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Rewrote "How Safe and Unsafe Interact" Nomicon chapter. The previous version of the chapter covered a lot of ground, but was a little meandering and hard to follow at times. This draft is intended to be clearer and more direct, while still providing the same information as the previous version. r? @steveklabnik
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| % How Safe and Unsafe Interact | ||
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| So what's the relationship between Safe and Unsafe Rust? How do they interact? | ||
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| Rust models the separation between Safe and Unsafe Rust with the `unsafe` | ||
| keyword, which can be thought as a sort of *foreign function interface* (FFI) | ||
| between Safe and Unsafe Rust. This is the magic behind why we can say Safe Rust | ||
| is a safe language: all the scary unsafe bits are relegated exclusively to FFI | ||
| *just like every other safe language*. | ||
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| However because one language is a subset of the other, the two can be cleanly | ||
| intermixed as long as the boundary between Safe and Unsafe Rust is denoted with | ||
| the `unsafe` keyword. No need to write headers, initialize runtimes, or any of | ||
| that other FFI boiler-plate. | ||
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| There are several places `unsafe` can appear in Rust today, which can largely be | ||
| grouped into two categories: | ||
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| * There are unchecked contracts here. To declare you understand this, I require | ||
| you to write `unsafe` elsewhere: | ||
| * On functions, `unsafe` is declaring the function to be unsafe to call. | ||
| Users of the function must check the documentation to determine what this | ||
| means, and then have to write `unsafe` somewhere to identify that they're | ||
| aware of the danger. | ||
| * On trait declarations, `unsafe` is declaring that *implementing* the trait | ||
| is an unsafe operation, as it has contracts that other unsafe code is free | ||
| to trust blindly. (More on this below.) | ||
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| * I am declaring that I have, to the best of my knowledge, adhered to the | ||
| unchecked contracts: | ||
| * On trait implementations, `unsafe` is declaring that the contract of the | ||
| `unsafe` trait has been upheld. | ||
| * On blocks, `unsafe` is declaring any unsafety from an unsafe | ||
| operation within to be handled, and therefore the parent function is safe. | ||
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| There is also `#[unsafe_no_drop_flag]`, which is a special case that exists for | ||
| historical reasons and is in the process of being phased out. See the section on | ||
| [drop flags] for details. | ||
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| Some examples of unsafe functions: | ||
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| * `slice::get_unchecked` will perform unchecked indexing, allowing memory | ||
| safety to be freely violated. | ||
| * every raw pointer to sized type has intrinsic `offset` method that invokes | ||
| Undefined Behavior if it is not "in bounds" as defined by LLVM. | ||
| * `mem::transmute` reinterprets some value as having the given type, | ||
| bypassing type safety in arbitrary ways. (see [conversions] for details) | ||
| * All FFI functions are `unsafe` because they can do arbitrary things. | ||
| C being an obvious culprit, but generally any language can do something | ||
| that Rust isn't happy about. | ||
| What's the relationship between Safe Rust and Unsafe Rust? How do they | ||
| interact? | ||
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| The separation between Safe Rust and Unsafe Rust is controlled with the | ||
| `unsafe` keyword, which acts as an interface from one to the other. This is | ||
| why we can say Safe Rust is a safe language: all the unsafe parts are kept | ||
| exclusively behind the boundary. | ||
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| The `unsafe` keyword has two uses: to declare the existence of contracts the | ||
| compiler can't check, and to declare that the adherence of some code to | ||
| those contracts has been checked by the programmer. | ||
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| You can use `unsafe` to indicate the existence of unchecked contracts on | ||
| _functions_ and on _trait declarations_. On functions, `unsafe` means that | ||
| users of the function must check that function's documentation to ensure | ||
| they are using it in a way that maintains the contracts the function | ||
| requires. On trait declarations, `unsafe` means that implementors of the | ||
| trait must check the trait documentation to ensure their implementation | ||
| maintains the contracts the trait requires. | ||
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| You can use `unsafe` on a block to declare that all constraints required | ||
| by an unsafe function within the block have been adhered to, and the code | ||
| can therefore be trusted. You can use `unsafe` on a trait implementation | ||
| to declare that the implementation of that trait has adhered to whatever | ||
| contracts the trait's documentation requires. | ||
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| There is also the `#[unsafe_no_drop_flag]` attribute, which exists for | ||
| historic reasons and is being phased out. See the section on [drop flags] | ||
| for details. | ||
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| The standard library has a number of unsafe functions, including: | ||
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| * `slice::get_unchecked`, which performs unchecked indexing, allowing | ||
| memory safety to be freely violated. | ||
| * `mem::transmute` reinterprets some value as having a given type, bypassing | ||
