C++ Google Style Guide
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Google C++ Style Guide
Table of Contents
Header
Files
Self-contained Headers The #define Guard Forward Declarations Inline Functions
Names and Order of Includes
Scoping Namespaces Unnamed Namespaces and Static Variables Nonmember, Static Member, and Global Functions
Local Variables Static and Global Variables thread_local Variables
Classes Doing Work in Constructors Implicit Conversions Copyable and Movable Types Structs vs. Classes
Inheritance Multiple Inheritance Interfaces Operator Overloading Access Control
Declaration Order
Functions Output Parameters Write Short Functions Reference Arguments Function Overloading
Default Arguments Trailing Return Type Syntax
Google-
Specific
Magic
Ownership and Smart Pointers cpplint
Other C++
Features
Rvalue References Friends Exceptions noexcept Run-Time Type Information (RTTI) Casting
Streams Preincrement and Predecrement Use of const Use of constexpr Integer Types
64-bit Portability Preprocessor Macros 0 and nullptr/NULL sizeof auto Braced Initializer List
Lambda expressions Template metaprogramming Boost std::hash C++11
Nonstandard Extensions Aliases
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Naming General Naming Rules File Names Type Names Variable Names Constant Names
Function Names Namespace Names Enumerator Names Macro Names Exceptions to Naming Rules
Comments Comment Style File Comments Class Comments Function Comments Variable Comments
Implementation Comments Punctuation, Spelling and Grammar TODO Comments
Deprecation Comments
Formatting Line Length Non-ASCII Characters Spaces vs. Tabs Function Declarations and Definitions
Lambda Expressions Function Calls Braced Initializer List Format Conditionals
Loops and Switch Statements Pointer and Reference Expressions Boolean Expressions Return Values
Variable and Array Initialization Preprocessor Directives Class Format Constructor Initializer Lists
Namespace Formatting Horizontal Whitespace Vertical Whitespace
Exceptions
to the
Rules
Existing Non-conformant Code Windows Code
Parting
Words
Background
C++ is one of the main development languages used by many of Google's open-source projects. As every C++ programmer knows, the
language has many powerful features, but this power brings with it complexity, which in turn can make code more bug-prone and harder to read
and maintain.
The goal of this guide is to manage this complexity by describing in detail the dos and don'ts of writing C++ code. These rules exist to keep the
code base manageable while still allowing coders to use C++ language features productively.
Style, also known as readability, is what we call the conventions that govern our C++ code. The term Style is a bit of a misnomer, since these
conventions cover far more than just source file formatting.
Most open-source projects developed by Google conform to the requirements in this guide.
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Note that this guide is not a C++ tutorial: we assume that the reader is familiar with the language.
Why do we have this document?
There are a few core goals that we believe this guide should serve. These are the fundamental whys that underlie all of the individual rules. By
bringing these ideas to the fore, we hope to ground discussions and make it clearer to our broader community why the rules are in place and
why particular decisions have been made. If you understand what goals each rule is serving, it should be clearer to everyone when a rule may
be waived (some can be), and what sort of argument or alternative would be necessary to change a rule in the guide.
The goals of the style guide as we currently see them are as follows:
Style rules should pull their weight
The benefit of a style rule must be large enough to justify asking all of our engineers to remember it. The benefit is measured relative to
the codebase we would get without the rule, so a rule against a very harmful practice may still have a small benefit if people are unlikely
to do it anyway. This principle mostly explains the rules we don’t have, rather than the rules we do: for example, goto contravenes many
of the following principles, but is already vanishingly rare, so the Style Guide doesn’t discuss it.
Optimize for the reader, not the writer
Our codebase (and most individual components submitted to it) is expected to continue for quite some time. As a result, more time will
be spent reading most of our code than writing it. We explicitly choose to optimize for the experience of our average software engineer
reading, maintaining, and debugging code in our codebase rather than ease when writing said code. "Leave a trace for the reader" is a
particularly common sub-point of this principle: When something surprising or unusual is happening in a snippet of code (for example,
transfer of pointer ownership), leaving textual hints for the reader at the point of use is valuable (std::unique_ptr demonstrates the
ownership transfer unambiguously at the call site).
Be consistent with existing code
Using one style consistently through our codebase lets us focus on other (more important) issues. Consistency also allows for
automation: tools that format your code or adjust your #includes only work properly when your code is consistent with the
expectations of the tooling. In many cases, rules that are attributed to "Be Consistent" boil down to "Just pick one and stop worrying
about it"; the potential value of allowing flexibility on these points is outweighed by the cost of having people argue over them.
Be consistent with the broader C++ community when appropriate
Consistency with the way other organizations use C++ has value for the same reasons as consistency within our code base. If a feature
in the C++ standard solves a problem, or if some idiom is widely known and accepted, that's an argument for using it. However,
sometimes standard features and idioms are flawed, or were just designed without our codebase's needs in mind. In those cases (as
described below) it's appropriate to constrain or ban standard features. In some cases we prefer a homegrown or third-party library over
a library defined in the C++ Standard, either out of perceived superiority or insufficient value to transition the codebase to the standard
interface.
Avoid surprising or dangerous constructs
Goals of the Style Guide
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C++ has features that are more surprising or dangerous than one might think at a glance. Some style guide restrictions are in place to
prevent falling into these pitfalls. There is a high bar for style guide waivers on such restrictions, because waiving such rules often
directly risks compromising program correctness.
Avoid constructs that our average C++ programmer would find tricky or hard to maintain
C++ has features that may not be generally appropriate because of the complexity they introduce to the code. In widely used code, it
may be more acceptable to use trickier language constructs, because any benefits of more complex implementation are multiplied
widely by usage, and the cost in understanding the complexity does not need to be paid again when working with new portions of the
codebase. When in doubt, waivers to rules of this type can be sought by asking your project leads. This is specifically important for our
codebase because code ownership and team membership changes over time: even if everyone that works with some piece of code
currently understands it, such understanding is not guaranteed to hold a few years from now.
Be mindful of our scale
With a codebase of 100+ million lines and thousands of engineers, some mistakes and simplifications for one engineer can become
costly for many. For instance it's particularly important to avoid polluting the global namespace: name collisions across a codebase of
hundreds of millions of lines are difficult to work with and hard to avoid if everyone puts things into the global namespace.
Concede to optimization when necessary
Performance optimizations can sometimes be necessary and appropriate, even when they conflict with the other principles of this
document.
