*map.entry(k).or_insert(0) += 1 is the classic Rust counter. The moment the “first time” branch needs to look different from the “next time” branch, that pattern stops fitting — and and_modify slots in.

HashMap::entry(k) returns an Entry enum pointing at the slot for k, occupied or vacant. The famous methods are or_insert(default) and or_insert_with(|| ...). Quieter but often nicer is and_modify: it runs a closure on the value when the key is already there, and does nothing when it isn’t. Chain it with or_insert and you get update if present, insert if not in one expression — with a single lookup.

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use std::collections::HashMap;

let mut counts: HashMap<&str, u32> = HashMap::new();

for word in ["rust", "iron", "rust", "rust", "iron"] {
    counts
        .entry(word)
        .and_modify(|n| *n += 1)
        .or_insert(1);
}

assert_eq!(counts["rust"], 3);
assert_eq!(counts["iron"], 2);

For pure counters that’s a tie with *entry.or_insert(0) += 1. The shape really pays off when the two branches store different data. Imagine grouping events by user, where the first event records the user’s name and later events only bump a counter:

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use std::collections::HashMap;

#[derive(Debug, PartialEq)]
struct UserStats { name: String, visits: u32 }

let events = [(1u32, "alice"), (2, "bob"), (1, "alice")];
let mut stats: HashMap<u32, UserStats> = HashMap::new();

for (id, name) in events {
    stats
        .entry(id)
        .and_modify(|s| s.visits += 1)
        .or_insert(UserStats { name: name.into(), visits: 1 });
}

assert_eq!(stats[&1], UserStats { name: "alice".into(), visits: 2 });
assert_eq!(stats[&2], UserStats { name: "bob".into(),   visits: 1 });

and_modify takes &mut V so you mutate in place; or_insert produces the initial V. and_modify also returns the Entry back, which is why the chain works — and which means you can stack several modifications before the final or_insert.

You write a generic struct, never actually store a T in any field, and the compiler stops you with “parameter T is never used”. PhantomData<T> is the zero-cost lie that fixes it — a marker that occupies no bytes but tells the compiler “act as if I own a T.”

The problem shows up the moment you build a typed handle around something that isn’t a T:

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// Won't compile: T isn't actually stored anywhere.
struct TypedId<T> {
    raw: u64,
}

rustc rejects this because an unused type parameter is almost always a bug — variance, drop checking, and Send/Sync all depend on what a struct claims to own. std::marker::PhantomData<T> is the escape hatch: a zero-sized struct that pretends the type parameter is used:

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use std::marker::PhantomData;

struct TypedId<T> {
    raw: u64,
    _marker: PhantomData<T>,
}

impl<T> TypedId<T> {
    fn new(raw: u64) -> Self {
        Self { raw, _marker: PhantomData }
    }
}

struct User;
struct Order;

let u: TypedId<User>  = TypedId::new(1);
let o: TypedId<Order> = TypedId::new(1);

// Same raw value, different types — the compiler refuses to mix them.
// let _: TypedId<User> = o; // error: expected TypedId<User>, found TypedId<Order>

assert_eq!(std::mem::size_of::<TypedId<User>>(), 8); // still just the u64

The _marker field disappears at runtime — size_of::<TypedId<User>>() is exactly size_of::<u64>(). But at compile time, TypedId<User> and TypedId<Order> are distinct types you can’t accidentally swap.

The same pattern fixes lifetimes too. FFI wrappers borrow from a buffer they don’t physically point into:

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use std::marker::PhantomData;

struct CursorHandle<'a> {
    raw_ptr: *const u8,
    _borrow: PhantomData<&'a [u8]>,
}

impl<'a> CursorHandle<'a> {
    fn new(buf: &'a [u8]) -> Self {
        Self { raw_ptr: buf.as_ptr(), _borrow: PhantomData }
    }
}

let buf = vec![1u8, 2, 3];
let cursor = CursorHandle::new(&buf);
// drop(buf); // compile error — cursor still borrows it, thanks to PhantomData
let _ = cursor;

Without the PhantomData<&'a [u8]>, the 'a would be unused and the compiler wouldn’t enforce that buf outlives cursor. With it, the borrow checker treats CursorHandle<'a> as if it held a real &'a [u8].

Three flavors of PhantomData you’ll see in the wild — pick by what you want the compiler to believe:

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use std::marker::PhantomData;

// 1. Owns a T (covariant, drops a T): PhantomData<T>
struct Owns<T>(PhantomData<T>);

// 2. Borrows a T (no drop): PhantomData<&'a T>
struct Borrows<'a, T>(PhantomData<&'a T>);

// 3. Neither Send nor Sync: PhantomData<*const ()>
struct NotThreadSafe(PhantomData<*const ()>);

fn assert_send<T: Send>() {}
// assert_send::<NotThreadSafe>(); // would fail — raw ptr makes it !Send

assert_eq!(std::mem::size_of::<Owns<u64>>(), 0);
assert_eq!(std::mem::size_of::<Borrows<'_, u64>>(), 0);
assert_eq!(std::mem::size_of::<NotThreadSafe>(), 0);

That last one is the cheap way to opt a type out of Send/Sync without unsafe — Rc<T> uses exactly this trick internally to stay single-threaded.

PhantomData is the bookkeeping behind almost every wrapper type you’ve used. Cell, Cow, Pin, Rc, and NonNull all carry one — it’s how they tell the compiler what they conceptually own without paying for it at runtime.

