From: Ralf Jung <post@ralfj.de>
Date: Wed, 15 Jul 2020 11:43:14 +0000 (+0200)
Subject: link to 'two kinds of invariants'
X-Git-Url: https://git.ralfj.de/web.git/commitdiff_plain/b91b3d141fdbdf9c913e620d0701ae9a95dca7e8?hp=9cccf23f421b07e0c4ac07e381833f3af1e67454

link to 'two kinds of invariants'
---

diff --git a/ralf/_posts/2020-07-15-unused-data.md b/ralf/_posts/2020-07-15-unused-data.md
index afdfff9..ccde204 100644
--- a/ralf/_posts/2020-07-15-unused-data.md
+++ b/ralf/_posts/2020-07-15-unused-data.md
@@ -30,6 +30,8 @@ fn example(b: bool) -> i32 {
 
 I hope it is not very surprising that calling `example` on, e.g., `3` transmuted to `bool` is Undefined Behavior (UB).
 When compiling `if`, the compiler assumes that `0` and `1` are the only possible values; there is no saying what could go wrong when that assumption is violated.
+(This is a compiler-understood *validity invariant* that is fixed in the language specification, which is very different from a user-defined *safety invariant*.
+See [this earlier post]({% post_url 2018-08-22-two-kinds-of-invariants.md %}) for more details on that distinction.)
 
 What is less obvious is why calling `example` on `3` is UB even when there is no such `if` being executed.
 To understand why that is important, let us consider the following example: