This repository the semantics of the MultiversX (formerly Elrond) blockchain in K on top of WebAssembly semantics (KWasm).
- Python3
- WABT v1.0.13
- K Framework (version)
- Poetry
- Rustup and
sc-meta
Python3 and WABT should be installable via your system's package manager alongside with the follwoing other dependencies. We use the Ubuntu package manager as an example:
sudo apt-get install --yes \
autoconf \
libtool \
cmake \
curl \
wget \
libcrypto++-dev \
libsecp256k1-dev \
libssl-dev \
python3 \
python3-pip \
python3-venv \
wabt
You need to install the K Framework on your system. While you can build it from soucre, the fastest way is via the kup package manager.
To install kup
simply run
bash <(curl https://kframework.org/install)
Once kup
is installed, to get the correct version of K run:
kup install k.openssl.secp256k1 --version v$(cat deps/k_release)
To install Poetry you can use the following command
curl -sSL https://install.python-poetry.org | python3 -
For more complete instructions see the official installer.
To install Rust and the necessary crates you have to install rustup
, which can be done by ruuning the following on a Unix-like OS:
curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh
Or, if you want to install a more fine-tuned version for this project:
wget -O rustup.sh https://sh.rustup.rs && \
chmod +x rustup.sh && \
./rustup.sh --verbose --default-toolchain nightly-2023-12-11 --target wasm32-unknown-unknown -y
sc-meta
is the MultiversX smart contract managing tool. To install it, you can run the following
cargo install multiversx-sc-meta --locked
However, if you run into problems with the above command, this might be because of your rustup
version. Try installing it with a nightly version of rustup
alongside your current one:
rustup install nightly
and to install sc-meta
with the nightly version run:
cargo +nightly install multiversx-sc-meta --locked
If the above doesn't succeed try installing a less recent version of the tool. For instance, to install version 0.48.1
run:
cargo +nightly install multiversx-sc-meta --locked --version 0.48.1
See Dockerfile for additional installation details.
Compile the semantics with:
$ make build
It will build MANDOS
as the main module using the LLVM backend. The compiled definition will be placed under ./build/defn
.
Then the tests can be run with:
$ make test
kmultiversx
is a Python package providing libraries and CLI tools to interact with the semantics.
To install kmultiversx
and its dependencies into a virtual environment, run
# from the 'elrond-semantics' directory
poetry -C kmultiversx install
After the installation, the Python package kmultiversx
and CLI tools mandos
and kasmer
will be available via the poetry run
command
poetry -C kmultiversx run mandos --help
poetry -C kmultiversx run kasmer --help
Or you can activate the virtual environment managed by poetry
and use the commands directly
poetry -C kmultiversx shell
mandos --help
Alternatively, you can install kmultiversx
globally
make -C kmultiversx build
pip install kmultiversx/dist/*.whl
mandos --help
kasmer --help
To run Mandos tests, first build the contract:
$ sc-meta all build "<path-to-contract-directory>" --wasm-symbols
Then run Mandos scenarios with:
poetry -C kmultiversx run mandos --definition .build/defn/llvm/mandos-kompiled <path-to-mandos-file>
Or with a globally installed instance
mandos --definition .build/defn/llvm/mandos-kompiled <path-to-mandos-file>
Example:
$ sc-meta all build "deps/mx-sdk-rs/contracts/examples/multisig" --wasm-symbols
...
INFO:projects.core:Build ran.
INFO:projects.core:WASM file generated: /path/to/multisig/output/multisig.wasm
$ mandos deps/mx-sdk-rs/contracts/examples/multisig/scenarios/changeBoard.scen.json
Compile the semantics with K_COVERAGE=true
to enable the coverage analysis. This will make krun
generate coverage data after every execution:
$ make build K_COVERAGE=true
Execute the programs to measure rule coverage for:
$ make test
Run the coverage analysis. This will list the locations of the rules that are not exercised.
$ make -s rule-coverage
deps/wasm-semantics/elrond-config.md:163:10
deps/wasm-semantics/elrond-config.md:322:10
deps/wasm-semantics/elrond-config.md:324:10
...
The coverage files generated by krun
are located under the build directory (.build/defn/llvm/mandos-kompiled
). To clean up the coverage data generated, run make clean-coverage
.
To begin writing tests for your smart contract, you'll first need to create an empty contract using sc-meta.
sc-meta new --template empty test_adder
Next, add testapi
as a dependency to your project. This package contains auxiliary external functions specifically designed for testing, implemented as WASM host functions.
$ cargo add <path to src/testapi/>
The testing API provides the test contract with special abilities that regular contracts do not have, such as accessing the storage of other contracts and deploying contracts using local WASM file paths.
