// contract, hence we add up `MaxCodeLen*2` more to the safety margin.
//
// Finally, the inefficiencies of the freeing-bump allocator
// being used in the client for the runtime memory allocations, could lead to possible
// memory allocations for contract code grow up to `x4` times in some extreme cases,
// which gives us total multiplier of `18*4` for `MaxCodeLen`.
//
// That being said, for every contract executed in runtime, at least `MaxCodeLen*18*4`
// memory should be available. Note that maximum allowed heap memory and stack size per
// each contract (stack frame) should also be counted.
//
// Finally, we allow 50% of the runtime memory to be utilized by the contracts call
// stack, keeping the rest for other facilities, such as PoV, etc.
//
// This gives us the following formula:
//
// `(MaxCodeLen * 18 * 4 + MAX_STACK_SIZE + max_heap_size) * max_call_depth <
// MAX_RUNTIME_MEM/2`
//
// Hence the upper limit for the `MaxCodeLen` can be defined as follows:
let code_len_limit = MAX_RUNTIME_MEM
.saturating_div(2)
.saturating_div(max_call_depth)
.saturating_sub(max_heap_size)
.saturating_sub(MAX_STACK_SIZE)
.saturating_div(18 * 4);
assert!(
T::MaxCodeLen::get() < code_len_limit,
"Given `CallStack` height {:?}, `MaxCodeLen` should be set less than {:?} \
(current value is {:?}), to avoid possible runtime oom issues.",
max_call_depth,
code_len_limit,
T::MaxCodeLen::get(),
);
// Debug buffer should at least be large enough to accommodate a simple error message
const MIN_DEBUG_BUF_SIZE: u32 = 256;
assert!(
T::MaxDebugBufferLen::get() > MIN_DEBUG_BUF_SIZE,
"Debug buffer should have minimum size of {} (current setting is {})",
MIN_DEBUG_BUF_SIZE,
T::MaxDebugBufferLen::get(),
)
}
#[pallet::call]
impl<T: Config> Pallet<T>
where
<BalanceOf<T> as HasCompact>::Type: Clone + Eq + PartialEq + Debug + TypeInfo + Encode,
/// Deprecated version if [`Self::call`] for use in an in-storage `Call`.
#[pallet::weight(T::WeightInfo::call().saturating_add(<Pallet<T>>::compat_weight_limit(*gas_limit)))]
#[allow(deprecated)]
#[deprecated(note = "1D weight is used in this extrinsic, please migrate to `call`")]
pub fn call_old_weight(
dest: AccountIdLookupOf<T>,
#[pallet::compact] value: BalanceOf<T>,
#[pallet::compact] gas_limit: OldWeight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
) -> DispatchResultWithPostInfo {
origin,
dest,
value,
<Pallet<T>>::compat_weight_limit(gas_limit),
storage_deposit_limit,
/// Deprecated version if [`Self::instantiate_with_code`] for use in an in-storage `Call`.
T::WeightInfo::instantiate_with_code(code.len() as u32, data.len() as u32, salt.len() as u32)
.saturating_add(<Pallet<T>>::compat_weight_limit(*gas_limit))
#[allow(deprecated)]
#[deprecated(
note = "1D weight is used in this extrinsic, please migrate to `instantiate_with_code`"
)]
pub fn instantiate_with_code_old_weight(
#[pallet::compact] value: BalanceOf<T>,
#[pallet::compact] gas_limit: OldWeight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
code: Vec<u8>,
data: Vec<u8>,
salt: Vec<u8>,
) -> DispatchResultWithPostInfo {
Self::instantiate_with_code(
<Pallet<T>>::compat_weight_limit(gas_limit),
storage_deposit_limit,
code,
salt,
/// Deprecated version if [`Self::instantiate`] for use in an in-storage `Call`.
T::WeightInfo::instantiate(data.len() as u32, salt.len() as u32).saturating_add(<Pallet<T>>::compat_weight_limit(*gas_limit))
#[allow(deprecated)]
#[deprecated(note = "1D weight is used in this extrinsic, please migrate to `instantiate`")]
pub fn instantiate_old_weight(
#[pallet::compact] value: BalanceOf<T>,
#[pallet::compact] gas_limit: OldWeight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
code_hash: CodeHash<T>,
data: Vec<u8>,
salt: Vec<u8>,
) -> DispatchResultWithPostInfo {
<Pallet<T>>::compat_weight_limit(gas_limit),
storage_deposit_limit,
code_hash,
salt,
/// Upload new `code` without instantiating a contract from it.
