Query Lifecycle
This document describes the lifecycle of a query in a Cosmos SDK application, from the user interface to application stores and back. The query is referred to as MyQuery
.
Query Creation
A query is a request for information made by end-users of applications through an interface and processed by a full-node. Users can query information about the network, the application itself, and application state directly from the application's stores or modules. Note that queries are different from transactions (view the lifecycle here), particularly in that they do not require consensus to be processed (as they do not trigger state-transitions); they can be fully handled by one full-node.
For the purpose of explaining the query lifecycle, let's say the query, MyQuery
, is requesting a list of delegations made by a certain delegator address in the application called simapp
. As is to be expected, the staking
module handles this query. But first, there are a few ways MyQuery
can be created by users.
CLI
The main interface for an application is the command-line interface. Users connect to a full-node and run the CLI directly from their machines - the CLI interacts directly with the full-node. To create MyQuery
from their terminal, users type the following command:
simd query staking delegations <delegatorAddress>
This query command was defined by the staking
module developer and added to the list of subcommands by the application developer when creating the CLI.
Note that the general format is as follows:
simd query [moduleName] [command] <arguments> --flag <flagArg>
To provide values such as --node
(the full-node the CLI connects to), the user can use the app.toml
config file to set them or provide them as flags.
The CLI understands a specific set of commands, defined in a hierarchical structure by the application developer: from the root command (simd
), the type of command (Myquery
), the module that contains the command (staking
), and command itself (delegations
). Thus, the CLI knows exactly which module handles this command and directly passes the call there.
gRPC
Another interface through which users can make queries is gRPC requests to a gRPC server. The endpoints are defined as Protocol Buffers service methods inside .proto
files, written in Protobuf's own language-agnostic interface definition language (IDL). The Protobuf ecosystem developed tools for code-generation from *.proto
files into various languages. These tools allow to build gRPC clients easily.
One such tool is grpcurl, and a gRPC request for MyQuery
using this client looks like:
grpcurl \
-plaintext # We want results in plain test
-import-path ./proto \ # Import these .proto files
-proto ./proto/cosmos/staking/v1beta1/query.proto \ # Look into this .proto file for the Query protobuf service
-d '{"address":"$MY_DELEGATOR"}' \ # Query arguments
localhost:9090 \ # gRPC server endpoint
cosmos.staking.v1beta1.Query/Delegations # Fully-qualified service method name
REST
Another interface through which users can make queries is through HTTP Requests to a REST server. The REST server is fully auto-generated from Protobuf services, using gRPC-gateway.
An example HTTP request for MyQuery
looks like:
GET http://localhost:1317/cosmos/staking/v1beta1/delegators/{delegatorAddr}/delegations
How Queries are Handled by the CLI
The preceding examples show how an external user can interact with a node by querying its state. To understand in more detail the exact lifecycle of a query, let's dig into how the CLI prepares the query, and how the node handles it. The interactions from the users' perspective are a bit different, but the underlying functions are almost identical because they are implementations of the same command defined by the module developer. This step of processing happens within the CLI, gRPC, or REST server, and heavily involves a client.Context
.
Context
The first thing that is created in the execution of a CLI command is a client.Context
. A client.Context
is an object that stores all the data needed to process a request on the user side. In particular, a client.Context
stores the following:
- Codec: The encoder/decoder used by the application, used to marshal the parameters and query before making the CometBFT RPC request and unmarshal the returned response into a JSON object. The default codec used by the CLI is Protobuf.
- Account Decoder: The account decoder from the
auth
module, which translates[]byte
s into accounts. - RPC Client: The CometBFT RPC Client, or node, to which requests are relayed.
- Keyring: A [Key Manager]../beginner/03-accounts.md#keyring) used to sign transactions and handle other operations with keys.
- Output Writer: A Writer used to output the response.
- Configurations: The flags configured by the user for this command, including
--height
, specifying the height of the blockchain to query, and--indent
, which indicates to add an indent to the JSON response.
The client.Context
also contains various functions such as Query()
, which retrieves the RPC Client and makes an ABCI call to relay a query to a full-node.
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The client.Context
's primary role is to store data used during interactions with the end-user and provide methods to interact with this data - it is used before and after the query is processed by the full-node. Specifically, in handling MyQuery
, the client.Context
is utilized to encode the query parameters, retrieve the full-node, and write the output. Prior to being relayed to a full-node, the query needs to be encoded into a []byte
form, as full-nodes are application-agnostic and do not understand specific types. The full-node (RPC Client) itself is retrieved using the client.Context
, which knows which node the user CLI is connected to. The query is relayed to this full-node to be processed. Finally, the client.Context
contains a Writer
to write output when the response is returned. These steps are further described in later sections.
Arguments and Route Creation
At this point in the lifecycle, the user has created a CLI command with all of the data they wish to include in their query. A client.Context
exists to assist in the rest of the MyQuery
's journey. Now, the next step is to parse the command or request, extract the arguments, and encode everything. These steps all happen on the user side within the interface they are interacting with.
Encoding
In our case (querying an address's delegations), MyQuery
contains an address delegatorAddress
as its only argument. However, the request can only contain []byte
s, as it is ultimately relayed to a consensus engine (e.g. CometBFT) of a full-node that has no inherent knowledge of the application types. Thus, the codec
of client.Context
is used to marshal the address.
Here is what the code looks like for the CLI command:
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gRPC Query Client Creation
The Cosmos SDK leverages code generated from Protobuf services to make queries. The staking
module's MyQuery
service generates a queryClient
, which the CLI uses to make queries. Here is the relevant code:
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Under the hood, the client.Context
has a Query()
function used to retrieve the pre-configured node and relay a query to it; the function takes the query fully-qualified service method name as path (in our case: /cosmos.staking.v1beta1.Query/Delegations
), and arguments as parameters. It first retrieves the RPC Client (called the node) configured by the user to relay this query to, and creates the ABCIQueryOptions
(parameters formatted for the ABCI call). The node is then used to make the ABCI call, ABCIQueryWithOptions()
.
Here is what the code looks like:
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RPC
With a call to ABCIQueryWithOptions()
, MyQuery
is received by a full-node which then processes the request. Note that, while the RPC is made to the consensus engine (e.g. CometBFT) of a full-node, queries are not part of consensus and so are not broadcasted to the rest of the network, as they do not require anything the network needs to agree upon.
Read more about ABCI Clients and CometBFT RPC in the CometBFT documentation.
Application Query Handling
When a query is received by the full-node after it has been relayed from the underlying consensus engine, it is at that point being handled within an environment that understands application-specific types and has a copy of the state. baseapp
implements the ABCI Query()
function and handles gRPC queries. The query route is parsed, and it matches the fully-qualified service method name of an existing service method (most likely in one of the modules), then baseapp
relays the request to the relevant module.
Since MyQuery
has a Protobuf fully-qualified service method name from the staking
module (recall /cosmos.staking.v1beta1.Query/Delegations
), baseapp
first parses the path, then uses its own internal GRPCQueryRouter
to retrieve the corresponding gRPC handler, and routes the query to the module. The gRPC handler is responsible for recognizing this query, retrieving the appropriate values from the application's stores, and returning a response. Read more about query services here.
Once a result is received from the querier, baseapp
begins the process of returning a response to the user.
Response
Since Query()
is an ABCI function, baseapp
returns the response as an abci.ResponseQuery
type. The client.Context
Query()
routine receives the response and.
CLI Response
The application codec
is used to unmarshal the response to a JSON and the client.Context
prints the output to the command line, applying any configurations such as the output type (text, JSON or YAML).
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And that's a wrap! The result of the query is outputted to the console by the CLI.