- Table of Contents
- Overview
- Setup
- Increase IPFS memory limits (for complex use cases)
- State transitions and data composition
- Major Components
- Development setup and instructions
- Monitoring and Debugging
- For Contributors
- Case Studies
- Find us
A snapshotter peer as part of Powerloom Protocol does exactly what the name suggests: It synchronizes with other snapshotter peers over a smart contract running on Powerloom Prost chain. It follows an architecture that is driven by state transitions which makes it easy to understand and modify.
Because of its decentralized nature, the snapshotter specification and its implementations share some powerful features that can adapt to your specific information requirements on blockchain applications:
- Each data point is calculated, updated, and synchronized with other snapshotter peers participating in the network
- synchronization of data points is defined as a function of an epoch ID(identifier) where epoch refers to an equally spaced collection of blocks on the data source blockchain (for eg, Ethereum Mainnet/Polygon Mainnet/Polygon Testnet -- Mumbai). This simplifies the building of use cases that are stateful (i.e. can be accessed according to their state at a given height of the data source chain), synchronized, and depend on reliable data. For example,
- dashboards by offering higher-order aggregate datapoints
- trading strategies and bots
- a snapshotter peer can load past epochs, indexes, and aggregates from a decentralized state and have access to a rich history of data
- all the datasets are decentralized on IPFS/Filecoin
- the power of these decentralized storage networks can be leveraged fully by applying the principle of composability
The Snapshotter Peer is thoughtfully designed with a modular and highly configurable architecture, allowing for easy customization and seamless integration. It consists of three core components:
-
Main Snapshotter Codebase:
- This foundational component defines all the essential interfaces and handles a wide range of tasks, from listening to epoch release events to distributing tasks and managing snapshot submissions.
-
Configuration Files:
- Configuration files, located in the
/config
directory are linked to snapshotter-configs repo, play a pivotal role in defining project types, specifying paths for individual compute modules, and managing various project-related settings.
- Configuration files, located in the
-
Compute Modules:
- The heart of the system resides in the
snapshotter/modules
directory are linked to snapshotter-computes, where the actual computation logic for each project type is defined. These modules drive the snapshot generation process for specific project types.
- The heart of the system resides in the
The architecture has been designed to facilitate the seamless interchange of configuration and modules. To achieve this, we maintain these components in separate Git repositories, which are then integrated into the Snapshotter Peer using Git Submodules. As a result, adapting the system to different use cases is as straightforward as changing a Git branch, offering unparalleled flexibility and versatility.
For more information on using Git Submodules, please refer to the Git Submodules Documentation.
The snapshotter is a distributed system with multiple moving parts. The easiest way to get started is by using the Docker-based setup according to the instructions in the section: Development setup and instructions.
If you're planning to participate as a snapshotter, refer to these instructions to start snapshotting.
If you're a developer, you can follow the manual configuration steps for pooler from this document followed by the instructions on the deploy
repo for code contributors for a more hands-on approach.
Note - RPC usage is highly use-case specific. If your use case is complicated and needs to make a lot of RPC calls, it is recommended to run your own RPC node instead of using third-party RPC services as it can be expensive.
If you want to increase the memory limits for IPFS, you can do so by running the following commands, this will reset on system restart though:
sudo sysctl -w net.core.rmem_max=8388608
sudo sysctl -w net.core.wmem_max=8388608
sudo sysctl -w net.ipv4.udp_mem='8388608 8388608 8388608'
sudo sysctl -w net.core.netdev_max_backlog=5000
sudo sysctl -w net.ipv4.tcp_rmem='4096 87380 8388608'
sudo sysctl -w net.ipv4.tcp_wmem='4096 87380 8388608'
To make these changes permanent, add or modify the following lines in /etc/sysctl.conf:
net.core.rmem_max=8388608
net.core.wmem_max=8388608
net.ipv4.udp_mem=8388608 8388608 8388608
net.core.netdev_max_backlog=5000
net.ipv4.tcp_rmem=4096 87380 8388608
net.ipv4.tcp_wmem=4096 87380 8388608
Apply the changes with:
sudo sysctl -p
Restart the docker service
sudo systemctl restart docker
Finally, bring up your Docker Compose stack again:
./clean_stop.sh
./build.sh
An epoch denotes a range of block heights on the EVM-compatible data source blockchain, for eg Ethereum mainnet/Polygon PoS mainnet/testnet. This makes it easier to collect state transitions and snapshots of data on equally spaced block height intervals, as well as to support future work on other lightweight anchor proof mechanisms like Merkle proofs, succinct proofs, etc.
