124 lines
5.6 KiB
Markdown
124 lines
5.6 KiB
Markdown
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# Watching Contract Storage
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One approach VulcanizeDB takes to caching and indexing smart contracts is to ingest raw contract storage values.
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Assuming that you are running an ethereum node that is writing contract storage changes to a CSV file, VulcanizeDB can parse them and persist the results to postgres.
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## Assumptions
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The current approach for caching smart contract storage diffs assumes that you are running a node that is writing contract storage diffs to a CSV file.
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The CSV file is expected to have 5 columns: contract address, block hash, block number, storage key, storage value.
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We have [a branch on vulcanize/parity-ethereum](https://github.com/vulcanize/parity-ethereum/tree/watch-storage-diffs) that enables running a node that writes storage diffs this way.
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We also have [sample data](https://github.com/8thlight/maker-vulcanizedb/pull/132/files) that comes from running that node against Kovan through block 9796184.
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Looking forward, we would like to isolate this assumption as much as possible.
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We may end up needing to read CSV data that is formatted differently, or reading data from a non-CSV source, and we do not want resulting changes to cascade throughout the codebase.
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## Shared Code
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VulcanizeDB has shared code for continuously reading from the CSV file written by the ethereum node and writing a parsed version of each row to postgres.
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### Storage Watcher
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The storage watcher is responsible for continuously delegating CSV rows to the appropriate transformer as they are being written by the ethereum node.
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It maintains a mapping of contract addresses to transformers, and will ignore storage diff rows for contract addresses that do not have a corresponding transformer.
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The storage watcher is currently initialized from the `parseStorageDiffs` command, which also adds transformers that the watcher should know about in its mapping of addresses to transformers.
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### Storage Transformer
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The storage transformer is responsible for converting raw contract storage hex values into useful data and writing them to postgres.
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The storage transformer depends on contract-specific implementations of code capable of recognizing storage keys and writing the matching (decoded) storage value to disk.
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```golang
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func (transformer Transformer) Execute(row shared.StorageDiffRow) error {
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metadata, lookupErr := transformer.Mappings.Lookup(row.StorageKey)
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if lookupErr != nil {
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return lookupErr
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}
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value, decodeErr := shared.Decode(row, metadata)
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if decodeErr != nil {
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return decodeErr
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}
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return transformer.Repository.Create(row.BlockHeight, row.BlockHash.Hex(), metadata, value)
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}
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```
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## Custom Code
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In order to watch an additional smart contract, a developer must create three things:
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1. Mappings - specify how to identify keys in the contract's storage trie.
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1. Repository - specify how to persist a parsed version of the storage value matching the recognized storage key.
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1. Instance - create an instance of the storage transformer that uses your mappings and repository.
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### Mappings
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```golang
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type Mappings interface {
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Lookup(key common.Hash) (shared.StorageValueMetadata, error)
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SetDB(db *postgres.DB)
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}
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```
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A contract-specific implementation of the mappings interface enables the storage transformer to fetch metadata associated with a storage key.
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Storage metadata contains: the name of the variable matching the storage key, a raw version of any keys associated with the variable (if the variable is a mapping), and the variable's type.
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```golang
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type StorageValueMetadata struct {
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Name string
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Keys map[Key]string
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Type ValueType
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}
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```
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Keys are only relevant if the variable is a mapping. For example, in the following Solidity code:
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```solidity
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pragma solidity ^0.4.0;
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contract Contract {
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uint x;
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mapping(address => uint) y;
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}
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```
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The metadata for variable `x` would not have any associated keys, but the metadata for a storage key associated with `y` would include the address used to specify that key's index in the mapping.
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The `SetDB` function is required for the mappings to connect to the database.
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A database connection may be desired when keys in a mapping variable need to be read from log events (e.g. to lookup what addresses may exist in `y`, above).
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### Repository
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```golang
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type Repository interface {
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Create(blockNumber int, blockHash string, metadata shared.StorageValueMetadata, value interface{}) error
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SetDB(db *postgres.DB)
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}
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```
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A contract-specific implementation of the repository interface enables the transformer to write the decoded storage value to the appropriate table in postgres.
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The `Create` function is expected to recognize and persist a given storage value by the variable's name, as indicated on the row's metadata.
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The `SetDB` function is required for the repository to connect to the database.
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### Instance
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```golang
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type Transformer struct {
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Address common.Address
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Mappings storage_diffs.Mappings
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Repository storage_diffs.Repository
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}
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```
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A new instance of the storage transformer is initialized with the contract-specific mappings and repository, as well as the contract's address.
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The contract's address is included so that the watcher can query that value from the transformer in order to build up its mapping of addresses to transformers.
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## Summary
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To begin watching an additional smart contract, create a new mappings file for looking up storage keys on that contract, a repository for writing storage values from the contract, and initialize a new storage transformer instance with the mappings, repository, and contract address.
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The new instance, wrapped in an initializer that calls `SetDB` on the mappings and repository, should be passed to the `AddTransformers` function on the storage watcher.
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