nimbus-eth2/beacon_chain/beacon_chain_db.nim

802 lines
30 KiB
Nim

# beacon_chain
# Copyright (c) 2018-2021 Status Research & Development GmbH
# Licensed and distributed under either of
# * MIT license (license terms in the root directory or at https://opensource.org/licenses/MIT).
# * Apache v2 license (license terms in the root directory or at https://www.apache.org/licenses/LICENSE-2.0).
# at your option. This file may not be copied, modified, or distributed except according to those terms.
{.push raises: [Defect].}
import
std/[typetraits, tables],
stew/[arrayops, assign2, byteutils, endians2, io2, objects, results],
serialization, chronicles, snappy,
eth/db/[kvstore, kvstore_sqlite3],
./networking/network_metadata, ./beacon_chain_db_immutable,
./spec/[crypto, datatypes, digest, state_transition],
./ssz/[ssz_serialization, merkleization],
./filepath
export crypto
logScope: topics = "bc_db"
type
DbSeq*[T] = object
insertStmt: SqliteStmt[openArray[byte], void]
selectStmt: SqliteStmt[int64, openArray[byte]]
recordCount: int64
DepositsSeq = DbSeq[DepositData]
DepositContractSnapshot* = object
eth1Block*: Eth2Digest
depositContractState*: DepositContractState
BeaconChainDBV0* = ref object
## BeaconChainDBV0 based on old kvstore table that sets the WITHOUT ROWID
## option which becomes unbearably slow with large blobs. It is used as a
## read-only store to support old versions - by freezing it at its current
## data set, downgrading remains possible since it's no longer touched -
## anyone downgrading will have to sync up whatever they missed.
##
## Newer versions read from the new tables first - if the data is not found,
## they turn to the old tables for reading. Writing is done only to the new
## tables.
##
## V0 stored most data in a single table, prefixing each key with a tag
## identifying the type of data.
##
## 1.1 introduced BeaconStateNoImmutableValidators storage where immutable
## validator data is stored in a separate table and only a partial
## BeaconState is written to kvstore
##
## 1.2 moved BeaconStateNoImmutableValidators to a separate table to
## alleviate some of the btree balancing issues - this doubled the speed but
## was still
##
## 1.3 creates `kvstore` with rowid, making it quite fast, but doesn't do
## anything about existing databases. Versions after that use a separate
## file instead (V1)
backend: KvStoreRef # kvstore
stateStore: KvStoreRef # state_no_validators
BeaconChainDB* = ref object
## Database storing resolved blocks and states - resolved blocks are such
## blocks that form a chain back to the tail block.
##
## We assume that the database backend is working / not corrupt - as such,
## we will raise a Defect any time there is an issue. This should be
## revisited in the future, when/if the calling code safely can handle
## corruption of this kind.
##
## We do however make an effort not to crash on invalid data inside the
## database - this may have a number of "natural" causes such as switching
## between different versions of the client and accidentally using an old
## database.
db: SqStoreRef
v0: BeaconChainDBV0
preset*: RuntimePreset
genesisDeposits*: DepositsSeq
# immutableValidatorsDb only stores the total count; it's a proxy for SQL
# queries.
immutableValidatorsDb*: DbSeq[ImmutableValidatorData2]
immutableValidators*: seq[ImmutableValidatorData2]
checkpoint*: proc() {.gcsafe, raises: [Defect].}
keyValues: KvStoreRef # Random stuff using DbKeyKind - suitable for small values mainly!
