Qubit Atomic

User-friendly atomic operations wrapper providing JDK-like atomic API for Rust.

Overview

Qubit Atomic is a comprehensive atomic operations library that provides easy-to-use atomic types with reasonable default memory orderings, similar to Java's java.util.concurrent.atomic package. It hides the complexity of memory ordering while maintaining zero-cost abstraction and allowing advanced users to access underlying types for fine-grained control.

Design Goals

Ease of Use: Hides memory ordering complexity with reasonable defaults
Completeness: Provides high-level operations similar to JDK atomic classes
Safety: Guarantees memory safety and thread safety
Performance: Zero-cost abstraction with no additional overhead
Flexibility: Exposes underlying types via inner() for advanced users
Simplicity: Minimal API surface without _with_ordering variants

Features

🔢 Generic Atomic Primitive Types

Integer Specializations: Atomic<i8>, Atomic<u8>, Atomic<i16>, Atomic<u16>, Atomic<i32>, Atomic<u32>, Atomic<i64>, Atomic<u64>, Atomic<i128>, Atomic<u128>, Atomic<isize>, Atomic<usize>
Boolean Specialization: Atomic<bool> with set, clear, negate, logical AND/OR/XOR, and conditional CAS helpers
Floating-Point Specializations: Atomic<f32> and Atomic<f64> with arithmetic operations implemented through CAS loops
Rich Operations: increment, decrement, add, subtract, multiply, divide, bitwise operations, max/min
Functional Updates: fetch_update, fetch_accumulate

🔢 `AtomicCount` and `AtomicSignedCount`

AtomicCount: non-negative count for active tasks, in-flight requests, and resource usage
AtomicSignedCount: signed count for deltas, balances, backlog, and offsets
No-Wrap Semantics: checked updates that panic or return None instead of wrapping
Zero-Transition Logic: inc, dec, add, and sub return the new value

🔗 Atomic Reference Type

AtomicRef: Thread-safe atomic reference using Arc<T>
Reference Updates: Atomic swap and CAS operations
Functional Updates: Transform references atomically

🎯 Focused Public API

Atomic: Generic entry point for primitive atomic values
AtomicRef: Atomic Arc<T> reference wrapper
AtomicCount / AtomicSignedCount: checked state-oriented semantics (no silent wrap)

Installation

Add this to your Cargo.toml:

[dependencies]
qubit-atomic = "0.10.0"

Quick Start

Specifying the value type `T`

Atomic<T> is generic over the primitive value type. Rust usually infers T from the argument to Atomic::new, but literals such as 0 can be ambiguous across integer widths.

In those cases, pick T explicitly using a turbofish on the constructor, or by annotating the variable:

use qubit_atomic::Atomic;

let wide: Atomic<u64> = Atomic::new(0);
assert_eq!(wide.load(), 0u64);

let narrow = Atomic::<i16>::new(0);
assert_eq!(narrow.load(), 0i16);

Example: concurrent `Atomic<i32>`

use qubit_atomic::Atomic;
use std::sync::Arc;
use std::thread;

fn main() {
    let counter = Arc::new(Atomic::<i32>::new(0));
    let mut handles = vec![];

    // Spawn 10 threads, each increments counter 1000 times
    for _ in 0..10 {
        let counter = counter.clone();
        let handle = thread::spawn(move || {
            for _ in 0..1000 {
                counter.fetch_inc();
            }
        });
        handles.push(handle);
    }

    // Wait for all threads to complete
    for handle in handles {
        handle.join().unwrap();
    }

    // Verify result
    assert_eq!(counter.load(), 10000);
    println!("Final count: {}", counter.load());
}

`AtomicCount` and `AtomicSignedCount`

Use Atomic<T> for pure metrics. Use AtomicCount when the count is part of concurrent state, such as active work or termination checks.

use qubit_atomic::{
    AtomicCount,
    AtomicSignedCount,
};

fn main() {
    let active_tasks = AtomicCount::zero();

    active_tasks.inc();
    assert!(!active_tasks.is_zero());

    if active_tasks.dec() == 0 {
        println!("all active tasks are finished");
    }

    let backlog_delta = AtomicSignedCount::zero();
    assert_eq!(backlog_delta.add(5), 5);
    assert_eq!(backlog_delta.sub(8), -3);
    assert!(backlog_delta.is_negative());
}

