Official Go implementation of the Ethereum protocol
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go-ethereum/core/state/journal.go

496 lines
12 KiB

// Copyright 2016 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library 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 Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
package state
import (
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
"fmt"
"maps"
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
"slices"
"sort"
"github.com/ethereum/go-ethereum/common"
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
"github.com/ethereum/go-ethereum/core/types"
"github.com/holiman/uint256"
)
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
type revision struct {
id int
journalIndex int
}
// journalEntry is a modification entry in the state change journal that can be
// reverted on demand.
type journalEntry interface {
// revert undoes the changes introduced by this journal entry.
revert(*StateDB)
// dirtied returns the Ethereum address modified by this journal entry.
dirtied() *common.Address
// copy returns a deep-copied journal entry.
copy() journalEntry
}
// journal contains the list of state modifications applied since the last state
// commit. These are tracked to be able to be reverted in the case of an execution
// exception or request for reversal.
type journal struct {
entries []journalEntry // Current changes tracked by the journal
dirties map[common.Address]int // Dirty accounts and the number of changes
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
validRevisions []revision
nextRevisionId int
}
// newJournal creates a new initialized journal.
func newJournal() *journal {
return &journal{
dirties: make(map[common.Address]int),
}
}
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
// reset clears the journal, after this operation the journal can be used anew.
// It is semantically similar to calling 'newJournal', but the underlying slices
// can be reused.
func (j *journal) reset() {
j.entries = j.entries[:0]
j.validRevisions = j.validRevisions[:0]
clear(j.dirties)
j.nextRevisionId = 0
}
// snapshot returns an identifier for the current revision of the state.
func (j *journal) snapshot() int {
id := j.nextRevisionId
j.nextRevisionId++
j.validRevisions = append(j.validRevisions, revision{id, j.length()})
return id
}
// revertToSnapshot reverts all state changes made since the given revision.
func (j *journal) revertToSnapshot(revid int, s *StateDB) {
// Find the snapshot in the stack of valid snapshots.
idx := sort.Search(len(j.validRevisions), func(i int) bool {
return j.validRevisions[i].id >= revid
})
if idx == len(j.validRevisions) || j.validRevisions[idx].id != revid {
panic(fmt.Errorf("revision id %v cannot be reverted", revid))
}
snapshot := j.validRevisions[idx].journalIndex
// Replay the journal to undo changes and remove invalidated snapshots
j.revert(s, snapshot)
j.validRevisions = j.validRevisions[:idx]
}
// append inserts a new modification entry to the end of the change journal.
func (j *journal) append(entry journalEntry) {
j.entries = append(j.entries, entry)
if addr := entry.dirtied(); addr != nil {
j.dirties[*addr]++
}
}
// revert undoes a batch of journalled modifications along with any reverted
// dirty handling too.
func (j *journal) revert(statedb *StateDB, snapshot int) {
for i := len(j.entries) - 1; i >= snapshot; i-- {
// Undo the changes made by the operation
j.entries[i].revert(statedb)
// Drop any dirty tracking induced by the change
if addr := j.entries[i].dirtied(); addr != nil {
if j.dirties[*addr]--; j.dirties[*addr] == 0 {
delete(j.dirties, *addr)
}
}
}
j.entries = j.entries[:snapshot]
}
// dirty explicitly sets an address to dirty, even if the change entries would
// otherwise suggest it as clean. This method is an ugly hack to handle the RIPEMD
// precompile consensus exception.
func (j *journal) dirty(addr common.Address) {
j.dirties[addr]++
}
// length returns the current number of entries in the journal.
func (j *journal) length() int {
return len(j.entries)
}
// copy returns a deep-copied journal.
