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// Copyright 2017-2020 Parity Technologies (UK) Ltd.
// This file is part of Substrate.
// Substrate is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Substrate is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Substrate. If not, see <http://www.gnu.org/licenses/>.
//! I/O host interface for substrate runtime.
#![warn(missing_docs)]
#![cfg_attr(not(feature = "std"), no_std)]
#![cfg_attr(not(feature = "std"), feature(alloc_error_handler))]
#![cfg_attr(feature = "std",
doc = "Substrate runtime standard library as compiled when linked with Rust's standard library.")]
#![cfg_attr(not(feature = "std"),
doc = "Substrate's runtime standard library as compiled without Rust's standard library.")]
use sp_std::vec::Vec;
use sp_std::ops::Deref;
traits::{KeystoreExt, CallInWasmExt, TaskExecutorExt},
offchain::{OffchainExt, TransactionPoolExt},
hexdisplay::HexDisplay,
crypto::KeyTypeId, ed25519, sr25519, H256, LogLevel,
offchain::{
Timestamp, HttpRequestId, HttpRequestStatus, HttpError, StorageKind, OpaqueNetworkState,
},
use sp_trie::{TrieConfiguration, trie_types::Layout};
use sp_runtime_interface::{runtime_interface, Pointer};
use codec::{Encode, Decode};
#[cfg(feature = "std")]
use sp_externalities::{ExternalitiesExt, Externalities};
#[cfg(feature = "std")]
mod batch_verifier;
#[cfg(feature = "std")]
use batch_verifier::BatchVerifier;
/// Error verifying ECDSA signature
pub enum EcdsaVerifyError {
/// Incorrect value of R or S
/// Incorrect value of V
/// Invalid signature
BadSignature,
}
/// Returns a `ChildStorageKey` if the given `storage_key` slice is a valid storage
/// key or panics otherwise.
///
/// Panicking here is aligned with what the `without_std` environment would do
/// in the case of an invalid child storage key.
#[cfg(feature = "std")]
fn child_storage_key_or_panic(storage_key: &[u8]) -> ChildStorageKey {
match ChildStorageKey::from_slice(storage_key) {
Some(storage_key) => storage_key,
None => panic!("child storage key is invalid"),
}
}
/// Interface for accessing the storage from within the runtime.
#[runtime_interface]
pub trait Storage {
/// Returns the data for `key` in the storage or `None` if the key can not be found.
fn get(&self, key: &[u8]) -> Option<Vec<u8>> {
self.storage(key).map(|s| s.to_vec())
}
/// All Child api uses :
/// - A `child_storage_key` to define the anchor point for the child proof
/// (commonly the location where the child root is stored in its parent trie).
/// - A `child_storage_types` to identify the kind of the child type and how its
/// `child definition` parameter is encoded.
/// - A `child_definition_parameter` which is the additional information required
/// to use the child trie. For instance defaults child tries requires this to
/// contain a collision free unique id.
///
/// This function specifically returns the data for `key` in the child storage or `None`
/// if the key can not be found.
fn child_get(
&self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
) -> Option<Vec<u8>> {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.child_storage(storage_key, child_info, key).map(|s| s.to_vec())
}
/// Get `key` from storage, placing the value into `value_out` and return the number of
/// bytes that the entry in storage has beyond the offset or `None` if the storage entry
/// doesn't exist at all.
/// If `value_out` length is smaller than the returned length, only `value_out` length bytes
/// are copied into `value_out`.
fn read(&self, key: &[u8], value_out: &mut [u8], value_offset: u32) -> Option<u32> {
self.storage(key).map(|value| {
let value_offset = value_offset as usize;
let data = &value[value_offset.min(value.len())..];
let written = std::cmp::min(data.len(), value_out.len());
value_out[..written].copy_from_slice(&data[..written]);
value.len() as u32
})
}
/// Get `key` from child storage, placing the value into `value_out` and return the number
/// of bytes that the entry in storage has beyond the offset or `None` if the storage entry
/// doesn't exist at all.