blocks: KvStoreRef # BlockRoot -> TrustedBeaconBlock
stateRoots: KvStoreRef # (Slot, BlockRoot) -> StateRoot
statesNoVal: KvStoreRef # StateRoot -> BeaconStateNoImmutableValidators
stateDiffs: KvStoreRef ##\
## StateRoot -> BeaconStateDiff
## Instead of storing full BeaconStates, one can store only the diff from
## a different state. As 75% of a typical BeaconState's serialized form's
## the validators, which are mostly immutable and append-only, just using
## a simple append-diff representation helps significantly. Various roots
## are stored in a mod-increment pattern across fixed-sized arrays, which
## addresses most of the rest of the BeaconState sizes.
summaries: KvStoreRef # BlockRoot -> BeaconBlockSummary
DbKeyKind = enum
kHashToState
kHashToBlock
kHeadBlock
## Pointer to the most recent block selected by the fork choice
kTailBlock
## Pointer to the earliest finalized block - this is the genesis block when
## the chain starts, but might advance as the database gets pruned
## TODO: determine how aggressively the database should be pruned. For a
## healthy network sync, we probably need to store blocks at least
## past the weak subjectivity period.
kBlockSlotStateRoot
## BlockSlot -> state_root mapping
kGenesisBlockRoot
## Immutable reference to the network genesis state
## (needed for satisfying requests to the beacon node API).
kEth1PersistedTo # Obsolete
kDepositsFinalizedByEth1 # Obsolete
kDepositsFinalizedByEth2
## A merkleizer checkpoint used for computing merkle proofs of
## deposits added to Eth2 blocks (it may lag behind the finalized
## eth1 deposits checkpoint).
kHashToBlockSummary # Block summaries for fast startup
kSpeculativeDeposits
## A merkelizer checkpoint created on the basis of deposit events
## that we were not able to verify against a `deposit_root` served
## by the web3 provider. This may happen on Geth nodes that serve
## only recent contract state data (i.e. only recent `deposit_roots`).
kHashToStateDiff # Obsolete
kHashToStateOnlyMutableValidators
BeaconBlockSummary* = object
## Cache of beacon block summaries - during startup when we construct the
## chain dag, loading full blocks takes a lot of time - the block
## summary contains a minimal snapshot of what's needed to instanciate
## the BlockRef tree.
slot*: Slot
parent_root*: Eth2Digest
const
# The largest object we're saving is the BeaconState, and by far, the largest
# part of it is the validator - each validator takes up at least 129 bytes
# in phase0, which means 100k validators is >12mb - in addition to this,
# there are several MB of hashes.
maxDecompressedDbRecordSize = 64*1024*1024
# Subkeys essentially create "tables" within the key-value store by prefixing
# each entry with a table id
func subkey(kind: DbKeyKind): array[1, byte] =
result[0] = byte ord(kind)
func subkey[N: static int](kind: DbKeyKind, key: array[N, byte]):
array[N + 1, byte] =
result[0] = byte ord(kind)
result[1 .. ^1] = key
func subkey(kind: type BeaconState, key: Eth2Digest): auto =
subkey(kHashToState, key.data)
func subkey(
kind: type BeaconStateNoImmutableValidators, key: Eth2Digest): auto =
subkey(kHashToStateOnlyMutableValidators, key.data)
func subkey(kind: type SignedBeaconBlock, key: Eth2Digest): auto =
subkey(kHashToBlock, key.data)
func subkey(kind: type BeaconBlockSummary, key: Eth2Digest): auto =
subkey(kHashToBlockSummary, key.data)
func subkey(root: Eth2Digest, slot: Slot): array[40, byte] =
var ret: array[40, byte]
# big endian to get a naturally ascending order on slots in sorted indices
ret[0..<8] = toBytesBE(slot.uint64)
# .. but 7 bytes should be enough for slots - in return, we get a nicely
# rounded key length
ret[0] = byte ord(kBlockSlotStateRoot)
ret[8..<40] = root.data
ret
template panic =
# TODO(zah): Could we recover from a corrupted database?
# Review all usages.
raiseAssert "The database should not be corrupted"
template expectDb(x: auto): untyped =
# There's no meaningful error handling implemented for a corrupt database or
# full disk - this requires manual intervention, so we'll panic for now
x.expect("working database (disk broken/full?)")