func (j *journal) copy() *journal {
entries := make([]journalEntry, 0, j.length())
for i := 0; i < j.length(); i++ {
entries = append(entries, j.entries[i].copy())
}
return &journal{
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
entries: entries,
dirties: maps.Clone(j.dirties),
validRevisions: slices.Clone(j.validRevisions),
nextRevisionId: j.nextRevisionId,
}
}
func (j *journal) logChange(txHash common.Hash) {
j.append(addLogChange{txhash: txHash})
}
func (j *journal) createObject(addr common.Address) {
j.append(createObjectChange{account: &addr})
}
func (j *journal) createContract(addr common.Address) {
j.append(createContractChange{account: addr})
}
func (j *journal) destruct(addr common.Address) {
j.append(selfDestructChange{account: &addr})
}
func (j *journal) storageChange(addr common.Address, key, prev, origin common.Hash) {
j.append(storageChange{
account: &addr,
key: key,
prevvalue: prev,
origvalue: origin,
})
}
func (j *journal) transientStateChange(addr common.Address, key, prev common.Hash) {
j.append(transientStorageChange{
account: &addr,
key: key,
prevalue: prev,
})
}
func (j *journal) refundChange(previous uint64) {
j.append(refundChange{prev: previous})
}
func (j *journal) balanceChange(addr common.Address, previous *uint256.Int) {
j.append(balanceChange{
account: &addr,
prev: previous.Clone(),
})
}
func (j *journal) setCode(address common.Address) {
j.append(codeChange{account: &address})
}
func (j *journal) nonceChange(address common.Address, prev uint64) {
j.append(nonceChange{
account: &address,
prev: prev,
})
}
func (j *journal) touchChange(address common.Address) {
j.append(touchChange{
account: &address,
})
if address == ripemd {
// Explicitly put it in the dirty-cache, which is otherwise generated from
// flattened journals.
j.dirty(address)
}
}
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
func (j *journal) accessListAddAccount(addr common.Address) {
j.append(accessListAddAccountChange{&addr})
}
func (j *journal) accessListAddSlot(addr common.Address, slot common.Hash) {
j.append(accessListAddSlotChange{
address: &addr,
slot: &slot,
})
}
type (
// Changes to the account trie.
createObjectChange struct {
account *common.Address
}
// createContractChange represents an account becoming a contract-account.
// This event happens prior to executing initcode. The journal-event simply
// manages the created-flag, in order to allow same-tx destruction.
createContractChange struct {
account common.Address
}
selfDestructChange struct {
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
account *common.Address
}
// Changes to individual accounts.
balanceChange struct {
account *common.Address
prev *uint256.Int
}
nonceChange struct {
account *common.Address
prev uint64
}
storageChange struct {
account *common.Address
key common.Hash
prevvalue common.Hash
origvalue common.Hash
}
codeChange struct {
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
account *common.Address
}
// Changes to other state values.
refundChange struct {
prev uint64
}
addLogChange struct {
txhash common.Hash
}
touchChange struct {
account *common.Address
}
// Changes to the access list
accessListAddAccountChange struct {
address *common.Address
}
accessListAddSlotChange struct {
address *common.Address
slot *common.Hash
}
// Changes to transient storage
transientStorageChange struct {
account *common.Address
key, prevalue common.Hash
}
)
func (ch createObjectChange) revert(s *StateDB) {
delete(s.stateObjects, *ch.account)
}
func (ch createObjectChange) dirtied() *common.Address {
return ch.account
}
func (ch createObjectChange) copy() journalEntry {
return createObjectChange{
account: ch.account,
}
}
func (ch createContractChange) revert(s *StateDB) {
s.getStateObject(ch.account).newContract = false
}
func (ch createContractChange) dirtied() *common.Address {
return nil
}
func (ch createContractChange) copy() journalEntry {
return createContractChange{
account: ch.account,
}
}
func (ch selfDestructChange) revert(s *StateDB) {
obj := s.getStateObject(*ch.account)
if obj != nil {
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
obj.selfDestructed = false
}
}
func (ch selfDestructChange) dirtied() *common.Address {
return ch.account
}
func (ch selfDestructChange) copy() journalEntry {
return selfDestructChange{
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
account: ch.account,
}
}
var ripemd = common.HexToAddress("0000000000000000000000000000000000000003")
func (ch touchChange) revert(s *StateDB) {
}
func (ch touchChange) dirtied() *common.Address {
return ch.account
}
func (ch touchChange) copy() journalEntry {
return touchChange{
account: ch.account,
}
}