The size of an epoch is configurable. Let that be referred to as size(E)
-
A trusted service keeps track of the head of the chain as it moves ahead, and a marker
h₀
against the max block height from the last released epoch. This makes the beginning of the next epoch,h₁ = h₀ + 1
-
Once the head of the chain has moved sufficiently ahead so that an epoch can be published, an epoch finalization service takes into account the following factors
- chain reorganization reports where the reorganized limits are a subset of the epoch qualified to be published
- a configurable ‘offset’ from the bleeding edge of the chain
and then publishes an epoch (h₁, h₂)
by sending a transaction to the protocol state smart contract deployed on the Prost Chain (anchor chain) so that h₂ - h₁ + 1 == size(E)
. The next epoch, therefore, is tracked from h₂ + 1
.
Each such transaction emits an EpochReleased
event
event EpochReleased(uint256 indexed epochId, uint256 begin, uint256 end, uint256 timestamp);
The epochId
here is incremented by 1 with every successive epoch release.
Preloaders perform an important function of fetching low-level data for eg. block details, and transaction receipts so that subsequent base snapshot building can proceed without performing unnecessary redundant calls that ultimately save on access costs on RPC and other queries on the underlying node infrastructure for the source data blockchain.
Each project type within the project configuration as found in config/projects.json
can specify the preloaders that their base snapshot builds depend on. Once the dependent preloaders have completed their fetches, the Processor Distributor subsequently triggers the base snapshot builders for each project type.
The preloaders implement one of the following two generic interfaces
GenericPreloader
GenericDelegatorPreloader
. Such preloaders are tasked with fetching large volumes of data and utilize delegated workers to which they submit large workloads over a request queue and wait for the results to be returned over a response queue.
The preloaders can be found in the snapshotter/utils/preloaders
directory. The preloaders that are available to project configuration entries are exposed through the config/preloader.json
configuration.
At the moment, we have 3 generic preloaders built into the snapshotter template.
- Block Details - It prefetches and stores block details for blocks in each Epoch and stores it in Redis
- Eth Price - It prefetches and stores ETH price for blocks in each Epoch and stores it in redis
- Tx Receipts - It prefetches all transaction details present in each Epoch and stores the data in Redis. Since fetching all block transactions is a lot of work, it utilizes the delegated workers architecture to parallelize and fetch data in a fast and reliable way
More preloaders can be easily added depending on the use case user is snapshotting for. It is as simple as writing logic in preloader.py
, adding the preloader config to config/preloader.json
, and adding the preloader dependency in config/projects.json
Workers, as mentioned in the configuration section for config/projects.json
, calculate base snapshots against this epochId
which corresponds to collections of state observations and event logs between the blocks at height in the range [begin, end]
.
The data sources are determined according to the following specification for the projects
key:
- an empty array against the
projects
indicates no specific data source is defined - an array of EVM-compatible wallet address strings can also be listed
- an array of "_" strings that denote the relationship between two EVM addresses (for eg ERC20 balance of
addr2
against a token contractaddr1
) - data sources can be dynamically added on the protocol state contract which the processor distributor syncs with:
The project ID is ultimately generated in the following manner:
The snapshots generated by workers defined in this config are the fundamental data models on which higher-order aggregates and richer data points are built. The SnapshotSubmitted
event generated on such base snapshots further triggers the building of sophisticated aggregates, super-aggregates, filters, and other data composites on top of them.
For situations where data sources are constantly changing or numerous, making it impractical to maintain an extensive list of them, the Snapshotter Peer offers a Bulk Mode. This feature is particularly useful in scenarios where specific data sources need not be defined explicitly.
In Bulk Mode, the system monitors all transactions and blocks without the need for predefined data sources. The Processor Distributor generates a SnapshotProcessMessage
with bulk mode enabled for each project type. When snapshot workers receive this message, they leverage preloaded transaction receipts for entire blocks, filtering out relevant transactions to generate snapshots for all data sources that interacted with the blockchain during that epoch. Snapshot worker then generates relevant project Ids for these snapshots and submits them for further processing.
