Spins up and tests CometBFT networks in Docker Compose based on a testnet manifest. To run the CI testnet:
make
./build/runner -f networks/ci.toml
This creates and runs a testnet named ci
under networks/ci/
.
To generate the testnet files in a different directory, run:
./build/runner -f networks/ci.toml -d networks/foo/bar/
If you need to run experiments on a testnet, you will probably want to compile the code multiple
times and make
could be slow. This is because make
builds an image by first copying all the
source code into it and then compiling the binary from inside. This is needed if, for example, you
want to create a binary that uses a different database (as in networks/ci.toml
), or to emulate
latencies by running the Python script.
If you just need to (re-)compile and run the binary without any extra building options, you can use
make fast
, which will first compile the code and then make a slim Docker image with the binary.
For example:
make fast
./build/runner -f networks/simple.toml
End-to-end testnets are used to test Tendermint functionality as a user would use it, by spinning up a set of nodes with various configurations and making sure the nodes and network behave correctly. The background for the E2E test suite is outlined in RFC-001.
The end-to-end tests can be thought of in this manner:
-
Does a certain (valid!) testnet configuration result in a block-producing network where all nodes eventually reach the latest height?
-
If so, does each node in that network satisfy all invariants specified by the Go E2E tests?
The above should hold for any arbitrary, valid network configuration, and that configuration space should be searched and tested by randomly generating testnets.
A testnet configuration is specified as a TOML testnet manifest (see below). The testnet runner uses the manifest to configure a set of Docker containers and start them in some order. The manifests can be written manually (to test specific configurations) or generated randomly by the testnet generator (to test a wide range of configuration permutations).
When running a testnet, the runner will first start the Docker nodes in some sequence, submit random transactions, and wait for the nodes to come online and the first blocks to be produced. This may involve e.g. waiting for nodes to block sync and/or state sync. If specified, it will then run any misbehaviors (e.g. double-signing) and perturbations (e.g. killing or disconnecting nodes). It then waits for the testnet to stabilize, with all nodes online and having reached the latest height.
Once the testnet stabilizes, a set of Go end-to-end tests are run against the live testnet to verify network invariants (for example that blocks are identical across nodes). These use the RPC client to interact with the network, and should consider the entire network as a black box (i.e. it should not test any network or node internals, only externally visible behavior via RPC). The tests may use the testNode()
helper to run parallel tests against each individual testnet node, and/or inspect the full blockchain history via fetchBlockChain()
.
The tests must take into account the network and/or node configuration, and tolerate that the network is still live and producing blocks. For example, validator tests should only run against nodes that are actually validators, and take into account the node's block retention and/or state sync configuration to not query blocks that don't exist.
Testnets are specified as TOML manifests. For an example see networks/ci.toml
, and for documentation see pkg/manifest.go
.
Random (but deterministic) combinations of testnets can be generated with generator
:
./build/generator -d networks/generated/
# Split networks into 8 groups (by filename)
./build/generator -g 8 -d networks/generated/
Multiple testnets can be run with the run-multiple.sh
script:
./run-multiple.sh networks/generated/gen-group3-*.toml
Testnets running different versions of CometBFT can be generated by the generator. For example:
# Generate testnets randomly choosing between v0.34.21 (making up 1/3rd of the
# network) and v0.34.22 (making up 2/3rds of the network).
./build/generator -m "v0.34.21:1,v0.34.22:2" -d networks/generated/
# "local" refers to the current local code. The E2E node built from the local
# code will be run on 2/3rds of the network, whereas the v0.34.23 E2E node will
# be run on the remaining 1/3rd.
./build/generator -m "v0.34.23:1,local:2" -d networks/generated/
# Using "latest" will cause the generator to auto-detect the latest
# non-pre-release version tag in the current Git repository that is closest to
# the CometBFT version in the current local code (as specified in
# ../../version/version.go).
#
# In the example below, if the local version value is "v0.34.24",
# for example, and the latest official release is v0.34.23, then 1/3rd of the
# network will run v0.34.23 and the remaining 2/3rds will run the E2E node built
# from the local code.
./build/generator -m "latest:1,local:2" -d networks/generated/
NB: The corresponding Docker images for the relevant versions of the E2E
node (the cometbft/e2e-node
image) must be available on the local machine,
or via Docker Hub.
