* docs: more updates * minor changes * workflow * yarn * structure * more updates * cleanup * additional cleanup * docs * interact with node * additional guides and testnet docs * update swagger * update docs * action
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Interacting with the Node
There are multiple ways to interact with a node: using the CLI, using gRPC or using the REST endpoints. {synopsis}
Using the CLI
Now that your very own node is running, it is time to try sending tokens from the first account you created to a second account. In a new terminal window, start by running the following query command:
ethermintd query bank balances $MY_VALIDATOR_ADDRESS --chain-id=ethermintd-1
You should see the current balance of the account you created, equal to the original balance of eth
you granted it minus the amount you delegated via the gentx
. Now, create a second account:
ethermintd keys add recipient --keyring-backend=file
# Put the generated address in a variable for later use.
RECIPIENT=$(ethermintd keys show recipient -a --keyring-backend=file)
The command above creates a local key-pair that is not yet registered on the chain. An account is created the first time it receives tokens from another account. Now, run the following command to send tokens to the recipient
account:
ethermintd tx bank send $MY_VALIDATOR_ADDRESS $RECIPIENT 1000000aphoton --chain-id=ethermintd-1 --keyring-backend=file
# Check that the recipient account did receive the tokens.
ethermintd query bank balances $RECIPIENT --chain-id=ethermintd-1
Finally, delegate some of the stake tokens sent to the recipient
account to the validator:
ethermintd tx staking delegate $(ethermintd keys show my_validator --bech val -a --keyring-backend=file) 500aphoton --from=recipient --chain-id=ethermintd-1 --keyring-backend=file
# Query the total delegations to `validator`.
ethermintd query staking delegations-to $(ethermintd keys show my_validator --bech val -a --keyring-backend=file) --chain-id=ethermintd-1
You should see two delegations, the first one made from the gentx
, and the second one you just performed from the recipient
account.
Using gRPC
The Protobuf ecosystem developed tools for different use cases, including code-generation from *.proto
files into various languages. These tools allow the building of clients easily. Often, the client connection (i.e. the transport) can be plugged and replaced very easily. Let's explore one of the most popular transport: gRPC.
Since the code generation library largely depends on your own tech stack, we will only present three alternatives:
grpcurl
for generic debugging and testing- programmatically via Go
- CosmJS for JavaScript/TypeScript developers
grpcurl
grpcurl is like curl
but for gRPC. It is also available as a Go library, but we will use it only as a CLI command for debugging and testing purposes. Follow the instructions in the previous link to install it.
Assuming you have a local node running (either a localnet, or connected a live network), you should be able to run the following command to list the Protobuf services available (you can replace localhost:9000
by the gRPC server endpoint of another node, which is configured under the grpc.address
field inside app.toml
):
grpcurl -plaintext localhost:9090 list
You should see a list of gRPC services, like cosmos.bank.v1beta1.Query
. This is called reflection, which is a Protobuf endpoint returning a description of all available endpoints. Each of these represents a different Protobuf service, and each service exposes multiple RPC methods you can query against.
In order to get a description of the service you can run the following command:
# Service we want to inspect
grpcurl \
localhost:9090 \
describe cosmos.bank.v1beta1.Query
It's also possible to execute an RPC call to query the node for information:
grpcurl \
-plaintext
-d '{"address":"$MY_VALIDATOR"}' \
localhost:9090 \
cosmos.bank.v1beta1.Query/AllBalances
Query for historical state using grpcurl
You may also query for historical data by passing some gRPC metadata to the query: the x-cosmos-block-height
metadata should contain the block to query. Using grpcurl as above, the command looks like:
grpcurl \
-plaintext \
-H "x-cosmos-block-height: 279256" \
-d '{"address":"$MY_VALIDATOR"}' \
localhost:9090 \
cosmos.bank.v1beta1.Query/AllBalances
Assuming the state at that block has not yet been pruned by the node, this query should return a non-empty response.