proc init*[T](Seq: type DbSeq[T], db: SqStoreRef, name: string): KvResult[Seq] =
? db.exec("""
CREATE TABLE IF NOT EXISTS """ & name & """(
id INTEGER PRIMARY KEY,
value BLOB
);
""")
let
insertStmt = db.prepareStmt(
"INSERT INTO " & name & "(value) VALUES (?);",
openArray[byte], void, managed = false).expect("this is a valid statement")
selectStmt = db.prepareStmt(
"SELECT value FROM " & name & " WHERE id = ?;",
int64, openArray[byte], managed = false).expect("this is a valid statement")
countStmt = db.prepareStmt(
"SELECT COUNT(1) FROM " & name & ";",
NoParams, int64, managed = false).expect("this is a valid statement")
var recordCount = int64 0
let countQueryRes = countStmt.exec do (res: int64):
recordCount = res
let found = ? countQueryRes
if not found:
return err("Cannot count existing items")
countStmt.dispose()
ok(Seq(insertStmt: insertStmt,
selectStmt: selectStmt,
recordCount: recordCount))
proc close*(s: DbSeq) =
s.insertStmt.dispose()
s.selectStmt.dispose()
proc add*[T](s: var DbSeq[T], val: T) =
var bytes = SSZ.encode(val)
s.insertStmt.exec(bytes).expectDb()
inc s.recordCount
template len*[T](s: DbSeq[T]): int64 =
s.recordCount
proc get*[T](s: DbSeq[T], idx: int64): T =
# This is used only locally
let resultAddr = addr result
let queryRes = s.selectStmt.exec(idx + 1) do (recordBytes: openArray[byte]):
try:
resultAddr[] = decode(SSZ, recordBytes, T)
except SerializationError:
panic()
let found = queryRes.expectDb()
if not found: panic()
proc loadImmutableValidators(vals: DbSeq[ImmutableValidatorData]): seq[ImmutableValidatorData] =
for i in 0 ..< vals.len:
result.add vals.get(i)
proc loadImmutableValidators(vals: DbSeq[ImmutableValidatorData2]): seq[ImmutableValidatorData2] =
for i in 0 ..< vals.len:
result.add vals.get(i)
proc new*(T: type BeaconChainDB,
preset: RuntimePreset,
dir: string,
inMemory = false,
): BeaconChainDB =
var db = if inMemory:
SqStoreRef.init("", "test", inMemory = true).expect(
"working database (out of memory?)")
else:
let s = secureCreatePath(dir)
doAssert s.isOk # TODO(zah) Handle this in a better way
SqStoreRef.init(
dir, "nbc", manualCheckpoint = true).expectDb()
# Remove the deposits table we used before we switched
# to storing only deposit contract checkpoints
if db.exec("DROP TABLE IF EXISTS deposits;").isErr:
debug "Failed to drop the deposits table"
# An old pubkey->index mapping that hasn't been used on any mainnet release
if db.exec("DROP TABLE IF EXISTS validatorIndexFromPubKey;").isErr:
debug "Failed to drop the validatorIndexFromPubKey table"
var
# V0 compatibility tables - these were created WITHOUT ROWID which is slow
# for large blobs
backend = kvStore db.openKvStore().expectDb()
# state_no_validators is similar to state_no_validators2 but uses a
# different key encoding and was created WITHOUT ROWID
stateStore = kvStore db.openKvStore("state_no_validators").expectDb()
genesisDepositsSeq =
DbSeq[DepositData].init(db, "genesis_deposits").expectDb()
immutableValidatorsDb =
DbSeq[ImmutableValidatorData2].init(db, "immutable_validators2").expectDb()
# V1 - expected-to-be small rows get without rowid optimizations
keyValues = kvStore db.openKvStore("key_values", true).expectDb()
blocks = kvStore db.openKvStore("blocks").expectDb()
stateRoots = kvStore db.openKvStore("state_roots", true).expectDb()
statesNoVal = kvStore db.openKvStore("state_no_validators2").expectDb()
stateDiffs = kvStore db.openKvStore("state_diffs").expectDb()
summaries = kvStore db.openKvStore("beacon_block_summaries", true).expectDb()