/// If `value_out` length is smaller than the returned length, only `value_out` length bytes
/// are copied into `value_out`.
///
/// See `child_get` for common child api parameters.
fn child_read(
&self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
value_out: &mut [u8],
value_offset: u32,
) -> Option<u32> {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.child_storage(storage_key, child_info, key)
.map(|value| {
let value_offset = value_offset as usize;
let data = &value[value_offset.min(value.len())..];
let written = std::cmp::min(data.len(), value_out.len());
value_out[..written].copy_from_slice(&data[..written]);
value.len() as u32
})
}
/// Set `key` to `value` in the storage.
fn set(&mut self, key: &[u8], value: &[u8]) {
self.set_storage(key.to_vec(), value.to_vec());
}
/// Set `key` to `value` in the child storage denoted by `child_storage_key`.
///
/// See `child_get` for common child api parameters.
fn child_set(
&mut self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
value: &[u8],
) {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.set_child_storage(storage_key, child_info, key.to_vec(), value.to_vec());
}
/// Clear the storage of the given `key` and its value.
fn clear(&mut self, key: &[u8]) {
self.clear_storage(key)
}
/// Clear the given child storage of the given `key` and its value.
///
/// See `child_get` for common child api parameters.
fn child_clear(
&mut self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
) {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.clear_child_storage(storage_key, child_info, key);
}
/// Clear an entire child storage.
///
/// See `child_get` for common child api parameters.
fn child_storage_kill(
&mut self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
) {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.kill_child_storage(storage_key, child_info);
}
/// Check whether the given `key` exists in storage.
fn exists(&self, key: &[u8]) -> bool {
self.exists_storage(key)
}
/// Check whether the given `key` exists in storage.
///
/// See `child_get` for common child api parameters.
fn child_exists(
&self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
) -> bool {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.exists_child_storage(storage_key, child_info, key)
}
/// Clear the storage of each key-value pair where the key starts with the given `prefix`.
fn clear_prefix(&mut self, prefix: &[u8]) {
Externalities::clear_prefix(*self, prefix)
}
/// Clear the child storage of each key-value pair where the key starts with the given `prefix`.
///
/// See `child_get` for common child api parameters.
fn child_clear_prefix(
&mut self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
prefix: &[u8],
) {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.clear_child_prefix(storage_key, child_info, prefix);
}
/// "Commit" all existing operations and compute the resulting storage root.
///
/// The hashing algorithm is defined by the `Block`.
///
/// Returns the SCALE encoded hash.
fn root(&mut self) -> Vec<u8> {
self.storage_root()
}
/// "Commit" all existing operations and compute the resulting child storage root.
///
/// The hashing algorithm is defined by the `Block`.
///
/// Returns the SCALE encoded hash.
///
/// See `child_get` for common child api parameters.
fn child_root(
&mut self,
child_storage_key: &[u8],
) -> Vec<u8> {
let storage_key = child_storage_key_or_panic(child_storage_key);
self.child_storage_root(storage_key)
}
/// "Commit" all existing operations and get the resulting storage change root.
/// `parent_hash` is a SCALE encoded hash.
///
/// The hashing algorithm is defined by the `Block`.
///
/// Returns an `Some(_)` which holds the SCALE encoded hash or `None` when
/// changes trie is disabled.
fn changes_root(&mut self, parent_hash: &[u8]) -> Option<Vec<u8>> {
Bastian Köcher
committed
self.storage_changes_root(parent_hash)
.expect("Invalid `parent_hash` given to `changes_root`.")