Bulk Mode is highly effective in situations where the project list is continually expanding or where snapshots don't need to be submitted in every epoch, perhaps because the data hasn't changed significantly. Example use cases include monitoring on-chain activities and tracking task or quest completion statuses on the blockchain.
An important advantage of Bulk Mode is that, since all transaction receipts are preloaded, this approach can efficiently scale to accommodate a large number of project types with little to no increase in RPC (Remote Procedure Call) calls.
As seen above in the section on base snapshot generation, data sources can be dynamically added to the contract according to the role of certain peers in the ecosystem known as 'signallers'. This is the most significant aspect of the Powerloom Protocol ecosystem apart from snapshotting and will soon be decentralized to factor in on-chain activity, and market forces and accommodate a demand-driven, dynamic data ecosystem.
In the existing setup, when the project_type
is set to an empty array ([]
) and bulk mode is not activated, the snapshotter node attempts to retrieve data sources corresponding to the projects
key from the protocol state contract.
Whenever a data source is added or removed by a combination of the data source-detector and signaller, the protocol state smart contract emits a ProjectUpdated
event, adhering to the defined data model.
The snapshotting for every such dynamically added project is initiated only when the epochId
, corresponding to the field enableEpochId
contained within the ProjectUpdated
event, is released. The processor distributor correctly triggers the snapshotting workflow for such dynamically added data sources in the following segment:
All snapshots per project reach consensus on the protocol state contract which results in a SnapshotFinalized
event being triggered.
event SnapshotFinalized(uint256 indexed epochId, uint256 epochEnd, string projectId, string snapshotCid, uint256 timestamp);
The following is a sequence of states that an epoch goes through from the point epoch is released until SnapshotFinalized
event is received by the processor distributor for the specific epoch. These state transitions can be inspected in detail as noted in the section on internal snapshotter APIs.
The state name is self explanatory.
For every project type's preloader specifications, the status of all the preloading dependencies being satisfied is captured here:
The snapshot builders as configured in projects.json
are executed. Also refer to the case study of the current implementation of Pooler for a detailed look at snapshot building for base as well as aggregates.
Captures the status of propagation of the built snapshot to the payload commit service in Audit Protocol for further submission to the protocol state contract.
Payload commit service has sent the snapshot to a transaction relayer to submit to the protocol state contract.
Finalized snapshot accepted against an epoch via a SnapshotFinalized
event.
Aggregation and data composition - snapshot generation of higher-order data points on base snapshots
Workers as defined in config/aggregator.json
are triggered by the appropriate signals forwarded to Processor Distributor
corresponding to the project ID filters as explained in the Configuration section. This is best seen in action in Pooler, the snapshotter implementation that serves multiple aggregated data points for Uniswap v2 trade information.
In case of aggregation over multiple projects, their project IDs are generated with a combination of the hash of the dependee project IDs along with the namespace
The system event detector tracks events being triggered on the protocol state contract running on the anchor chain and forwards it to a callback queue with the appropriate routing key depending on the event signature and type among other information.
Related information and other services depending on these can be found in previous sections: State Transitions, Configuration.
The Process Hub Core, defined in process_hub_core.py
, serves as the primary process manager in the snapshotter.
- Operated by the CLI tool
processhub_cmd.py
, it is responsible for starting and managing theSystemEventDetector
andProcessorDistributor
processes. - Additionally, it spawns the base snapshot and aggregator workers required for processing tasks from the
powerloom-backend-callback
queue. The number of workers and their configuration path can be adjusted inconfig/settings.json
.
The Processor Distributor, defined in processor_distributor.py
, is initiated using the processhub_cmd.py
CLI.
