# Developing This file attempts to provide a brief overview of developing this contract, assuming you have installed a recent version of Rust already (eg. 1.51.0+). ## Prerequisites Before starting, make sure you have [rustup](https://rustup.rs/) along with a recent `rustc` and `cargo` version installed. Currently, we are testing on 1.51.0+. And you need to have the `wasm32-unknown-unknown` target installed as well. You can check that via: ```sh rustc --version cargo --version rustup target list --installed # if wasm32 is not listed above, run this rustup target add wasm32-unknown-unknown ``` ## Compiling and running tests Now that you created your custom contract, make sure you can compile and run it before making any changes. Go into the repository and do: ```sh # this will produce a wasm build in ./target/wasm32-unknown-unknown/release/YOUR_NAME_HERE.wasm cargo wasm # this runs unit tests with helpful backtraces RUST_BACKTRACE=1 cargo unit-test # auto-generate json schema cargo schema ``` ### Understanding the tests The main code is in `src/contract.rs` and the unit tests there run in pure rust, which makes them very quick to execute and give nice output on failures, especially if you do `RUST_BACKTRACE=1 cargo unit-test`. We consider testing critical for anything on a blockchain, and recommend to always keep the tests up to date. ## Generating JSON Schema While the Wasm calls (`instantiate`, `execute`, `query`) accept JSON, this is not enough information to use it. We need to expose the schema for the expected messages to the clients. You can generate this schema by calling `cargo schema`, which will output 4 files in `./schema`, corresponding to the 3 message types the contract accepts, as well as the internal `State`. These files are in standard json-schema format, which should be usable by various client side tools, either to auto-generate codecs, or just to validate incoming json wrt. the defined schema. ## Preparing the Wasm bytecode for production Before we upload it to a chain, we need to ensure the smallest output size possible, as this will be included in the body of a transaction. We also want to have a reproducible build process, so third parties can verify that the uploaded Wasm code did indeed come from the claimed rust code. To solve both these issues, we have produced `rust-optimizer`, a docker image to produce an extremely small build output in a consistent manner. The suggest way to run it is this: ```sh docker run --rm -v "$(pwd)":/code \ --mount type=volume,source="$(basename "$(pwd)")_cache",target=/code/target \ --mount type=volume,source=registry_cache,target=/usr/local/cargo/registry \ cosmwasm/rust-optimizer:0.11.3 ``` We must mount the contract code to `/code`. You can use a absolute path instead of `$(pwd)` if you don't want to `cd` to the directory first. The other two volumes are nice for speedup. Mounting `/code/target` in particular is useful to avoid docker overwriting your local dev files with root permissions. Note the `/code/target` cache is unique for each contract being compiled to limit interference, while the registry cache is global. This is rather slow compared to local compilations, especially the first compile of a given contract. The use of the two volume caches is very useful to speed up following compiles of the same contract. This produces an `artifacts` directory with a `PROJECT_NAME.wasm`, as well as `checksums.txt`, containing the Sha256 hash of the wasm file. The wasm file is compiled deterministically (anyone else running the same docker on the same git commit should get the identical file with the same Sha256 hash). It is also stripped and minimized for upload to a blockchain (we will also gzip it in the uploading process to make it even smaller).