From: Ralf Jung <post@ralfj.de>
Date: Tue, 18 Jul 2017 02:06:05 +0000 (-0700)
Subject: clarify 'elements' of a type
X-Git-Url: https://git.ralfj.de/web.git/commitdiff_plain/79a5dd1fee6c524d75aaed6e38d0e1440320a4b0?hp=4ae5e63b997a5662ebe0bad613e4c433f23399ea;ds=sidebyside

clarify 'elements' of a type
---

diff --git a/ralf/_posts/2017-07-17-types-as-contracts.md b/ralf/_posts/2017-07-17-types-as-contracts.md
index 8ad613f..125a1aa 100644
--- a/ralf/_posts/2017-07-17-types-as-contracts.md
+++ b/ralf/_posts/2017-07-17-types-as-contracts.md
@@ -29,8 +29,8 @@ I'd like to propose that the fundamental reason this is UB is the *type* of the
 Borrowing some terminology from related fields, we can see the function type as stating a *contract*:  The `&mut` say that `simple` expects to be called with non-aliasing pointers.
 If we violate the contract, all bets are off.
 
-To realize this idea, we need to define, for every type, what is the contract associated with that type. When are elements of any given type *valid*?
-For some types, that's simple: `i32` is any four-byte value. `bool` is one byte, either `0` or `1`.
+To realize this idea, we need to define, for every type, what is the contract associated with that type. When is some piece of storage *valid* at any given type?
+For some types, that's simple: `i32` is any fully initialized four-byte value. `bool` is one byte, either `0` (representing `false`) or `1` (representing `true`).
 Compound types like `(T, U)` are defined in terms of their constituent types:  The first component must be a valid `T`, the second component a valid `U`.
 
 Where it gets interesting is the reference types: `&mut T` says that we have a (non-null, properly aligned) pointer.