The moment you hand-roll Future::poll, you have a Pin<&mut Self> and a question Rust won’t answer for you: how do I touch my fields? self.inner doesn’t compile, &mut self.inner is what Pin exists to prevent, and the answer — pin projection — is one of those idioms everyone reinvents until they reach for pin-project-lite.

bite-162 covered what Pin<P> is and why async futures need it. This one is about the very next thing you trip over: actually polling the inner future from your own poll method.

The problem

A wrapper that polls an inner future and counts how many times it was polled:

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struct Logged<F> {
    inner: F,
    polls: u32,
}

impl<F: Future> Future for Logged<F> {
    type Output = F::Output;
    fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
        self.inner.poll(cx) // ERROR: can't borrow through Pin<&mut Self>
    }
}

Pin<&mut Self> deliberately won’t deref-mut into &mut Self — that would hand back the exact &mut you need to mem::swap the whole struct out from under whatever pinned it. So self.inner is a non-starter. You have to project: turn a Pin<&mut Self> into a Pin<&mut F> pointing at the inner field.

Manual projection with unsafe

The raw tools are Pin::get_unchecked_mut and Pin::new_unchecked. You take &mut Self out of the pin (unsafe — you’re promising not to move the whole value), borrow disjoint fields, then re-pin the ones that need it.

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use std::future::Future;
use std::pin::Pin;
use std::task::{Context, Poll};

struct Logged<F> {
    inner: F,
    polls: u32,
}

impl<F: Future> Future for Logged<F> {
    type Output = F::Output;
    fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
        // SAFETY: we promise not to move `self`. `inner` is treated as
        // structurally pinned; `polls` is treated as freely movable.
        let this = unsafe { self.get_unchecked_mut() };
        this.polls += 1;
        let inner = unsafe { Pin::new_unchecked(&mut this.inner) };
        inner.poll(cx)
    }
}

Two unsafe blocks and an invariant you have to remember everywhere else in the file: if some other method ever does mem::replace(&mut this.inner, _), you’ve broken the pin contract and quietly created UB. The compiler will not catch it.

The clean answer: pin-project-lite

pin-project-lite mechanically derives the safe projection. Mark each structurally-pinned field with #[pin]:

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use std::future::Future;
use std::pin::Pin;
use std::task::{Context, Poll};
use pin_project_lite::pin_project;

pin_project! {
    struct Logged<F> {
        #[pin]
        inner: F,
        polls: u32,
    }
}

impl<F: Future> Future for Logged<F> {
    type Output = F::Output;
    fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
        let this = self.project();
        *this.polls += 1;
        this.inner.poll(cx)
    }
}

self.project() returns a generated struct where every #[pin] field is a Pin<&mut Field> and every other field is a plain &mut Field. No unsafe, no projection mistakes, no chance of accidentally mem::replace-ing a pinned field — the macro generates the accessors so the wrong move never compiles. This is the pattern tokio, hyper, futures, and effectively every library implementing custom futures lives on.

Structural vs non-structural — the choice you’re making

Marking a field #[pin] locks in three guarantees:

• You will never move out of it once Self is pinned (no mem::replace, no mem::swap).
• Its Drop impl runs while the field is still pinned.
• Accessors hand you Pin<&mut Field>, not &mut Field.

Unmarked fields go the other way: you treat them as freely movable. Pick wrong — pin one structurally and then mem::swap it elsewhere — and you’ve quietly invalidated whatever pointers something else handed out into that field.

Rule of thumb: if a field is itself a future, or any !Unpin type that needs to be polled in place, mark it #[pin]. Counters, flags, owned Strings — leave them unmarked.

Self-referential structs are the obvious “this should work but doesn’t” pattern in Rust: a struct that holds a buffer plus a reference into that buffer falls apart the moment it moves and the reference dangles. Pin<P> is the type that says “the pointee is fixed in memory” — and is the reason every async fn future you’ve ever .awaited can keep a pointer to its own local variables.

Why Pin exists at all

Take a String and a slice into it:

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struct Mess<'a> {
    buf: String,
    view: &'a str,   // borrows from buf
}

You can’t actually build this — Rust won’t let you write a struct that borrows from one of its own fields, because the move that follows construction would invalidate the borrow. Any helper that produces a Mess and returns it by value moves buf into the caller’s stack frame; view would still point at the old location. Disaster.

async fn bodies generate exactly this kind of struct under the hood: an enum of “states,” each carrying the locals live across an .await. If one of those locals is a reference to another local, the future is self-referential. Move it after polling and you’ve hit UB.

What Pin actually does

Pin<P> wraps a pointer — Box<T>, &mut T, Rc<T>, etc. — and downgrades its API. Specifically: you can no longer reach the inner &mut T unless T: Unpin.

Without &mut T, you can’t std::mem::swap or mem::replace to move the value out. That’s the whole guarantee: the value behind a Pin<P> will never move again, except by running its destructor.

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use std::pin::Pin;

let mut boxed: Pin<Box<i32>> = Box::pin(42);
// i32: Unpin, so we can still write through the pin.
*boxed = 99;
assert_eq!(*boxed, 99);

For i32 the pinning is theatre — primitives implement Unpin, the marker that says “moving me is fine.” Pin only bites when the inner type is !Unpin.

Where it bites: polling a future

Future::poll takes self: Pin<&mut Self>. The compiler-generated futures from async {} are !Unpin, so you can’t poll them through a plain &mut. You have to pin first.