# `immutable_validators` stores validator keys in compressed format - this is
# slow to load and has been superceded by `immutable_validators2` which uses
# uncompressed keys instead. The migration is lossless but the old table
# should not be removed until after altair, to permit downgrades.
let immutableValidatorsDb1 =
DbSeq[ImmutableValidatorData].init(db, "immutable_validators").expectDb()
if immutableValidatorsDb.len() < immutableValidatorsDb1.len():
notice "Migrating validator keys, this may take a minute",
len = immutableValidatorsDb1.len()
while immutableValidatorsDb.len() < immutableValidatorsDb1.len():
let val = immutableValidatorsDb1.get(immutableValidatorsDb.len())
immutableValidatorsDb.add(ImmutableValidatorData2(
pubkey: val.pubkey.loadValid().toUncompressed(),
withdrawal_credentials: val.withdrawal_credentials
))
immutableValidatorsDb1.close()
T(
db: db,
v0: BeaconChainDBV0(
backend: backend,
stateStore: stateStore,
),
preset: preset,
genesisDeposits: genesisDepositsSeq,
immutableValidatorsDb: immutableValidatorsDb,
immutableValidators: loadImmutableValidators(immutableValidatorsDb),
checkpoint: proc() = db.checkpoint(),
keyValues: keyValues,
blocks: blocks,
stateRoots: stateRoots,
statesNoVal: statesNoVal,
stateDiffs: stateDiffs,
summaries: summaries,
)
proc decodeSSZ[T](data: openArray[byte], output: var T): bool =
try:
readSszBytes(data, output, updateRoot = false)
true
except SerializationError as e:
# If the data can't be deserialized, it could be because it's from a
# version of the software that uses a different SSZ encoding
warn "Unable to deserialize data, old database?",
err = e.msg, typ = name(T), dataLen = data.len
false
proc decodeSnappySSZ[T](data: openArray[byte], output: var T): bool =
try:
let decompressed = snappy.decode(data, maxDecompressedDbRecordSize)
readSszBytes(decompressed, output, updateRoot = false)
true
except SerializationError as e:
# If the data can't be deserialized, it could be because it's from a
# version of the software that uses a different SSZ encoding
warn "Unable to deserialize data, old database?",
err = e.msg, typ = name(T), dataLen = data.len
false
proc encodeSSZ(v: auto): seq[byte] =
try:
SSZ.encode(v)
except IOError as err:
raiseAssert err.msg
proc encodeSnappySSZ(v: auto): seq[byte] =
try:
snappy.encode(SSZ.encode(v))
except CatchableError as err:
# In-memory encode shouldn't fail!
raiseAssert err.msg
proc getRaw(db: KvStoreRef, key: openArray[byte], T: type Eth2Digest): Opt[T] =
var res: Opt[T]
proc decode(data: openArray[byte]) =
if data.len == sizeof(Eth2Digest):
res.ok Eth2Digest(data: toArray(sizeof(Eth2Digest), data))
else:
# If the data can't be deserialized, it could be because it's from a
# version of the software that uses a different SSZ encoding
warn "Unable to deserialize data, old database?",
typ = name(T), dataLen = data.len
discard
discard db.get(key, decode).expectDb()
res
proc putRaw(db: KvStoreRef, key: openArray[byte], v: Eth2Digest) =
db.put(key, v.data).expectDb()
type GetResult = enum
found = "Found"
notFound = "Not found"
corrupted = "Corrupted"
proc getSSZ[T](db: KvStoreRef, key: openArray[byte], output: var T): GetResult =
var status = GetResult.notFound
# TODO address is needed because there's no way to express lifetimes in nim
# we'll use unsafeAddr to find the code later
var outputPtr = unsafeAddr output # callback is local, ptr wont escape
proc decode(data: openArray[byte]) =
status =
if decodeSSZ(data, outputPtr[]): GetResult.found
else: GetResult.corrupted