- It loads the preloader, base snapshotting, and aggregator config information from the settings file
- It reads the events forwarded by the event detector to the
f'powerloom-event-detector:{settings.namespace}:{settings.instance_id}'
RabbitMQ queue bound to a topic exchange as configured insettings.rabbitmq.setup.event_detector.exchange
(code-ref: RabbitMQ exchanges and queue setup in pooler) - It creates and distributes processing messages based on the preloader configuration present in
config/preloader.json
, the project configuration present inconfig/projects.json
andconfig/aggregator.json
, and the topic pattern used in the routing key received from the topic exchange- For
EpochReleased
events, it forwards such messages to base snapshot builders for data source contracts as configured inconfig/projects.json
for the current epoch information contained in the event. https://github.com/PowerLoom/pooler/blob/d8b7be32ad329e8dcf0a7e5c1b27862894bc990a/snapshotter/processor_distributor.py#L694-L810 - For
SnapshotSubmitted
events, it forwards such messages to single and multi-project aggregate topic routing keys. https://github.com/PowerLoom/pooler/blob/d8b7be32ad329e8dcf0a7e5c1b27862894bc990a/snapshotter/processor_distributor.py#L928-L1042
- For
The preloaders often fetch and cache large volumes of data, for eg, all the transaction receipts for a block on the data source blockchain. In such a case, a single worker will never be enough to feasibly fetch the data for a timely base snapshot generation and subsequent aggregate snapshot generations to finally reach a consensus.
Hence such workers are defined as delegate_tasks
in config/preloader.json
and the process hub core launches a certain number of workers as defined in the primary settings file, config/settings.json
under the key callback_worker_config.num_delegate_workers
.
Delegation workers operate over a simple request-response queue architecture over RabbitMQ.
One of the preloaders bundled with this snapshotter peer is tasked with fetching all the transaction receipts within a given epoch's block range and because of the volume of data to be fetched it delegates this work to a bunch of delegation worker
- The Preloader: snapshotter/utils/preloaders/tx_receipts/preloader.py.
- The Delegation Workers: snapshotter/utils/preloaders/tx_receipts/delegated_worker/tx_receipts.py
As a common functionality shared by all preloaders that utilize delegate workers, this logic is present in the generic class DelegatorPreloaderAsyncWorker
that all such preloaders inherit. Here you can observe the workload is sent to the delegation workers
Upon sending out the workloads tagged by unique request IDs, the delegator sets up a temporary exclusive queue to which only the delegation workers meant for the task type push their responses.
The corresponding response being pushed by the delegation workers can be found here in the generic class DelegateAsyncWorker
that all such workers should inherit from:
The callback workers are the ones that build the base snapshot and aggregation snapshots and as explained above, are launched by the process hub core according to the configurations in aggregator/projects.json
and config/aggregator.json
.
They listen to new messages on the RabbitMQ topic exchange as described in the following configuration, and the topic queue's initialization is as follows.
Upon receiving a message from the processor distributor after preloading is complete, the workers do most of the heavy lifting along with some sanity checks and then call the compute()
callback function on the project's configured snapshot worker class to transform the dependent data points as cached by the preloaders to finally generate the base snapshots.
Extracting data from the blockchain state and generating the snapshot can be a complex task. The RpcHelper
, defined in utils/rpc.py
, has a bunch of helper functions to make this process easier. It handles all the retry
and caching
logic so that developers can focus on efficiently building their use cases.
This component is one of the most important and allows you to access the finalized protocol state on the smart contract running on the anchor chain. Find it in core_api.py
.
The pooler-frontend that serves the Uniswap v2 dashboards hosted by the PowerLoom foundation on locations like https://uniswapv2.powerloom.io/ is a great example of a frontend specific web application that makes use of this API service.
Among many things, the core API allows you to access the finalized CID as well as its contents at a given epoch ID for a project.
The main endpoint implementations can be found as follows:
The first endpoint in GET /last_finalized_epoch/{project_id}
returns the last finalized EpochId for a given project ID and the second one is GET /data/{epoch_id}/{project_id}/
which can be used to return the actual snapshot data for a given EpochId and ProjectId.
These endpoints along with the combination of a bunch of other helper endpoints present in Core API
can be used to build powerful Dapps and dashboards.
You can observe the way it is used in pooler-frontend
repo to fetch the dataset for the aggregate projects of top pairs trade volume and token reserves summary:
try {
response = await axios.get(API_PREFIX+`/data/${epochInfo.epochId}/${top_pairs_7d_project_id}/`);
console.log('got 7d top pairs', response.data);
if (response.data) {
for (let pair of response.data.pairs) {
pairsData7d[pair.name] = pair;
}
} else {
throw new Error(JSON.stringify(response.data));
}
}
catch (e){
console.error('7d top pairs', e);
}
These instructions are needed to run the system using build-docker.sh
.
