All claims, content, designs, algorithms, estimates, roadmaps, specifications, and performance measurements described in this project are done with the author's best effort. It is up to the reader to check and validate their accuracy and truthfulness. Furthermore nothing in this project constitutes a solicitation for investment.
Solana™ is a new architecture for a high performance blockchain. It aims to support over 700 thousand transactions per second on a gigabit network.
First, install Rust's package manager Cargo.
$ curl https://sh.rustup.rs -sSf | sh
$ source $HOME/.cargo/env
The testnode server is initialized with a ledger from stdin and generates new ledger entries on stdout. To create the input ledger, we'll need to create the mint and use it to generate a genesis ledger. It's done in two steps because the mint.json file contains a private key that will be used later in this demo.
$ echo 1000000000 | cargo run --release --bin solana-mint | tee mint.json
$ cat mint.json | cargo run --release --bin solana-genesis | tee genesis.log
Now you can start the server:
$ cat genesis.log | cargo run --release --bin solana-testnode | tee transactions0.log
Then, in a separate shell, let's execute some transactions. Note we pass in the JSON configuration file here, not the genesis ledger.
$ cat mint.json | cargo run --release --bin solana-client-demo
Now kill the server with Ctrl-C, and take a look at the ledger. You should see something similar to:
{"num_hashes":27,"id":[0, "..."],"event":"Tick"}
{"num_hashes":3,"id":[67, "..."],"event":{"Transaction":{"tokens":42}}}
{"num_hashes":27,"id":[0, "..."],"event":"Tick"}
Now restart the server from where we left off. Pass it both the genesis ledger, and the transaction ledger.
$ cat genesis.log transactions0.log | cargo run --release --bin solana-testnode | tee transactions1.log
Lastly, run the client demo again, and verify that all funds were spent in the previous round, and so no additional transactions are added.
$ cat mint.json | cargo run --release --bin solana-client-demo
Stop the server again, and verify there are only Tick entries, and no Transaction entries.
Install rustc, cargo and rustfmt:
$ curl https://sh.rustup.rs -sSf | sh
$ source $HOME/.cargo/env
$ rustup component add rustfmt-preview
Download the source code:
$ git clone https://github.com/solana-labs/solana.git
$ cd solana
Run the test suite:
cargo test
First install the nightly build of rustc. cargo bench
requires unstable features:
$ rustup install nightly
Run the benchmarks:
$ cargo +nightly bench --features="unstable"
To generate code coverage statistics, run kcov via Docker:
$ docker run -it --rm --security-opt seccomp=unconfined --volume "$PWD:/volume" elmtai/docker-rust-kcov
Why coverage? While most see coverage as a code quality metric, we see it primarily as a developer productivity metric. When a developer makes a change to the codebase, presumably it's a solution to some problem. Our unit-test suite is how we encode the set of problems the codebase solves. Running the test suite should indicate that your change didn't infringe on anyone else's solutions. Adding a test protects your solution from future changes. Say you don't understand why a line of code exists, try deleting it and running the unit-tests. The nearest test failure should tell you what problem was solved by that code. If no test fails, go ahead and submit a Pull Request that asks, "what problem is solved by this code?" On the other hand, if a test does fail and you can think of a better way to solve the same problem, a Pull Request with your solution would most certainly be welcome! Likewise, if rewriting a test can better communicate what code it's protecting, please send us that patch!