discard db.get(key, decode).expectDb()
status
proc putSSZ(db: KvStoreRef, key: openArray[byte], v: auto) =
db.put(key, encodeSSZ(v)).expectDb()
proc getSnappySSZ[T](db: KvStoreRef, key: openArray[byte], output: var T): GetResult =
var status = GetResult.notFound
# TODO address is needed because there's no way to express lifetimes in nim
# we'll use unsafeAddr to find the code later
var outputPtr = unsafeAddr output # callback is local, ptr wont escape
proc decode(data: openArray[byte]) =
status =
if decodeSnappySSZ(data, outputPtr[]): GetResult.found
else: GetResult.corrupted
discard db.get(key, decode).expectDb()
status
proc putSnappySSZ(db: KvStoreRef, key: openArray[byte], v: auto) =
db.put(key, encodeSnappySSZ(v)).expectDb()
proc close*(db: BeaconChainDBV0) =
discard db.stateStore.close()
discard db.backend.close()
proc close*(db: BeaconchainDB) =
if db.db == nil: return
# Close things in reverse order
discard db.summaries.close()
discard db.stateDiffs.close()
discard db.statesNoVal.close()
discard db.stateRoots.close()
discard db.blocks.close()
discard db.keyValues.close()
db.immutableValidatorsDb.close()
db.genesisDeposits.close()
db.v0.close()
db.db.close()
db.db = nil
func toBeaconBlockSummary(v: SomeBeaconBlock): BeaconBlockSummary =
BeaconBlockSummary(
slot: v.slot,
parent_root: v.parent_root,
)
proc putBeaconBlockSummary(
db: BeaconChainDB, root: Eth2Digest, value: BeaconBlockSummary) =
# Summaries are too simple / small to compress, store them as plain SSZ
db.summaries.putSSZ(root.data, value)
proc putBlock*(db: BeaconChainDB, value: TrustedSignedBeaconBlock) =
db.blocks.putSnappySSZ(value.root.data, value)
db.putBeaconBlockSummary(value.root, value.message.toBeaconBlockSummary())
proc updateImmutableValidators*(
db: BeaconChainDB, validators: openArray[Validator]) =
# Must be called before storing a state that references the new validators
let numValidators = validators.len
while db.immutableValidators.len() < numValidators:
let immutableValidator =
getImmutableValidatorData(validators[db.immutableValidators.len()])
db.immutableValidatorsDb.add immutableValidator
db.immutableValidators.add immutableValidator
proc putState*(db: BeaconChainDB, key: Eth2Digest, value: BeaconState) =
db.updateImmutableValidators(value.validators.asSeq())
db.statesNoVal.putSnappySSZ(
key.data,
isomorphicCast[BeaconStateNoImmutableValidators](value))
proc putState*(db: BeaconChainDB, value: BeaconState) =
db.putState(hash_tree_root(value), value)
func stateRootKey(root: Eth2Digest, slot: Slot): array[40, byte] =
var ret: array[40, byte]
# big endian to get a naturally ascending order on slots in sorted indices
ret[0..<8] = toBytesBE(slot.uint64)
ret[8..<40] = root.data
ret
proc putStateRoot*(db: BeaconChainDB, root: Eth2Digest, slot: Slot,
value: Eth2Digest) =
db.stateRoots.putRaw(stateRootKey(root, slot), value)
proc putStateDiff*(db: BeaconChainDB, root: Eth2Digest, value: BeaconStateDiff) =
db.stateDiffs.putSnappySSZ(root.data, value)
proc delBlock*(db: BeaconChainDB, key: Eth2Digest) =
db.blocks.del(key.data).expectDb()
db.summaries.del(key.data).expectDb()
proc delState*(db: BeaconChainDB, key: Eth2Digest) =
db.statesNoVal.del(key.data).expectDb()
proc delStateRoot*(db: BeaconChainDB, root: Eth2Digest, slot: Slot) =
db.stateRoots.del(stateRootKey(root, slot)).expectDb()
proc delStateDiff*(db: BeaconChainDB, root: Eth2Digest) =
db.stateDiffs.del(root.data).expectDb()
proc putHeadBlock*(db: BeaconChainDB, key: Eth2Digest) =
db.keyValues.putRaw(subkey(kHeadBlock), key)