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use std::future::Future;
use std::pin::Pin;
use std::task::{Context, Poll, Waker};

let fut = async { 7 * 6 };
let mut boxed: Pin<Box<_>> = Box::pin(fut);

let mut cx = Context::from_waker(Waker::noop());

match boxed.as_mut().poll(&mut cx) {
    Poll::Ready(v) => assert_eq!(v, 42),
    Poll::Pending => unreachable!(),
}

Box::pin is the easy answer when you need an owned, heap-allocated, pinned future. The allocation is what makes the address stable — Box already promised that.

Stack pinning with pin!

Heap allocation just to poll a future feels heavy, and it is. The pin! macro pins a value on the stack instead: it shadows the binding so you can never get a non-pinned reference to it again.

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use std::future::Future;
use std::pin::pin;
use std::task::{Context, Poll, Waker};

let mut fut = pin!(async { String::from("ready") });

let mut cx = Context::from_waker(Waker::noop());

if let Poll::Ready(s) = fut.as_mut().poll(&mut cx) {
    assert_eq!(s, "ready");
}

The trick is that pin! re-binds fut to a Pin<&mut _> that borrows from a hidden, scope-local slot. The original value lives until the end of the block; nothing can sneak in and move it. Stable since Rust 1.68.

Unpin: the escape hatch for ordinary types

Unpin is an auto trait: almost everything implements it automatically. String, Vec<T>, your own struct of plain fields — all Unpin. For those, Pin<&mut T> and &mut T are interchangeable via Pin::new and Pin::into_inner:

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use std::pin::Pin;

let mut s = String::from("hi");
let pinned: Pin<&mut String> = Pin::new(&mut s);
// String: Unpin, so we get back a normal &mut String.
// `into_inner` is an associated function, not a method — avoids
// shadowing whatever `into_inner` the underlying type might have.
Pin::into_inner(pinned).push_str(", world");
assert_eq!(s, "hi, world");

This is why most of the time you can pretend Pin doesn’t exist. It only shows teeth when something is deliberately !Unpin — async-generated futures, intrusive linked-list nodes, and any self-referential struct you opt into with PhantomPinned.

When you’ll see it yourself

In day-to-day code you almost never write Pin<P> directly — the pin! macro and Box::pin cover polling, and tokio::pin! or tokio::spawn cover the async runtime case. You’ll meet Pin<&mut Self> in earnest when you:

• Hand-roll a Future. poll takes Pin<&mut Self>, so any state machine you implement by hand has to thread it through.
• Write a self-referential struct. Stick a PhantomPinned field in, and from then on the only way to use the type is through a Pin.
• Build a custom executor. Pinning the futures the executor stores is exactly the invariant the Future trait is asking you for.

The mental model that sticks: Pin<P> doesn’t pin the pointer — it pins what the pointer points at. The pointer can move, be copied, be passed around; the value under it has promised to stay where it was first pinned, all the way until Drop. That’s the contract the async machinery is built on, and the reason it’s safe to keep an .await point inside a function call hundreds of frames deep.

Cow<str> is the type everyone reaches for when a function might need to modify its input. Cow::Borrowed and Cow::Owned are the constructors that get the spotlight; to_mut is the third piece, and it’s the one that actually pays off the laziness.

What to_mut does

to_mut takes &mut Cow<str> and hands back &mut String:

• If the Cow is already Owned, you get a direct &mut to the inner String.
• If it’s Borrowed, to_mut clones the slice into a fresh String, swaps the Cow over to Owned, and then hands you the mutable reference.

That asymmetry is the whole point. Many callers borrow and never touch to_mut — they never allocate. The ones that do call it pay the allocation cost exactly once, on first write.

A walking-the-string example

Expand \t into two spaces, but only allocate if the input actually contains a tab:

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use std::borrow::Cow;

fn expand_tabs(s: &str) -> Cow<'_, str> {
    let mut out: Cow<'_, str> = Cow::Borrowed(s);
    if let Some(i) = s.find('\t') {
        // First write — `to_mut` clones the slice into a String, then we
        // rebuild from byte `i` onwards.
        let buf = out.to_mut();
        buf.truncate(i);
        for c in s[i..].chars() {
            if c == '\t' {
                buf.push_str("  ");
            } else {
                buf.push(c);
            }
        }
    }
    out
}

The happy path — input has no tab — never enters the if, never allocates, and returns the original slice wrapped in Cow::Borrowed. The unhappy path allocates exactly once.

Composing transformations

to_mut really earns its keep when you chain several optional mutations. The first one that fires flips the Cow to Owned; every following mutation sees an already-owned buffer and reuses it:

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use std::borrow::Cow;

fn apply_rules<'a>(s: &'a str, rules: &[(char, &str)]) -> Cow<'a, str> {
    let mut out: Cow<'a, str> = Cow::Borrowed(s);
    for &(from, to) in rules {
        if out.contains(from) {
            let replaced = out.replace(from, to);
            *out.to_mut() = replaced;
        }
    }
    out
}

Three things worth pointing at. First, out.contains(from) works because Cow<str> derefs to str. Second, the assignment *out.to_mut() = replaced replaces the inner String, not the Cow itself. Third, once the first rule fires, all subsequent to_mut calls are a no-op &mut String — no extra clones.

Pitfall: to_mut always commits

There’s no “preview, then maybe commit” mode. Calling to_mut on a borrowed Cow clones immediately, even if you never end up writing through the returned reference. So this is a trap:

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if !out.is_empty() {
    let _ = out.to_mut();  // allocates even though we may not change anything
    // ... maybe mutate, maybe not
}

Guard the call with the actual condition that means “I’m about to write,” not the condition that means “I might.” The mental shortcut: to_mut is the moment you trade your &str for a String. Reach for it lazily, but commit completely.