///
/// If the code does not already exist a deposit is reserved from the caller
/// and unreserved only when [`Self::remove_code`] is called. The size of the reserve
/// depends on the instrumented size of the the supplied `code`.
///
/// If the code already exists in storage it will still return `Ok` and upgrades
/// the in storage version to the current
/// [`InstructionWeights::version`](InstructionWeights).
///
/// - `determinism`: If this is set to any other value but [`Determinism::Deterministic`]
/// then the only way to use this code is to delegate call into it from an offchain
/// execution. Set to [`Determinism::Deterministic`] if in doubt.
///
/// # Note
///
/// Anyone can instantiate a contract from any uploaded code and thus prevent its removal.
/// To avoid this situation a constructor could employ access control so that it can
/// only be instantiated by permissioned entities. The same is true when uploading
/// through [`Self::instantiate_with_code`].
#[pallet::weight(T::WeightInfo::upload_code(code.len() as u32))]
pub fn upload_code(
origin: OriginFor<T>,
code: Vec<u8>,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
determinism: Determinism,
) -> DispatchResult {
let origin = ensure_signed(origin)?;
Self::bare_upload_code(origin, code, storage_deposit_limit.map(Into::into), determinism)
.map(|_| ())
}
/// Remove the code stored under `code_hash` and refund the deposit to its owner.
///
/// A code can only be removed by its original uploader (its owner) and only if it is
/// not used by any contract.
#[pallet::weight(T::WeightInfo::remove_code())]
pub fn remove_code(
origin: OriginFor<T>,
code_hash: CodeHash<T>,
) -> DispatchResultWithPostInfo {
let origin = ensure_signed(origin)?;
<PrefabWasmModule<T>>::remove(&origin, code_hash)?;
// we waive the fee because removing unused code is beneficial
Ok(Pays::No.into())
}
/// Privileged function that changes the code of an existing contract.
///
/// This takes care of updating refcounts and all other necessary operations. Returns
/// an error if either the `code_hash` or `dest` do not exist.
///
/// # Note
///
/// This does **not** change the address of the contract in question. This means
/// that the contract address is no longer derived from its code hash after calling
/// this dispatchable.
#[pallet::weight(T::WeightInfo::set_code())]
pub fn set_code(
origin: OriginFor<T>,
dest: AccountIdLookupOf<T>,
code_hash: CodeHash<T>,
) -> DispatchResult {
ensure_root(origin)?;
let dest = T::Lookup::lookup(dest)?;
<ContractInfoOf<T>>::try_mutate(&dest, |contract| {
let contract = if let Some(contract) = contract {
contract
} else {
return Err(<Error<T>>::ContractNotFound.into())
};
<PrefabWasmModule<T>>::add_user(code_hash)?;
<PrefabWasmModule<T>>::remove_user(contract.code_hash);
Self::deposit_event(
vec![T::Hashing::hash_of(&dest), code_hash, contract.code_hash],
Event::ContractCodeUpdated {
contract: dest.clone(),
new_code_hash: code_hash,
old_code_hash: contract.code_hash,
},
);
contract.code_hash = code_hash;
Ok(())
})
}
/// Makes a call to an account, optionally transferring some balance.
///
/// # Parameters
///
/// * `dest`: Address of the contract to call.
/// * `value`: The balance to transfer from the `origin` to `dest`.
/// * `gas_limit`: The gas limit enforced when executing the constructor.
/// * `storage_deposit_limit`: The maximum amount of balance that can be charged from the
/// caller to pay for the storage consumed.
/// * `data`: The input data to pass to the contract.
///
/// * If the account is a smart-contract account, the associated code will be
/// executed and any value will be transferred.
/// * If the account is a regular account, any value will be transferred.
/// * If no account exists and the call value is not less than `existential_deposit`,
/// a regular account will be created and any value will be transferred.
#[pallet::weight(T::WeightInfo::call().saturating_add(*gas_limit))]
pub fn call(
origin: OriginFor<T>,
dest: AccountIdLookupOf<T>,
#[pallet::compact] value: BalanceOf<T>,
gas_limit: Weight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
data: Vec<u8>,
) -> DispatchResultWithPostInfo {
let gas_limit: Weight = gas_limit.into();
let origin = ensure_signed(origin)?;
let dest = T::Lookup::lookup(dest)?;
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let common = CommonInput {
origin,
value,
data,
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gas_limit,
storage_deposit_limit: storage_deposit_limit.map(Into::into),
debug_message: None,
};
let mut output = CallInput::<T> { dest, determinism: Determinism::Deterministic }
.run_guarded(common);
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if let Ok(retval) = &output.result {
if retval.did_revert() {
output.result = Err(<Error<T>>::ContractReverted.into());
}
}
output.gas_meter.into_dispatch_result(output.result, T::WeightInfo::call())
}
/// Instantiates a new contract from the supplied `code` optionally transferring
/// some balance.
