#rustc was also involved

[web.git] / ralf / _posts / 2016-01-09-the-scope-of-unsafe.md

diff --git a/ralf/_posts/2016-01-09-the-scope-of-unsafe.md b/ralf/_posts/2016-01-09-the-scope-of-unsafe.md
index 6c69d0970e524d3b7377e9e992f4a06779e4b89c..757bd738ca155ea2402454551dd0bec225e04eed 100644 (file)
--- a/ralf/_posts/2016-01-09-the-scope-of-unsafe.md
+++ b/ralf/_posts/2016-01-09-the-scope-of-unsafe.md
@@ -1,6 +1,7 @@
 ---
 title: The Scope of Unsafe
 categories: research rust
+reddit: /rust/comments/4065l2/the_scope_of_unsafe/
 ---
 
 I'd like to talk about an important aspect of dealing with unsafe code, that still regularly seems to catch people on the wrong foot:
@@ -13,6 +14,8 @@ What I am saying is that the scope of `unsafe` is larger than the `unsafe` block
 It turns out that the underlying reason for this observation is also a nice illustration for the concept of *semantic types* that comes up in my [work on formalizing Rust]({{ site.baseurl }}{% post_url 2015-10-12-formalizing-rust %}) (or rather, its type system).
 Finally, this discussion will once again lead us to realize that we rely on our type systems to provide much more than just type safety.
 
+**Update (Jan 11th):** Clarified the role of privacy; argued why `evil` is the problem.
+
 <!-- MORE -->
 
 ## An Example
@@ -35,7 +38,7 @@ Roughly speaking, `ptr` points to the heap-allocated block of memory holding the
 It is very easy to add a function to `Vec` that contains no `unsafe` code, and still breaks the safety of the data structure:
 {% highlight rust %}
 impl Vec<T> {
-    fn evil(&mut self) {
+    pub fn evil(&mut self) {
         self.len += 2;
     }
 }
@@ -59,7 +62,13 @@ More precisely speaking, `ptr` points to an array of type `T` and size `cap`, of
 The function `evil` above violates this invariant, while all the functions actually provided by `Vec` (including the ones that are implemented unsafely) preserve the invariant.
 That's why `evil` is the bad guy. (The name kind of gave it away, didn't it?)
 
-This may seem obvious in hindsight, but I think it is actually fairly subtle.
+Some will disagree here and say: "Wait, but there is some `unsafe` code in `Vec`, and without that `unsafe` code `evil` would be all right, so isn't the problem actually that `unsafe` code?"
+This observation is correct, however I don't think this position is useful in practice.
+`Vec` with `evil` clearly is a faulty data structure, and to fix the bug, we would remove `evil`.
+We would never even think about changing the `unsafe` code such that `evil` would be okay, that would defeat the entire purpose of `Vec`.
+In that sense, it is `evil` which is the problem, and not the `unsafe` code.
+
+This may seem obvious in hindsight (and it is also [discussed in the Rustonomicon](https://doc.rust-lang.org/nightly/nomicon/working-with-unsafe.html)), but I think it is actually fairly subtle.
 There used to be claims on the interwebs that "if a Rust program crashes, the bug must be in some `unsafe` block". (And there probably still are.)
 Even academic researchers working on Rust got this wrong, arguing that in order to detect bugs in data structures like `Vec` it suffices to check functions involving unsafe code.
 That's why I think it's worth dedicating an entire blog post to this point.
@@ -82,7 +91,7 @@ pub struct MyType<T> {
 We will define only one function for this type:
 {% highlight rust %}
 impl MyType<T> {
-    fn evil(&mut self) {
+    pub fn evil(&mut self) {
         self.len += 2;
     }
 }
@@ -129,9 +138,10 @@ Or, to put it slightly differently: If the scope of `unsafe` grows beyond the sy
 Does it sprawl through all our code, silently infecting everything we write -- or is there some limit to its effect?
 
 As you probably imagined, of course there *is* a limit. Rust would not be a useful language otherwise.
-The scope of `unsafe` ends at the next *abstraction boundary*.
-This means that everything outside of the `std::vec` module does not have to worry about `Vec`.
-Due to the privacy rules enforced by the compiler, code outside of that module cannot access the private fields of `Vec`, and hence it cannot tell the difference between the syntactic appearance of `Vec` and its actual, semantic meaning.
+*If* all your additional invariants are about *private* fields of your data structure, then the scope of `unsafe` ends at the next *abstraction boundary*.
+This means that everything outside of the `std::vec` module does not have to worry about `Vec`. 
+Due to the privacy rules enforced by the compiler, code outside of that module cannot access the private fields of `Vec`.
+That code does not have a chance to violate the additional invariants of `Vec` -- it cannot tell the difference between the syntactic appearance of `Vec` and its actual, semantic meaning.
 Of course, this also means that *everything* inside `std::vec` is potentially dangerous and needs to be proven to respect the semantics of `Vec`.
 
 ## Abstraction Safety
@@ -142,7 +152,8 @@ This nicely brings us to another important point, which I can only glimpse at he
 
 If the type system of Rust lacked a mechanism to establish abstraction (i.e., if there were no private fields), type safety would not be affected.
 However, it would be very dangerous to write a type like `Vec` that has a semantic meaning beyond its syntactic appearance.
-Since users of `Vec` can accidentally perform invalid operations, there would actually be *no bound to the scope of `unsafe`*.
+All code could perform invalid operations like `Vec::evil`, operations that rely on the assumption that `Vec` is just like `MyType`.
+There would actually be *no bound to the scope of `unsafe`*.
 To formally establish safety, one would have to literally go over the entire program and prove that it doesn't misuse `Vec`.
 The safety promise of Rust would be pretty much useless.