Rc<T> is a counter, not a tracing GC: two Rcs pointing at each other will sit in memory forever, each propping the other’s strong-count above zero. Weak<T> is the cure — a pointer that observes an Rc’s allocation without keeping it alive.

The leak Rc lets you write

A parent node owning its children with Rc, and each child holding an Rc back at the parent, looks innocent — and leaks every node:

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use std::cell::RefCell;
use std::rc::Rc;

struct Node {
    name: String,
    parent: RefCell<Option<Rc<Node>>>,    // <-- the trap
    children: RefCell<Vec<Rc<Node>>>,
}

let root  = Rc::new(Node {
    name: "root".into(),
    parent: RefCell::new(None),
    children: RefCell::new(vec![]),
});
let child = Rc::new(Node {
    name: "child".into(),
    parent: RefCell::new(Some(Rc::clone(&root))),  // child owns root
    children: RefCell::new(vec![]),
});
root.children.borrow_mut().push(Rc::clone(&child));  // root owns child

// drop(root); drop(child);  -> strong_count of each is still 1. Memory never freed.

Once root and child go out of scope, their last external Rcs drop, but each still holds an Rc to the other. The strong-counts never hit zero. Drop never runs. The allocation stays put until the process exits.

Weak<T>: a pointer that doesn’t keep things alive

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use std::cell::RefCell;
use std::rc::{Rc, Weak};

struct Node {
    name: String,
    parent: RefCell<Weak<Node>>,          // <-- the fix
    children: RefCell<Vec<Rc<Node>>>,
}

let root = Rc::new(Node {
    name: "root".into(),
    parent: RefCell::new(Weak::new()),
    children: RefCell::new(vec![]),
});

let child = Rc::new(Node {
    name: "child".into(),
    parent: RefCell::new(Rc::downgrade(&root)),  // weak — doesn't bump strong count
    children: RefCell::new(vec![]),
});
root.children.borrow_mut().push(Rc::clone(&child));

assert_eq!(Rc::strong_count(&root), 1);   // only `root` itself
assert_eq!(Rc::weak_count(&root), 1);     // `child.parent`
assert_eq!(Rc::strong_count(&child), 2);  // `child` + `root.children[0]`

Strong pointers own; weak pointers observe. Rc::downgrade(&root) gives you a Weak<Node> that points at the same allocation but only bumps the weak counter. The strong counter — the one that decides when to drop — is unaffected. When the last Rc to a node disappears, the node is destroyed, even if a hundred Weaks are still aimed at it.

Reading through a Weak: upgrade

A Weak doesn’t deref. To get at the value, ask for a temporary Rc back — and be ready for None, because the allocation may already be gone:

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use std::rc::{Rc, Weak};

let strong = Rc::new(String::from("alive"));
let weak: Weak<String> = Rc::downgrade(&strong);

if let Some(rc) = weak.upgrade() {
    assert_eq!(*rc, "alive");
}

drop(strong);            // strong count -> 0, value dropped
assert!(weak.upgrade().is_none());

upgrade is the only way to read through a Weak<T>. The Option return type is the whole point: it forces every caller to handle the case where the upgraded pointer no longer refers to anything. That’s exactly the discipline a back-pointer in a tree needs — “give me my parent, if it’s still around.”

A standalone Weak: Weak::new

You usually want a Weak field initialised before its target exists. Weak::new makes one that points at nothing and upgrades to None:

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use std::rc::Weak;

let dangling: Weak<i32> = Weak::new();
assert!(dangling.upgrade().is_none());

This is what filled the parent field of root above before we had any pointer to give it. No allocation happens until something is actually downgraded into it.

Counts: strong_count and weak_count

Both counters are inspectable. weak_count is what Rc::downgrade increments; strong_count is the one that gates the drop:

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use std::rc::{Rc, Weak};

let a = Rc::new(42);
let w1: Weak<i32> = Rc::downgrade(&a);
let w2: Weak<i32> = Rc::downgrade(&a);

assert_eq!(Rc::strong_count(&a), 1);
assert_eq!(Rc::weak_count(&a), 2);

drop(w1);
assert_eq!(Rc::weak_count(&a), 1);

// Dropping the only strong owner frees the *value* immediately.
// The remaining weak pointer keeps the allocation header alive but
// upgrades will return None.
drop(a);
assert!(w2.upgrade().is_none());

One nuance worth knowing: a live Weak keeps a small allocation header around (so it can check whether the value is still there), but not the value itself. Drop runs on the inner T as soon as the strong-count hits zero, even if a million Weaks outlive it.

When to reach for Weak

Whenever the ownership graph has a back-edge or a cycle:

• Parent pointers in a tree. Children own children with Rc; children point back to parents with Weak.
• Observer / listener lists. A subject holds Weak<Listener> so listeners can be dropped externally without first deregistering.
• Caches. A cache holding Weak<T> lets entries vanish the moment their last real user lets go.

The rule is mechanical: pick one direction in the cycle to be the owner (Rc), and make every edge that closes the loop a Weak. If that direction is hard to choose, the lifetime question is probably a real design question hiding inside the data.

Arc<T> has the same thing

Arc<T> gives you the same pair on the thread-safe side: Arc::downgrade returns a std::sync::Weak<T> (different type, same shape) that you upgrade to an Option<Arc<T>>. Same rules, same idiom — atomic counters under the hood.