The intent of this document is to provide maximal guidance with reasonable restriction. As always, common sense and good taste should
prevail. By this we specifically refer to the established conventions of the entire Google C++ community, not just your personal preferences or
those of your team. Be skeptical about and reluctant to use clever or unusual constructs: the absence of a prohibition is not the same as a
license to proceed. Use your judgment, and if you are unsure, please don't hesitate to ask your project leads to get additional input.
In general, every .cc file should have an associated .h file. There are some common exceptions, such as unittests and small .cc files
containing just a main() function.
Correct use of header files can make a huge difference to the readability, size and performance of your code.
The following rules will guide you through the various pitfalls of using header files.
Header Files
Self-contained Headers
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Header files should be self-contained (compile on their own) and end in .h. Non-header files that are meant for inclusion should end in .inc
and be used sparingly.
All header files should be self-contained. Users and refactoring tools should not have to adhere to special conditions to include the header.
Specifically, a header should have header guards and include all other headers it needs.
Prefer placing the definitions for template and inline functions in the same file as their declarations. The definitions of these constructs must be
included into every .cc file that uses them, or the program may fail to link in some build configurations. If declarations and definitions are in
different files, including the former should transitively include the latter. Do not move these definitions to separately included header files
(-inl.h); this practice was common in the past, but is no longer allowed.
As an exception, a template that is explicitly instantiated for all relevant sets of template arguments, or that is a private implementation detail of
a class, is allowed to be defined in the one and only .cc file that instantiates the template.
There are rare cases where a file designed to be included is not self-contained. These are typically intended to be included at unusual
locations, such as the middle of another file. They might not use header guards, and might not include their prerequisites. Name such files with
the .inc extension. Use sparingly, and prefer self-contained headers when possible.
All header files should have #define guards to prevent multiple inclusion. The format of the symbol name should be
<PROJECT>_<PATH>_<FILE>_H_.
To guarantee uniqueness, they should be based on the full path in a project's source tree. For example, the file foo/src/bar/baz.h in
project foo should have the following guard:
#ifndef FOO_BAR_BAZ_H_
#define FOO_BAR_BAZ_H_
...
#endif // FOO_BAR_BAZ_H_
The #define Guard
Forward Declarations
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Avoid using forward declarations where possible. Just #include the headers you need.
Definition:
A "forward declaration" is a declaration of a class, function, or template without an associated definition.
Pros:
Forward declarations can save compile time, as #includes force the compiler to open more files and process more input.
Forward declarations can save on unnecessary recompilation. #includes can force your code to be recompiled more often, due to
unrelated changes in the header.
Cons:
Forward declarations can hide a dependency, allowing user code to skip necessary recompilation when headers change.
A forward declaration may be broken by subsequent changes to the library. Forward declarations of functions and templates can prevent
the header owners from making otherwise-compatible changes to their APIs, such as widening a parameter type, adding a template
parameter with a default value, or migrating to a new namespace.
Forward declaring symbols from namespace std:: yields undefined behavior.
It can be difficult to determine whether a forward declaration or a full #include is needed. Replacing an #include with a forward
declaration can silently change the meaning of code:
// b.h:
struct B {};
struct D : B {};
// good_user.cc:
#include "b.h"
void f(B*);
void f(void*);
void test(D* x) { f(x); } // calls f(B*)
If the #include was replaced with forward decls for B and D, test() would call f(void*).
Forward declaring multiple symbols from a header can be more verbose than simply #includeing the header.
Structuring code to enable forward declarations (e.g. using pointer members instead of object members) can make the code slower and
more complex.
Decision:
Try to avoid forward declarations of entities defined in another project.
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When using a function declared in a header file, always #include that header.
When using a class template, prefer to #include its header file.
Please see Names and Order of Includes for rules about when to #include a header.
Define functions inline only when they are small, say, 10 lines or fewer.
Definition:
You can declare functions in a way that allows the compiler to expand them inline rather than calling them through the usual function call
mechanism.
Pros:
Inlining a function can generate more efficient object code, as long as the inlined function is small. Feel free to inline accessors and mutators,
and other short, performance-critical functions.
Cons:
Overuse of inlining can actually make programs slower. Depending on a function's size, inlining it can cause the code size to increase or
decrease. Inlining a very small accessor function will usually decrease code size while inlining a very large function can dramatically increase
code size. On modern processors smaller code usually runs faster due to better use of the instruction cache.
Decision:
A decent rule of thumb is to not inline a function if it is more than 10 lines long. Beware of destructors, which are often longer than they appear
because of implicit member- and base-destructor calls!
Another useful rule of thumb: it's typically not cost effective to inline functions with loops or switch statements (unless, in the common case, the
loop or switch statement is never executed).
It is important to know that functions are not always inlined even if they are declared as such; for example, virtual and recursive functions are
not normally inlined. Usually recursive functions should not be inline. The main reason for making a virtual function inline is to place its
definition in the class, either for convenience or to document its behavior, e.g., for accessors and mutators.
Inline Functions
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Use standard order for readability and to avoid hidden dependencies: Related header, C library, C++ library, other libraries' .h, your project's
.h.
All of a project's header files should be listed as descendants of the project's source directory without use of UNIX directory shortcuts . (the
current directory) or .. (the parent directory). For example, google-awesome-project/src/base/logging.h should be included as:
#include "base/logging.h"
In dir/foo.cc or dir/foo_test.cc, whose main purpose is to implement or test the stuff in dir2/foo2.h, order your includes as follows:
1. dir2/foo2.h.
2. A blank line
3. C system files.
4. C++ system files.
5. A blank line
6. Other libraries' .h files.
7. Your project's .h files.
Note that any adjacent blank lines should be collapsed.
With the preferred ordering, if dir2/foo2.h omits any necessary includes, the build of dir/foo.cc or dir/foo_test.cc will break. Thus,
this rule ensures that build breaks show up first for the people working on these files, not for innocent people in other packages.
dir/foo.cc and dir2/foo2.h are usually in the same directory (e.g. base/basictypes_test.cc and base/basictypes.h), but may
sometimes be in different directories too.
Note that the C compatibility headers such as stddef.h are essentially interchangeable with their C++ counterparts (cstddef) Either style is
acceptable, but prefer consistency with existing code.
Within each section the includes should be ordered alphabetically. Note that older code might not conform to this rule and should be fixed when
convenient.
You should include all the headers that define the symbols you rely upon, except in the unusual case of forward declaration. If you rely on
symbols from bar.h, don't count on the fact that you included foo.h which (currently) includes bar.h: include bar.h yourself, unless foo.h
explicitly demonstrates its intent to provide you the symbols of bar.h. However, any includes present in the related header do not need to be
included again in the related cc (i.e., foo.cc can rely on foo.h's includes).