proc putTailBlock*(db: BeaconChainDB, key: Eth2Digest) =
db.keyValues.putRaw(subkey(kTailBlock), key)
proc putGenesisBlockRoot*(db: BeaconChainDB, key: Eth2Digest) =
db.keyValues.putRaw(subkey(kGenesisBlockRoot), key)
proc putEth2FinalizedTo*(db: BeaconChainDB,
eth1Checkpoint: DepositContractSnapshot) =
db.keyValues.putSnappySSZ(subkey(kDepositsFinalizedByEth2), eth1Checkpoint)
proc getBlock(db: BeaconChainDBV0, key: Eth2Digest): Opt[TrustedSignedBeaconBlock] =
# We only store blocks that we trust in the database
result.ok(TrustedSignedBeaconBlock())
if db.backend.getSnappySSZ(subkey(SignedBeaconBlock, key), result.get) != GetResult.found:
result.err()
else:
# set root after deserializing (so it doesn't get zeroed)
result.get().root = key
proc getBlock*(db: BeaconChainDB, key: Eth2Digest): Opt[TrustedSignedBeaconBlock] =
# We only store blocks that we trust in the database
result.ok(TrustedSignedBeaconBlock())
if db.blocks.getSnappySSZ(key.data, result.get) != GetResult.found:
result = db.v0.getBlock(key)
else:
# set root after deserializing (so it doesn't get zeroed)
result.get().root = key
proc getStateOnlyMutableValidators(
immutableValidators: openArray[ImmutableValidatorData2],
store: KvStoreRef, key: openArray[byte], output: var BeaconState,
rollback: RollbackProc): bool =
## Load state into `output` - BeaconState is large so we want to avoid
## re-allocating it if possible
## Return `true` iff the entry was found in the database and `output` was
## overwritten.
## Rollback will be called only if output was partially written - if it was
## not found at all, rollback will not be called
# TODO rollback is needed to deal with bug - use `noRollback` to ignore:
# https://github.com/nim-lang/Nim/issues/14126
# TODO RVO is inefficient for large objects:
# https://github.com/nim-lang/Nim/issues/13879
case store.getSnappySSZ(
key, isomorphicCast[BeaconStateNoImmutableValidators](output))
of GetResult.found:
let numValidators = output.validators.len
doAssert immutableValidators.len >= numValidators
for i in 0 ..< numValidators:
let
# Bypass hash cache invalidation
dstValidator = addr output.validators.data[i]
assign(
dstValidator.pubkey,
immutableValidators[i].pubkey.loadValid().toPubKey())
assign(
dstValidator.withdrawal_credentials,
immutableValidators[i].withdrawal_credentials)
output.validators.resetCache()
true
of GetResult.notFound:
false
of GetResult.corrupted:
rollback(output)
false
proc getState(
db: BeaconChainDBV0,
immutableValidators: openArray[ImmutableValidatorData2],
key: Eth2Digest, output: var BeaconState,
rollback: RollbackProc): bool =
# Nimbus 1.0 reads and writes writes genesis BeaconState to `backend`
# Nimbus 1.1 writes a genesis BeaconStateNoImmutableValidators to `backend` and
# reads both BeaconState and BeaconStateNoImmutableValidators from `backend`
# Nimbus 1.2 writes a genesis BeaconStateNoImmutableValidators to `stateStore`
# and reads BeaconState from `backend` and BeaconStateNoImmutableValidators
# from `stateStore`. We will try to read the state from all these locations.
if getStateOnlyMutableValidators(
immutableValidators, db.stateStore,
subkey(BeaconStateNoImmutableValidators, key), output, rollback):
return true
if getStateOnlyMutableValidators(
immutableValidators, db.backend,
subkey(BeaconStateNoImmutableValidators, key), output, rollback):
return true
case db.backend.getSnappySSZ(subkey(BeaconState, key), output)
of GetResult.found:
true
of GetResult.notFound:
false
of GetResult.corrupted:
rollback(output)