CAS Loop

use qubit_atomic::Atomic;

fn increment_even_only(atomic: &Atomic<i32>) -> Result<i32, &'static str> {
    let mut current = atomic.load();
    loop {
        // Only increment even values
        if current % 2 != 0 {
            return Err("Value is odd");
        }

        let new = current + 2;
        match atomic.compare_set(current, new) {
            Ok(_) => return Ok(new),
            Err(actual) => current = actual, // Retry
        }
    }
}

fn main() {
    let atomic = Atomic::<i32>::new(10);
    match increment_even_only(&atomic) {
        Ok(new_value) => println!("Successfully incremented to: {}", new_value),
        Err(e) => println!("Failed: {}", e),
    }
    assert_eq!(atomic.load(), 12);
}

Functional Updates

use qubit_atomic::Atomic;

fn main() {
    let atomic = Atomic::<i32>::new(10);

    // Update using a function (returns old value)
    let old_value = atomic.fetch_update(|x| {
        if x < 100 {
            x * 2
        } else {
            x
        }
    });

    assert_eq!(old_value, 10);
    assert_eq!(atomic.load(), 20);
    println!("Updated value: {}", atomic.load());

    // Accumulate operation (returns old value)
    let old_result = atomic.fetch_accumulate(5, |a, b| a + b);
    assert_eq!(old_result, 20);
    assert_eq!(atomic.load(), 25);
    println!("Accumulated value: {}", atomic.load());
}

Atomic Reference

use qubit_atomic::AtomicRef;
use std::sync::Arc;

#[derive(Debug, Clone)]
struct Config {
    timeout: u64,
    max_retries: u32,
}

fn main() {
    let config = Arc::new(Config {
        timeout: 1000,
        max_retries: 3,
    });

    let atomic_config = AtomicRef::new(config);

    // Update configuration
    let new_config = Arc::new(Config {
        timeout: 2000,
        max_retries: 5,
    });

    let old_config = atomic_config.swap(new_config);
    println!("Old config: {:?}", old_config);
    println!("New config: {:?}", atomic_config.load());

    // Update using a function (returns old value)
    let old = atomic_config.fetch_update(|current| {
        Arc::new(Config {
            timeout: current.timeout * 2,
            max_retries: current.max_retries + 1,
        })
    });

    println!("Previous config: {:?}", old);
    println!("Updated config: {:?}", atomic_config.load());
}

Boolean Flag

use qubit_atomic::Atomic;
use std::sync::Arc;

struct Service {
    running: Arc<Atomic<bool>>,
}

impl Service {
    fn new() -> Self {
        Self {
            running: Arc::new(Atomic::<bool>::new(false)),
        }
    }

    fn start(&self) {
        // Only start if not already running
        if self.running.set_if_false(true).is_ok() {
            println!("Service started successfully");
        } else {
            println!("Service is already running");
        }
    }

    fn stop(&self) {
        // Only stop if currently running
        if self.running.set_if_true(false).is_ok() {
            println!("Service stopped successfully");
        } else {
            println!("Service is already stopped");
        }
    }

    fn is_running(&self) -> bool {
        self.running.load()
    }
}

fn main() {
    let service = Service::new();

    service.start();
    assert!(service.is_running());

    service.start(); // Duplicate start will fail

    service.stop();
    assert!(!service.is_running());

    service.stop(); // Duplicate stop will fail
}

Floating-Point Atomics

use qubit_atomic::Atomic;
use std::sync::Arc;
use std::thread;

fn main() {
    let sum = Arc::new(Atomic::<f32>::new(0.0));
    let mut handles = vec![];

    // Spawn 10 threads, each adds 100 times
    for _ in 0..10 {
        let sum = sum.clone();
        let handle = thread::spawn(move || {
            for _ in 0..100 {
                sum.fetch_add(0.01);
            }
        });
        handles.push(handle);
    }

    for handle in handles {
        handle.join().unwrap();
    }

    // Note: Due to floating-point precision, result may not be exactly 10.0
    let result = sum.load();
    println!("Sum: {:.6}", result);
    println!("Error: {:.6}", (result - 10.0).abs());
}