///
/// This dispatchable has the same effect as calling [`Self::upload_code`] +
/// [`Self::instantiate`]. Bundling them together provides efficiency gains. Please
/// also check the documentation of [`Self::upload_code`].
///
/// # Parameters
///
/// * `value`: The balance to transfer from the `origin` to the newly created contract.
/// * `gas_limit`: The gas limit enforced when executing the constructor.
/// * `storage_deposit_limit`: The maximum amount of balance that can be charged/reserved
/// from the caller to pay for the storage consumed.
/// * `code`: The contract code to deploy in raw bytes.
/// * `data`: The input data to pass to the contract constructor.
/// * `salt`: Used for the address derivation. See [`Pallet::contract_address`].
///
/// Instantiation is executed as follows:
///
/// - The supplied `code` is instrumented, deployed, and a `code_hash` is created for that
/// code.
/// - If the `code_hash` already exists on the chain the underlying `code` will be shared.
/// - The destination address is computed based on the sender, code_hash and the salt.
/// - The smart-contract account is created at the computed address.
/// - The `value` is transferred to the new account.
/// - The `deploy` function is executed in the context of the newly-created account.
T::WeightInfo::instantiate_with_code(code.len() as u32, data.len() as u32, salt.len() as u32)
.saturating_add(*gas_limit)
)]
pub fn instantiate_with_code(
origin: OriginFor<T>,
#[pallet::compact] value: BalanceOf<T>,
gas_limit: Weight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
code: Vec<u8>,
data: Vec<u8>,
salt: Vec<u8>,
) -> DispatchResultWithPostInfo {
let origin = ensure_signed(origin)?;
let code_len = code.len() as u32;
let data_len = data.len() as u32;
let salt_len = salt.len() as u32;
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let common = CommonInput {
origin,
value,
data,
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gas_limit,
storage_deposit_limit: storage_deposit_limit.map(Into::into),
debug_message: None,
};
let mut output =
InstantiateInput::<T> { code: Code::Upload(code), salt }.run_guarded(common);
if let Ok(retval) = &output.result {
if retval.1.did_revert() {
output.result = Err(<Error<T>>::ContractReverted.into());
}
}
output.gas_meter.into_dispatch_result(
output.result.map(|(_address, result)| result),
T::WeightInfo::instantiate_with_code(code_len, data_len, salt_len),
)
}
/// Instantiates a contract from a previously deployed wasm binary.
///
/// This function is identical to [`Self::instantiate_with_code`] but without the
/// code deployment step. Instead, the `code_hash` of an on-chain deployed wasm binary
/// must be supplied.
T::WeightInfo::instantiate(data.len() as u32, salt.len() as u32).saturating_add(*gas_limit)
)]
pub fn instantiate(
origin: OriginFor<T>,
#[pallet::compact] value: BalanceOf<T>,
gas_limit: Weight,
storage_deposit_limit: Option<<BalanceOf<T> as codec::HasCompact>::Type>,
code_hash: CodeHash<T>,
data: Vec<u8>,
salt: Vec<u8>,
) -> DispatchResultWithPostInfo {
let origin = ensure_signed(origin)?;
let data_len = data.len() as u32;
let salt_len = salt.len() as u32;
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let common = CommonInput {
origin,
value,
data,
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gas_limit,
storage_deposit_limit: storage_deposit_limit.map(Into::into),
debug_message: None,
};
let mut output =
InstantiateInput::<T> { code: Code::Existing(code_hash), salt }.run_guarded(common);
if let Ok(retval) = &output.result {
if retval.1.did_revert() {
output.result = Err(<Error<T>>::ContractReverted.into());
}
}
output.gas_meter.into_dispatch_result(
output.result.map(|(_address, output)| output),
T::WeightInfo::instantiate(data_len, salt_len),
}
#[pallet::event]
pub enum Event<T: Config> {
/// Contract deployed by address at the specified address.
