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Perry Kivolowitz 88c8f496c4 Document hex dump display convention in alignment chapter

Closes #22.

The alignment chapter's hex dump examples (e.g. "0011 eeff ccdd aabb"
for a little-endian long initialized to 0xaabbccddeeff0011) are correct
under the default hexdump(1) output convention: bytes grouped into
16-bit little-endian words, each word printed most-significant byte
first. But the chapter never told the reader which convention was in
use, so a reader reproducing the example with xxd or hexdump -C (both
byte-oriented, showing raw memory order) would get a different-looking
result and conclude the book had an endianness bug. That is exactly
what issue #22 reported, and it is also part of what the #33 filer
flagged as "there are no instructions about how to do such a thing"
for hex dumps in this chapter.

Fix: one new subsection "A Note on Hex Dumps" placed before Example 1,
stating the convention explicitly and warning xxd / hexdump -C users
that the bytes within each pair will appear swapped relative to the
examples. The examples themselves are unchanged; they were already
self-consistent under the word-oriented convention.

Rejected alternative: rewriting all the examples in byte-oriented
(xxd) form. That would have matched what most modern readers reach
for, but would also have required regenerating every hex dump in the
chapter and losing continuity with any reader who already absorbed
the current notation. A single explanatory paragraph is less invasive
and teaches the distinction, which is useful in its own right.

No test coverage applies; this is prose.

2026-04-19 02:20:10 -05:00

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Section 1 / Alignment Within Structs

Overview

First, it is important to note that this section applies equally to both classes and structs. Ignoring methods (which are just functions connected to classes and structs), there is only a small difference between them.

In a C++ class, members default to private.

In a C++ struct, members default to public.

Classes, of course, do not exist in C.

Hereafter, we will use class and struct interchangeable.

In order to access data members of a struct you must be able to locate them relative to the start of the struct. If an instance of a struct begins at some address X, the first data member is also located at X so its relative offset from X is 0.

In our discussion of alignment, we'll frequently refer to the notion of offset.

Simple Rule

Data members exhibit natural alignment.

That is:

a long will be found at addresses which are a multiple of 8.
an int will be found at addresses which are a multiple of 4.
a short will be found at addresses which are even.
a char can be found anywhere.

Impact of the Simple Rule

Let's assume assume an int data member is placed properly at address some address, let's say 104. This is OK because 104 is a multiple of 4, the length of an int.

Suppose a long comes next. Does it start at location 108 or 112?

The answer is 112 even though this leaves a 4 byte gap between the end of the int and the beginning of the long. This is because the natural alignment of a long is upon addresses that are multiples of 8, the length of a long.

Sometimes, there are holes or gaps in a struct.

Higher level languages like C and C++ know this and produce the right code. Assembly language programmers have no obligation to stick to no stinkin' rules.

If they don't mind writing code that's buggy, that is.

A Note on Hex Dumps

The hex dumps shown in the examples that follow use the default hexdump(1) output format: bytes are grouped into 16-bit little endian words, and each word is printed with its most significant byte first. A byte-oriented tool such as xxd or hexdump -C displays the raw bytes in memory order instead — the same contents, shown differently. If you reproduce these examples with xxd, expect the bytes within each pair to appear swapped relative to what is shown here.

Example 1

struct {
    long a;
    short b;
    int c;
};

Wrong:

Offset	Width	Member
0	8	a
8	2	b
10	4	c

Correct:

Offset	Width	Member
0	8	a
8	2	b
10	2	-- gap --
12	4	c

Demonstration:

Given this:

struct Foo {
    long a;
    short b;
    int c;
};

struct Foo Bar = { 0xaaaaaaaaaaaaaaaa, 0xbbbb, 0xcccccccc };

A hex dump will show:

aaaa aaaa aaaa aaaa bbbb 0000 cccc cccc

Notice the gap filled in which zeros. Note, if this were a local variable, the zeros might be garbage.

Example 2

Given this:

struct Foo {
    short a;
    char b;
    int c;
};

struct Foo Bar = { 0xaaaa, 0xbb, 0xcccccccc };

A hex dump will show:

aaaa 00bb cccc cccc

Notice there is only one byte of gap before the int c starts.

But, but, but - why are the zeros to the left of the b's?

This ARM processor is running as a little endian machine.

Diversion: Little Endian

Little endian means that within each unit of 2 (above a word), the least significant bytes come first.

In a little endian machine:

Type	Logical Contents	Actual Contents
`long`	`aabbccddeeff0011`	`0011 eeff ccdd aabb`

This shows that a long is 8 bytes:

aabbccddeeff0011

Transpose the two 4 byte groups:

eeff0011 aabbccdd

Transpose the 2 byte groups:

0011 eeff ccdd aabb

Type	Logical Contents	Actual Contents
`int`	`44556677`	`6677 4455`

This shows that an int is 4 bytes:

44556677

Transpose the two 2 byte groups:

6677 4455

The discussion on little endian is important if you are looking directly at the contents of memory, like when you are using gdb.

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