func (ch balanceChange) revert(s *StateDB) {
s.getStateObject(*ch.account).setBalance(ch.prev)
}
func (ch balanceChange) dirtied() *common.Address {
return ch.account
}
func (ch balanceChange) copy() journalEntry {
return balanceChange{
account: ch.account,
prev: new(uint256.Int).Set(ch.prev),
}
}
func (ch nonceChange) revert(s *StateDB) {
s.getStateObject(*ch.account).setNonce(ch.prev)
}
func (ch nonceChange) dirtied() *common.Address {
return ch.account
}
func (ch nonceChange) copy() journalEntry {
return nonceChange{
account: ch.account,
prev: ch.prev,
}
}
func (ch codeChange) revert(s *StateDB) {
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
s.getStateObject(*ch.account).setCode(types.EmptyCodeHash, nil)
}
func (ch codeChange) dirtied() *common.Address {
return ch.account
}
func (ch codeChange) copy() journalEntry {
core/state: semantic journalling (part 1) (#28880) This is a follow-up to #29520, and a preparatory PR to a more thorough change in the journalling system. ### API methods instead of `append` operations This PR hides the journal-implementation details away, so that the statedb invokes methods like `JournalCreate`, instead of explicitly appending journal-events in a list. This means that it's up to the journal whether to implement it as a sequence of events or aggregate/merge events. ### Snapshot-management inside the journal This PR also makes it so that management of valid snapshots is moved inside the journal, exposed via the methods `Snapshot() int` and `RevertToSnapshot(revid int, s *StateDB)`. ### SetCode JournalSetCode journals the setting of code: it is implicit that the previous values were "no code" and emptyCodeHash. Therefore, we can simplify the setCode journal. ### Selfdestruct The self-destruct journalling is a bit strange: we allow the selfdestruct operation to be journalled several times. This makes it so that we also are forced to store whether the account was already destructed. What we can do instead, is to only journal the first destruction, and after that only journal balance-changes, but not journal the selfdestruct itself. This simplifies the journalling, so that internals about state management does not leak into the journal-API. ### Preimages Preimages were, for some reason, integrated into the journal management, despite not being a consensus-critical data structure. This PR undoes that. --------- Co-authored-by: Gary Rong <garyrong0905@gmail.com>
2 months ago
return codeChange{account: ch.account}
}
func (ch storageChange) revert(s *StateDB) {
s.getStateObject(*ch.account).setState(ch.key, ch.prevvalue, ch.origvalue)
}
func (ch storageChange) dirtied() *common.Address {
return ch.account
}
func (ch storageChange) copy() journalEntry {
return storageChange{
account: ch.account,
key: ch.key,
prevvalue: ch.prevvalue,
}
}
func (ch transientStorageChange) revert(s *StateDB) {
s.setTransientState(*ch.account, ch.key, ch.prevalue)
}
func (ch transientStorageChange) dirtied() *common.Address {
return nil
}
func (ch transientStorageChange) copy() journalEntry {
return transientStorageChange{
account: ch.account,
key: ch.key,
prevalue: ch.prevalue,
}
}
func (ch refundChange) revert(s *StateDB) {
s.refund = ch.prev
}
func (ch refundChange) dirtied() *common.Address {
return nil
}
func (ch refundChange) copy() journalEntry {
return refundChange{
prev: ch.prev,
}
}
func (ch addLogChange) revert(s *StateDB) {
logs := s.logs[ch.txhash]
if len(logs) == 1 {
delete(s.logs, ch.txhash)
} else {
s.logs[ch.txhash] = logs[:len(logs)-1]
}
s.logSize--
}
func (ch addLogChange) dirtied() *common.Address {
return nil
}
func (ch addLogChange) copy() journalEntry {
return addLogChange{
txhash: ch.txhash,
}
}
func (ch accessListAddAccountChange) revert(s *StateDB) {
/*
One important invariant here, is that whenever a (addr, slot) is added, if the
addr is not already present, the add causes two journal entries:
- one for the address,
- one for the (address,slot)
Therefore, when unrolling the change, we can always blindly delete the
(addr) at this point, since no storage adds can remain when come upon
a single (addr) change.
*/
s.accessList.DeleteAddress(*ch.address)
}
func (ch accessListAddAccountChange) dirtied() *common.Address {
return nil
}
func (ch accessListAddAccountChange) copy() journalEntry {
return accessListAddAccountChange{
address: ch.address,
}
}
func (ch accessListAddSlotChange) revert(s *StateDB) {
s.accessList.DeleteSlot(*ch.address, *ch.slot)
}
func (ch accessListAddSlotChange) dirtied() *common.Address {
return nil
}
func (ch accessListAddSlotChange) copy() journalEntry {
return accessListAddSlotChange{
address: ch.address,
slot: ch.slot,
}
}