Multiversion testnets can also perform uncoordinated upgrades. Nodes containing a
perturbation of type upgrade
will upgrade to the target version specified in
testnet's attribute upgrade_version
of the testnet manifest.
The generator generates this type of perturbation both on full nodes and on light nodes.
Perturbations of type upgrade
are a noop if the node's version matches the
one in upgrade_version
.
The test runner has the following stages, which can also be executed explicitly by running ./build/runner -f <manifest> <stage>
:
-
setup
: generates configuration files. -
start
: starts Docker containers. -
load
: generates a transaction load against the testnet nodes. -
perturb
: runs any requested perturbations (e.g. node restarts or network disconnects). -
wait
: waits for a few blocks to be produced, and for all nodes to catch up to it. -
test
: runs test cases intests/
against all nodes in a running testnet. -
stop
: stops Docker containers. -
cleanup
: removes configuration files and Docker containers/networks.
Auxiliary commands:
-
logs
: outputs all node logs. -
tail
: tails (follows) node logs until canceled.
Test cases are written as normal Go tests in tests/
. They use a testNode()
helper which executes each test as a parallel subtest for each node in the network.
To run tests manually, set the E2E_MANIFEST
environment variable to the path of the testnet manifest (e.g. networks/ci.toml
) and run them as normal, e.g.:
./build/runner -f networks/ci.toml start
E2E_MANIFEST=networks/ci.toml go test -v ./tests/...
If the testnet files are located in a custom directory, you need to set it in the E2E_TESTNET_DIR
environment variable.
Optionally, E2E_NODE
specifies the name of a single testnet node to test.
These environment variables can also be specified in tests/e2e_test.go
to run tests from an editor or IDE:
func init() {
// This can be used to manually specify a testnet manifest and/or node to
// run tests against. The testnet must have been started by the runner first.
os.Setenv("E2E_MANIFEST", "networks/ci.toml")
os.Setenv("E2E_TESTNET_DIR", "networks/foo")
os.Setenv("E2E_NODE", "validator01")
}
If a command or test fails, the runner simply exits with an error message and
non-zero status code. The testnet is left running with data in the testnet
directory, and can be inspected with e.g. docker ps
, docker logs
, or
./build/runner -f <manifest> logs
or tail
. To shut down and remove the
testnet, run ./build/runner -f <manifest> cleanup
.
If the standard log_level
is not detailed enough (e.g. you want "debug" level
logging for certain modules), you can change it in the manifest file.
Each node exposes a pprof server. To
find out the local port, run docker port <NODENAME> 6060 | awk -F: '{print $2}'
. Then you may perform any queries supported by the pprof tool. Julia
Evans has a great
post on this
subject.
export PORT=$(docker port full01 6060 | awk -F: '{print $2}')
go tool pprof http://localhost:$PORT/debug/pprof/goroutine
go tool pprof http://localhost:$PORT/debug/pprof/heap
go tool pprof http://localhost:$PORT/debug/pprof/threadcreate
go tool pprof http://localhost:$PORT/debug/pprof/block
go tool pprof http://localhost:$PORT/debug/pprof/mutex
Docker does not enable IPv6 by default. To do so, enter the following in
daemon.json
(or in the Docker for Mac UI under Preferences → Docker Engine):
{
"ipv6": true,
"fixed-cidr-v6": "2001:db8:1::/64"
}
It is also possible to run a simple benchmark on a testnet. This is done through the benchmark
command. This manages the entire process: setting up the environment, starting the test net, waiting for a considerable amount of blocks to be used (currently 100), and then returning the following metrics from the sample of the blockchain:
- Average time to produce a block
- Standard deviation of producing a block
- Minimum and maximum time to produce a block
The E2E test harness is designed to run several nodes of varying configurations within docker. It is also possible to run a single node in the case of running larger, geographically-dispersed testnets. To run a single node you can either run:
Built-in
make node
cometbft init validator
CMTHOME=$HOME/.cometbft ./build/node ./node/built-in.toml
To make things simpler the e2e application can also be run in the cometbft
binary
by running
cometbft start --proxy-app e2e
However this won't offer the same level of configurability of the application.
Socket
make node
cometbft init validator
cometbft start
./build/node ./node.socket.toml
Check node/config.go
to see how the settings of the test application can be tweaked.