API Reference

Common Operations (All Types)

Method	Description	Memory Ordering
`new(value)`	Create new atomic	-
`load()`	Load current value	Acquire
`store(value)`	Store new value	Release
`swap(value)`	Swap value, return old	AcqRel
`compare_set(current, new)`	CAS operation, return Result	AcqRel/Acquire
`compare_set_weak(current, new)`	Weak CAS, return Result	AcqRel/Acquire
`compare_and_exchange(current, new)`	CAS operation, return actual value	AcqRel/Acquire
`compare_and_exchange_weak(current, new)`	Weak CAS, return actual value	AcqRel/Acquire
`fetch_update(f)`	Functional update, return old	AcqRel/Acquire
`inner()`	Access underlying backend type	-

Integer Operations

Method	Description	Memory Ordering
`fetch_inc()`	Post-increment, return old	Relaxed
`fetch_dec()`	Post-decrement, return old	Relaxed
`fetch_add(delta)`	Post-add, return old	Relaxed
`fetch_sub(delta)`	Post-subtract, return old	Relaxed
`fetch_mul(factor)`	Post-multiply, return old	AcqRel (CAS loop)
`fetch_div(divisor)`	Post-divide, return old	AcqRel (CAS loop)
`fetch_and(value)`	Bitwise AND, return old	AcqRel
`fetch_or(value)`	Bitwise OR, return old	AcqRel
`fetch_xor(value)`	Bitwise XOR, return old	AcqRel
`fetch_not()`	Bitwise NOT, return old	AcqRel
`fetch_max(value)`	Atomic max, return old	AcqRel
`fetch_min(value)`	Atomic min, return old	AcqRel
`fetch_update(f)`	Functional update, return old	AcqRel/Acquire
`fetch_accumulate(x, f)`	Accumulate, return old	AcqRel/Acquire

`AtomicCount` / `AtomicSignedCount` operations

Method	`AtomicCount`	`AtomicSignedCount`	Description
`new(value)`	`usize`	`isize`	Create a count
`zero()`	Yes	Yes	Create a zero value
`get()`	`usize`	`isize`	Read the current value
`is_zero()`	Yes	Yes	Check whether the value is zero
`is_positive()`	Yes	Yes	Check whether the value is positive
`is_negative()`	No	Yes	Check whether the value is negative
`inc()`	Yes	Yes	Increment by one, return new value
`dec()`	Panic on underflow	Allows negative values	Decrement by one, return new value
`add(delta)`	Panic on overflow	Panic on overflow	Add delta, return new value
`sub(delta)`	Panic on underflow	Panic on overflow	Subtract delta, return new value
`try_add(delta)`	`None` on overflow	`None` on overflow	Checked add
`try_dec()`	`None` at zero	No	Checked decrement
`try_sub(delta)`	`None` on underflow	`None` on overflow	Checked subtract

Boolean Operations

Method	Description	Memory Ordering
`fetch_set()`	Set to true, return old	AcqRel
`fetch_clear()`	Set to false, return old	AcqRel
`fetch_not()`	Negate, return old	AcqRel
`fetch_and(value)`	Logical AND, return old	AcqRel
`fetch_or(value)`	Logical OR, return old	AcqRel
`fetch_xor(value)`	Logical XOR, return old	AcqRel
`set_if_false(new)`	CAS if false	AcqRel/Acquire
`set_if_true(new)`	CAS if true	AcqRel/Acquire

Floating-Point Operations

Method	Description	Memory Ordering
`fetch_add(delta)`	Atomic add, return old	AcqRel (CAS loop)
`fetch_sub(delta)`	Atomic subtract, return old	AcqRel (CAS loop)
`fetch_mul(factor)`	Atomic multiply, return old	AcqRel (CAS loop)
`fetch_div(divisor)`	Atomic divide, return old	AcqRel (CAS loop)
`fetch_update(f)`	Functional update, return old	AcqRel/Acquire