Reach for Weak the moment any node in your structure needs to point at something that also points back. The borrow checker can’t catch this leak; making the back-edge weak is the design that does.

Rc<T> gave us shared ownership inside one thread. The moment you thread::spawn it, the compiler refuses. Arc<T> is the same shape with an atomic counter: same clone-the-pointer ergonomics, but Send + Sync and safe to share between threads — and the building block under almost every concurrent pattern in Rust.

The pain: Rc stops at the thread boundary

Rc’s counter is a plain usize. Two threads incrementing it at the same time could read, write, and lose updates — and a lost increment would free a still-referenced allocation. So Rc<T> is deliberately !Send, and the compiler stops you before you can try:

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use std::rc::Rc;
use std::thread;

let cfg = Rc::new(String::from("app"));
thread::spawn(move || println!("{cfg}"));
// error[E0277]: `Rc<String>` cannot be sent between threads safely

Arc<T>: same API, atomic counter

Arc is Rc’s sibling with an atomic strong-count. Same new, same clone, same Deref<Target = T>, same “read-only through the pointer.” The cost is a fetch_add on every clone and a fetch_sub on every drop — measurable in tight benchmarks, free everywhere else:

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use std::sync::Arc;
use std::thread;

let shared = Arc::new(vec![1, 2, 3, 4, 5]);

let mut handles = vec![];
for i in 0..3 {
    let view = Arc::clone(&shared);
    handles.push(thread::spawn(move || {
        let sum: i32 = view.iter().sum();
        (i, sum)
    }));
}

let results: Vec<_> = handles.into_iter().map(|h| h.join().unwrap()).collect();
assert_eq!(results.len(), 3);
assert!(results.iter().all(|(_, s)| *s == 15));

Every spawned thread gets its own Arc clone, bumps the strong-count on the way in, and decrements on the way out. The Vec is dropped exactly once — when the last thread (or the main one) lets go of the final clone.

The Arc::clone(&x) convention is even more important here than for Rc: at a glance you want to know that the closure captured a counter bump, not a 200MB deep copy of the value inside.

Read-only is still the default — wrap for mutation

Just like Rc, you only get &T through an Arc<T>:

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use std::sync::Arc;
let a = Arc::new(String::from("app"));
let b = Arc::clone(&a);
a.push_str("-prod");
// error: cannot borrow data in an `Arc` as mutable

That’s the right default — two threads with &mut to the same value would be an instant data race. To mutate, you compose Arc with a lock. The wrapper choice mirrors the morning’s tradeoff: RefCell would have given us runtime borrow checking on one thread; across threads we need synchronization the OS understands.

Arc<Mutex<T>>: the workhorse of shared mutable state

Pair an Arc with a Mutex and you get the most common concurrent pattern in Rust: many threads, one allocation, exclusive write access at a time.

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use std::sync::{Arc, Mutex};
use std::thread;

let counter = Arc::new(Mutex::new(0_u64));

let mut handles = vec![];
for _ in 0..8 {
    let c = Arc::clone(&counter);
    handles.push(thread::spawn(move || {
        for _ in 0..1_000 {
            *c.lock().unwrap() += 1;
        }
    }));
}
for h in handles { h.join().unwrap(); }

assert_eq!(*counter.lock().unwrap(), 8_000);

The Arc is what each thread owns; the Mutex is what makes the increment safe. Drop either half and the code doesn’t compile: without the Arc, the Mutex can’t be moved into eight closures at once; without the Mutex, you can’t get &mut u64 from &Mutex<u64> at all.

Arc<RwLock<T>>: when reads dominate

When the value is read far more often than it’s written — a config, a cache, a routing table — swap the Mutex for an RwLock. Many readers can hold a shared lock at the same time; writers still take it exclusively.

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use std::sync::{Arc, RwLock};
use std::thread;

let config = Arc::new(RwLock::new(String::from("v1")));

let mut readers = vec![];
for _ in 0..4 {
    let c = Arc::clone(&config);
    readers.push(thread::spawn(move || {
        let g = c.read().unwrap();
        g.len()
    }));
}

{
    let mut w = config.write().unwrap();
    *w = String::from("v2-prod");
}

let lens: Vec<_> = readers.into_iter().map(|h| h.join().unwrap()).collect();
assert!(lens.iter().all(|&n| n == 2 || n == 7));
assert_eq!(*config.read().unwrap(), "v2-prod");

Arc<Mutex<T>> vs Arc<RwLock<T>> is one of those daily judgment calls: if write contention is high, Mutex is often faster because RwLock has more bookkeeping; if reads are ≥10× writes, RwLock lets the readers actually run in parallel.

The catch: Arc<T> doesn’t make T thread-safe

Arc::new(x) only requires T: Sync to be Send. If you wrap a Cell<u32> (which is !Sync) in an Arc, the type system catches you trying to share it across threads — there’s no magic; the wrappers compose because their Send/Sync bounds compose.

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use std::sync::Arc;
use std::cell::Cell;
use std::thread;

let a = Arc::new(Cell::new(0));
let b = Arc::clone(&a);
thread::spawn(move || b.set(1));
// error: `Cell<i32>` cannot be shared between threads safely

That’s why Arc<Mutex<T>> and Arc<RwLock<T>> are the workhorses: the inner type provides the Sync, the Arc provides the Send.

When not to reach for Arc

Arc is the right tool for genuine shared ownership across threads, but it isn’t the only way to move data across one. If a thread just needs to borrow something for a bounded scope, scoped threads let you hand out plain &T without an Arc clone at all. If a value only needs to move from producer to consumer, an mpsc channel transfers ownership directly. Use Arc when more than one thread genuinely owns the same allocation at the same time — not as the default smart pointer for “I have a value and threads.”

