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The professional programmer's manual for avoiding or correcting 99 of the most common, destructive, and interesting C++ programming errors.
° Author is highly regarded and very well known.
° Provides intermediate programmers with the practical know-how needed to gain expert status.
° In the prestigious Addison-Wesley Professional Computing Series!
C++ Gotchas is the latest addition to the distinguished roster of Addison-Wesley's bestselling programming titles, such as Effective C++ and Exceptional C++. While appealing to the same broad audience of intermediate C++ programmers, this book has a completely different approach. The author presents 99 "gotchas" - common and preventable problems in C++ programming and design. The gotchas run the gamut from minor syntactic annoyances to basic design flaws to psychological behavior. The material has been selected based on the author's extensive experience presenting gotchas in his training classes, speaking engagements, and magazine articles. By learning the lessons in this book C++ programmers will save themselves much time and wasted effort. C++ Gotchas is destined to become an invaluable reference to many programmers.
C++ Memory and Resource Management
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Preface.
Acknowledgments.
1. Basics.
Gotcha #1: Excessive Commenting.
Gotcha #2: Magic Numbers.
Gotcha #3: Global Variables.
Gotcha #4: Failure to Distinguish Overloading from Default Initialization.
Gotcha #5: Misunderstanding References.
Gotcha #6: Misunderstanding Const.
Gotcha #7: Ignorance of Base Language Subtleties.
Gotcha #8: Failure to Distinguish Access and Visibility.
Gotcha #9: Using Bad Language.
Gotcha #10: Ignorance of Idiom.
Gotcha #11: Unnecessary Cleverness.
Gotcha #12: Adolescent Behavior.
Gotcha #13: Array/Initializer Confusion.
Gotcha #14: Evaluation Order Indecision.
Gotcha #15: Precedence Problems.
Gotcha #16: for Statement Debacle.
Gotcha #17: Maximal Munch Problems.
Gotcha #18: Creative Declaration-Specifier Ordering.
Gotcha #19: Function/Object Ambiguity.
Gotcha #20: Migrating Type-Qualifiers.
Gotcha #21: Self Initialization.
Gotcha #22: Static and Extern Types.
Gotcha #23: Operator Function Lookup Anomaly.
Gotcha #24: Operator — Subtleties.
Gotcha #25: #define Literals.
Gotcha #26: #define Pseudofunctions.
Gotcha #27: Overuse of #if.
Gotcha #28: Side Effects in Assertions.
Gotcha #29: Converting Through void *.
Gotcha #30: Slicing.
Gotcha #31: Misunderstanding Pointer-to-Const Conversion.
Gotcha #32: Misunderstanding Pointer-to-Pointer-to-Const Conversion.
Gotcha #33: Misunderstanding Pointer-to-Pointer-to-Base Conversion.
Gotcha #34: Pointer-to-MultiDimensional Array Problems.
Gotcha #35: Unchecked Downcasting.
Gotcha #36: Misusing Conversion Operators.
Gotcha #37: Unintended Constructor Conversion.
Gotcha #38: Casting Under Multiple Inheritance.
Gotcha #39: Casting Incomplete Types.
Gotcha #40: Old-Style Casts.
Gotcha #41: Static Casts.
Gotcha #42: Temporary Initialization of Formal Arguments.
Gotcha #43: Temporary Lifetime.
Gotcha #44: References and Temporaries.
Gotcha #45: Ambiguity Failure of dynamic_cast.
Gotcha #46: Misunderstanding Contravariance.
Gotcha #47: Assignment/Initialization Confusion.
Gotcha #48: Improperly Scoped Variables.
Gotcha #49: Failure to Appreciate C++'s Fixation on Copy Operations.
Gotcha #50: Bitwise Copy of Class Objects.
Gotcha #51: Confusing Initialization and Assignment in Constructors.
Gotcha #52: Inconsistent Ordering of the Member Initialization List.
Gotcha #53: Virtual Base Default Initialization.
Gotcha #54: Copy Constructor Base Initialization.
Gotcha #55: Runtime Static Initialization Order.
Gotcha #56: Direct versus Copy Initialization.
Gotcha #57: Direct Argument Initialization.
Gotcha #58: Ignorance of the Return Value Optimizations.
Gotcha #59: Initializing a Static Member in a Constructor.
Gotcha #60: Failure to Distinguish Scalar and Array Allocation.
Gotcha #61: Checking for Allocation Failure.
Gotcha #62: Replacing Global New and Delete.
Gotcha #63: Confusing Scope and Activation of Member new and delete.
Gotcha #64: Throwing String Literals.
Gotcha #65: Improper Exception Mechanics.
Gotcha #66: Abusing Local Addresses.