/// Get the next key in storage after the given one in lexicographic order.
fn next_key(&mut self, key: &[u8]) -> Option<Vec<u8>> {
self.next_storage_key(&key)
}
/// Get the next key in storage after the given one in lexicographic order in child storage.
fn child_next_key(
&mut self,
child_storage_key: &[u8],
child_definition: &[u8],
child_type: u32,
key: &[u8],
) -> Option<Vec<u8>> {
let storage_key = child_storage_key_or_panic(child_storage_key);
let child_info = ChildInfo::resolve_child_info(child_type, child_definition)
.expect("Invalid child definition");
self.next_child_storage_key(storage_key, child_info, key)
/// Interface that provides trie related functionality.
#[runtime_interface]
pub trait Trie {
/// A trie root formed from the iterated items.
fn blake2_256_root(input: Vec<(Vec<u8>, Vec<u8>)>) -> H256 {
Layout::<sp_core::Blake2Hasher>::trie_root(input)
}
/// A trie root formed from the enumerated items.
fn blake2_256_ordered_root(input: Vec<Vec<u8>>) -> H256 {
Layout::<sp_core::Blake2Hasher>::ordered_trie_root(input)
}
}
/// Interface that provides miscellaneous functions for communicating between the runtime and the node.
#[runtime_interface]
pub trait Misc {
/// The current relay chain identifier.
fn chain_id(&self) -> u64 {
sp_externalities::Externalities::chain_id(*self)
}
/// Print a number.
fn print_num(val: u64) {
log::debug!(target: "runtime", "{}", val);
}
/// Print any valid `utf8` buffer.
fn print_utf8(utf8: &[u8]) {
if let Ok(data) = std::str::from_utf8(utf8) {
log::debug!(target: "runtime", "{}", data)
/// Print any `u8` slice as hex.
fn print_hex(data: &[u8]) {
log::debug!(target: "runtime", "{}", HexDisplay::from(&data));
/// Extract the runtime version of the given wasm blob by calling `Core_version`.
///
/// Returns the SCALE encoded runtime version and `None` if the call failed.
///
/// # Performance
///
/// Calling this function is very expensive and should only be done very occasionally.
/// For getting the runtime version, it requires instantiating the wasm blob and calling a
/// function in this blob.
fn runtime_version(&mut self, wasm: &[u8]) -> Option<Vec<u8>> {
// Create some dummy externalities, `Core_version` should not write data anyway.
let mut ext = sp_state_machine::BasicExternalities::default();
self.extension::<CallInWasmExt>()
.expect("No `CallInWasmExt` associated for the current context!")
.call_in_wasm(wasm, None, "Core_version", &[], &mut ext)
}
/// Interfaces for working with crypto related types from within the runtime.
#[runtime_interface]
pub trait Crypto {
/// Returns all `ed25519` public keys for the given key id from the keystore.
fn ed25519_public_keys(&mut self, id: KeyTypeId) -> Vec<ed25519::Public> {
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.read()
.ed25519_public_keys(id)
}
/// Generate an `ed22519` key for the given key type using an optional `seed` and
/// store it in the keystore.
///
/// The `seed` needs to be a valid utf8.
///
/// Returns the public key.
fn ed25519_generate(&mut self, id: KeyTypeId, seed: Option<Vec<u8>>) -> ed25519::Public {
let seed = seed.as_ref().map(|s| std::str::from_utf8(&s).expect("Seed is valid utf8!"));
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.write()
.ed25519_generate_new(id, seed)
.expect("`ed25519_generate` failed")
}
/// Sign the given `msg` with the `ed25519` key that corresponds to the given public key and
/// key type in the keystore.
///
/// Returns the signature.
fn ed25519_sign(
&mut self,
id: KeyTypeId,
pub_key: &ed25519::Public,
msg: &[u8],
) -> Option<ed25519::Signature> {
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.read()
.sign_with(id, &pub_key.into(), msg)
.map(|sig| ed25519::Signature::from_slice(sig.as_slice()))
.ok()
/// Returns `true` when the verification is either successful or batched.