The borrow checker’s one-owner rule is a feature until you’re modeling a graph, a cache, or any structure where “who owns this?” honestly has more than one answer. Rc<T> is the escape hatch: a reference-counted pointer that lets multiple owners share the same heap allocation, single-threaded, no locking, no overhead beyond a counter increment.

The pain: a value with no single owner

Imagine a config blob a couple of subsystems need to read. You don’t want to copy it — it’s big — and you can’t give either subsystem a &Config without inventing a parent that outlives them both:

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struct Config { name: String }

fn build() -> (Logger, Metrics) {
    let cfg = Config { name: "app".into() };
    let logger = Logger { cfg: &cfg };  // error: `cfg` does not live long enough
    let metrics = Metrics { cfg: &cfg };
    (logger, metrics)
}

You could clone() the Config and hand each subsystem its own copy. You could thread the lifetime through every type that touches it. Or you could acknowledge that this value genuinely has multiple owners and say so.

Rc<T>: many owners, one allocation

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use std::rc::Rc;

struct Config { name: String }
struct Logger { cfg: Rc<Config> }
struct Metrics { cfg: Rc<Config> }

let cfg = Rc::new(Config { name: "app".into() });
let logger = Logger { cfg: Rc::clone(&cfg) };
let metrics = Metrics { cfg: Rc::clone(&cfg) };

assert_eq!(logger.cfg.name, "app");
assert_eq!(metrics.cfg.name, "app");

Rc::new puts the Config on the heap alongside a strong-count of 1. Rc::clone doesn’t clone the Config — it bumps the counter and hands back another pointer to the same allocation. When a clone is dropped the count decrements; when the last clone is dropped, the Config is destroyed and the heap memory is freed.

The convention is Rc::clone(&x) rather than x.clone(). Both compile, both do the same thing, but the explicit form makes “this is a cheap counter bump, not a deep copy” obvious at the call site — especially helpful when T itself is Clone.

Inspecting the count

Rc::strong_count is a debugging window into the same counter:

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use std::rc::Rc;

let a = Rc::new(String::from("shared"));
assert_eq!(Rc::strong_count(&a), 1);

let b = Rc::clone(&a);
let c = Rc::clone(&a);
assert_eq!(Rc::strong_count(&a), 3);

drop(b);
assert_eq!(Rc::strong_count(&a), 2);

You almost never need to read it in production code — its main use is asserting “yes, this is actually shared” in tests, or understanding a memory leak.

You only get &T through an Rc<T>

The price for shared ownership is read-only access. Rc<T> is Deref<Target = T>, but not DerefMut. Try to mutate and the compiler stops you:

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use std::rc::Rc;

let cfg = Rc::new(String::from("app"));
let other = Rc::clone(&cfg);
cfg.push_str("-prod");
// error: cannot borrow data in an `Rc` as mutable

This is the correct default. If two owners could both call &mut simultaneously, you’d have a data race in single-threaded code — exactly the bug Rust exists to prevent. So you need a runtime borrow check, which is what RefCell<T> provides.

The classic pattern: Rc<RefCell<T>>

When the shared value also needs to mutate, wrap it in a RefCell. The outer Rc gives you shared ownership; the inner RefCell gives you borrow_mut through &self:

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use std::rc::Rc;
use std::cell::RefCell;

let log: Rc<RefCell<Vec<String>>> = Rc::new(RefCell::new(Vec::new()));

let writer_a = Rc::clone(&log);
let writer_b = Rc::clone(&log);

writer_a.borrow_mut().push("a says hi".into());
writer_b.borrow_mut().push("b says hi".into());

let snapshot = log.borrow();
assert_eq!(snapshot.len(), 2);
assert_eq!(snapshot[0], "a says hi");

Every Rc::clone owns the cell; every borrow goes through RefCell’s runtime check. Forget the inner RefCell and you’ll be staring at cannot borrow as mutable errors. Forget the outer Rc and you can’t share the cell in the first place. The pair shows up so often that “Rc<RefCell<…>>” should land in your fingers as one token.

Rc::clone vs (*rc).clone()

It’s worth seeing the difference once:

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use std::rc::Rc;

let a = Rc::new(vec![1, 2, 3]);

let cheap = Rc::clone(&a);        // counter += 1, no allocation
let expensive: Vec<i32> = (*a).clone();   // brand new Vec, separate heap allocation

assert_eq!(Rc::strong_count(&a), 2);   // a + cheap; `expensive` isn't an Rc at all
assert_eq!(expensive, vec![1, 2, 3]);

Rc<T> doesn’t change what T::clone does — it just adds a much cheaper way to make another pointer to the same T. Use Rc::clone for the pointer; reach for (*rc).clone() only when you really do want a fresh, independent T.

The catch: Rc<T> is not Send

Rc is deliberately not thread-safe. The counter increment isn’t atomic; if two threads bumped it simultaneously you could undercount and free a still-referenced allocation. Try to move one across a thread boundary and the compiler refuses:

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use std::rc::Rc;
use std::thread;

let a = Rc::new(42);
thread::spawn(move || println!("{a}"));
// error: `Rc<i32>` cannot be sent between threads safely

That refusal is the whole reason Rc is cheap — no atomic ops, no fences. Cross threads and you want the atomically-counted sibling: Arc<T>, which this afternoon’s bite is about. Same API, same shape, just Send + Sync and a slightly costlier clone.