Programmatically via Go
The following snippet shows how to query the state using gRPC inside a Go program. The idea is to create a gRPC connection, and use the Protobuf-generated client code to query the gRPC server.
import (
"context"
"fmt"
"google.golang.org/grpc"
sdk "github.com/cosmos/cosmos-sdk/types"
"github.com/cosmos/cosmos-sdk/types/tx"
)
func queryState() error {
myAddress, err := sdk.AccAddressFromBech32("eth...")
if err != nil {
return err
}
// Create a connection to the gRPC server.
grpcConn := grpc.Dial(
"127.0.0.1:9090", // your gRPC server address.
grpc.WithInsecure(), // The SDK doesn't support any transport security mechanism.
)
defer grpcConn.Close()
// This creates a gRPC client to query the x/bank service.
bankClient := banktypes.NewQueryClient(grpcConn)
bankRes, err := bankClient.Balance(
context.Background(),
&banktypes.QueryBalanceRequest{Address: myAddress, Denom: "eth"},
)
if err != nil {
return err
}
fmt.Println(bankRes.GetBalance()) // Prints the account balance
return nil
}
Query for historical state using Go
Querying for historical blocks is done by adding the block height metadata in the gRPC request.
import (
"context"
"fmt"
"google.golang.org/grpc"
"google.golang.org/grpc/metadata"
grpctypes "github.com/cosmos/cosmos-sdk/types/grpc"
"github.com/cosmos/cosmos-sdk/types/tx"
)
func queryState() error {
// --snip--
var header metadata.MD
bankRes, err = bankClient.Balance(
metadata.AppendToOutgoingContext(context.Background(), grpctypes.GRPCBlockHeightHeader, "12"), // Add metadata to request
&banktypes.QueryBalanceRequest{Address: myAddress, Denom: denom},
grpc.Header(&header), // Retrieve header from response
)
if err != nil {
return err
}
blockHeight = header.Get(grpctypes.GRPCBlockHeightHeader)
fmt.Println(blockHeight) // Prints the block height (12)
return nil
}
CosmJS
CosmJS documentation can be found at https://cosmos.github.io/cosmjs. As of January 2021, CosmJS documentation is still work in progress.
Using the REST Endpoints
All gRPC services on the Cosmos SDK are made available for more convenient REST-based queries through gRPC-gateway. The format of the URL path is based on the Protobuf service method's full-qualified name, but may contain small customizations so that final URLs look more idiomatic. For example, the REST endpoint for the cosmos.bank.v1beta1.Query/AllBalances
method is GET /cosmos/bank/v1beta1/balances/{address}
. Request arguments are passed as query parameters.
As a concrete example, the curl
command to make balances request is:
curl \
-X GET \
-H "Content-Type: application/json" \
http://localhost:1317/cosmos/bank/v1beta1/balances/$MY_VALIDATOR
Make sure to replace localhost:1317
with the REST endpoint of your node, configured under the api.address
field.
The list of all available REST endpoints is available as a Swagger specification file, it can be viewed at localhost:1317/swagger
. Make sure that the api.swagger
field is set to true in your app.toml
file.
Query for historical state using REST
Querying for historical state is done using the HTTP header x-cosmos-block-height
. For example, a curl command would look like:
curl \
-X GET \
-H "Content-Type: application/json" \
-H "x-cosmos-block-height: 279256"
http://localhost:1317/cosmos/bank/v1beta1/balances/$MY_VALIDATOR
Assuming the state at that block has not yet been pruned by the node, this query should return a non-empty response.
Cross-Origin Resource Sharing (CORS)
CORS policies are not enabled by default to help with security. If you would like to use the rest-server in a public environment we recommend you provide a reverse proxy, this can be done with nginx. For testing and development purposes there is an enabled-unsafe-cors
field inside app.toml
.
Next {hide}
Sending transactions using gRPC and REST requires some additional steps: generating the transaction, signing it, and finally broadcasting it. Read about generating and signing transactions. {hide}