zslayton / Lifeguard
Programming Languages
lifeguard 
Object Pool Manager
Examples
Pool issues owned values wrapped in smartpointers.
extern crate lifeguard;
use lifeguard::*;
fn main() {
let pool : Pool<String> = pool().with(StartingSize(10)).build();
{
let string = pool.new_from("Hello, World!"); // Remove a value from the pool
assert_eq!(9, pool.size());
} // Values that have gone out of scope are automatically moved back into the pool.
assert_eq!(10, pool.size());
}
Values taken from the pool can be dereferenced to access/mutate their contents.
extern crate lifeguard;
use lifeguard::*;
fn main() {
let pool : Pool<String> = pool().with(StartingSize(10)).build();
let mut string = pool.new_from("cat");
string.push_str("s love eating mice"); //string.as_mut() also works
assert_eq!("cats love eating mice", *string);
}
Values can be unwrapped, detaching them from the pool.
extern crate lifeguard;
use lifeguard::*;
fn main() {
let pool : Pool<String> = pool().with(StartingSize(10)).build();
{
let string : String = pool.new().detach();
} // The String goes out of scope and is dropped; it is not returned to the pool
assert_eq!(9, pool.size());
}
Values can be manually entered into / returned to the pool.
extern crate lifeguard;
use lifeguard::*;
fn main() {
let pool : Pool<String> = pool().with(StartingSize(10)).build();
{
let string : String = pool.detached(); // An unwrapped String, detached from the Pool
assert_eq!(9, pool.size());
let rstring : Recycled<String> = pool.attach(string); // The String is attached to the pool again
assert_eq!(9, pool.size()); // but it is still checked out from the pool
} // rstring goes out of scope and is added back to the pool
assert_eq!(10, pool.size());
}
Pool's builder API can be used to customize the behavior of the pool.
extern crate lifeguard;
use lifeguard::*;
fn main() {
let pool : Pool<String> = pool()
// The pool will allocate 128 values for immediate use. More will be allocated on demand.
.with(StartingSize(128))
// The pool will only grow up to 4096 values. Further values will be dropped.
.with(MaxSize(4096))
// The pool will use this closure (or other object implementing Supply<T>) to allocate
.with(Supplier(|| String::with_capacity(1024)))
.build();
// ...
}
Highly Unscientific Benchmarks
Benchmark source can be found here. Tests were run on an early 2015 MacBook Pro.
Each benchmark comes in three flavors:
-
tests::*_standard: Uses the system allocator to create new values. -
tests::*_pooled_rc: Uses aPoolto create new values which holdRcreferences to thePool. These values can be freely passed to other scopes. -
tests::*_pooled: Uses aPoolto create new values which hold&locally-scoped references to thePool. These values are the cheapest to create but are bound to the lifetime of thePool.
Uninitialized Allocation
Compares the cost of allocating a new String (using String::with_capacity, as String::new does not allocate immediately) with the cost of retrieving a String from the pool.
tests::allocation_standard ... bench: 5,322,513 ns/iter (+/- 985,898)
tests::allocation_pooled_rc ... bench: 784,885 ns/iter (+/- 95,245)
tests::allocation_pooled ... bench: 565,864 ns/iter (+/- 66,036)
Initialized Allocation
Compares the cost of allocating a new String and initializing it to a given value (via &str::to_owned) with the cost of retrieving a String from the pool and initializing it to the same value.
tests::initialized_allocation_standard ... bench: 5,329,948 ns/iter (+/- 547,725)
tests::initialized_allocation_pooled_rc ... bench: 1,151,493 ns/iter (+/- 119,293)
tests::initialized_allocation_pooled ... bench: 927,214 ns/iter (+/- 147,935)
Vec<Vec<String>> Allocation
Creates a two-dimensional vector of initialized Strings. All Vecs and Strings created are from a Pool where applicable. Adapted from this benchmark.
tests::vec_vec_str_standard ... bench: 1,353,906 ns/iter (+/- 142,094)
tests::vec_vec_str_pooled_rc ... bench: 298,087 ns/iter (+/- 168,703)
tests::vec_vec_str_pooled ... bench: 251,082 ns/iter (+/- 24,408)
Ideas and PRs welcome!
Inspired by frankmcsherry's recycler.