This crate provides auto-generated unsafe Rust bindings, through bindgen, to C functions provided by uplink-c, the C interface for the Storj uplink API library.
- Install Go
- Install Rust
- Install GCC and make
sudo apt install build-essential - Install libclang (required by bindgen for generating platform specific c bindings)
sudo apt install libclang-dev - Checkout this repo
- Build crate
make build(fromuplink-sysdirectory)
- Install Go
- Install libclang (required by bindgen for generating platform specific c bindings)
- Add uplink-sys to Cargo.toml
NOTE the project has been tested on the following operating systems:
* ubuntu
* Version: 20.04.2 LTS
* Processor: Intel® Core™ i7-10510U CPU @ 1.80GHz × 8
* macOS
* Version: 10.15.7
* Processor: 2.6 GHz 6-Core Intel Corei7
To allow the integrations tests access to the test project, create a file in this directory with the satellite address and api key for running tests.
Do not commit this file to the repo.
test_secrets.txt:
<satellite_addresss>
<api_key>
make test
See the examples directory to see how use the uplink-sys crate.
Below is an example showing how to list buckets using the crate's unsafe C bindings.
// Access parameters
let satellite_address = CString::new("SATELLITE ADDRESS HERE").expect("CString::new failed");
let api_key = CString::new("API KEY HERE").expect("CString::new failed");
let passphrase = CString::new("PASSPHRASE HERE").expect("CString::new failed");
unsafe {
// Request access
let access_result = uplink_sys::uplink_request_access_with_passphrase(
satellite_address.as_ptr() as *mut uplink_sys::uplink_const_char,
api_key.as_ptr() as *mut uplink_sys::uplink_const_char,
passphrase.as_ptr() as *mut uplink_sys::uplink_const_char,
);
if access_result.error != std::ptr::null_mut() {
println!("Error requesting access: {:?}", *(access_result.error));
}
// Access project
let project_result = uplink_sys::uplink_open_project(access_result.access);
if project_result.error != std::ptr::null_mut() {
println!("Error accessing project: {:?}", *(project_result.error));
}
// Create empty string for bucket option struct
let bucket_options_str = CString::new("").expect("CString::new failed");
let mut bucket_options = uplink_sys::UplinkListBucketsOptions {
cursor: bucket_options_str.as_ptr(),
};
// Request bucket iterator
let p_bucket_iterator =
uplink_sys::uplink_list_buckets(project_result.project, &mut bucket_options);
// Check for valid bucket iterator
let p_bucket_iterator_err = uplink_sys::uplink_bucket_iterator_err(p_bucket_iterator);
if p_bucket_iterator_err == std::ptr::null_mut() {
println!("Valid bucket iterator.");
} else {
println!(
"Invalid bucket iterator. Error: {:?}.",
*p_bucket_iterator_err
);
}
// Iterate through all buckets
let mut bucket_count = 0;
while uplink_sys::uplink_bucket_iterator_next(p_bucket_iterator) {
bucket_count += 1;
let p_bucket_result = uplink_sys::uplink_bucket_iterator_item(p_bucket_iterator);
let bucket_name = CStr::from_ptr((*p_bucket_result).name)
.to_str()
.expect("Invalid bucket name C string.");
let created = datetime_string_from_unix_time((*p_bucket_result).created);
println!(
"Bucket {} => name: {}, created: {}",
bucket_count, bucket_name, created
);
// Free memory
uplink_sys::uplink_free_bucket(p_bucket_result);
}
// Free memory
uplink_sys::uplink_free_access_result(access_result);
uplink_sys::uplink_free_project_result(project_result);
uplink_sys::uplink_free_bucket_iterator(p_bucket_iterator);
uplink_sys::uplink_free_error(p_bucket_iterator_err);
}