Expand description
Parallel file I/O
This crate provides a simple interface to read and write from/to files in parallel. Data consumption is decoupled from data production by having separate groups of producer and consumer threads.
Files are read and written through synchronous pread and pwrite function calls.
The same buffers are reused for both production and consumption and consumed buffers are sent back to the producer, thus the total amount of memory used is equal to the number of producers times the number of buffers per producer.
When reading, the client callback function acts as the consumer and when writing it acts as the producer.
Reading
Producer threads read data chunks from the file and send them to the consumer threads which pass the data to a client callback function.
Client code can use the read_file function to read the file specifying a callback
function that will be called for each chunk read from the file.
The signature of the callback object passed to read_file is:
type Consumer<T, R> =
dyn Fn(&[u8], // data read from file
&T, // client data
u64, // chunk id
u64, // number of chunks
u64 // file offset (where data is read from)
) -> R;Example
...
let consume = |buffer: &[u8], // <- client callback
data: &Data, // <- generic parameter
chunk_id: u64,
num_chunks: u64,
_offset: u64|
-> Result<usize, String> {
std::thread::sleep(std::time::Duration::from_secs(1));
println!(
"Consumer: {}/{} {} {}",
chunk_id,
num_chunks,
data.msg,
buffer.len()
);
Ok(buffer.len())
};
let tag = "TAG".to_string();
match read_file(
&filename,
num_producers,
num_consumers,
chunks_per_producer,
std::sync::Arc::new(consume),
tag,
num_buffers_per_producer,
) {
Ok(v) => {
let bytes_consumed = v
.iter()
.fold(0, |acc, x| if let (_, Ok(b)) = x { acc + b } else { acc });
assert_eq!(bytes_consumed, len as usize);
}
Err(err) => {
use par_io::read::ReadError;
match err {
ReadError::IO(err) => {
eprintln!("IO error: {:?}", err);
},
ReadError::Send(err) => {
eprintln!("Send error: {:?}", err);
},
ReadError::Other(err) => {
eprintln!("Error: {:?}", err);
}
}
}
}Writing
Producer threads invoke a client callback to generate data which is then sent to consumer threads which write data to file.
The signature of the callback object passed to the write_to_file function is:
type Producer<T> = dyn Fn(&mut Vec<u8>, // <- buffer to write to
&T, // <- client data
u64 // <- file offset (where data is written)
) -> Result<(), String>;Example
...
let producer = |buffer: &mut Vec<u8>, // <- client callback
_tag: &String, // <- generic parameter
_offset: u64| -> Result<(), String> {
std::thread::sleep(std::time::Duration::from_secs(1));
*buffer = vec![1_u8; buffer.len()];
Ok(())
};
let data = "TAG".to_string();
match write_to_file(
&filename,
num_producers,
num_consumers,
chunks_per_producer,
std::sync::Arc::new(producer),
data,
num_buffers_per_producer,
buffer_size,
) {
Ok(bytes_consumed) => {
let len = std::fs::metadata(&filename)
.expect("Cannot access file")
.len();
assert_eq!(bytes_consumed, len as usize);
std::fs::remove_file(&filename).expect("Cannot delete file");
},
Err(err) => {
use par_io::write::{WriteError, ProducerError, ConsumerError};
match err {
WriteError::Producer(ProducerError{msg, offset}) => {
eprintln!("Producer error: {} at {}", msg, offset);
},
WriteError::IO(err) => {
eprintln!("I/O error: {:?}", err);
},
WriteError::Other(err) => {
eprintln!("Error: {:?}", err);
},
}
}
}Modules
- Parallel async file read.
- Parallel async file write.