/// If no batching verification extension registered, this will return the result
/// of verification immediately. If batching verification extension is registered
/// caller should call `crypto::finish_batch_verify` to actualy check all submitted
/// signatures.
fn ed25519_verify(
sig: &ed25519::Signature,
msg: &[u8],
pub_key: &ed25519::Public,
) -> bool {
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// TODO: see #5554, this is used outside of externalities context/runtime, thus this manual
// `with_externalities`.
//
// This `with_externalities(..)` block returns Some(Some(result)) if signature verification was successfully
// batched, everything else (Some(None)/None) means it was not batched and needs to be verified.
let evaluated = sp_externalities::with_externalities(|mut instance|
instance.extension::<VerificationExt>().map(
|extension| extension.push_ed25519(
sig.clone(),
pub_key.clone(),
msg.to_vec(),
)
)
);
match evaluated {
Some(Some(val)) => val,
_ => ed25519::Pair::verify(sig, msg, pub_key),
}
}
/// Verify `sr25519` signature.
///
/// Returns `true` when the verification is either successful or batched.
/// If no batching verification extension registered, this will return the result
/// of verification immediately. If batching verification extension is registered,
/// caller should call `crypto::finish_batch_verify` to actualy check all submitted
#[version(2)]
fn sr25519_verify(
sig: &sr25519::Signature,
msg: &[u8],
pub_key: &sr25519::Public,
) -> bool {
// TODO: see #5554, this is used outside of externalities context/runtime, thus this manual
// `with_externalities`.
//
// This `with_externalities(..)` block returns Some(Some(result)) if signature verification was successfully
// batched, everything else (Some(None)/None) means it was not batched and needs to be verified.
let evaluated = sp_externalities::with_externalities(|mut instance|
instance.extension::<VerificationExt>().map(
|extension| extension.push_sr25519(
sig.clone(),
pub_key.clone(),
msg.to_vec(),
)
)
);
match evaluated {
Some(Some(val)) => val,
_ => sr25519::Pair::verify(sig, msg, pub_key),
}
}
/// Start verification extension.
fn start_batch_verify(&mut self) {
let scheduler = self.extension::<TaskExecutorExt>()
.expect("No task executor associated with the current context!")
.0
.clone();
self.register_extension(VerificationExt(BatchVerifier::new(scheduler)))
.expect("Failed to register required extension: `VerificationExt`");
}
/// Finish batch-verification of signatures.
///
/// Verify or wait for verification to finish for all signatures which were previously
/// deferred by `sr25519_verify`/`ed25519_verify`.
///
/// Will panic if no `VerificationExt` is registered (`start_batch_verify` was not called).
fn finish_batch_verify(&mut self) -> bool {
let result = self.extension::<VerificationExt>()
.expect("`finish_batch_verify` should only be called after `start_batch_verify`")
.verify_and_clear();
self.deregister_extension::<VerificationExt>()
.expect("No verification extension in current context!");
result
/// Returns all `sr25519` public keys for the given key id from the keystore.
fn sr25519_public_keys(&mut self, id: KeyTypeId) -> Vec<sr25519::Public> {
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.read()
.sr25519_public_keys(id)
}
/// Generate an `sr22519` key for the given key type using an optional seed and
/// store it in the keystore.
///
/// The `seed` needs to be a valid utf8.
///
/// Returns the public key.
fn sr25519_generate(&mut self, id: KeyTypeId, seed: Option<Vec<u8>>) -> sr25519::Public {
let seed = seed.as_ref().map(|s| std::str::from_utf8(&s).expect("Seed is valid utf8!"));
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.write()
.sr25519_generate_new(id, seed)
.expect("`sr25519_generate` failed")
}
/// Sign the given `msg` with the `sr25519` key that corresponds to the given public key and
/// key type in the keystore.
///
/// Returns the signature.
fn sr25519_sign(
&mut self,
id: KeyTypeId,
pub_key: &sr25519::Public,
msg: &[u8],
) -> Option<sr25519::Signature> {
self.extension::<KeystoreExt>()
.expect("No `keystore` associated for the current context!")