Gotcha #67: Failure to Employ Resource Acquisition Is Initialization.
Gotcha #68: Improper Use of auto_ptr.
Gotcha #69: Type Codes.
Gotcha #70: Nonvirtual Base Class Destructor.
Gotcha #71: Hiding Nonvirtual Functions.
Gotcha #72: Making Template Methods Too Flexible.
Gotcha #73: Overloading Virtual Functions.
Gotcha #74: Virtual Functions with Default Argument Initializers.
Gotcha #75: Calling Virtual Functions in Constructors and Destructors.
Gotcha #76: Virtual Assignment.
Gotcha #77: Failure to Distinguish among Overloading, Overriding, and Hiding.
Gotcha #78: Failure to Grok Virtual Functions and Overriding.
Gotcha #79: Dominance Issues.
Gotcha #80: Get/Set Interfaces.
Gotcha #81: Const and Reference Data Members.
Gotcha #82: Not Understanding the Meaning of Const Member Functions.
Gotcha #83: Failure to Distinguish Aggregation and Acquaintance.
Gotcha #84: Improper Operator Overloading.
Gotcha #85: Precedence and Overloading.
Gotcha #86: Friend versus Member Operators.
Gotcha #87: Problems with Increment and Decrement.
Gotcha #88: Misunderstanding Templated Copy Operations.
Gotcha #89: Arrays of Class Objects.
Gotcha #90: Improper Container Substitutability.
Gotcha #91: Failure to Understand Protected Access.
Gotcha #92: Public Inheritance for Code Reuse.
Gotcha #93: Concrete Public Base Classes.
Gotcha #94: Failure to Employ Degenerate Hierarchies.
Gotcha #95: Overuse of Inheritance.
Gotcha #96: Type-Based Control Structures.
Gotcha #97: Cosmic Hierarchies.
Gotcha #98: Asking Personal Questions of an Object.
Gotcha #99: Capability Queries.
This book is the result of nearly two decades of minor frustrations, serious bugs, late nights, and weekends spent involuntarily at the keyboard. This collection consists of 99 of some of the more common, severe, or interesting C++ gotchas, most of which I have (I'm sorry to say) experienced personally.The term "gotcha" has a rather cloudy history, and a variety of definitions. For the purposes of this book, we'll define C++ gotchas as common and preventable problems in C++ programming and design. The gotchas described here run the gamut from minor syntactic annoyances to basic design flaws to full-blown sociopathic behavior.
Almost ten years ago, I started including notes about individual gotchas in my C++ course material. My feeling was that pointing out these common misconceptions and misapplications in apposition to correct use would have the effect of inoculating the student against them, and help to prevent new generations of C++ programmers from repeating the gotchas of the past. By and large, the approach worked, and I was induced to collect sets of related gotchas together for presentation at conferences. These presentations proved to be popular (misery loves company?) and I was encouraged to write a "gotcha" book.Any discussion of avoiding or recovering from C++ gotchas involves other subjects, most commonly design patterns, idioms, and technical details of C++ language features.
This is not a book about design patterns, but we often find ourselves referring to patterns as a means of avoiding or recovering from a particular gotcha. Conventionally, the pattern name is capitalized, as in "Template Method" pattern or "Bridge" pattern. When we mention a pattern, we describe its mechanics briefly if they are simple, but delegate detailed discussion of patterns to works devoted to them. Unless otherwise noted, a fuller description of a pattern, as well as a richer discussion of patterns in general, may be found in Design Patterns. Descriptions of the Acyclic Visitor, Monostate, and Null Object patterns may be found in Agile Software Development (see the bibliography).
From the perspective of gotchas, design patterns have two important properties. First, they describe proven, successful design techniques that can be customized in a context-dependent way to new design situations. Second, and perhaps more importantly, mentioning the application of a particular pattern serves to document not only the technique that is applied, but also the reasons for its application and the effect of having applied it. For example, when we see that the Bridge pattern has been applied to a design, we know at a simple mechanical level that an abstract data type implementation has been separated into an interface class and an implementation class. Additionally, we know that the reason this was done was to separate strongly the interface from the implementation, so that changes to the implementation will not affect users of the interface. We also know that there is a runtime cost for this separation, how the source code for the abstract data type should be arranged, and many other details. A pattern name is an efficient, unambiguous handle to a wealth of information and experience about a technique, and careful, accurate use of patterns and pattern terminology in design and documentation clarify code and help to prevent gotchas from occurring.