The other catch: reference cycles

Two Rcs pointing at each other never drop, because each is keeping the other’s count above zero:

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struct Node {
    next: RefCell<Option<Rc<Node>>>,
}
// build a -> b -> a … and neither will ever be freed

Rc is a counter, not a tracing GC — it can’t notice that an island of nodes is unreachable from the outside as long as the nodes are still pointing at each other. The fix is Weak<T>, the non-owning sibling pointer you get from Rc::downgrade. That’s tomorrow’s bite. For now: if your data is a tree, plain Rc<RefCell<T>> is fine; if it’s a graph or has back-pointers, plan for Weak.

This morning’s Atomic* handled “many threads, one scalar.” For “many threads, one value — computed once, then read forever” the std answer is two types: LazyLock<T, F> when you can name the initializer up front, OnceLock<T> when you only learn the value at runtime. Both make the old lazy_static! macro and the once_cell crate redundant.

The bad old days: lazy_static!

Until Rust 1.80 (mid-2024), a thread-safe lazy global meant a macro from a crate:

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// Cargo.toml: lazy_static = "1"
use lazy_static::lazy_static;
use std::collections::HashMap;

lazy_static! {
    static ref COUNTRIES: HashMap<&'static str, &'static str> = {
        let mut m = HashMap::new();
        m.insert("fr", "France");
        m.insert("de", "Germany");
        m
    };
}

fn main() {
    assert_eq!(COUNTRIES.get("fr"), Some(&"France"));
}

It worked, but it pulled in a dependency, used macro magic to fake a static, and gave you a custom Deref wrapper instead of a normal type. Every dependency in your tree that wanted a lazy global was either pulling in lazy_static or the more modern once_cell crate.

The std way: LazyLock<T, F>

Stabilized in Rust 1.80, LazyLock is a normal type — no macro, no Deref trickery, just a static like any other:

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use std::collections::HashMap;
use std::sync::LazyLock;

static COUNTRIES: LazyLock<HashMap<&'static str, &'static str>> = LazyLock::new(|| {
    let mut m = HashMap::new();
    m.insert("fr", "France");
    m.insert("de", "Germany");
    m
});

assert_eq!(COUNTRIES.get("fr"), Some(&"France"));

The closure runs the first time anything touches COUNTRIES, exactly once, and every thread that races to be that “first” gets the same value back. If two threads arrive together, one wins the init and the other blocks until it’s done — same contract lazy_static! always had, now in std.

When the initializer isn’t known at compile time: OnceLock<T>

LazyLock is great when you can write the initializer as a const fn-friendly closure. But what about config you only know after main() starts — a CLI flag, an env var, a parsed file? Stuffing that into a closure means either re-reading the env var at first use or capturing values you don’t have yet at static time. That’s OnceLock<T>’s job:

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use std::sync::OnceLock;

static GREETING: OnceLock<String> = OnceLock::new();

fn init_from_args(name: &str) {
    GREETING.set(format!("hello, {name}")).ok();   // ok() = ignore "already set"
}

fn greeting() -> &'static str {
    GREETING.get().map(String::as_str).unwrap_or("hello, world")
}

init_from_args("ferris");
assert_eq!(greeting(), "hello, ferris");

set returns Err(value) if someone beat you to it — handy when multiple call sites might initialize and you want the first one to win without panicking.

The convenience method: get_or_init

The “check if set, init if not” dance is so common that OnceLock ships it as one call:

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use std::sync::OnceLock;

fn config() -> &'static String {
    static CFG: OnceLock<String> = OnceLock::new();
    CFG.get_or_init(|| std::env::var("APP_CFG").unwrap_or_else(|_| "default".into()))
}

assert!(!config().is_empty());
assert_eq!(config(), config());    // same &'static str on every call

This is what most “lazy global computed from runtime data” code actually wants. Functions can own their own OnceLock as a function-local static — no need to pollute the module namespace.

Which one when

LazyLock is the closer match to lazy_static!. OnceLock is the closer match to manual Mutex<Option<T>> patterns where you wanted “set once, read many.”

The trait bounds, briefly

Because these are Sync and live in a static, the contained T must be Send + Sync. The initializer closure for LazyLock must be Send. You won’t notice for String, HashMap, Vec, Arc<…> — but if you try to stuff an Rc<T> in there the compiler will (correctly) yell. The single-threaded versions, LazyCell and OnceCell, have no such bound — that’s the whole reason both pairs exist.

What you can finally delete

If a crate in your tree still has lazy_static = "1" or once_cell = "1" in its Cargo.toml, and your MSRV is 1.80 or newer, the migration is mechanical:

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// before
lazy_static! { static ref X: T = init(); }
// after
static X: LazyLock<T> = LazyLock::new(init);

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// before
use once_cell::sync::OnceCell;
static X: OnceCell<T> = OnceCell::new();
// after
use std::sync::OnceLock;
static X: OnceLock<T> = OnceLock::new();

One fewer dependency, one less macro in the expansion, and the type that shows up in error messages is just LazyLock<T> — not some crate-private deref wrapper. Tomorrow’s bite picks up the thread on Arc<T> — what to reach for when “one global value” isn’t enough and you need shared ownership across threads.

A Cell<T> lets a single thread mutate through &self — get/set instead of &mut. The atomic types in std::sync::atomic are the same shape, just Sync: a counter, flag, or pointer many threads can poke at without a Mutex, no lock acquisition, no guard, no panic on contention.