Names and Order of Includes
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For example, the includes in google-awesome-project/src/foo/internal/fooserver.cc might look like this:
#include "foo/server/fooserver.h"
#include <sys/types.h>
#include <unistd.h>
#include <vector>
#include "base/basictypes.h"
#include "base/commandlineflags.h"
#include "foo/server/bar.h"
Exception:
Sometimes, system-specific code needs conditional includes. Such code can put conditional includes after other includes. Of course, keep your
system-specific code small and localized. Example:
#include "foo/public/fooserver.h"
#include "base/port.h" // For LANG_CXX11.
#ifdef LANG_CXX11
#include <initializer_list>
#endif // LANG_CXX11
With few exceptions, place code in a namespace. Namespaces should have unique names based on the project name, and possibly its path.
Do not use using-directives (e.g. using namespace foo). Do not use inline namespaces. For unnamed namespaces, see Unnamed
Scoping
Namespaces
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Namespaces and Static Variables.
Definition:
Namespaces subdivide the global scope into distinct, named scopes, and so are useful for preventing name collisions in the global scope.
Pros:
Namespaces provide a method for preventing name conflicts in large programs while allowing most code to use reasonably short names.
For example, if two different projects have a class Foo in the global scope, these symbols may collide at compile time or at runtime. If each
project places their code in a namespace, project1::Foo and project2::Foo are now distinct symbols that do not collide, and code
within each project's namespace can continue to refer to Foo without the prefix.
Inline namespaces automatically place their names in the enclosing scope. Consider the following snippet, for example:
namespace outer {
inline namespace inner {
void foo();
} // namespace inner
} // namespace outer
The expressions outer::inner::foo() and outer::foo() are interchangeable. Inline namespaces are primarily intended for ABI
compatibility across versions.
Cons:
Namespaces can be confusing, because they complicate the mechanics of figuring out what definition a name refers to.
Inline namespaces, in particular, can be confusing because names aren't actually restricted to the namespace where they are declared. They
are only useful as part of some larger versioning policy.
In some contexts, it's necessary to repeatedly refer to symbols by their fully-qualified names. For deeply-nested namespaces, this can add a lot
of clutter.
Decision:
Namespaces should be used as follows:
Follow the rules on Namespace Names.
Terminate namespaces with comments as shown in the given examples.
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Namespaces wrap the entire source file after includes, gflags definitions/declarations and forward declarations of classes from other
namespaces.
// In the .h file
namespace mynamespace {
// All declarations are within the namespace scope.
// Notice the lack of indentation.
class MyClass {
public:
...
void Foo();
};
} // namespace mynamespace
// In the .cc file
namespace mynamespace {
// Definition of functions is within scope of the namespace.
void MyClass::Foo() {
...
}
} // namespace mynamespace
More complex .cc files might have additional details, like flags or using-declarations.
#include "a.h"
DEFINE_FLAG(bool, someflag, false, "dummy flag");
namespace mynamespace {
using ::foo::bar;
...code for mynamespace... // Code goes against the left margin.
} // namespace mynamespace
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To place generated protocol message code in a namespace, use the package specifier in the .proto file. See Protocol Buffer
Packages for details.
Do not declare anything in namespace std, including forward declarations of standard library classes. Declaring entities in namespace
std is undefined behavior, i.e., not portable. To declare entities from the standard library, include the appropriate header file.
You may not use a using-directive to make all names from a namespace available.
// Forbidden -- This pollutes the namespace.
using namespace foo;
Do not use Namespace aliases at namespace scope in header files except in explicitly marked internal-only namespaces, because
anything imported into a namespace in a header file becomes part of the public API exported by that file.
// Shorten access to some commonly used names in .cc files.
namespace baz = ::foo::bar::baz;
// Shorten access to some commonly used names (in a .h file).
namespace librarian {
namespace impl { // Internal, not part of the API.
namespace sidetable = ::pipeline_diagnostics::sidetable;
} // namespace impl
inline void my_inline_function() {
// namespace alias local to a function (or method).
namespace baz = ::foo::bar::baz;
...
}
} // namespace librarian
Do not use inline namespaces.
When definitions in a .cc file do not need to be referenced outside that file, place them in an unnamed namespace or declare them static.
Do not use either of these constructs in .h files.
Unnamed Namespaces and Static Variables
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Definition:
All declarations can be given internal linkage by placing them in unnamed namespaces. Functions and variables can also be given internal
linkage by declaring them static. This means that anything you're declaring can't be accessed from another file. If a different file declares
something with the same name, then the two entities are completely independent.
Decision:
Use of internal linkage in .cc files is encouraged for all code that does not need to be referenced elsewhere. Do not use internal linkage in .h
files.
Format unnamed namespaces like named namespaces. In the terminating comment, leave the namespace name empty:
namespace {
...
} // namespace
Prefer placing nonmember functions in a namespace; use completely global functions rarely. Do not use a class simply to group static
functions. Static methods of a class should generally be closely related to instances of the class or the class's static data.
Pros:
Nonmember and static member functions can be useful in some situations. Putting nonmember functions in a namespace avoids polluting the
global namespace.
Cons:
Nonmember and static member functions may make more sense as members of a new class, especially if they access external resources or
have significant dependencies.
Decision:
Sometimes it is useful to define a function not bound to a class instance. Such a function can be either a static member or a nonmember
function. Nonmember functions should not depend on external variables, and should nearly always exist in a namespace. Do not create
classes only to group static member functions; this is no different than just giving the function names a common prefix, and such grouping is
usually unnecessary anyway.
Nonmember, Static Member, and Global Functions
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If you define a nonmember function and it is only needed in its .cc file, use internal linkage to limit its scope.
Place a function's variables in the narrowest scope possible, and initialize variables in the declaration.
C++ allows you to declare variables anywhere in a function. We encourage you to declare them in as local a scope as possible, and as close to
the first use as possible. This makes it easier for the reader to find the declaration and see what type the variable is and what it was initialized
to. In particular, initialization should be used instead of declaration and assignment, e.g.:
int i;
i = f(); // Bad -- initialization separate from declaration.
int j = g(); // Good -- declaration has initialization.
std::vector<int> v;
v.push_back(1); // Prefer initializing using brace initialization.
v.push_back(2);
std::vector<int> v = {1, 2}; // Good -- v starts initialized.