.read()
.sign_with(id, &pub_key.into(), msg)
.map(|sig| sr25519::Signature::from_slice(sig.as_slice()))
.ok()
/// Verify an `sr25519` signature.
///
/// Returns `true` when the verification in successful regardless of
/// signature version.
fn sr25519_verify(sig: &sr25519::Signature, msg: &[u8], pubkey: &sr25519::Public) -> bool {
sr25519::Pair::verify_deprecated(sig, msg, pubkey)
}
/// Verify and recover a SECP256k1 ECDSA signature.
///
/// - `sig` is passed in RSV format. V should be either `0/1` or `27/28`.
/// - `msg` is the blake2-256 hash of the message.
///
/// Returns `Err` if the signature is bad, otherwise the 64-byte pubkey
/// (doesn't include the 0x04 prefix).
fn secp256k1_ecdsa_recover(
sig: &[u8; 65],
msg: &[u8; 32],
) -> Result<[u8; 64], EcdsaVerifyError> {
let rs = secp256k1::Signature::parse_slice(&sig[0..64])
.map_err(|_| EcdsaVerifyError::BadRS)?;
let v = secp256k1::RecoveryId::parse(if sig[64] > 26 { sig[64] - 27 } else { sig[64] } as u8)
.map_err(|_| EcdsaVerifyError::BadV)?;
let pubkey = secp256k1::recover(&secp256k1::Message::parse(msg), &rs, &v)
.map_err(|_| EcdsaVerifyError::BadSignature)?;
let mut res = [0u8; 64];
res.copy_from_slice(&pubkey.serialize()[1..65]);
Ok(res)
}
/// Verify and recover a SECP256k1 ECDSA signature.
///
/// - `sig` is passed in RSV format. V should be either `0/1` or `27/28`.
/// - `msg` is the blake2-256 hash of the message.
///
/// Returns `Err` if the signature is bad, otherwise the 33-byte compressed pubkey.
fn secp256k1_ecdsa_recover_compressed(
sig: &[u8; 65],
msg: &[u8; 32],
) -> Result<[u8; 33], EcdsaVerifyError> {
let rs = secp256k1::Signature::parse_slice(&sig[0..64])
.map_err(|_| EcdsaVerifyError::BadRS)?;
let v = secp256k1::RecoveryId::parse(if sig[64] > 26 { sig[64] - 27 } else { sig[64] } as u8)
.map_err(|_| EcdsaVerifyError::BadV)?;
let pubkey = secp256k1::recover(&secp256k1::Message::parse(msg), &rs, &v)
.map_err(|_| EcdsaVerifyError::BadSignature)?;
Ok(pubkey.serialize_compressed())
}
}
/// Interface that provides functions for hashing with different algorithms.
#[runtime_interface]
pub trait Hashing {
/// Conduct a 256-bit Keccak hash.
fn keccak_256(data: &[u8]) -> [u8; 32] {
sp_core::hashing::keccak_256(data)
/// Conduct a 256-bit Sha2 hash.
fn sha2_256(data: &[u8]) -> [u8; 32] {
sp_core::hashing::sha2_256(data)
/// Conduct a 128-bit Blake2 hash.
fn blake2_128(data: &[u8]) -> [u8; 16] {
sp_core::hashing::blake2_128(data)
/// Conduct a 256-bit Blake2 hash.
fn blake2_256(data: &[u8]) -> [u8; 32] {
sp_core::hashing::blake2_256(data)
}
/// Conduct four XX hashes to give a 256-bit result.
fn twox_256(data: &[u8]) -> [u8; 32] {
sp_core::hashing::twox_256(data)
}
/// Conduct two XX hashes to give a 128-bit result.
fn twox_128(data: &[u8]) -> [u8; 16] {
sp_core::hashing::twox_128(data)
}
/// Conduct two XX hashes to give a 64-bit result.
fn twox_64(data: &[u8]) -> [u8; 8] {
sp_core::hashing::twox_64(data)
#[cfg(feature = "std")]
sp_externalities::decl_extension! {
/// The keystore extension to register/retrieve from the externalities.
pub struct VerificationExt(BatchVerifier);
}
/// Interface that provides functions to access the offchain functionality.