Memory Ordering Strategy

Operation Type	Default Ordering	Reason
Pure Read (`load()`)	`Acquire`	Ensure reading latest value
Pure Write (`store()`)	`Release`	Ensure write visibility
Read-Modify-Write (`swap()`, CAS)	`AcqRel`	Ensure both read and write correctness
`Atomic<T>` integer ops (`fetch_inc()`, `fetch_add()`)	`Relaxed`	Pure metrics; no need to sync other data
`AtomicCount` / `AtomicSignedCount` (`inc()`, `dec()`)	CAS loop	Values used as concurrent state signals
Bitwise Operations (`fetch_and()`, `fetch_or()`)	`AcqRel`	Usually used for flag synchronization
Max/Min Operations (`fetch_max()`, `fetch_min()`)	`AcqRel`	Often used with threshold checks
Functional Updates (`fetch_update()`)	`AcqRel` / `Acquire`	CAS loop standard semantics

Advanced Usage: Direct Access to Underlying Types

For scenarios requiring fine-grained memory ordering control (approximately 1% of use cases), use inner() to access the underlying backend type:

use std::sync::atomic::Ordering;
use qubit_atomic::Atomic;

let atomic = Atomic::<i32>::new(0);

// 99% of scenarios: use simple API
let value = atomic.load();

// 1% of scenarios: need fine-grained control
let value = atomic.inner().load(Ordering::Relaxed);
atomic.inner().store(42, Ordering::Release);

Comparison with JDK

Feature	JDK	Qubit Atomic	Notes
Basic Types	3 types	`Atomic<T>` specializations	Rust supports more integer, floating-point, boolean, and counter use cases
Memory Ordering	Implicit (volatile)	Default + `inner()` optional	Rust more flexible
Weak CAS	`weakCompareAndSet`	`compare_set_weak`	Equivalent
Reference Type	`AtomicReference<V>`	`AtomicRef<T>`	Rust uses `Arc<T>`
`AtomicCount` / `AtomicSignedCount`	Manual composition	`AtomicCount`, `AtomicSignedCount`	Non-negative / signed counts for state tracking
Nullability	Allows `null`	Use `Option<Arc<T>>`	Rust no null pointers
Bitwise Operations	Partial support	Full support	Rust more powerful
Max/Min Operations	Java 9+ support	Supported	Equivalent
API Count	~20 methods/type	~25 methods/type	Rust provides more convenience methods

Performance Considerations

Zero-Cost Abstraction

Primitive wrappers use #[repr(transparent)] and #[inline] so the generic API compiles down to the backend atomic operations:

// Our wrapper
let atomic = Atomic::<i32>::new(0);
let value = atomic.load();

// Compiles to the same code as
let atomic = std::sync::atomic::AtomicI32::new(0);
let value = atomic.load(Ordering::Acquire);

When to Use `inner()`

99% of scenarios: Use default API, which already provides optimal performance.

1% of scenarios: Use inner() only when:

Extreme performance optimization (need Relaxed ordering)
Complex lock-free algorithms (need precise memory ordering control)
Interoperating with code that directly uses standard library or portable-atomic backend types

Golden Rule: Default API first, inner() as last resort.

Testing & Code Coverage

This project maintains comprehensive test coverage with detailed validation of all functionality.

Running Tests

# Run all tests
cargo test

# Run with coverage report
./coverage.sh

# Generate text format report
./coverage.sh text

# Run CI checks (format, clippy, test, coverage)
./ci-check.sh

Coverage Metrics

See COVERAGE.md for detailed coverage statistics.

Dependencies

Runtime dependencies are intentionally small:

arc-swap powers AtomicRef<T>.
portable-atomic provides the stable backend for Atomic<i128> and Atomic<u128>.

License

Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at

http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

See LICENSE for the full license text.

Contributing

Contributions are welcome! Please feel free to submit a Pull Request.

Development Guidelines

Follow the Rust API guidelines
Maintain comprehensive test coverage
Document all public APIs with examples
Ensure all tests pass before submitting PR

Author

Haixing Hu - Qubit Co. Ltd.

Related Projects

More Rust libraries from Qubit are published under the qubit-ltd organization on GitHub.

Repository: https://github.com/qubit-ltd/rs-atomic

qubit-atomic 0.10.0