Variables needed for if, while and for statements should normally be declared within those statements, so that such variables are confined
to those scopes. E.g.:
while (const char* p = strchr(str, '/')) str = p + 1;
There is one caveat: if the variable is an object, its constructor is invoked every time it enters scope and is created, and its destructor is invoked
every time it goes out of scope.
// Inefficient implementation:
for (int i = 0; i < 1000000; ++i) {
Foo f; // My ctor and dtor get called 1000000 times each.
f.DoSomething(i);
}
Local Variables
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It may be more efficient to declare such a variable used in a loop outside that loop:
Foo f; // My ctor and dtor get called once each.
for (int i = 0; i < 1000000; ++i) {
f.DoSomething(i);
}
Objects with static storage duration are forbidden unless they are trivially destructible. Informally this means that the destructor does not do
anything, even taking member and base destructors into account. More formally it means that the type has no user-defined or virtual destructor
and that all bases and non-static members are trivially destructible. Static function-local variables may use dynamic initialization. Use of
dynamic initialization for static class member variables or variables at namespace scope is discouraged, but allowed in limited circumstances;
see below for details.
As a rule of thumb: a global variable satisfies these requirements if its declaration, considered in isolation, could be constexpr.
Definition:
Every object has a storage duration, which correlates with its lifetime. Objects with static storage duration live from the point of their initialization
until the end of the program. Such objects appear as variables at namespace scope ("global variables"), as static data members of classes, or
as function-local variables that are declared with the static specifier. Function-local static variables are initialized when control first passes
through their declaration; all other objects with static storage duration are initialized as part of program start-up. All objects with static storage
duration are destroyed at program exit (which happens before unjoined threads are terminated).
Initialization may be dynamic, which means that something non-trivial happens during initialization. (For example, consider a constructor that
allocates memory, or a variable that is initialized with the current process ID.) The other kind of initialization is static initialization. The two aren't
quite opposites, though: static initialization always happens to objects with static storage duration (initializing the object either to a given
constant or to a representation consisting of all bytes set to zero), whereas dynamic initialization happens after that, if required.
Pros:
Global and static variables are very useful for a large number of applications: named constants, auxiliary data structures internal to some
translation unit, command-line flags, logging, registration mechanisms, background infrastructure, etc.
Cons:
Static and Global Variables
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Global and static variables that use dynamic initialization or have non-trivial destructors create complexity that can easily lead to hard-to-find
bugs. Dynamic initialization is not ordered across translation units, and neither is destruction (except that destruction happens in reverse order
of initialization). When one initialization refers to another variable with static storage duration, it is possible that this causes an object to be
accessed before its lifetime has begun (or after its lifetime has ended). Moreover, when a program starts threads that are not joined at exit,
those threads may attempt to access objects after their lifetime has ended if their destructor has already run.
Decision:
Decision on destruction
When destructors are trivial, their execution is not subject to ordering at all (they are effectively not "run"); otherwise we are exposed to the risk
of accessing objects after the end of their lifetime. Therefore, we only allow objects with static storage duration if they are trivially destructible.
Fundamental types (like pointers and int) are trivially destructible, as are arrays of trivially destructible types. Note that variables marked with
constexpr are trivially destructible.
const int kNum = 10; // allowed
struct X { int n; };
const X kX[] = {{1}, {2}, {3}}; // allowed
void foo() {
static const char* const kMessages[] = {"hello", "world"}; // allowed
}
// allowed: constexpr guarantees trivial destructor
constexpr std::array<int, 3> kArray = {{1, 2, 3}};
// bad: non-trivial destructor
const string kFoo = "foo";
// bad for the same reason, even though kBar is a reference (the
// rule also applies to lifetime-extended temporary objects)
const string& kBar = StrCat("a", "b", "c");
void bar() {
// bad: non-trivial destructor
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static std::map<int, int> kData = {{1, 0}, {2, 0}, {3, 0}};
}
Note that references are not objects, and thus they are not subject to the constraints on destructibility. The constraint on dynamic initialization
still applies, though. In particular, a function-local static reference of the form static T& t = *new T; is allowed.
Decision on initialization
Initialization is a more complex topic. This is because we must not only consider whether class constructors execute, but we must also consider
the evaluation of the initializer:
int n = 5; // fine
int m = f(); // ? (depends on f)
Foo x; // ? (depends on Foo::Foo)
Bar y = g(); // ? (depends on g and on Bar::Bar)
All but the first statement expose us to indeterminate initialization ordering.
The concept we are looking for is called constant initialization in the formal language of the C++ standard. It means that the initializing
expression is a constant expression, and if the object is initialized by a constructor call, then the constructor must be specified as constexpr,
too:
struct Foo { constexpr Foo(int) {} };
int n = 5; // fine, 5 is a constant expression
Foo x(2); // fine, 2 is a constant expression and the chosen constructor is constexpr
Foo a[] = { Foo(1), Foo(2), Foo(3) }; // fine
Constant initialization is always allowed. Constant initialization of static storage duration variables should be marked with constexpr or where
possible the ABSL_CONST_INIT attribute. Any non-local static storage duration variable that is not so marked should be presumed to have
dynamic initialization, and reviewed very carefully.
By contrast, the following initializations are problematic:
time_t time(time_t*); // not constexpr!
int f(); // not constexpr!
struct Bar { Bar() {} };
struct Bar { Bar() {} };
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struct Bar { Bar() {} };
time_t m = time(nullptr); // initializing expression not a constant expression
Foo y(f()); // ditto
Bar b; // chosen constructor Bar::Bar() not constexpr
Dynamic initialization of nonlocal variables is discouraged, and in general it is forbidden. However, we do permit it if no aspect of the program
depends on the sequencing of this initialization with respect to all other initializations. Under those restrictions, the ordering of the initialization
does not make an observable difference. For example:
int p = getpid(); // allowed, as long as no other static variable
// uses p in its own initialization
Dynamic initialization of static local variables is allowed (and common).
Common patterns
Global strings: if you require a global or static string constant, consider using a simple character array, or a char pointer to the first
element of a string literal. String literals have static storage duration already and are usually sufficient.
Maps, sets, and other dynamic containers: if you require a static, fixed collection, such as a set to search against or a lookup table, you
cannot use the dynamic containers from the standard library as a static variable, since they have non-trivial destructors. Instead,
consider a simple array of trivial types, e.g. an array of arrays of ints (for a "map from int to int"), or an array of pairs (e.g. pairs of int
and const char*). For small collections, linear search is entirely sufficient (and efficient, due to memory locality). If necessary, keep
the collection in sorted order and use a binary search algorithm. If you do really prefer a dynamic container from the standard library,
consider using a function-local static pointer, as described below.