Pooler needs the following config files to be present
settings.json
inpooler/auth/settings
: Changes are trivial. Copyconfig/auth_settings.example.json
toconfig/auth_settings.json
. This enables an authentication layer over the core API exposed by the pooler snapshotter.- settings files in
config/
-
config/projects.json
: Each entry in this configuration file defines the most fundamental unit of data representation in Powerloom Protocol, that is, a project. It is of the following schema{ "project_type": "snapshot_project_name_prefix_", "projects": ["array of smart contract addresses"], // Uniswap v2 pair contract addresses in this implementation "preload_tasks":[ "eth_price", "block_details" ], "processor":{ "module": "snapshotter.modules.uniswapv2.pair_total_reserves", "class_name": "PairTotalReservesProcessor" // class to be found in module snapshotter/modules/pooler/uniswapv2/pair_total_reserves.py } }
Copy over
config/projects.example.json
toconfig/projects.json
. For more details, read on in the use case study for this current implementation. -
config/aggregator.json
: This lists out different type of aggregation work to be performed over a span of snapshots. Copy overconfig/aggregator.example.json
toconfig/aggregator.json
. The span is usually calculated as a function of the epoch size and average block time on the data source network. For eg, * the following configuration calculates a snapshot of total trade volume over a 24 hour time period, based on the snapshot finalization of a project ID corresponding to a pair contract. This can be seen by theaggregate_on
key being set toSingleProject
. * This is specified by thefilters
key below. When a snapshot build is achieved for an epoch over a project ID (ref:generation of project ID for snapshot building workers). For eg, a snapshot build onpairContract_trade_volume:0xb4e16d0168e52d35cacd2c6185b44281ec28c9dc:UNISWAPV2
triggers the workerAggregateTradeVolumeProcessor
as defined in theprocessor
section of the config against the pair contract0xb4e16d0168e52d35cacd2c6185b44281ec28c9dc
.{ "config": [ { "project_type": "aggregate_pairContract_24h_trade_volume", "aggregate_on": "SingleProject", "filters": { // this triggers the compute() contained in the processor class at the module location // every time a `SnapshotFinalized` event is received for project IDs containing the prefix `pairContract_trade_volume` // at each epoch ID "projectId": "pairContract_trade_volume" }, "processor": { "module": "snapshotter.modules.uniswapv2.aggregate.single_uniswap_trade_volume_24h", "class_name": "AggregateTradeVolumeProcessor" } } ] }
-
The following configuration generates a collection of data sets of 24 hour trade volume as calculated by the worker above across multiple pair contracts. This can be seen by the
aggregate_on
key being set toMultiProject
. *projects_to_wait_for
specifies the exact project IDs on which this collection will be generated once a snapshot build has been achieved for anepochId
.{ "config": [ "project_type": "aggregate_24h_top_pairs_lite", "aggregate_on": "MultiProject", "projects_to_wait_for": [ "aggregate_pairContract_24h_trade_volume:0xb4e16d0168e52d35cacd2c6185b44281ec28c9dc:UNISWAPV2", "pairContract_pair_total_reserves:0xb4e16d0168e52d35cacd2c6185b44281ec28c9dc:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0xae461ca67b15dc8dc81ce7615e0320da1a9ab8d5:UNISWAPV2", "pairContract_pair_total_reserves:0xae461ca67b15dc8dc81ce7615e0320da1a9ab8d5:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0x0d4a11d5eeaac28ec3f61d100daf4d40471f1852:UNISWAPV2", "pairContract_pair_total_reserves:0x0d4a11d5eeaac28ec3f61d100daf4d40471f1852:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0x3041cbd36888becc7bbcbc0045e3b1f144466f5f:UNISWAPV2", "pairContract_pair_total_reserves:0x3041cbd36888becc7bbcbc0045e3b1f144466f5f:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0xd3d2e2692501a5c9ca623199d38826e513033a17:UNISWAPV2", "pairContract_pair_total_reserves:0xd3d2e2692501a5c9ca623199d38826e513033a17:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0xbb2b8038a1640196fbe3e38816f3e67cba72d940:UNISWAPV2", "pairContract_pair_total_reserves:0xbb2b8038a1640196fbe3e38816f3e67cba72d940:UNISWAPV2", "aggregate_pairContract_24h_trade_volume:0xa478c2975ab1ea89e8196811f51a7b7ade33eb11:UNISWAPV2", "pairContract_pair_total_reserves:0xa478c2975ab1ea89e8196811f51a7b7ade33eb11:UNISWAPV2" ], "processor": { "module": "snapshotter.modules.uniswapv2.aggregate.multi_uniswap_top_pairs_24h", "class_name": "AggreagateTopPairsProcessor" } ] }
-
To begin with, you can keep the workers and contracts as specified in the example files.