The pain: Mutex<u64> for a single counter

A request counter shared across worker threads is the textbook reach-for-Arc<Mutex<_>> case — and the textbook overkill:

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use std::sync::{Arc, Mutex};
use std::thread;

let hits = Arc::new(Mutex::new(0u64));
let mut handles = Vec::new();

for _ in 0..8 {
    let h = Arc::clone(&hits);
    handles.push(thread::spawn(move || {
        for _ in 0..1000 {
            let mut g = h.lock().unwrap();   // lock, increment, unlock — 1000 times
            *g += 1;
        }
    }));
}
for h in handles { h.join().unwrap(); }
assert_eq!(*hits.lock().unwrap(), 8_000);

Eight threads contending on a lock for an n += 1 is a lot of ceremony to add one to an integer. The CPU has a single instruction for this. Rust exposes it.

The fix: AtomicU64 (or AtomicUsize, AtomicBool, …)

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use std::sync::Arc;
use std::sync::atomic::{AtomicU64, Ordering};
use std::thread;

let hits = Arc::new(AtomicU64::new(0));
let mut handles = Vec::new();

for _ in 0..8 {
    let h = Arc::clone(&hits);
    handles.push(thread::spawn(move || {
        for _ in 0..1000 {
            h.fetch_add(1, Ordering::Relaxed);   // one instruction, no lock
        }
    }));
}
for h in handles { h.join().unwrap(); }
assert_eq!(hits.load(Ordering::Relaxed), 8_000);

No lock(), no guard, no unwrap. fetch_add is a single read-modify-write — on x86 it’s literally lock xadd. The Arc is still there because the threads need shared ownership, but the interior is lock-free.

The API is just Cell’s API, with orderings

Every atomic has the same small surface:

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use std::sync::atomic::{AtomicUsize, Ordering};

let n = AtomicUsize::new(7);

// like Cell::get / Cell::set
let v = n.load(Ordering::Relaxed);     assert_eq!(v, 7);
n.store(42, Ordering::Relaxed);
assert_eq!(n.load(Ordering::Relaxed), 42);

// like Cell::replace
let old = n.swap(100, Ordering::Relaxed);
assert_eq!(old, 42);
assert_eq!(n.load(Ordering::Relaxed), 100);

Notice what’s missing: there is no &mut T anywhere. You never borrow the inside. You read out a copy or write one in. That’s why this works across threads at all — there’s nothing to alias.

Read-modify-write: the real reason atomics exist

The fetch_* family is where atomics earn their keep. Each is a single uninterruptible round-trip:

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use std::sync::atomic::{AtomicI32, Ordering};

let n = AtomicI32::new(10);

assert_eq!(n.fetch_add(5, Ordering::Relaxed), 10);  // returns old
assert_eq!(n.load(Ordering::Relaxed), 15);

assert_eq!(n.fetch_sub(3, Ordering::Relaxed), 15);
assert_eq!(n.fetch_or(0b1000, Ordering::Relaxed), 12);
assert_eq!(n.fetch_and(0b1100, Ordering::Relaxed), 0b1100);
assert_eq!(n.load(Ordering::Relaxed), 0b1100);

fetch_add, fetch_sub, fetch_or, fetch_and, fetch_xor, fetch_min, fetch_max — each one returns the value before the operation. That “before” is what makes them composable: you know exactly which thread did the increment that took you from 999 to 1000.

For anything more complex than a single op (clamp, toggle a state machine, transform), reach for update instead of hand-rolling a compare_exchange loop.

AtomicBool: the flag that doesn’t need a Mutex

The most common “I just want one bit” case:

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use std::sync::atomic::{AtomicBool, Ordering};

let stop = AtomicBool::new(false);

// thread A
stop.store(true, Ordering::Release);

// thread B's hot loop
if stop.load(Ordering::Acquire) {
    // shut down
}
# assert!(stop.load(Ordering::Acquire));

Release on the writer + Acquire on the reader pairs everything written before the store with everything read after the load — the standard cancellation-flag pattern. Relaxed would be fine if stop is the only thing the two threads share; use Acquire/Release when the flag is gating other writes.

The full menu

std::sync::atomic ships an atomic for every primitive size:

Not every target supports every width lock-free (32-bit ARM lacks 64-bit CAS, for example). cfg(target_has_atomic = "64") lets you gate code that requires it. On modern x86_64 and aarch64, all of the above are lock-free.

What you give up vs Mutex<T>

Atomics work only on values the CPU already knows how to swap in one instruction. The moment you need to atomically update two fields together — a counter and a timestamp, say — you’re back to Mutex<T>. There is no AtomicStruct. You can’t fetch_push a Vec.

The other thing you give up is loud failure. A Mutex poisoned by a panic returns an Err; a deadlock blocks forever and shows up in a stack dump. An atomic happily does the wrong thing forever if you pick the wrong Ordering — the bug manifests as a flaky test under heavy load on a weakly-ordered CPU, and not at all on your laptop. Use SeqCst when in doubt; reach for Relaxed/Acquire/Release only when you can name what’s being synchronized with what.

When to reach for atomics

Counters, flags, generation numbers, fetch_add-style ID allocators, the “is this initialized yet” bit. Anything where the value fits in a register and the only operation is read / write / one-shot RMW.

Anything fatter — a config map, a parsed AST, a connection pool — wants a Mutex<T> or RwLock<T> wrapped in an Arc. And for the “compute once, then read forever” case across threads, there’s a purpose-built tool — that’s this afternoon’s bite.