| type safety in arbitrary ways (see [conversions] for details). | ||
| * Every raw pointer to a sized type has an intrinstic `offset` method that | ||
| invokes Undefined Behavior if the passed offset is not "in bounds" as | ||
| defined by LLVM. | ||
| * All FFI functions are `unsafe` because the other language can do arbitrary | ||
| operations that the Rust compiler can't check. | ||
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| As of Rust 1.0 there are exactly two unsafe traits: | ||
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| * `Send` is a marker trait (it has no actual API) that promises implementors | ||
| are safe to send (move) to another thread. | ||
| * `Sync` is a marker trait that promises that threads can safely share | ||
| implementors through a shared reference. | ||
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| The need for unsafe traits boils down to the fundamental property of safe code: | ||
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| **No matter how completely awful Safe code is, it can't cause Undefined | ||
| Behavior.** | ||
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| This means that Unsafe Rust, **the royal vanguard of Undefined Behavior**, has to be | ||
| *super paranoid* about generic safe code. To be clear, Unsafe Rust is totally free to trust | ||
| specific safe code. Anything else would degenerate into infinite spirals of | ||
| paranoid despair. In particular it's generally regarded as ok to trust the standard library | ||
| to be correct. `std` is effectively an extension of the language, and you | ||
| really just have to trust the language. If `std` fails to uphold the | ||
| guarantees it declares, then it's basically a language bug. | ||
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| That said, it would be best to minimize *needlessly* relying on properties of | ||
| concrete safe code. Bugs happen! Of course, I must reinforce that this is only | ||
| a concern for Unsafe code. Safe code can blindly trust anyone and everyone | ||
| as far as basic memory-safety is concerned. | ||
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| On the other hand, safe traits are free to declare arbitrary contracts, but because | ||
| implementing them is safe, unsafe code can't trust those contracts to actually | ||
| be upheld. This is different from the concrete case because *anyone* can | ||
| randomly implement the interface. There is something fundamentally different | ||
| about trusting a particular piece of code to be correct, and trusting *all the | ||
| code that will ever be written* to be correct. | ||
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| For instance Rust has `PartialOrd` and `Ord` traits to try to differentiate | ||
| between types which can "just" be compared, and those that actually implement a | ||
| total ordering. Pretty much every API that wants to work with data that can be | ||
| compared wants Ord data. For instance, a sorted map like BTreeMap | ||
| *doesn't even make sense* for partially ordered types. If you claim to implement | ||
| Ord for a type, but don't actually provide a proper total ordering, BTreeMap will | ||
| get *really confused* and start making a total mess of itself. Data that is | ||
| inserted may be impossible to find! | ||
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| But that's okay. BTreeMap is safe, so it guarantees that even if you give it a | ||
| completely garbage Ord implementation, it will still do something *safe*. You | ||
| won't start reading uninitialized or unallocated memory. In fact, BTreeMap | ||
| manages to not actually lose any of your data. When the map is dropped, all the | ||
| destructors will be successfully called! Hooray! | ||
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| However BTreeMap is implemented using a modest spoonful of Unsafe Rust (most collections | ||
| are). That means that it's not necessarily *trivially true* that a bad Ord | ||
| implementation will make BTreeMap behave safely. BTreeMap must be sure not to rely | ||
| on Ord *where safety is at stake*. Ord is provided by safe code, and safety is not | ||
| safe code's responsibility to uphold. | ||
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| But wouldn't it be grand if there was some way for Unsafe to trust some trait | ||
| contracts *somewhere*? This is the problem that unsafe traits tackle: by marking | ||
| *the trait itself* as unsafe to implement, unsafe code can trust the implementation | ||
| to uphold the trait's contract. Although the trait implementation may be | ||
| incorrect in arbitrary other ways. | ||
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| For instance, given a hypothetical UnsafeOrd trait, this is technically a valid | ||
| implementation: | ||
| * `Send` is a marker trait (a trait with no API) that promises implementors are | ||
| safe to send (move) to another thread. | ||
| * `Sync` is a marker trait that promises threads can safely share implementors | ||
| through a shared reference. | ||
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| Much of the Rust standard library also uses Unsafe Rust internally, although | ||
| these implementations are rigorously manually checked, and the Safe Rust | ||
| interfaces provided on top of these implementations can be assumed to be safe. | ||
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| The need for all of this separation boils down a single fundamental property | ||
| of Safe Rust: | ||
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| **No matter what, Safe Rust can't cause Undefined Behavior.** | ||
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| The design of the safe/unsafe split means that Safe Rust inherently has to | ||
| trust that any Unsafe Rust it touches has been written correctly (meaning | ||
| the Unsafe Rust actually maintains whatever contracts it is supposed to | ||