false
proc getState*(
db: BeaconChainDB, key: Eth2Digest, output: var BeaconState,
rollback: RollbackProc): bool =
## Load state into `output` - BeaconState is large so we want to avoid
## re-allocating it if possible
## Return `true` iff the entry was found in the database and `output` was
## overwritten.
## Rollback will be called only if output was partially written - if it was
## not found at all, rollback will not be called
# TODO rollback is needed to deal with bug - use `noRollback` to ignore:
# https://github.com/nim-lang/Nim/issues/14126
# TODO RVO is inefficient for large objects:
# https://github.com/nim-lang/Nim/issues/13879
if not getStateOnlyMutableValidators(
db.immutableValidators, db.statesNoVal, key.data, output, rollback):
db.v0.getState(db.immutableValidators, key, output, rollback)
else:
true
proc getStateRoot(db: BeaconChainDBV0,
root: Eth2Digest,
slot: Slot): Opt[Eth2Digest] =
db.backend.getRaw(subkey(root, slot), Eth2Digest)
proc getStateRoot*(db: BeaconChainDB,
root: Eth2Digest,
slot: Slot): Opt[Eth2Digest] =
db.stateRoots.getRaw(stateRootKey(root, slot), Eth2Digest) or
db.v0.getStateRoot(root, slot)
proc getStateDiff*(db: BeaconChainDB,
root: Eth2Digest): Opt[BeaconStateDiff] =
result.ok(BeaconStateDiff())
if db.stateDiffs.getSnappySSZ(root.data, result.get) != GetResult.found:
result.err
proc getHeadBlock(db: BeaconChainDBV0): Opt[Eth2Digest] =
db.backend.getRaw(subkey(kHeadBlock), Eth2Digest)
proc getHeadBlock*(db: BeaconChainDB): Opt[Eth2Digest] =
db.keyValues.getRaw(subkey(kHeadBlock), Eth2Digest) or
db.v0.getHeadBlock()
proc getTailBlock(db: BeaconChainDBV0): Opt[Eth2Digest] =
db.backend.getRaw(subkey(kTailBlock), Eth2Digest)
proc getTailBlock*(db: BeaconChainDB): Opt[Eth2Digest] =
db.keyValues.getRaw(subkey(kTailBlock), Eth2Digest) or
db.v0.getTailBlock()
proc getGenesisBlockRoot(db: BeaconChainDBV0): Opt[Eth2Digest] =
db.backend.getRaw(subkey(kGenesisBlockRoot), Eth2Digest)
proc getGenesisBlockRoot*(db: BeaconChainDB): Opt[Eth2Digest] =
db.keyValues.getRaw(subkey(kGenesisBlockRoot), Eth2Digest) or
db.v0.getGenesisBlockRoot()
proc getEth2FinalizedTo(db: BeaconChainDBV0): Opt[DepositContractSnapshot] =
result.ok(DepositContractSnapshot())
let r = db.backend.getSnappySSZ(subkey(kDepositsFinalizedByEth2), result.get)
if r != found: result.err()
proc getEth2FinalizedTo*(db: BeaconChainDB): Opt[DepositContractSnapshot] =
result.ok(DepositContractSnapshot())
let r = db.keyValues.getSnappySSZ(subkey(kDepositsFinalizedByEth2), result.get)
if r != found: return db.v0.getEth2FinalizedTo()
proc containsBlock*(db: BeaconChainDBV0, key: Eth2Digest): bool =
db.backend.contains(subkey(SignedBeaconBlock, key)).expectDb()
proc containsBlock*(db: BeaconChainDB, key: Eth2Digest): bool =
db.blocks.contains(key.data).expectDb() or db.v0.containsBlock(key)
proc containsState*(db: BeaconChainDBV0, key: Eth2Digest): bool =
let sk = subkey(BeaconStateNoImmutableValidators, key)
db.stateStore.contains(sk).expectDb() or
db.backend.contains(sk).expectDb() or
db.backend.contains(subkey(BeaconState, key)).expectDb()
proc containsState*(db: BeaconChainDB, key: Eth2Digest, legacy: bool = true): bool =
db.statesNoVal.contains(key.data).expectDb or
(legacy and db.v0.containsState(key))
iterator getAncestors*(db: BeaconChainDB, root: Eth2Digest):