Instantiated { deployer: T::AccountId, contract: T::AccountId },
///
/// # Note
///
/// The only way for a contract to be removed and emitting this event is by calling
/// `seal_terminate`.
Terminated {
/// The contract that was terminated.
contract: T::AccountId,
/// The account that received the contracts remaining balance
beneficiary: T::AccountId,
},
/// Code with the specified hash has been stored.
CodeStored { code_hash: T::Hash },
/// A custom event emitted by the contract.
ContractEmitted {
/// The contract that emitted the event.
contract: T::AccountId,
/// Data supplied by the contract. Metadata generated during contract compilation
/// is needed to decode it.
data: Vec<u8>,
},
/// A code with the specified hash was removed.
CodeRemoved { code_hash: T::Hash },
/// A contract's code was updated.
ContractCodeUpdated {
/// The contract that has been updated.
contract: T::AccountId,
/// New code hash that was set for the contract.
new_code_hash: T::Hash,
/// Previous code hash of the contract.
old_code_hash: T::Hash,
},
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/// A contract was called either by a plain account or another contract.
///
/// # Note
///
/// Please keep in mind that like all events this is only emitted for successful
/// calls. This is because on failure all storage changes including events are
/// rolled back.
Called {
/// The account that called the `contract`.
caller: T::AccountId,
/// The contract that was called.
contract: T::AccountId,
},
/// A contract delegate called a code hash.
///
/// # Note
///
/// Please keep in mind that like all events this is only emitted for successful
/// calls. This is because on failure all storage changes including events are
/// rolled back.
DelegateCalled {
/// The contract that performed the delegate call and hence in whose context
/// the `code_hash` is executed.
contract: T::AccountId,
/// The code hash that was delegate called.
code_hash: CodeHash<T>,
},
}
#[pallet::error]
pub enum Error<T> {
/// A new schedule must have a greater version than the current one.
InvalidScheduleVersion,
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/// Invalid combination of flags supplied to `seal_call` or `seal_delegate_call`.
InvalidCallFlags,
/// The executed contract exhausted its gas limit.
OutOfGas,
/// The output buffer supplied to a contract API call was too small.
OutputBufferTooSmall,
/// Performing the requested transfer failed. Probably because there isn't enough
/// free balance in the sender's account.
TransferFailed,
/// Performing a call was denied because the calling depth reached the limit
/// of what is specified in the schedule.
MaxCallDepthReached,
/// No contract was found at the specified address.
ContractNotFound,
/// The code supplied to `instantiate_with_code` exceeds the limit specified in the
/// current schedule.
CodeTooLarge,
/// No code could be found at the supplied code hash.
CodeNotFound,
/// A buffer outside of sandbox memory was passed to a contract API function.
OutOfBounds,
/// Input passed to a contract API function failed to decode as expected type.
DecodingFailed,
/// Contract trapped during execution.
ContractTrapped,
/// The size defined in `T::MaxValueSize` was exceeded.
ValueTooLarge,
/// Termination of a contract is not allowed while the contract is already
/// on the call stack. Can be triggered by `seal_terminate`.
TerminatedWhileReentrant,
/// `seal_call` forwarded this contracts input. It therefore is no longer available.
InputForwarded,
/// The subject passed to `seal_random` exceeds the limit.
RandomSubjectTooLong,
/// The amount of topics passed to `seal_deposit_events` exceeds the limit.
TooManyTopics,
/// The chain does not provide a chain extension. Calling the chain extension results
/// in this error. Note that this usually shouldn't happen as deploying such contracts
/// is rejected.
NoChainExtension,
/// Removal of a contract failed because the deletion queue is full.
///
/// This can happen when calling `seal_terminate`.
/// The queue is filled by deleting contracts and emptied by a fixed amount each block.
/// Trying again during another block is the only way to resolve this issue.
DeletionQueueFull,
/// A contract with the same AccountId already exists.
DuplicateContract,
/// A contract self destructed in its constructor.
///
/// This can be triggered by a call to `seal_terminate`.
TerminatedInConstructor,
/// A call tried to invoke a contract that is flagged as non-reentrant.
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/// The only other cause is that a call from a contract into the runtime tried to call back
/// into `pallet-contracts`. This would make the whole pallet reentrant with regard to
/// contract code execution which is not supported.
ReentranceDenied,
/// Origin doesn't have enough balance to pay the required storage deposits.
StorageDepositNotEnoughFunds,
/// More storage was created than allowed by the storage deposit limit.
StorageDepositLimitExhausted,
/// Code removal was denied because the code is still in use by at least one contract.