| maintain). On the other hand, Unsafe Rust has to be very careful about | ||
| trusting Safe Rust. | ||
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| As an example, Rust has the `PartialOrd` and `Ord` traits to differentiate | ||
| between types which can "just" be compared, and those that provide a total | ||
| ordering (where every value of the type is either equal to, greater than, | ||
| or less than any other value of the same type). The sorted map type | ||
| `BTreeMap` doesn't make sense for partially-ordered types, and so it | ||
| requires that any key type for it implements the `Ord` trait. However, | ||
| `BTreeMap` has Unsafe Rust code inside of its implementation, and this | ||
| Unsafe Rust code cannot assume that any `Ord` implementation it gets makes | ||
| sense. The unsafe portions of `BTreeMap`'s internals have to be careful to | ||
| maintain all necessary contracts, even if a key type's `Ord` implementation | ||
| does not implement a total ordering. | ||
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| Unsafe Rust cannot automatically trust Safe Rust. When writing Unsafe Rust, | ||
| you must be careful to only rely on specific Safe Rust code, and not make | ||
| assumptions about potential future Safe Rust code providing the same | ||
| guarantees. | ||
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| This is the problem that `unsafe` traits exist to resolve. The `BTreeMap` | ||
| type could theoretically require that keys implement a new trait called | ||
| `UnsafeOrd`, rather than `Ord`, that might look like this: | ||
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| ```rust | ||
| # use std::cmp::Ordering; | ||
| # struct MyType; | ||
| # unsafe trait UnsafeOrd { fn cmp(&self, other: &Self) -> Ordering; } | ||
| unsafe impl UnsafeOrd for MyType { | ||
| fn cmp(&self, other: &Self) -> Ordering { | ||
| Ordering::Equal | ||
| } | ||
| use std::cmp::Ordering; | ||
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| unsafe trait UnsafeOrd { | ||
| fn cmp(&self, other: &Self) -> Ordering; | ||
| } | ||
| ``` | ||
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| But it's probably not the implementation you want. | ||
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| Rust has traditionally avoided making traits unsafe because it makes Unsafe | ||
| pervasive, which is not desirable. The reason Send and Sync are unsafe is because thread | ||
| safety is a *fundamental property* that unsafe code cannot possibly hope to defend | ||
| against in the same way it would defend against a bad Ord implementation. The | ||
| only way to possibly defend against thread-unsafety would be to *not use | ||
| threading at all*. Making every load and store atomic isn't even sufficient, | ||
| because it's possible for complex invariants to exist between disjoint locations | ||
| in memory. For instance, the pointer and capacity of a Vec must be in sync. | ||
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| Even concurrent paradigms that are traditionally regarded as Totally Safe like | ||
| message passing implicitly rely on some notion of thread safety -- are you | ||
| really message-passing if you pass a pointer? Send and Sync therefore require | ||
| some fundamental level of trust that Safe code can't provide, so they must be | ||
| unsafe to implement. To help obviate the pervasive unsafety that this would | ||
| introduce, Send (resp. Sync) is automatically derived for all types composed only | ||
| of Send (resp. Sync) values. 99% of types are Send and Sync, and 99% of those | ||
| never actually say it (the remaining 1% is overwhelmingly synchronization | ||
| primitives). | ||
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| Then, a type would use `unsafe` to implement `UnsafeOrd`, indicating that | ||
| they've ensured their implementation maintains whatever contracts the | ||
| trait expects. In this situation, the Unsafe Rust in the internals of | ||
| `BTreeMap` could trust that the key type's `UnsafeOrd` implementation is | ||
| correct. If it isn't, it's the fault of the unsafe trait implementation | ||
| code, which is consistent with Rust's safety guarantees. | ||
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| The decision of whether to mark a trait `unsafe` is an API design choice. | ||
| Rust has traditionally avoided marking traits unsafe because it makes Unsafe | ||
| Rust pervasive, which is not desirable. `Send` and `Sync` are marked unsafe | ||
| because thread safety is a *fundamental property* that unsafe code can't | ||
| possibly hope to defend against in the way it could defend against a bad | ||
| `Ord` implementation. The decision of whether to mark your own traits `unsafe` | ||
| depends on the same sort of consideration. If `unsafe` code cannot reasonably | ||
| expect to defend against a bad implementation of the trait, then marking the | ||
| trait `unsafe` is a reasonable choice. | ||
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| As an aside, while `Send` and `Sync` are `unsafe` traits, they are | ||
| automatically implemented for types when such derivations are provably safe | ||
| to do. `Send` is automatically derived for all types composed only of values | ||
| whose types also implement `Send`. `Sync` is automatically derived for all | ||
| types composed only of values whose types also implement `Sync`. | ||
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| This is the dance of Safe Rust and Unsafe Rust. It is designed to make using | ||
| Safe Rust as ergonomic as possible, but requires extra effort and care when | ||
| writing Unsafe Rust. The rest of the book is largely a discussion of the sort | ||
| of care that must be taken, and what contracts it is expected of Unsafe Rust | ||
| to uphold. | ||
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| [drop flags]: drop-flags.html | ||
| [conversions]: conversions.html | ||
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