Smart pointers (unique_ptr, shared_ptr): smart pointers execute cleanup during destruction and are therefore forbidden. Consider
whether your use case fits into one of the other patterns described in this section. One simple solution is to use a plain pointer to a
dynamically allocated object and never delete it (see last item).
Static variables of custom types: if you require static, constant data of a type that you need to define yourself, give the type a trivial
destructor and a constexpr constructor.
If all else fails, you can create an object dynamically and never delete it by binding the pointer to a function-local static pointer variable:
static const auto* const impl = new T(args...); (If the initialization is more complex, it can be moved into a function or
lambda expression.)
thread_local Variables
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thread_local variables that aren't declared inside a function must be initialized with a true compile-time constant, and this must be enforced
by using the ABSL_CONST_INIT attribute. Prefer thread_local over other ways of defining thread-local data.
Definition:
Starting with C++11, variables can be declared with the thread_local specifier:
thread_local Foo foo = ...;
Such a variable is actually a collection of objects, so that when different threads access it, they are actually accessing different objects.
thread_local variables are much like static storage duration variables in many respects. For instance, they can be declared at namespace
scope, inside functions, or as static class members, but not as ordinary class members.
thread_local variable instances are initialized much like static variables, except that they must be initialized separately for each thread,
rather than once at program startup. This means that thread_local variables declared within a function are safe, but other thread_local
variables are subject to the same initialization-order issues as static variables (and more besides).
thread_local variable instances are destroyed when their thread terminates, so they do not have the destruction-order issues of static
variables.
Pros:
Thread-local data is inherently safe from races (because only one thread can ordinarily access it), which makes thread_local useful
for concurrent programming.
thread_local is the only standard-supported way of creating thread-local data.
Cons:
Accessing a thread_local variable may trigger execution of an unpredictable and uncontrollable amount of other code.
thread_local variables are effectively global variables, and have all the drawbacks of global variables other than lack of thread-
safety.
The memory consumed by a thread_local variable scales with the number of running threads (in the worst case), which can be quite
large in a program.
An ordinary class member cannot be thread_local.
thread_local may not be as efficient as certain compiler intrinsics.
Decision:
thread_local variables inside a function have no safety concerns, so they can be used without restriction. Note that you can use a function-
scope thread_local to simulate a class- or namespace-scope thread_local by defining a function or static method that exposes it:
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Foo& MyThreadLocalFoo() {
thread_local Foo result = ComplicatedInitialization();
return result;
}
thread_local variables at class or namespace scope must be initialized with a true compile-time constant (i.e. they must have no dynamic
initialization). To enforce this, thread_local variables at class or namespace scope must be annotated with ABSL_CONST_INIT (or
constexpr, but that should be rare):
ABSL_CONST_INIT thread_local Foo foo = ...;
thread_local should be preferred over other mechanisms for defining thread-local data.
Classes are the fundamental unit of code in C++. Naturally, we use them extensively. This section lists the main dos and don'ts you should
follow when writing a class.
Avoid virtual method calls in constructors, and avoid initialization that can fail if you can't signal an error.
Definition:
It is possible to perform arbitrary initialization in the body of the constructor.
Pros:
No need to worry about whether the class has been initialized or not.
Objects that are fully initialized by constructor call can be const and may also be easier to use with standard containers or algorithms.
Classes
Doing Work in Constructors
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Cons:
If the work calls virtual functions, these calls will not get dispatched to the subclass implementations. Future modification to your class
can quietly introduce this problem even if your class is not currently subclassed, causing much confusion.
There is no easy way for constructors to signal errors, short of crashing the program (not always appropriate) or using exceptions (which
are forbidden).
If the work fails, we now have an object whose initialization code failed, so it may be an unusual state requiring a bool IsValid()
state checking mechanism (or similar) which is easy to forget to call.
You cannot take the address of a constructor, so whatever work is done in the constructor cannot easily be handed off to, for example,
another thread.
Decision:
Constructors should never call virtual functions. If appropriate for your code , terminating the program may be an appropriate error handling
response. Otherwise, consider a factory function or Init() method as described in TotW #42 . Avoid Init() methods on objects with no
other states that affect which public methods may be called (semi-constructed objects of this form are particularly hard to work with correctly).
Do not define implicit conversions. Use the explicit keyword for conversion operators and single-argument constructors.
Definition:
Implicit conversions allow an object of one type (called the source type) to be used where a different type (called the destination type) is
expected, such as when passing an int argument to a function that takes a double parameter.
In addition to the implicit conversions defined by the language, users can define their own, by adding appropriate members to the class
definition of the source or destination type. An implicit conversion in the source type is defined by a type conversion operator named after the
destination type (e.g. operator bool()). An implicit conversion in the destination type is defined by a constructor that can take the source
type as its only argument (or only argument with no default value).
The explicit keyword can be applied to a constructor or (since C++11) a conversion operator, to ensure that it can only be used when the
destination type is explicit at the point of use, e.g. with a cast. This applies not only to implicit conversions, but to C++11's list initialization
syntax:
class Foo {
explicit Foo(int x, double y);
...
Implicit Conversions
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};
void Func(Foo f);
Func({42, 3.14}); // Error
This kind of code isn't technically an implicit conversion, but the language treats it as one as far as explicit is concerned.
Pros:
Implicit conversions can make a type more usable and expressive by eliminating the need to explicitly name a type when it's obvious.
Implicit conversions can be a simpler alternative to overloading, such as when a single function with a string_view parameter takes
the place of separate overloads for string and const char*.
List initialization syntax is a concise and expressive way of initializing objects.
Cons:
Implicit conversions can hide type-mismatch bugs, where the destination type does not match the user's expectation, or the user is
unaware that any conversion will take place.
Implicit conversions can make code harder to read, particularly in the presence of overloading, by making it less obvious what code is
actually getting called.
Constructors that take a single argument may accidentally be usable as implicit type conversions, even if they are not intended to do so.
When a single-argument constructor is not marked explicit, there's no reliable way to tell whether it's intended to define an implicit
conversion, or the author simply forgot to mark it.
It's not always clear which type should provide the conversion, and if they both do, the code becomes ambiguous.
List initialization can suffer from the same problems if the destination type is implicit, particularly if the list has only a single element.
