Victor Baranov
b0ed567435
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3 years ago | |
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.. | ||
config | 3 years ago | |
lib | 3 years ago | |
test | 3 years ago | |
.gitignore | 7 years ago | |
README.md | 4 years ago | |
mix.exs | 4 years ago |
README.md
Indexer
TODO: Add description
Structure
The indexer is split into multiple fetchers. Each fetcher has its own supervising tree with a separate TaskSupervisor
for better detecting of memory, message or blocking problems.
Most fetchers have their Supervisor
module generated automatically using use Indexer.Fetcher
macro.
There are different fetchers described below, but the final step of almost all of them is importing data into database.
A map of lists of different entities is constructed and fed to Explorer.Chain.import
method.
This method assigns different runners from Explorer.Chain.Import.Runner
namespace, matching key in map to option_key
attribute of a runner.
The runners are then performing according to the order specified in stages in Explorer.Chain.Import.Stage
.
Transformers
Some data has to be extracted from already fetched data, and there're several transformers in lib/indexer/transform
to do just that. They normally accept a part of the Chain.import
-able map and return another part of it.
addresses
: extracts all encountered addresses from different entitiesaddress_coin_balances
: detects coin balance-changing entities (transactions, minted blocks, etc) to create coin balance entities for further fetchingtoken_transfers
: parses logs to extract token transfersmint_transfers
: parses logs to extract token mint transfersaddress_token_balances
: creates token balance entities for futher fetching, based on detected token transfersblocks
: extracts block signer hash from additional data for Clique chains
Root fetchers
pending_transaction
: fetches pending transactions (i.e. not yet collated into a block) every second (pending_transaction_interval
)block/realtime
: listens for new blocks from websocket and polls node for new blocks, imports new ones one by oneblock/catchup
: gets unfetched ranges of blocks, imports them in batches
Both block fetchers retrieve/extract the blocks themselves and the following additional data:
block_second_degree_relations
transactions
logs
token_transfers
addresses
The following stubs for further async fetching are inserted as well:
block_rewards
address_coin_balances
address_token_balances
tokens
Realtime fetcher also immediately fetches from the node:
- current balances for
addresses
address_coin_balances
The following async fetchers are launched for importing missing data:
replaced_transaction
block_reward
uncle_block
internal_transaction
coin_balance
(only in catchup fetcher)token_balance
token
contract_code
staking_pools
Async fetchers
These are responsible for fetching additional block data not retrieved in root fetchers.
Most of them are based off BufferedTask
, and the basic algorithm goes like this:
- Make an initial streaming request to database to fetch identifiers of all existing unfetched items.
- Accept new identifiers for fetching via
async_fetch()
method. - Split identifier in batches and run tasks on
TaskSupervisor
according tomax_batch_size
andmax_concurrency
settings. - Make requests using
EthereumJSONRPC
. - Optionally post-process results using transformers.
- Optionally pass new identifiers to other async fetchers using
async_fetch
. - Run
Chain.import
with fetched data.
replaced_transaction
: not a fetcher per se, but rather an async worker, which discards previously pending transactions after they are replaced with new pending transactions with the same nonce, or are collated in a block.block_reward
: missingblock_rewards
for consensus blocksuncle_block
: blocks forblock_second_degree_relations
with nulluncle_fetched_at
internal_transaction
: for eitherblocks
(Parity) ortransactions
with nullinternal_transactions_indexed_at
coin_balance
: foraddress_coin_balances
with nullvalue_fetched_at
token_balance
: foraddress_token_balances
with nullvalue_fetched_at
. Also upsertsaddress_current_token_balances
token
: fortokens
withcataloged == false
contract_code
: fortransactions
with non-nullcreated_contract_address_hash
and nullcreated_contract_code_indexed_at
staking_pools
: for fetching staking pools
Additionally:
token_updater
is run every 2 days to update token metadatacoin_balance_on_demand
is triggered from web UI to ensure address balance is as up-to-date as possible
Temporary workers
These workers are created for fetching information, which previously wasn't fetched in existing fetchers, or was fetched incorrectly. After all deployed instances get all needed data, these fetchers should be deprecated and removed.
uncataloged_token_transfers
: extracts token transfers from logs, which previously weren't parsed due to unknown formatuncles_without_index
: adds previously unfetchedindex
field for unfetched blocks inblock_second_degree_relations
blocks_transactions_mismatch
: refetches each block once and revokes consensus to those whose transaction number mismatches with the number currently stored. This is meant to force the correction of a race condition that caused successfully fetched transactions to be overwritten by a following non-consensus block: #1911.
Memory Usage
The work queues for building the index of all blocks, balances (coin and token), and internal transactions can grow quite large. By default, the soft-limit is 1 GiB, which can be changed in config/config.exs
:
config :indexer, memory_limit: 1 <<< 30
Memory usage is checked once per minute. If the soft-limit is reached, the shrinkable work queues will shed half their load. The shed load will be restored from the database, the same as when a restart of the server occurs, so rebuilding the work queue will be slower, but use less memory.
If all queues are at their minimum size, then no more memory can be reclaimed and an error will be logged.
Websocket Keepalive
This defaults to 150 seconds, but it can be set via adding a configuration to subscribe_named_arguments
in the appropriate config file (indexer/config//.exs) called :keep_alive
. The value is an integer representing milliseconds.
Testing
Parity
Mox
This is the default setup. mix test
will work on its own, but to be explicit, use the following setup:
export ETHEREUM_JSONRPC_CASE=EthereumJSONRPC.Case.Parity.Mox
mix test --exclude no_parity
HTTP / WebSocket
export ETHEREUM_JSONRPC_CASE=EthereumJSONRPC.Case.Parity.HTTPWebSocket
mix test --exclude no_parity
Protocol | URL |
---|---|
HTTP | http://localhost:8545 |
WebSocket | ws://localhost:8546 |
Geth
Mox
export ETHEREUM_JSONRPC_CASE=EthereumJSONRPC.Case.Geth.Mox
mix test --exclude no_geth
HTTP / WebSocket
export ETHEREUM_JSONRPC_CASE=EthereumJSONRPC.Case.Geth.HTTPWebSocket
mix test --exclude no_geth
Protocol | URL |
---|---|
HTTP | https://mainnet.infura.io/8lTvJTKmHPCHazkneJsY |
WebSocket | wss://mainnet.infura.io/ws/8lTvJTKmHPCHazkneJsY |