We will use the init
function to deploy the contract(s) involved in our test cases and create an initial state for running the test cases. This can be thought of as the equivalent of the setState
and scDeploy
steps in scenario tests.
fn init(&self, code_path: ManagedBuffer)
The init
function takes a path to the contract's wasm file as an argument and utilizes the testapi::deploy_contract function
to deploy it. This function works similarly to the scDeploy
step in the scenario format.
let adder = testapi::deploy_contract(
&owner, // address of the owner account
5000000000000, // some gas
&BigUint::zero(), // value
&code_path, // path to wasm file
&adder_init_args,
);
self.adder_address().set(&adder);
Once you've implemented the init function, it's essential to make sure the test runner knows the correct file path to use when deploying the test contract. To achieve this, you'll need to create a kasmer.json
file in the root directory of your test contract. In this file, specify the relative path to the contract's WASM file that you want to deploy for testing.
For example, assuming your test contract is named test_adder
, and you want to deploy the adder.wasm
contract located in the ../../../deps/mx-sdk-rs/contracts/examples/adder/output/ directory, your kasmer.json
file should look like this:
{
"contract_paths": [
"../mx-sdk-rs/contracts/examples/adder/output/adder.wasm"
]
}
By providing the correct file path in the kasmer.json
file, the test runner will be able to deploy the specified contract during the testing process. With the init
function in place and the contract file path specified, you are now ready to write test cases in endpoints.
In our testing approach, test cases are organized as endpoints, clearly labeled with the 'test_' prefix for easy identification.
#[endpoint(test_call_add)]
fn test_call_add(&self, value: BigUint)
These endpoints can accept parameters, enabling us to express the contract's properties parametrically by varying these variables. This flexibility allows us to execute tests with fuzzing techniques or prove them using symbolic execution.
Within each endpoint, we interact with the contract deployed during the init
phase and employ the testing API to make specific assertions. These assertions serve as validation checks, ensuring that the contract behaves as intended and produces the expected outcomes during testing.
In certain testing scenarios, it becomes necessary to simulate actions from another account. To achieve this, we employ a feature known as "pranks."
Pranks enable the test contract to act as another account temporarily. We initiate a prank by using the testapi::start_prank(&acct_addr)
function, where acct_addr
represents the address of the account we wish to impersonate. Once the prank is started, any calls made by the test contract will be executed as if they were sent from the specified acct_addr
. This allows us to test various functionalities from the perspective of that particular account.
For instance, let's consider the following code snippet:
testapi::start_prank(&owner);
let res = self.send_raw().direct_egld_execute(
&adder,
&BigUint::from(0u32),
5000000,
&ManagedBuffer::from(b"add"),
&adder_init_args,
);
testapi::stop_prank();
In this example, we initiate a prank using the owner
account address. Subsequently, we execute a call to the contract adder
as if it were invoked from the owner
account. Once the intended actions are completed, we stop the prank using testapi::stop_prank()
.
After executing the call to the adder
contract through a prank, it's common to observe changes in the contract's storage. To verify whether the expected changes have occurred, we can access the storage of the account using testapi::get_storage
. In the following code snippet, we retrieve the value stored under the key "sum" in the storage of the adder
contract:
let sum_as_bytes = testapi::get_storage(&adder, &ManagedBuffer::from(b"sum"));
let sum = BigUint::from(sum_as_bytes);
Once we have obtained the stored value, we can then proceed to make assertions to verify its correctness. In this example, we are checking if the sum
value is equal to the sum of the initial value (INIT_SUM
) and the current value
:
testapi::assert(sum == (value + INIT_SUM));
By combining pranks with storage access and assertions, we can comprehensively test the behavior of our Smart Contracts, ensuring their accuracy and robustness in various scenarios.
To run the tests for your Smart Contracts, ensure that you have fulfilled the following prerequisites:
- Compile the semantics by executing
make build-kasmer
. - Add a
<path to adder contract>/multicontract.toml
file to the adder contract, something like:The stack-size should be as low as possible, while also allowing the contract to run without errors. Also, if the contract does not need it, the allocator should be "fail".[settings] main = "main" [contracts.main] name = "adder" add-unlabelled = true allocator = "fail" stack-size = "1 pages"
- Compile the contract using
sc-meta all build <path to adder contract>
. - Install the
hypothesis
library by runningpip3 install hypothesis
. This library will be utilized for concrete execution with fuzzing.
Now, follow these steps to run the test contract:
Build the test contract by executing
sc-meta all build <path to test contract>
Run the kasmer
tool with the test contract's path as the argument:
kasmer --definition-dir .build/defn/llvm/kasmer-kompiled --directory <path to test contract>
The kasmer
tool will deploy the test contract using the arguments specified in the kasmer.json
file located in the test directory. It will extract the names and argument types of the test endpoints. Subsequently, the script will test these endpoints using random inputs generated with the hypothesis
library, enabling fuzz testing. If it encounters an input that falsifies the assertions made in the test cases, it attempts to shrink the input and identify a minimal failing example.
By following these steps, you can efficiently and comprehensively evaluate your Smart Contracts, ensuring their correctness and reliability in various scenarios and inputs.