Decision:
Type conversion operators, and constructors that are callable with a single argument, must be marked explicit in the class definition. As an
exception, copy and move constructors should not be explicit, since they do not perform type conversion. Implicit conversions can
sometimes be necessary and appropriate for types that are designed to transparently wrap other types. In that case, contact your project leads
to request a waiver of this rule.
Constructors that cannot be called with a single argument may omit explicit. Constructors that take a single std::initializer_list
parameter should also omit explicit, in order to support copy-initialization (e.g. MyType m = {1, 2};).
Copyable and Movable Types
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A class's public API should make explicit whether the class is copyable, move-only, or neither copyable nor movable. Support copying and/or
moving if these operations are clear and meaningful for your type.
Definition:
A movable type is one that can be initialized and assigned from temporaries.
A copyable type is one that can be initialized or assigned from any other object of the same type (so is also movable by definition), with the
stipulation that the value of the source does not change. std::unique_ptr<int> is an example of a movable but not copyable type (since
the value of the source std::unique_ptr<int> must be modified during assignment to the destination). int and string are examples of
movable types that are also copyable. (For int, the move and copy operations are the same; for string, there exists a move operation that is
less expensive than a copy.)
For user-defined types, the copy behavior is defined by the copy constructor and the copy-assignment operator. Move behavior is defined by
the move constructor and the move-assignment operator, if they exist, or by the copy constructor and the copy-assignment operator otherwise.
The copy/move constructors can be implicitly invoked by the compiler in some situations, e.g. when passing objects by value.
Pros:
Objects of copyable and movable types can be passed and returned by value, which makes APIs simpler, safer, and more general. Unlike
when passing objects by pointer or reference, there's no risk of confusion over ownership, lifetime, mutability, and similar issues, and no need
to specify them in the contract. It also prevents non-local interactions between the client and the implementation, which makes them easier to
understand, maintain, and optimize by the compiler. Further, such objects can be used with generic APIs that require pass-by-value, such as
most containers, and they allow for additional flexibility in e.g., type composition.
Copy/move constructors and assignment operators are usually easier to define correctly than alternatives like Clone(), CopyFrom() or
Swap(), because they can be generated by the compiler, either implicitly or with = default. They are concise, and ensure that all data
members are copied. Copy and move constructors are also generally more efficient, because they don't require heap allocation or separate
initialization and assignment steps, and they're eligible for optimizations such as copy elision.
Move operations allow the implicit and efficient transfer of resources out of rvalue objects. This allows a plainer coding style in some cases.
Cons:
Some types do not need to be copyable, and providing copy operations for such types can be confusing, nonsensical, or outright incorrect.
Types representing singleton objects (Registerer), objects tied to a specific scope (Cleanup), or closely coupled to object identity (Mutex)
cannot be copied meaningfully. Copy operations for base class types that are to be used polymorphically are hazardous, because use of them
can lead to object slicing. Defaulted or carelessly-implemented copy operations can be incorrect, and the resulting bugs can be confusing and
difficult to diagnose.
Copy constructors are invoked implicitly, which makes the invocation easy to miss. This may cause confusion for programmers used to
languages where pass-by-reference is conventional or mandatory. It may also encourage excessive copying, which can cause performance
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problems.
Decision:
Every class's public interface should make explicit which copy and move operations the class supports. This should usually take the form of
explicitly declaring and/or deleting the appropriate operations in the public section of the declaration.
Specifically, a copyable class should explicitly declare the copy operations, a move-only class should explicitly declare the move operations,
and a non-copyable/movable class should explicitly delete the copy operations. Explicitly declaring or deleting all four copy/move operations is
permitted, but not required. If you provide a copy or move assignment operator, you must also provide the corresponding constructor.
class Copyable {
public:
Copyable(const Copyable& rhs) = default;
Copyable& operator=(const Copyable& rhs) = default;
// The implicit move operations are suppressed by the declarations above.
};
class MoveOnly {
public:
MoveOnly(MoveOnly&& rhs);
MoveOnly& operator=(MoveOnly&& rhs);
// The copy operations are implicitly deleted, but you can
// spell that out explicitly if you want:
MoveOnly(const MoveOnly&) = delete;
MoveOnly& operator=(const MoveOnly&) = delete;
};
class NotCopyableOrMovable {
public:
// Not copyable or movable
NotCopyableOrMovable(const NotCopyableOrMovable&) = delete;
NotCopyableOrMovable& operator=(const NotCopyableOrMovable&)
= delete;
// The move operations are implicitly disabled, but you can
// spell that out explicitly if you want:
NotCopyableOrMovable(NotCopyableOrMovable&&) = delete;
NotCopyableOrMovable& operator=(NotCopyableOrMovable&&)
= delete;
= delete;
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delete;
};
These declarations/deletions can be omitted only if they are obvious: for example, if a base class isn't copyable or movable, derived classes
naturally won't be either. Similarly, a struct's copyability/movability is normally determined by the copyability/movability of its data members (this
does not apply to classes because in Google code their data members are not public). Note that if you explicitly declare or delete any of the
copy/move operations, the others are not obvious, and so this paragraph does not apply (in particular, the rules in this section that apply to
"classes" also apply to structs that declare or delete any copy/move operations).
A type should not be copyable/movable if the meaning of copying/moving is unclear to a casual user, or if it incurs unexpected costs. Move
operations for copyable types are strictly a performance optimization and are a potential source of bugs and complexity, so avoid defining them
unless they are significantly more efficient than the corresponding copy operations. If your type provides copy operations, it is recommended
that you design your class so that the default implementation of those operations is correct. Remember to review the correctness of any
defaulted operations as you would any other code.
Due to the risk of slicing, prefer to avoid providing a public assignment operator or copy/move constructor for a class that's intended to be
derived from (and prefer to avoid deriving from a class with such members). If your base class needs to be copyable, provide a public virtual
Clone() method, and a protected copy constructor that derived classes can use to implement it.
Use a struct only for passive objects that carry data; everything else is a class.
The struct and class keywords behave almost identically in C++. We add our own semantic meanings to each keyword, so you should use
the appropriate keyword for the data-type you're defining.
structs should be used for passive objects that carry data, and may have associated constants, but lack any functionality other than
access/setting the data members. The accessing/setting of fields is done by directly accessing the fields rather than through method
invocations. Methods should not provide behavior but should only be used to set up the data members, e.g., constructor, destructor,
Initialize(), Reset(), Validate().
If more functionality is required, a class is more appropriate. If in doubt, make it a class.
For consistency with STL, you can use struct instead of class for functors and traits.
Note that member variables in structs and classes have different naming rules.
