Let's break that down:

"alignment rules" that "require the address of every primitive data element to be an even multiple of the element’s size". It's not very interesting that we're talking about alignment rules; we knew that already.

"require the address" of "every primitive data element" to be "an even multiple of the element’s size". Now we're getting somewhere. We have a requirement and a scope:

```
Requirement: The address is an even multiple of the element's size.
Scope: Every primitive data element.
```

So, every time we position an element, we must impose the requirement.

Let us try to position an element in memory. The first thing we will position is the `short`

labelled `s`

. Since a short takes up 2 bytes of memory, and we must make its address a multiple of that size, the address must be a multiple of 2. Let's call that address N.

So, `s`

takes up the space from `N`

up to `N + 2`

. (**NOTE**: For all of these ranges, the first endpoint is included, but the last endpoint is not. This is the normal way to describe ranges of integers in computer science; in most cases it is by far the most useful and least error-prone way to do it. Trust me.)

We continue with each other field.

`c`

takes up one byte, from `N + 2`

to `N + 3`

.

We are at `N + 3`

, but we cannot start `t`

there, because `N + 3`

is odd (since `N`

is even). So we must skip a byte. Thus `t`

ranges from `N + 4`

to `N + 6`

.

Continuing with this sort of logic, we end up with `d`

from `N + 6`

to `N + 7`

; `r`

from `N + 8`

to `N + 16`

; `i`

from `N + 16`

to `N + 20`

. (**NOTE** that this only works if we restrict N to be a multiple of 8, or `r`

will be unaligned. This is ok; when we allocate the memory for the array, we can align the start of it however we want - we just have to be consistent about the sequence of data after that point.)

So we need **at least** 20 bytes for this structure. (That's one of the advantages of the half-open ranges: the difference between the endpoints equals the size. If we included or excluded both endpoints from the range, we'd have to make a +1 or -1 correction.)

Now let's say we try to lay out the array as ten consecutive chunks of 20 bytes. Will this work? No; say that element 0 is at address 256 (a multiple of 8). Now `r`

in element 1 will be unaligned, because it will start at 256 + 20 + 8, which is not divisible by 8. That's not allowed.

So what do we do now? We can't just insert an extra 4 bytes before `r`

in element 1, because every element of the array must have the same layout (not to mention size). But there is a simple solution: we insert 4 bytes of additional padding at the **end** of **each** element. Now, as long as the array starts at some multiple of 8, every element will also start at a multiple of 8 (which, in turn, keeps `r`

aligned), because the size is now a multiple of 8.

We conclude that we need 24 bytes for the structure, and thus 24 * 10 = 240 bytes for the array.