CodeInUse,
/// The contract ran to completion but decided to revert its storage changes.
/// Please note that this error is only returned from extrinsics. When called directly
/// or via RPC an `Ok` will be returned. In this case the caller needs to inspect the flags
/// to determine whether a reversion has taken place.
ContractReverted,
/// The contract's code was found to be invalid during validation or instrumentation.
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///
/// The most likely cause of this is that an API was used which is not supported by the
/// node. This happens if an older node is used with a new version of ink!. Try updating
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/// your node to the newest available version.
///
/// A more detailed error can be found on the node console if debug messages are enabled
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/// by supplying `-lruntime::contracts=debug`.
CodeRejected,
/// An indetermistic code was used in a context where this is not permitted.
Indeterministic,
/// A mapping from an original code hash to the original code, untouched by instrumentation.
#[pallet::storage]
pub(crate) type PristineCode<T: Config> = StorageMap<_, Identity, CodeHash<T>, CodeVec<T>>;
/// A mapping between an original code hash and instrumented wasm code, ready for execution.
#[pallet::storage]
pub(crate) type CodeStorage<T: Config> =
StorageMap<_, Identity, CodeHash<T>, PrefabWasmModule<T>>;
/// A mapping between an original code hash and its owner information.
#[pallet::storage]
pub(crate) type OwnerInfoOf<T: Config> = StorageMap<_, Identity, CodeHash<T>, OwnerInfo<T>>;
/// This is a **monotonic** counter incremented on contract instantiation.
///
/// This is used in order to generate unique trie ids for contracts.
/// The trie id of a new contract is calculated from hash(account_id, nonce).
/// The nonce is required because otherwise the following sequence would lead to
/// a possible collision of storage:
///
/// 1. Create a new contract.
/// 2. Terminate the contract.
/// 3. Immediately recreate the contract with the same account_id.
///
/// This is bad because the contents of a trie are deleted lazily and there might be
/// storage of the old instantiation still in it when the new contract is created. Please
/// note that we can't replace the counter by the block number because the sequence above
/// can happen in the same block. We also can't keep the account counter in memory only
/// because storage is the only way to communicate across different extrinsics in the
/// same block.
///
/// # Note
///
/// Do not use it to determine the number of contracts. It won't be decremented if
/// a contract is destroyed.
pub(crate) type Nonce<T: Config> = StorageValue<_, u64, ValueQuery>;
/// The code associated with a given account.
///
/// TWOX-NOTE: SAFE since `AccountId` is a secure hash.
#[pallet::storage]
pub(crate) type ContractInfoOf<T: Config> =
StorageMap<_, Twox64Concat, T::AccountId, ContractInfo<T>>;
/// Evicted contracts that await child trie deletion.
///
/// Child trie deletion is a heavy operation depending on the amount of storage items
/// stored in said trie. Therefore this operation is performed lazily in `on_initialize`.
#[pallet::storage]
pub(crate) type DeletionQueue<T: Config> =
StorageValue<_, BoundedVec<DeletedContract, T::DeletionQueueDepth>, ValueQuery>;
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/// Context of a contract invocation.
struct CommonInput<'a, T: Config> {
origin: T::AccountId,
value: BalanceOf<T>,
data: Vec<u8>,
gas_limit: Weight,
storage_deposit_limit: Option<BalanceOf<T>>,
debug_message: Option<&'a mut DebugBufferVec<T>>,
}
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/// Input specific to a call into contract.
struct CallInput<T: Config> {
dest: T::AccountId,
determinism: Determinism,
}
/// Input specific to a contract instantiation invocation.
struct InstantiateInput<T: Config> {
code: Code<CodeHash<T>>,
salt: Vec<u8>,
}
/// Return type of private helper functions.
struct InternalOutput<T: Config, O> {
/// The gas meter that was used to execute the call.
gas_meter: GasMeter<T>,
/// The storage deposit used by the call.
storage_deposit: StorageDeposit<BalanceOf<T>>,
/// The result of the call.
result: Result<O, ExecError>,
}
/// Helper trait to wrap contract execution entry points into a single function
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/// [`Invokable::run_guarded`].
trait Invokable<T: Config> {
/// What is returned as a result of a successful invocation.
type Output;
/// Single entry point to contract execution.
/// Downstream execution flow is branched by implementations of [`Invokable`] trait:
///
/// - [`InstantiateInput::run`] runs contract instantiation,
/// - [`CallInput::run`] runs contract call.