Structs vs. Classes
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Composition is often more appropriate than inheritance. When using inheritance, make it public.
Definition:
When a sub-class inherits from a base class, it includes the definitions of all the data and operations that the parent base class defines. In
practice, inheritance is used in two major ways in C++: implementation inheritance, in which actual code is inherited by the child, and interface
inheritance, in which only method names are inherited.
Pros:
Implementation inheritance reduces code size by re-using the base class code as it specializes an existing type. Because inheritance is a
compile-time declaration, you and the compiler can understand the operation and detect errors. Interface inheritance can be used to
programmatically enforce that a class expose a particular API. Again, the compiler can detect errors, in this case, when a class does not define
a necessary method of the API.
Cons:
For implementation inheritance, because the code implementing a sub-class is spread between the base and the sub-class, it can be more
difficult to understand an implementation. The sub-class cannot override functions that are not virtual, so the sub-class cannot change
implementation.
Decision:
All inheritance should be public. If you want to do private inheritance, you should be including an instance of the base class as a member
instead.
Do not overuse implementation inheritance. Composition is often more appropriate. Try to restrict use of inheritance to the "is-a" case: Bar
subclasses Foo if it can reasonably be said that Bar "is a kind of" Foo.
Limit the use of protected to those member functions that might need to be accessed from subclasses. Note that data members should be
private.
Explicitly annotate overrides of virtual functions or virtual destructors with exactly one of an override or (less frequently) final specifier. Do
not use virtual when declaring an override. Rationale: A function or destructor marked override or final that is not an override of a base
class virtual function will not compile, and this helps catch common errors. The specifiers serve as documentation; if no specifier is present, the
reader has to check all ancestors of the class in question to determine if the function or destructor is virtual or not.
Inheritance
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Only very rarely is multiple implementation inheritance actually useful. We allow multiple inheritance only when at most one of the base classes
has an implementation; all other base classes must be pure interface classes tagged with the Interface suffix.
Definition:
Multiple inheritance allows a sub-class to have more than one base class. We distinguish between base classes that are pure interfaces and
those that have an implementation.
Pros:
Multiple implementation inheritance may let you re-use even more code than single inheritance (see Inheritance).
Cons:
Only very rarely is multiple implementation inheritance actually useful. When multiple implementation inheritance seems like the solution, you
can usually find a different, more explicit, and cleaner solution.
Decision:
Multiple inheritance is allowed only when all superclasses, with the possible exception of the first one, are pure interfaces. In order to ensure
that they remain pure interfaces, they must end with the Interface suffix.
Note:
There is an exception to this rule on Windows.
Classes that satisfy certain conditions are allowed, but not required, to end with an Interface suffix.
Definition:
A class is a pure interface if it meets the following requirements:
Multiple Inheritance
Interfaces
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It has only public pure virtual ("= 0") methods and static methods (but see below for destructor).
It may not have non-static data members.
It need not have any constructors defined. If a constructor is provided, it must take no arguments and it must be protected.
If it is a subclass, it may only be derived from classes that satisfy these conditions and are tagged with the Interface suffix.
An interface class can never be directly instantiated because of the pure virtual method(s) it declares. To make sure all implementations of the
interface can be destroyed correctly, the interface must also declare a virtual destructor (in an exception to the first rule, this should not be
pure). See Stroustrup, The C++ Programming Language, 3rd edition, section 12.4 for details.
Pros:
Tagging a class with the Interface suffix lets others know that they must not add implemented methods or non static data members. This is
particularly important in the case of multiple inheritance. Additionally, the interface concept is already well-understood by Java programmers.
Cons:
The Interface suffix lengthens the class name, which can make it harder to read and understand. Also, the interface property may be
considered an implementation detail that shouldn't be exposed to clients.
Decision:
A class may end with Interface only if it meets the above requirements. We do not require the converse, however: classes that meet the
above requirements are not required to end with Interface.
Overload operators judiciously. Do not create user-defined literals.
Definition:
C++ permits user code to declare overloaded versions of the built-in operators using the operator keyword, so long as one of the parameters
is a user-defined type. The operator keyword also permits user code to define new kinds of literals using operator"", and to define type-
conversion functions such as operator bool().
Pros:
Operator overloading can make code more concise and intuitive by enabling user-defined types to behave the same as built-in types.
Overloaded operators are the idiomatic names for certain operations (e.g. ==, <, =, and <<), and adhering to those conventions can make user-
defined types more readable and enable them to interoperate with libraries that expect those names.
Operator Overloading
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User-defined literals are a very concise notation for creating objects of user-defined types.
Cons:
Providing a correct, consistent, and unsurprising set of operator overloads requires some care, and failure to do so can lead to confusion
and bugs.
Overuse of operators can lead to obfuscated code, particularly if the overloaded operator's semantics don't follow convention.
The hazards of function overloading apply just as much to operator overloading, if not more so.
Operator overloads can fool our intuition into thinking that expensive operations are cheap, built-in operations.
Finding the call sites for overloaded operators may require a search tool that's aware of C++ syntax, rather than e.g. grep.
If you get the argument type of an overloaded operator wrong, you may get a different overload rather than a compiler error. For
example, foo < bar may do one thing, while &foo < &bar does something totally different.
Certain operator overloads are inherently hazardous. Overloading unary & can cause the same code to have different meanings
depending on whether the overload declaration is visible. Overloads of &&, ||, and , (comma) cannot match the evaluation-order
semantics of the built-in operators.
Operators are often defined outside the class, so there's a risk of different files introducing different definitions of the same operator. If
both definitions are linked into the same binary, this results in undefined behavior, which can manifest as subtle run-time bugs.
User-defined literals allow the creation of new syntactic forms that are unfamiliar even to experienced C++ programmers.
Decision:
Define overloaded operators only if their meaning is obvious, unsurprising, and consistent with the corresponding built-in operators. For
example, use | as a bitwise- or logical-or, not as a shell-style pipe.
Define operators only on your own types. More precisely, define them in the same headers, .cc files, and namespaces as the types they
operate on. That way, the operators are available wherever the type is, minimizing the risk of multiple definitions. If possible, avoid defining
operators as templates, because they must satisfy this rule for any possible template arguments. If you define an operator, also define any
related operators that make sense, and make sure they are defined consistently. For example, if you overload <, overload all the comparison
operators, and make sure < and > never return true for the same arguments.
Prefer to define non-modifying binary operators as non-member functions. If a binary operator is defined as a class member, implicit
conversions will apply to the right-hand argument, but not the left-hand one. It will confuse your users if a < b compiles but b < a doesn't.