-
config/settings.json
: This is the primary configuration. We've provided a settings template inconfig/settings.example.json
to help you get started. Copy overconfig/settings.example.json
toconfig/settings.json
. There can be a lot to fine tune but the following are essential.instance_id
: This is the unique public key for your node to participate in consensus. It is currently registered on approval of an application (refer deploy repo for more details on applying).namespace
, is the unique key used to identify your project namespace around which all consensus activity takes place.- RPC service URL(s) and rate limit configurations. Rate limits are service provider specific, different RPC providers have different rate limits. Example rate limit config for a node looks something like this
"100000000/day;20000/minute;2500/second"
rpc.full_nodes
: This will correspond to RPC nodes for the chain on which the data source smart contracts live (for eg. Ethereum Mainnet, Polygon Mainnet, etc).anchor_chain_rpc.full_nodes
: This will correspond to RPC nodes for the anchor chain on which the protocol state smart contract lives (Prost Chain).protocol_state.address
: This will correspond to the address at which the protocol state smart contract is deployed on the anchor chain.protocol_state.abi
is already filled in the example and already available at the static path specifiedpooler/static/abis/ProtocolContract.json
-
-
Login to the pooler docker container using docker exec -it deploy-boost-1 bash
(use docker ps
to verify its presence in the list of running containers) and use the following commands for monitoring and debugging
- To monitor the status of running processes, you simply need to run
pm2 status
. - To see all logs you can run
pm2 logs
- To see logs for a specific process you can run
pm2 logs <Process Identifier>
- To see only error logs you can run
pm2 logs --err
All implementations of a snapshotter come equipped with a barebones API service that return detailed insights into its state. You can tunnel into port 8002 of an instance running the snapshotter and right away try out the internal APIs among others by visting the FastAPI generated SwaggerUI.
http://localhost:8002/docs
As detailed out in the section on epoch processing state transitions, this internal API endpoint offers the most detailed insight into each epoch's processing status as it passes through the snapshot builders and is sent out for consensus.
NOTE: The endpoint, though paginated and cached, serves a raw dump of insights into an epoch's state transitions and the payloads are significantly large enough for requests to timeout or to clog the internal API's limited resource. Hence it is advisable to query somewhere between 1 to 5 epochs. The same can be specified as the
size
query parameter.