#[runtime_interface]
pub trait Offchain {
/// Returns if the local node is a potential validator.
///
/// Even if this function returns `true`, it does not mean that any keys are configured
/// and that the validator is registered in the chain.
fn is_validator(&mut self) -> bool {
self.extension::<OffchainExt>()
.expect("is_validator can be called only in the offchain worker context")
.is_validator()
}
/// Submit an encoded transaction to the pool.
///
/// The transaction will end up in the pool.
fn submit_transaction(&mut self, data: Vec<u8>) -> Result<(), ()> {
self.extension::<TransactionPoolExt>()
.expect("submit_transaction can be called only in the offchain call context with
TransactionPool capabilities enabled")
.submit_transaction(data)
}
/// Returns information about the local node's network state.
fn network_state(&mut self) -> Result<OpaqueNetworkState, ()> {
self.extension::<OffchainExt>()
.expect("network_state can be called only in the offchain worker context")
.network_state()
}
/// Returns current UNIX timestamp (in millis)
fn timestamp(&mut self) -> Timestamp {
self.extension::<OffchainExt>()
.expect("timestamp can be called only in the offchain worker context")
.timestamp()
}
/// Pause the execution until `deadline` is reached.
fn sleep_until(&mut self, deadline: Timestamp) {
self.extension::<OffchainExt>()
.expect("sleep_until can be called only in the offchain worker context")
.sleep_until(deadline)
}
/// Returns a random seed.
///
/// This is a truly random, non-deterministic seed generated by host environment.
/// Obviously fine in the off-chain worker context.
fn random_seed(&mut self) -> [u8; 32] {
self.extension::<OffchainExt>()
.expect("random_seed can be called only in the offchain worker context")
.random_seed()
}
/// Sets a value in the local storage.
///
/// Note this storage is not part of the consensus, it's only accessible by
/// offchain worker tasks running on the same machine. It IS persisted between runs.
fn local_storage_set(&mut self, kind: StorageKind, key: &[u8], value: &[u8]) {
self.extension::<OffchainExt>()
.expect("local_storage_set can be called only in the offchain worker context")
.local_storage_set(kind, key, value)
}
/// Sets a value in the local storage if it matches current value.
///
/// Since multiple offchain workers may be running concurrently, to prevent
/// data races use CAS to coordinate between them.
///
/// Returns `true` if the value has been set, `false` otherwise.
///
/// Note this storage is not part of the consensus, it's only accessible by
/// offchain worker tasks running on the same machine. It IS persisted between runs.
fn local_storage_compare_and_set(
&mut self,
kind: StorageKind,
key: &[u8],
old_value: Option<Vec<u8>>,
new_value: &[u8],
) -> bool {
self.extension::<OffchainExt>()
.expect("local_storage_compare_and_set can be called only in the offchain worker context")
.local_storage_compare_and_set(kind, key, old_value.as_ref().map(|v| v.deref()), new_value)
}
/// Gets a value from the local storage.
///
/// If the value does not exist in the storage `None` will be returned.
/// Note this storage is not part of the consensus, it's only accessible by
/// offchain worker tasks running on the same machine. It IS persisted between runs.
fn local_storage_get(&mut self, kind: StorageKind, key: &[u8]) -> Option<Vec<u8>> {
self.extension::<OffchainExt>()
.expect("local_storage_get can be called only in the offchain worker context")
.local_storage_get(kind, key)
}
/// Initiates a http request given HTTP verb and the URL.
///
/// Meta is a future-reserved field containing additional, parity-scale-codec encoded parameters.