C++ is a complex programming language, and the more complex a language is, the more important is the use of idiom in programming. For a programming language, an idiom is a commonly used and generally understood combination of lower-level language features that produces a higher-level construct, in much the same way that patterns do at higher levels of design. Therefore, in C++ we can discuss copy operations, function objects, smart pointers, and throwing an exception without having to specify these concepts at their lowest level of implementation. It is important to note that an idiom is not only a common combination of language features, but also a common set of expectations about how these combined features should behave. What do copy operations mean? What can we expect to happen when an exception is thrown? Much of the advice found in this book involves being aware of and employing idioms in C++ coding and design. Many of the gotchas listed here could be described simply as departing from a particular C++ idiom, and the accompanying solution to the problem could often be described simply as following the appropriate idiom (see Gotcha #10).A significant portion of this book is spent in describing the nuances of certain areas of the C++ language that are commonly misunderstood and frequently lead to gotchas. While some of this material may have an esoteric feel to it, unfamiliarity with these areas of the language is a source of problems and a barrier to expert use of C++. These "dark corners" of the language also make an interesting and profitable study in themselves. They are in the C++ language for a reason, and expert C++ programmers often find use for them in advanced programming and design.
Another area of connection between gotchas and design patterns is the similar importance of describing relatively simple instances. Simple patterns are important. In some respects, they may be more important than technically difficult patterns because they are likely to be more commonly employed. The benefits obtained from the pattern description will, therefore, be leveraged over a larger body of code and design. In much the same way, the gotchas described in this book range over a wide range of difficulty, from a simple exhortation to act like a responsible professional (Gotcha #12) to warnings to avoid misunderstanding the dominance rule under virtual inheritance (Gotcha #79). But, as in the analogous case with patterns, acting responsibly is probably more commonly applicable on a day-to-day basis than is the dominance rule.
Two common themes run through the presentation. The first is the overriding importance of convention. This is especially important in a complex language like C++. Adherence to established convention allows us to communicate efficiently and accurately with others. The second theme is the recognition that others will maintain the code we write. The maintenance may be direct, so that our code must be readily and generally understood by competent maintainers; or it may be indirect, in which case we must ensure that our code remains correct even as its behavior is modified by remote changes.
The gotchas in this book are presented as a collection of short essays, each of which describes a gotcha, or a set of related gotchas, along with suggestions for avoiding or correcting them. I'm not sure that any book about gotchas can be entirely cohesive, due to the anarchistic nature of the subject. However, the gotchas are grouped into chapters according to their general nature or area of (mis)applicability. Additionally, discussion of one gotcha inevitably touches on others. Where it makes sense to do so--and it generally does--I've made these links explicit. Cohesion within each item is sometimes at risk as well. Often it is necessary, before getting to the description of a particular gotcha, to describe the context in which it appears. That description, in turn, may require discussion of a technique, idiom, pattern, or language nuance that may lead us even further afield before we return to the advertised gotcha. I've tried to keep this meandering to a minimum, but it would have been dishonest, I think, to attempt to avoid it entirely. Effective programming in C++ involves intelligent coordination of so many disparate areas, that it's impractical to imagine that one can examine its etiology effectively without involving a similar eclectic collection of topics.
It is certainly not necessary--and possibly inadvisable--to read this book straight through from Gotcha #1 to Gotcha #99. Such a concentrated dose of mayhem may put you off programming in C++ altogether. A better approach may be to start with a gotcha that you have experienced or with one that sounds interesting, and follow links to related gotchas. Alternatively, you may sample the gotchas at random.
The text employs a number of devices that are intended to clarify the presentation. First, incorrect or inadvisable code is indicated by a grey background, whereas correct and proper code is presented with no background. Second, code that appears in the text has been edited for brevity and clarity. As a result, it is often the case that the examples, as presented, will not compile without additional, supporting code. The source code for non-trivial examples is available from the author's web site: www.semantics.org. All such code is indicated in the text by an abbreviated pathname appearing near the code example, as in gotcha00/somecode.cpp.
Finally, a warning: The one thing you should not do with gotchas is elevate them to the same status as idioms or patterns. One of the signs that you're using patterns and idiom properly is that the pattern or idiom appropriate to the design or coding context will arise "spontaneously" from your subconscious just when you need it. However, you do not want to encourage a similar spontaneous recall of gotchas, since you're interested in how to produce an effective design or correct code, not how to produce a failed design and buggy code. Rather, learning to recognize a gotcha is analogous to a conditioned response to danger: once burned, twice shy. The recollection of the appropriate gotcha is triggered by its presence; it is not considered and rejected a priori. However, as with matches and firearms, it is not necessary to suffer a burn or a gunshot wound to the head personally to learn how to recognize and avoid a dangerous situation; generally all that's necessary is advance warning. Consider this collection as a means to keep your head in the face of C++ gotchas.
Stephen C. Dewhurst
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