Sample Request:
curl -X 'GET' \
'http://localhost:8002/internal/snapshotter/epochProcessingStatus?page=1&size=3' \
-H 'accept: application/json'
Sample Response:
{
"items": [
{
"epochId": 43523,
"transitionStatus": {
"EPOCH_RELEASED": {
"status": "success",
"error": null,
"extra": null,
"timestamp": 1692530595
},
"PRELOAD": {
"pairContract_pair_total_reserves": {
"status": "success",
"error": null,
"extra": null,
"timestamp": 1692530595
},
},
"SNAPSHOT_BUILD": {
"aggregate_24h_stats_lite:35ee1886fa4665255a0d0486c6079c4719c82f0f62ef9e96a98f26fde2e8a106:UNISWAPV2": {
"status": "success",
"error": null,
"extra": null,
"timestamp": 1692530596
},
},
"SNAPSHOT_SUBMIT_PAYLOAD_COMMIT": {
},
"RELAYER_SEND": {
},
"SNAPSHOT_FINALIZE": {
},
},
}
],
"total": 3,
"page": 1,
"size": 3,
"pages": 1
}
/status
Returns the overall status of all the projects
Response
{
"totalSuccessfulSubmissions": 10,
"totalMissedSubmissions": 5,
"totalIncorrectSubmissions": 1,
"projects":[
{
"projectId": "projectid"
"successfulSubmissions": 3,
"missedSubmissions": 2,
"incorrectSubmissions": 1
},
]
}
Returns the overall status of all the projects
Response
{
"totalSuccessfulSubmissions": 10,
"totalMissedSubmissions": 5,
"totalIncorrectSubmissions": 1,
"projects":[
{
"projectId": "projectid"
"successfulSubmissions": 3,
"missedSubmissions": 2,
"incorrectSubmissions": 1
},
]
}
Returns project specific detailed status report
Response
{
"missedSubmissions": [
{
"epochId": 10,
"finalizedSnapshotCid": "cid",
"reason": "error/exception/trace"
}
],
"incorrectSubmissions": [
{
"epochId": 12,
"submittedSnapshotCid": "snapshotcid",
"finalizedSnapshotCid": "finalizedsnapshotcid",
"reason": "reason for incorrect submission"
}
]
}
Returns project specific detailed status report with snapshot data
Response
{
"missedSubmissions": [
{
"epochId": 10,
"finalizedSnapshotCid": "cid",
"reason": "error/exception/trace"
}
],
"incorrectSubmissions": [
{
"epochId": 12,
"submittedSnapshotCid": "snapshotcid",
"submittedSnapshot": {}
"finalizedSnapshotCid": "finalizedsnapshotcid",
"finalizedSnapshot": {},
"reason": "reason for incorrect submission"
}
]
}
We use pre-commit hooks to ensure our code quality is maintained over time. For this contributors need to do a one-time setup by running the following commands.
- Install the required dependencies using
pip install -r dev-requirements.txt
, this will set up everything needed for pre-commit checks. - Run
pre-commit install
Now, whenever you commit anything, it'll automatically check the files you've changed/edited for code quality issues and suggest improvements.
Pooler is a Uniswap specific implementation of what is known as a 'snapshotter' in the PowerLoom Protocol ecosystem. It synchronizes with other snapshotter peers over a smart contract running on the present version of the PowerLoom Protocol testnet. It follows an architecture that is driven by state transitions which makes it easy to understand and modify. This present release ultimately provide access to rich aggregates that can power a Uniswap v2 dashboard with the following data points:
- Total Value Locked (TVL)
- Trade Volume, Liquidity reserves, Fees earned
- grouped by
- Pair contracts
- Individual tokens participating in pair contract
- aggregated over time periods
- 24 hours
- 7 days
- grouped by
- Transactions containing
Swap
,Mint
, andBurn
events
In this section, let us take a look at the data composition abilities of Pooler to build on the base snapshot being built that captures information on Uniswap trades.
Required reading:
As you can notice in config/projects.example.json
, each project config needs to have the following components
project_type
(unique identifier prefix for the usecase, used to generate project ID)projects
(smart contracts to extract data from, pooler can generate different snapshots from multiple sources as long as the Contract ABI is same)processor
(the actual compuation logic reference, while you can write the logic anywhere, it is recommended to write your implementation in pooler/modules folder)
There's currently no limitation on the number or type of usecases you can build using snapshotter. Just write the Processor class and pooler libraries will take care of the rest.
If we take a look at the TradeVolumeProcessor
class present at snapshotter/modules/computes/trade_volume.py
it implements the interface of GenericProcessorSnapshot
defined in pooler/utils/callback_helpers.py
.
There are a couple of important concepts here necessary to write your extraction logic:
compute
is the main function where most of the snapshot extraction and generation logic needs to be written. It receives the following inputs:
epoch
(current epoch details)redis
(async redis connection)rpc_helper
(RpcHelper
instance to help with any calls to the data source contract's chain)
Output format can be anything depending on the usecase requirements. Although it is recommended to use proper pydantic
models to define the snapshot interface.
The resultant output model in this specific example is UniswapTradesSnapshot
as defined in the Uniswap v2 specific modules directory: utils/models/message_models.py
. This encapsulates state information captured by TradeVolumeProcessor
between the block heights of the epoch: min_chain_height
and max_chain_height
.