/// Returns the id of newly started request.
fn http_request_start(
&mut self,
method: &str,
uri: &str,
meta: &[u8],
) -> Result<HttpRequestId, ()> {
self.extension::<OffchainExt>()
.expect("http_request_start can be called only in the offchain worker context")
.http_request_start(method, uri, meta)
}
/// Append header to the request.
fn http_request_add_header(
&mut self,
request_id: HttpRequestId,
name: &str,
value: &str,
) -> Result<(), ()> {
self.extension::<OffchainExt>()
.expect("http_request_add_header can be called only in the offchain worker context")
.http_request_add_header(request_id, name, value)
}
/// Write a chunk of request body.
///
/// Writing an empty chunks finalizes the request.
/// Passing `None` as deadline blocks forever.
///
/// Returns an error in case deadline is reached or the chunk couldn't be written.
fn http_request_write_body(
&mut self,
request_id: HttpRequestId,
chunk: &[u8],
deadline: Option<Timestamp>,
) -> Result<(), HttpError> {
self.extension::<OffchainExt>()
.expect("http_request_write_body can be called only in the offchain worker context")
.http_request_write_body(request_id, chunk, deadline)
}
/// Block and wait for the responses for given requests.
///
/// Returns a vector of request statuses (the len is the same as ids).
/// Note that if deadline is not provided the method will block indefinitely,
/// otherwise unready responses will produce `DeadlineReached` status.
///
/// Passing `None` as deadline blocks forever.
fn http_response_wait(
&mut self,
ids: &[HttpRequestId],
deadline: Option<Timestamp>,
) -> Vec<HttpRequestStatus> {
self.extension::<OffchainExt>()
.expect("http_response_wait can be called only in the offchain worker context")
.http_response_wait(ids, deadline)
}
/// Read all response headers.
///
/// Returns a vector of pairs `(HeaderKey, HeaderValue)`.
/// NOTE response headers have to be read before response body.
fn http_response_headers(&mut self, request_id: HttpRequestId) -> Vec<(Vec<u8>, Vec<u8>)> {
self.extension::<OffchainExt>()
.expect("http_response_headers can be called only in the offchain worker context")
.http_response_headers(request_id)
}
/// Read a chunk of body response to given buffer.
///
/// Returns the number of bytes written or an error in case a deadline
/// is reached or server closed the connection.
/// If `0` is returned it means that the response has been fully consumed
/// and the `request_id` is now invalid.
/// NOTE this implies that response headers must be read before draining the body.
/// Passing `None` as a deadline blocks forever.
fn http_response_read_body(
&mut self,
request_id: HttpRequestId,
buffer: &mut [u8],
deadline: Option<Timestamp>,
) -> Result<u32, HttpError> {
self.extension::<OffchainExt>()
.expect("http_response_read_body can be called only in the offchain worker context")
.http_response_read_body(request_id, buffer, deadline)
.map(|r| r as u32)
}
}
/// Wasm only interface that provides functions for calling into the allocator.
#[runtime_interface(wasm_only)]
trait Allocator {
/// Malloc the given number of bytes and return the pointer to the allocated memory location.
fn malloc(&mut self, size: u32) -> Pointer<u8> {
self.allocate_memory(size).expect("Failed to allocate memory")
}
/// Free the given pointer.
fn free(&mut self, ptr: Pointer<u8>) {
self.deallocate_memory(ptr).expect("Failed to deallocate memory")
}
}
/// Interface that provides functions for logging from within the runtime.
#[runtime_interface]
pub trait Logging {
/// Request to print a log message on the host.
///
/// Note that this will be only displayed if the host is enabled to display log messages with
/// given level and target.
///
/// Instead of using directly, prefer setting up `RuntimeLogger` and using `log` macros.
fn log(level: LogLevel, target: &str, message: &[u8]) {
if let Ok(message) = std::str::from_utf8(message) {
log::log!(
target: target,
log::Level::from(level),
"{}",
message,
)
}
}
}
/// Wasm-only interface that provides functions for interacting with the sandbox.
