Read an Excerpt

Why Programs Fail

Morgan Kaufmann

Chapter One

Your program fails. How can this be? The answer is that the programmer creates a defect in the code. When the code is executed, the defect causes an infection in the program state, which later becomes visible as a failure. To find the defect, one must reason backward, starting with the failure. This chapter defines the essential concepts when talking about debugging, and hints at the techniques discussed subsequently—hopefully whetting your appetite for the remainder of this book.

1.1 MY PROGRAM DOES NOT WORK!

Oops! Your program fails. Now what? This is a common situation that interrupts our routine and requires immediate attention. Because the program mostly worked until now, we assume that something external has crept into our machine—something that is natural and unavoidable;something we are not responsible for—namely,a bug.

If you are a user, you have probably already learned to live with bugs. You may even think that bugs are unavoidable when it comes to software. As a programmer, though, you know that bugs do not creep out of mother nature into our programs. (See Bug Story 1 for an exception.) Rather, bugs are inherent parts of the programs we produce. At the beginning of any bug story stands a human who produces the program in question.

The following is a small program I once produced. The sample program is a very simple sorting tool. Given a list of numbers as command-line arguments, sample prints them as a sorted list on the standard output ($ is the command-line prompt).

$ ./sample 9 7 8 Output: 7 8 9 $ _

Unfortunately, sample does not always work properly, as demonstrated by the following failure:

$ ./sample 11 14 Output: 0 11 $ _

Although the sample output is sorted and contains the right number of items, some original arguments are missing and replaced by bogus numbers. Here, 14 is missing and replaced by 0. (Actual bogus numbers and behavior on your system may vary.) From the sample failure, we can deduce that sample has a bug (or, more precisely, a defect). This brings us to the key question of this chapter:

1.2 FROM DEFECTS TO FAILURES

In general, a failure such as that in the sample program comes about in the four stages discussed in the following.

1. The programmer creates a defect. A defect is a piece of the code that can cause an infection. Because the defect is part of the code, and because every code is initially written by a programmer, the defect is technically created by the programmer. If the programmer creates a defect, does that mean the programmer was at fault? Not necessarily. Consider the following:

* The original requirements did not foresee future changes. Think about the Y2K problem, for instance.

* A program behavior may become classified as a "failure" only when the user sees it for the first time.

* In a modular program, a failure may happen because of incompatible interfaces of two modules.

* In a distributed program, a failure may be the result of some unpredictable interaction of several components.

In such settings, deciding on who is to blame is a political, not a technical, question. Nobody made a mistake, and yet a failure occurred. (See Bug Story 2 for more on such failures.)

2. The defect causes an infection. The program is executed, and with it the defect. The defect now creates an infection—that is, after execution of the defect, the program state differs from what the programmer intended.

A defect in the code does not necessarily cause an infection. The defective code must be executed, and it must be executed under such conditions that the infection actually occurs.

3. The infection propagates. Most functions result in errors when fed with erroneous input. As the remaining program execution accesses the state, it generates further infections that can spread into later program states. An infection need not, however, propagate continuously. It may be overwritten, masked, or corrected by some later program action.

4. The infection causes a failure. A failure is an externally observable error in the program behavior. It is caused by an infection in the program state.

The program execution process is sketched in Figure 1.1. Each program state consists of the values of the program variables, as well as the current execution position (formally, the program counter). Each state determines subsequent states, up to the final state (at the bottom in the figure),in which we can observe the failure (indicated by the x).

Not every defect results in an infection, and not every infection results in a failure. Thus, having no failures does not imply having no defects. This is the curse of testing, as pointed out by Dijkstra. Testing can only show the presence of defects, but never their absence.

In the case of sample, though, we have actually experienced a failure. In hindsight, every failure is thus caused by some infection, and every infection is caused by some earlier infection, originating at the defect. This cause–effect chain from defect to failure is called an infection chain.

The issue of debugging is thus to identify the infection chain, to find its root cause (the defect),and to remove the defect such that the failure no longer occurs. This is what we shall do with the sample program.

1.3 LOST IN TIME AND SPACE

In general, debugging of a program such as sample can be decomposed into seven steps (List 1.1), of which the initial letters form the word TRAFFIC.

1. Track the problem in the database.

2. Reproduce the failure.

3. Automate and simplify the test case.

4. Find possible infection origins.

5. Focus on the most likely origins.

6. Isolate the infection chain.

7. Correct the defect.

Of these steps, tracking the problem in a problem database is mere bookkeeping (see also Chapter 2) and reproducing the problem is not that difficult for deterministic programs such as sample. It can be difficult for nondeterministic programs and long-running programs, though, which is why Chapter 4 discusses the issues involved in reproducing failures.

Automating the test case is also rather straightforward, and results in automatic simplification (see also Chapter 5). The last step, correcting the defect, is usually simple once you have understood how the defect causes the failure (see Chapter 15).

The final three steps—from finding the infection origins to isolating the infection chain—are the steps concerned with understanding how the failure came to be. This task requires by far the most time, as well as other resources. Understanding how the failure came to be is what the rest of this section, and the other chapters of this book, are about.

Why is understanding the failure so difficult? Considering Figure 1.1,all one need do to find the defect is isolate the transition from a sane state (i.e., noninfected, as intended) to an infected state. This is a search in space (as we have to find out which part of the state is infected) as well as in time (as we have to find out when the infection takes place).

However, examination of space and time are enormous tasks for even the simplest programs. Each state consists of dozens, thousands, or even millions of variables. For example, Figure 1.2 shows a visualization of the program state of the GNU compiler (GCC) while compiling a program. The program state consists of about 44,000 individual variables, each with a distinct value, and about 42,000 references between variables. (Chapter 14 discusses how to obtain and use such program states in debugging.)

Not only is a single state quite large, a program execution consists of thousands, millions, or even billions of such states. Space and time thus form a wide area in which only two points are well known (Figure 1.3): initially, the entire state is sane (