TrustedSignedBeaconBlock =
## Load a chain of ancestors for blck - returns a list of blocks with the
## oldest block last (blck will be at result[0]).
##
## The search will go on until the ancestor cannot be found.
var
res: TrustedSignedBeaconBlock
root = root
while db.blocks.getSnappySSZ(root.data, res) == GetResult.found or
db.v0.backend.getSnappySSZ(
subkey(SignedBeaconBlock, root), res) == GetResult.found:
res.root = root
yield res
root = res.message.parent_root
proc loadSummaries(db: BeaconChainDB): Table[Eth2Digest, BeaconBlockSummary] =
# Load summaries into table - there's no telling what order they're in so we
# load them all - bugs in nim prevent this code from living in the iterator.
var summaries = initTable[Eth2Digest, BeaconBlockSummary](1024*1024)
discard db.summaries.find([], proc(k, v: openArray[byte]) =
var output: BeaconBlockSummary
if k.len() == sizeof(Eth2Digest) and decodeSSz(v, output):
summaries[Eth2Digest(data: toArray(sizeof(Eth2Digest), k))] = output
else:
warn "Invalid summary in database", klen = k.len(), vlen = v.len()
)
summaries
type RootedSummary = tuple[root: Eth2Digest, summary: BeaconBlockSummary]
iterator getAncestorSummaries*(db: BeaconChainDB, root: Eth2Digest):
RootedSummary =
## Load a chain of ancestors for blck - returns a list of blocks with the
## oldest block last (blck will be at result[0]).
##
## The search will go on until the ancestor cannot be found.
# Summaries are loaded from the dedicated summaries table. For backwards
# compatibility, we also load from `kvstore` and finally, if no summaries
# can be found, by loading the blocks instead.
# First, load the full summary table into memory in one query - this makes
# initial startup very fast.
var
summaries = db.loadSummaries()
res: RootedSummary
blck: TrustedSignedBeaconBlock
newSummaries: seq[RootedSummary]
res.root = root
defer: # in case iteration is stopped along the way
# Write the newly found summaries in a single transaction - on first migration
# from the old format, this brings down the write from minutes to seconds
if newSummaries.len() > 0:
db.db.exec("BEGIN TRANSACTION;").expectDb()
for s in newSummaries:
db.putBeaconBlockSummary(s.root, s.summary)
db.db.exec("COMMIT;").expectDb()
if false:
# When the current version has been online for a bit, we can safely remove
# summaries from kvstore by enabling this little snippet - if users were
# to downgrade after the summaries have been purged, the old versions that
# use summaries can also recreate them on the fly from blocks.
db.db.exec(
"DELETE FROM kvstore WHERE key >= ? and key < ?",
([byte ord(kHashToBlockSummary)], [byte ord(kHashToBlockSummary) + 1])).expectDb()
# Yield summaries in reverse chain order by walking the parent references.
# If a summary is missing, try loading it from the older version or create one
# from block data.
while true:
summaries.withValue(res.root, summary) do:
res.summary = summary[]
yield res
do: # Summary was not found in summary table, look elsewhere
if db.v0.backend.getSnappySSZ(subkey(BeaconBlockSummary, res.root), res.summary) == GetResult.found:
yield res
elif db.v0.backend.getSnappySSZ(subkey(SignedBeaconBlock, res.root), blck) == GetResult.found:
res.summary = blck.message.toBeaconBlockSummary()
yield res
else:
break
# Next time, load them from the right place
newSummaries.add(res)
res.root = res.summary.parent_root