ada6136a6c
tpu-client/tpu_connection_cache is refactored out the module and moved to connection-cache/connection_cache and the logic in client/connection_cache is consolidated to connection-cache/connection_cache as well. client/connection_cache only has a thin wrapper which forward calls to connection-cache/connection_cache and deal with constructions of quic/udp connection cache for clients using them both.2. The TpuConnection is refactored to ClientConnection to make it generic and functions renamed to be proper for other workflows. eg. tpu_addr -> server_addr, send_transaction --> send_data and etc... The enum dispatch is removed so that we can make the bulk of code of quic and udp agnostic of each other. The client is possible to load quic or udp only into its runtime. The generic type parameter in the tpu-client/tpu_connection_cache is removed in order to create both quic and udp connection cache and use the object to send transactions with multiple branching when sending data. The generic type parameters and associated types are dropped in other types in order to make the trait "object safe" for this purpose. I have annotated the code explaining the reasoning and the refactoring source -> destination. There is no functional changes bench-tps has been performed for rpc-client, thin-client and tpu-client. And it is found the performance number largely match the ones before the refactoring. |
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.buildkite | ||
.github | ||
account-decoder | ||
accounts-bench | ||
accounts-cluster-bench | ||
banking-bench | ||
banks-client | ||
banks-interface | ||
banks-server | ||
bench-streamer | ||
bench-tps | ||
bloom | ||
bucket_map | ||
cd | ||
ci | ||
clap-utils | ||
clap-v3-utils | ||
cli | ||
cli-config | ||
cli-output | ||
client | ||
client-test | ||
connection-cache | ||
core | ||
docs | ||
dos | ||
download-utils | ||
entry | ||
explorer | ||
faucet | ||
frozen-abi | ||
genesis | ||
genesis-utils | ||
geyser-plugin-interface | ||
geyser-plugin-manager | ||
gossip | ||
install | ||
keygen | ||
ledger | ||
ledger-tool | ||
local-cluster | ||
log-analyzer | ||
logger | ||
measure | ||
memory-management | ||
merkle-root-bench | ||
merkle-tree | ||
metrics | ||
multinode-demo | ||
net | ||
net-shaper | ||
net-utils | ||
notifier | ||
perf | ||
poh | ||
poh-bench | ||
program-runtime | ||
program-test | ||
programs | ||
pubsub-client | ||
quic-client | ||
rayon-threadlimit | ||
rbpf-cli | ||
remote-wallet | ||
rpc | ||
rpc-client | ||
rpc-client-api | ||
rpc-client-nonce-utils | ||
rpc-test | ||
runtime | ||
scripts | ||
sdk | ||
send-transaction-service | ||
stake-accounts | ||
storage-bigtable | ||
storage-proto | ||
streamer | ||
sys-tuner | ||
system-test | ||
test-validator | ||
thin-client | ||
tokens | ||
tpu-client | ||
transaction-dos | ||
transaction-status | ||
udp-client | ||
upload-perf | ||
validator | ||
version | ||
watchtower | ||
zk-token-sdk | ||
.clippy.toml | ||
.gitignore | ||
.mergify.yml | ||
.travis.yml | ||
CONTRIBUTING.md | ||
Cargo.lock | ||
Cargo.toml | ||
LICENSE | ||
README.md | ||
RELEASE.md | ||
SECURITY.md | ||
cargo | ||
cargo-build-bpf | ||
cargo-build-sbf | ||
cargo-test-bpf | ||
cargo-test-sbf | ||
fetch-perf-libs.sh | ||
fetch-spl.sh | ||
run.sh | ||
rust-toolchain.toml | ||
rustfmt.toml | ||
test-abi.sh | ||
vercel.json |
README.md
Building
1. Install rustc, cargo and rustfmt.
$ curl https://sh.rustup.rs -sSf | sh
$ source $HOME/.cargo/env
$ rustup component add rustfmt
When building the master branch, please make sure you are using the latest stable rust version by running:
$ rustup update
When building a specific release branch, you should check the rust version in ci/rust-version.sh
and if necessary, install that version by running:
$ rustup install VERSION
Note that if this is not the latest rust version on your machine, cargo commands may require an override in order to use the correct version.
On Linux systems you may need to install libssl-dev, pkg-config, zlib1g-dev, protobuf etc.
On Ubuntu:
$ sudo apt-get update
$ sudo apt-get install libssl-dev libudev-dev pkg-config zlib1g-dev llvm clang cmake make libprotobuf-dev protobuf-compiler
On Fedora:
$ sudo dnf install openssl-devel systemd-devel pkg-config zlib-devel llvm clang cmake make protobuf-devel protobuf-compiler perl-core
2. Download the source code.
$ git clone https://github.com/solana-labs/solana.git
$ cd solana
3. Build.
$ ./cargo build
Testing
Run the test suite:
$ ./cargo test
Starting a local testnet
Start your own testnet locally, instructions are in the online docs.
Accessing the remote development cluster
devnet
- stable public cluster for development accessible via devnet.solana.com. Runs 24/7. Learn more about the public clusters
Benchmarking
First, install the nightly build of rustc. cargo bench
requires the use of the
unstable features only available in the nightly build.
$ rustup install nightly
Run the benchmarks:
$ cargo +nightly bench
Release Process
The release process for this project is described here.
Code coverage
To generate code coverage statistics:
$ scripts/coverage.sh
$ open target/cov/lcov-local/index.html
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!
Disclaimer
All claims, content, designs, algorithms, estimates, roadmaps, specifications, and performance measurements described in this project are done with the Solana Labs, Inc. (“SL”) good faith efforts. It is up to the reader to check and validate their accuracy and truthfulness. Furthermore, nothing in this project constitutes a solicitation for investment.
Any content produced by SL or developer resources that SL provides are for educational and inspirational purposes only. SL does not encourage, induce or sanction the deployment, integration or use of any such applications (including the code comprising the Solana blockchain protocol) in violation of applicable laws or regulations and hereby prohibits any such deployment, integration or use. This includes the use of any such applications by the reader (a) in violation of export control or sanctions laws of the United States or any other applicable jurisdiction, (b) if the reader is located in or ordinarily resident in a country or territory subject to comprehensive sanctions administered by the U.S. Office of Foreign Assets Control (OFAC), or (c) if the reader is or is working on behalf of a Specially Designated National (SDN) or a person subject to similar blocking or denied party prohibitions.
The reader should be aware that U.S. export control and sanctions laws prohibit U.S. persons (and other persons that are subject to such laws) from transacting with persons in certain countries and territories or that are on the SDN list. Accordingly, there is a risk to individuals that other persons using any of the code contained in this repo, or a derivation thereof, may be sanctioned persons and that transactions with such persons would be a violation of U.S. export controls and sanctions law.