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Final draft, change the release date
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@ -21,8 +21,8 @@ break them. See, Rust will go so far as to claim:
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it's correct. There's ongoing work to [formalize](https://plv.mpi-sws.org/rustbelt/popl18/)
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the rules and *prove* that Rust is safe, but for our purposes it's a reasonable assumption.
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Until it isn't. It's totally possible for "safe" Rust programs
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(under contrived circumstances) to encounter memory corruption and trigger a
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Until it isn't. Under specific circumstances, it's totally possible for "safe"
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Rust programs to encounter memory corruption and trigger a
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["segfault"](https://en.wikipedia.org/wiki/Segmentation_fault).
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To prove it, this demonstration was run using an unmodified compiler:
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@ -79,17 +79,17 @@ and crash too? The answer is that `sudo` deletes environment variables
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like `LD_PRELOAD` and `LD_LIBRARY_PATH` when running commands.
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It's technically possible to crash `sudo` in the same way using
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our evil `malloc` implementation, but the default security policy
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deletes those variables.
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deletes the variables we need.
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Finally, why does the program run when compiled with Rust 1.31, and not 1.32?
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The answer is in the release notes:
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[`jemalloc` is removed by default](https://blog.rust-lang.org/2019/01/17/Rust-1.32.0.html#jemalloc-is-removed-by-default).
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In Rust 1.28 through 1.31, programs are statically compiled against
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In all versions of Rust through 1.31, executables are statically compiled against
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[jemalloc](http://jemalloc.net/) by default; our dynamically loaded
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evil `malloc` implementation never gets an opportunity to run. However, it's still
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possible to trigger segfaults in Rust programs from 1.28 - 1.31 by using the
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evil `malloc` implementation never gets an opportunity to run. It's still
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possible to trigger segfaults in Rust binaries from 1.28 to 1.31 by using the
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[`System`](https://doc.rust-lang.org/std/alloc/struct.System.html)
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global allocator. Rust programs prior to 1.28 aren't affected by this
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global allocator, but programs prior to 1.28 aren't affected by this
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`LD_PRELOAD` trick.
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# So what?
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@ -105,11 +105,11 @@ But this example does highlight an assumption of Rust's memory model
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that I haven't seen discussed much: **safe Rust is safe if, and only if,
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the allocator it relies on is "correct"**. And because writing an allocator is
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[fundamentally unsafe](https://doc.rust-lang.org/std/alloc/trait.GlobalAlloc.html#unsafety),
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safe Rust will always rely on unsafe Rust somewhere.
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Rust's promises will always rely on some amount of "unsafe" code.
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That all said, know that "safe" Rust can claim to be safe because it stands
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on the shoulders of incredible developers working on jemalloc,
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That all said, know that "safe" Rust can claim to be so only because it stands
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on the shoulders of incredible libraries like jemalloc,
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[kmalloc](https://linux-kernel-labs.github.io/master/labs/kernel_api.html#memory-allocation),
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and others. Without being able to trust the allocators, we wouldn't
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be able to trust the promise of safe Rust. So to all the people
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who make the safety promises of Rust possible - thanks.
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and others. Without being able to trust the allocators, we'd have no reason
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to trust the safety guarantees made by Rust. So to all the people
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who make safe Rust possible - thanks.
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