-
As demonstrated in the previous section, the
TradeVolumeProcessor
logic takes care of capturing a snapshot of information regarding Uniswap v2 trades between the block heights ofmin_chain_height
andmax_chain_height
. -
The epoch size as described in the prior section on epoch generation can be considered to be constant for this specific implementation of the Uniswap v2 use case on PowerLoom Protocol, and by extension, the time duration captured within the epoch.
-
As shown in the section on dependency graph of data composition, every aggregate is calculated relative to the
epochId
at which the dependeeSnapshotFinalized
event is receieved. -
The finalized state and data CID corresponding to each epoch can be accessed on the smart contract on the anchor chain that holds the protocol state. The corresponding helpers for that can be found in
get_project_epoch_snapshot()
inpooler/utils/data_utils
- Considering the incoming
epochId
to be the head of the span, the quickest formula to arrive at the tail of the span of 24 hours worth of snapshots and trade information becomes,
time_in_seconds = 86400
tail_epoch_id = current_epoch_id - int(time_in_seconds / (source_chain_epoch_size * source_chain_block_time))
- The worker class for such aggregation is defined in
config/aggregator.json
in the following manner
{
"project_type": "aggregate_pairContract_24h_trade_volume",
"aggregate_on": "SingleProject",
"filters": {
"projectId": "pairContract_trade_volume"
},
"processor": {
"module": "computes.aggregate.single_uniswap_trade_volume_24h",
"class_name": "AggregateTradeVolumeProcessor"
}
}
- Each finalized
epochId
is registered with a snapshot commit against the aggregated data set generated by running summations on trade volumes on all the base snapshots contained within the span calculated above.
From the information provided above, the following is left as an exercise for the reader to generate aggregate datasets at every epochId
finalization for a pair contract, spanning 2 hours worth of snapshots and containing only Swap
event logs and the trade volume generated from them as a result.
Feel free to fork this repo and commit these on your implementation branch. By following the steps recommended for developers for the overall setup on
deploy
, you can begin capturing aggregates for this datapoint.
-
Add a new configuration entry in
config/aggregator.json
for this new aggregation worker class -
Define a new data model in
utils/message_models.py
referring toUniswapTradesAggregateSnapshot
as used in above exampleUniswapTradesSnapshot
used to capture each epoch's trade snapshots which includes the raw event logs as well
-
Follow the example of the aggregator worker as implemented for 24 hours aggregation calculation , and work on calculating an
epochId
span of 2 hours and filtering out only theSwap
events and the trade volume contained within.
Phase 2 quests form a crucial part of the Powerloom testnet program, where we leverage Snapshotter Peers to monitor on-chain activities of testnet participants across various chains and protocols. These quests predominantly operate in Bulk Mode due to their one-time nature and the highly dynamic set of participants involved.
In this particular implementation of the peer, known as 'Snapshotter' in the Powerloom Protocol, we have successfully harnessed its capabilities to provide accurate metrics, verified through consensus, pertaining to fundamental data points. These metrics allow us to determine if and when a quest is completed by a testnet participant.
This case study serves as a testament to the effectiveness and versatility of the Snapshotter Peer in real-world scenarios, highlighting its ability to support complex use cases with precision and reliability.
The snapshot builders can be found under the snapshotter-specific implementation directory: snapshotter/modules/computes
. Every snapshot builder must implement the interface of GenericProcessorSnapshot
compute()
is the callback where the snapshot extraction and generation logic needs to be written. It receives the following inputs:epoch
(current epoch details)redis
(async redis connection)rpc_helper
(RpcHelper
instance to help with any calls to the data source contract's chain)
compute()
should return an instance of a Pydantic model which is in turn uploaded to IPFS by the payload commit service helper method.
Looking at the pre-supplied example configuration of config/projects.json
, we can find the following snapshots being generated
Snapshot builder: snapshotter/modules/computes/bungee_bridge.py
{
"project_type": "zkevm:bungee_bridge",
"projects":[
],
"preload_tasks":[
"block_transactions"
],
"processor":{
"module": "snapshotter.modules.boost.bungee_bridge",
"class_name": "BungeeBridgeProcessor"
}
},
Its preloader dependency is block_transactions
as seen in the preloader configuration.
The snapshot builder then goes through all preloaded block transactions, filters out, and then generates relevant snapshots for wallet address that received funds from the Bungee Bridge refuel contract during that epoch.