f1ee8d507e
* squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * squash * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE * SE |
||
---|---|---|
.. | ||
buffers.go | ||
collector.go | ||
dataprovider.go | ||
etl_test.go | ||
ETL-collector.png | ||
etl.go | ||
ETL.png | ||
heap.go | ||
progress.go | ||
README.md |
ETL
ETL framework is most commonly used in staged sync.
It implements a pattern where we extract some data from a database, transform it, then put it into temp files and insert back to the database in sorted order.
Inserting entries into our KV storage sorted by keys helps to minimize write amplification, hence it is much faster, even considering additional I/O that is generated by storing files.
It behaves similarly to enterprise Extract, Tranform, Load frameworks, hence the name. We use temporary files because that helps keep RAM usage predictable and allows using ETL on large amounts of data.
Example
func keyTransformExtractFunc(transformKey func([]byte) ([]byte, error)) etl.ExtractFunc {
return func(k, v []byte, next etl.ExtractNextFunc) error {
newK, err := transformKey(k)
if err != nil {
return err
}
return next(k, newK, v)
}
}
err := etl.Transform(
db, // database
dbutils.PlainStateBucket, // "from" bucket
dbutils.CurrentStateBucket, // "to" bucket
datadir, // where to store temp files
keyTransformExtractFunc(transformPlainStateKey), // transformFunc on extraction
etl.IdentityLoadFunc, // transform on load
etl.TransformArgs{ // additional arguments
Quit: quit,
},
)
if err != nil {
return err
}
Data Transformation
The whole flow is shown in the image
Data could be transformed in two places along the pipeline:
-
transform on extraction
-
transform on loading
Transform On Extraction
type ExtractFunc func(k []byte, v []byte, next ExtractNextFunc) error
Transform on extraction function receives the currenk key and value from the source bucket.
Transform On Loading
type LoadFunc func(k []byte, value []byte, state State, next LoadNextFunc) error
As well as the current key and value, the transform on loading function
receives the State
object that can receive data from the destination bucket.
That is used in index generation where we want to extend index entries with new data instead of just adding new ones.
<...>NextFunc
pattern
Sometimes we need to produce multiple entries from a single entry when transforming.
To do that, each of the transform function receives a next function that should be called to move data further. That means that each transformation can produce any number of outputs for a single input.
It can be one output, like in IdentityLoadFunc
:
func IdentityLoadFunc(k []byte, value []byte, _ State, next LoadNextFunc) error {
return next(k, k, value) // go to the next step
}
It can be multiple outputs like when each entry is a ChangeSet
:
func(dbKey, dbValue []byte, next etl.ExtractNextFunc) error {
blockNum, _ := dbutils.DecodeTimestamp(dbKey)
return bytes2walker(dbValue).Walk(func(changesetKey, changesetValue []byte) error {
key := common.CopyBytes(changesetKey)
v := make([]byte, 9)
binary.BigEndian.PutUint64(v, blockNum)
if len(changesetValue) == 0 {
v[8] = 1
}
return next(dbKey, key, v) // go to the next step
})
}
Buffer Types
Before the data is being flushed into temp files, it is getting collected into
a buffer until if overflows (etl.ExtractArgs.BufferSize
).
There are different types of buffers available with different behaviour.
-
SortableSliceBuffer
-- just append(k, v1)
,(k, v2)
onto a slice. Duplicate keys will lead to duplicate entries:[(k, v1) (k, v2)]
. -
SortableAppendBuffer
-- on duplicate keys: merge.(k, v1)
,(k, v2)
will lead tok: [v1 v2]
-
SortableOldestAppearedBuffer
-- on duplicate keys: keep the oldest.(k, v1)
,(k v2)
will lead tok: v1
Transforming Structs
Both transform functions and next functions allow only byte arrays. If you need to pass a struct, you will need to marshal it.
Loading Into Database
We load data from the temp files into a database in batches, limited by
IdealBatchSize()
of an ethdb.Mutation
.
(for tests we can also override it)
Handling Interruptions
ETL processes are long, so we need to be able to handle interruptions.
Handing Ctrl+C
You can pass your quit channel into Quit
parameter into etl.TransformArgs
.
When this channel is closed, ETL will be interrupted.
Saving & Restoring State
Interrupting in the middle of loading can lead to inconsistent state in the database.
To avoid that, the ETL framework allows storing progress by setting OnLoadCommit
in etl.TransformArgs
.
Then we can use this data to know the progress the ETL transformation made.
You can also specify ExtractStartKey
and ExtractEndKey
to limit the nubmer
of items transformed.
Ways to work with ETL framework
There might be 2 scenarios on how you want to work with the ETL framework.
etl.Transform
function
The vast majority of use-cases is when we extract data from one bucket and in
the end, load it into another bucket. That is the use-case for etl.Transform
function.
etl.Collector
struct
If you want a more modular behaviour instead of just reading from the DB (like
generating intermediate hashes in ../../core/chain_makers.go
, you can use
etl.Collector
struct directly.
It has a .Collect()
method that you can provide your data to.
Optimizations
- if all data fits into a single file, we don't write anything to disk and just use in-memory storage.