#[runtime_interface(wasm_only)]
pub trait Sandbox {
/// Instantiate a new sandbox instance with the given `wasm_code`.
fn instantiate(
&mut self,
dispatch_thunk: u32,
wasm_code: &[u8],
env_def: &[u8],
state_ptr: Pointer<u8>,
) -> u32 {
self.sandbox()
.instance_new(dispatch_thunk, wasm_code, env_def, state_ptr.into())
.expect("Failed to instantiate a new sandbox")
}
/// Invoke `function` in the sandbox with `sandbox_idx`.
fn invoke(
&mut self,
instance_idx: u32,
function: &str,
args: &[u8],
return_val_ptr: Pointer<u8>,
return_val_len: u32,
state_ptr: Pointer<u8>,
) -> u32 {
self.sandbox().invoke(
instance_idx,
&function,
&args,
return_val_ptr,
return_val_len,
state_ptr.into(),
).expect("Failed to invoke function with sandbox")
}
/// Create a new memory instance with the given `initial` and `maximum` size.
fn memory_new(&mut self, initial: u32, maximum: u32) -> u32 {
self.sandbox()
.memory_new(initial, maximum)
.expect("Failed to create new memory with sandbox")
}
/// Get the memory starting at `offset` from the instance with `memory_idx` into the buffer.
fn memory_get(
&mut self,
memory_idx: u32,
offset: u32,
buf_ptr: Pointer<u8>,
buf_len: u32,
) -> u32 {
self.sandbox()
.memory_get(memory_idx, offset, buf_ptr, buf_len)
.expect("Failed to get memory with sandbox")
}
/// Set the memory in the given `memory_idx` to the given value at `offset`.
fn memory_set(
&mut self,
memory_idx: u32,
offset: u32,
val_ptr: Pointer<u8>,
val_len: u32,
) -> u32 {
self.sandbox()
.memory_set(memory_idx, offset, val_ptr, val_len)
.expect("Failed to set memory with sandbox")
}
/// Teardown the memory instance with the given `memory_idx`.
fn memory_teardown(&mut self, memory_idx: u32) {
self.sandbox().memory_teardown(memory_idx).expect("Failed to teardown memory with sandbox")
}
/// Teardown the sandbox instance with the given `instance_idx`.
fn instance_teardown(&mut self, instance_idx: u32) {
self.sandbox().instance_teardown(instance_idx).expect("Failed to teardown sandbox instance")
/// Get the value from a global with the given `name`. The sandbox is determined by the given
/// `instance_idx`.
///
/// Returns `Some(_)` when the requested global variable could be found.
fn get_global_val(&mut self, instance_idx: u32, name: &str) -> Option<sp_wasm_interface::Value> {
self.sandbox().get_global_val(instance_idx, name).expect("Failed to get global from sandbox")
}
}
/// Allocator used by Substrate when executing the Wasm runtime.
#[cfg(not(feature = "std"))]
struct WasmAllocator;
#[cfg(all(not(feature = "disable_allocator"), not(feature = "std")))]
#[global_allocator]
static ALLOCATOR: WasmAllocator = WasmAllocator;
#[cfg(not(feature = "std"))]
mod allocator_impl {
use super::*;
use core::alloc::{GlobalAlloc, Layout};
unsafe impl GlobalAlloc for WasmAllocator {
unsafe fn alloc(&self, layout: Layout) -> *mut u8 {
allocator::malloc(layout.size() as u32)
}
unsafe fn dealloc(&self, ptr: *mut u8, _: Layout) {
allocator::free(ptr)
}
}
}
/// A default panic handler for WASM environment.
#[cfg(all(not(feature = "disable_panic_handler"), not(feature = "std")))]
#[panic_handler]
#[no_mangle]
pub fn panic(info: &core::panic::PanicInfo) -> ! {
unsafe {
let message = sp_std::alloc::format!("{}", info);
logging::log(LogLevel::Error, "runtime", message.as_bytes());
core::arch::wasm32::unreachable();