Don't go out of your way to avoid defining operator overloads. For example, prefer to define ==, =, and <<, rather than Equals(),
CopyFrom(), and PrintTo(). Conversely, don't define operator overloads just because other libraries expect them. For example, if your type
doesn't have a natural ordering, but you want to store it in a std::set, use a custom comparator rather than overloading <.
Do not overload &&, ||, , (comma), or unary &. Do not overload operator"", i.e. do not introduce user-defined literals.
Type conversion operators are covered in the section on implicit conversions. The = operator is covered in the section on copy constructors.
Overloading << for use with streams is covered in the section on streams. See also the rules on function overloading, which apply to operator
overloading as well.
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Make data members private, unless they are static const (and follow the naming convention for constants).
For technical reasons, we allow data members of a test fixture class to be protected when using Google Test).
Group similar declarations together, placing public parts earlier.
A class definition should usually start with a public: section, followed by protected:, then private:. Omit sections that would be empty.
Within each section, generally prefer grouping similar kinds of declarations together, and generally prefer the following order: types (including
typedef, using, and nested structs and classes), constants, factory functions, constructors, assignment operators, destructor, all other
methods, data members.
Do not put large method definitions inline in the class definition. Usually, only trivial or performance-critical, and very short, methods may be
defined inline. See Inline Functions for more details.
Prefer using return values rather than output parameters. If output-only parameters are used they should appear after input parameters.
Access Control
Declaration Order
Functions
Output Parameters
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The output of a C++ function is naturally provided via a return value and sometimes via output parameters.
Prefer using return values instead of output parameters since they improve readability and oftentimes provide the same or better performance.
Parameters are either input to the function, output from the function, or both. Input parameters are usually values or const references, while
output and input/output parameters will be pointers to non-const.
When ordering function parameters, put all input-only parameters before any output parameters. In particular, do not add new parameters to
the end of the function just because they are new; place new input-only parameters before the output parameters.
This is not a hard-and-fast rule. Parameters that are both input and output (often classes/structs) muddy the waters, and, as always,
consistency with related functions may require you to bend the rule.
Prefer small and focused functions.
We recognize that long functions are sometimes appropriate, so no hard limit is placed on functions length. If a function exceeds about 40
lines, think about whether it can be broken up without harming the structure of the program.
Even if your long function works perfectly now, someone modifying it in a few months may add new behavior. This could result in bugs that are
hard to find. Keeping your functions short and simple makes it easier for other people to read and modify your code.
You could find long and complicated functions when working with some code. Do not be intimidated by modifying existing code: if working with
such a function proves to be difficult, you find that errors are hard to debug, or you want to use a piece of it in several different contexts,
consider breaking up the function into smaller and more manageable pieces.
All parameters passed by reference must be labeled const.
Definition:
Write Short Functions
Reference Arguments
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In C, if a function needs to modify a variable, the parameter must use a pointer, eg int foo(int *pval). In C++, the function can
alternatively declare a reference parameter: int foo(int &val).
Pros:
Defining a parameter as reference avoids ugly code like (*pval)++. Necessary for some applications like copy constructors. Makes it clear,
unlike with pointers, that a null pointer is not a possible value.
Cons:
References can be confusing, as they have value syntax but pointer semantics.
Decision:
Within function parameter lists all references must be const:
void Foo(const string &in, string *out);
In fact it is a very strong convention in Google code that input arguments are values or const references while output arguments are pointers.
Input parameters may be const pointers, but we never allow non-const reference parameters except when required by convention, e.g.,
swap().
However, there are some instances where using const T* is preferable to const T& for input parameters. For example:
You want to pass in a null pointer.
The function saves a pointer or reference to the input.
Remember that most of the time input parameters are going to be specified as const T&. Using const T* instead communicates to the
reader that the input is somehow treated differently. So if you choose const T* rather than const T&, do so for a concrete reason; otherwise
it will likely confuse readers by making them look for an explanation that doesn't exist.
Use overloaded functions (including constructors) only if a reader looking at a call site can get a good idea of what is happening without having
to first figure out exactly which overload is being called.
Definition:
Function Overloading
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You may write a function that takes a const string& and overload it with another that takes const char*. However, in this case consider
std::string_view instead.
class MyClass {
public:
void Analyze(const string &text);
void Analyze(const char *text, size_t textlen);
};
Pros:
Overloading can make code more intuitive by allowing an identically-named function to take different arguments. It may be necessary for
templatized code, and it can be convenient for Visitors.
Cons:
If a function is overloaded by the argument types alone, a reader may have to understand C++'s complex matching rules in order to tell what's
going on. Also many people are confused by the semantics of inheritance if a derived class overrides only some of the variants of a function.
Decision:
You may overload a function when there are no semantic differences between variants, or when the differences are clear at the callsite.
If you are overloading a function to support variable number of arguments of the same type, consider making it take a std::vector so that
the user can use an initializer list to specify the arguments.
Default arguments are allowed on non-virtual functions when the default is guaranteed to always have the same value. Follow the same
restrictions as for function overloading, and prefer overloaded functions if the readability gained with default arguments doesn't outweigh the
downsides below.
Pros:
Often you have a function that uses default values, but occasionally you want to override the defaults. Default parameters allow an easy way to
do this without having to define many functions for the rare exceptions. Compared to overloading the function, default arguments have a
cleaner syntax, with less boilerplate and a clearer distinction between 'required' and 'optional' arguments.
Default Arguments
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Cons:
Defaulted arguments are another way to achieve the semantics of overloaded functions, so all the reasons not to overload functions apply.
The defaults for arguments in a virtual function call are determined by the static type of the target object, and there's no guarantee that all
overrides of a given function declare the same defaults.
Default parameters are re-evaluated at each call site, which can bloat the generated code. Readers may also expect the default's value to be
fixed at the declaration instead of varying at each call.
Function pointers are confusing in the presence of default arguments, since the function signature often doesn't match the call signature.
Adding function overloads avoids these problems.
Decision:
Default arguments are banned on virtual functions, where they don't work properly, and in cases where the specified default might not evaluate
to the same value depending on when it was evaluated. (For example, don't write void f(int n = counter++);.)
In some other cases, default arguments can improve the readability of their function declarations enough to overcome the downsides above, so
they are allowed. When in doubt, use overloads.
Use trailing return types only where using the ordinary syntax (leading return types) is impractical or much less readable.
Definition:
C++ allows two different forms of function declarations. In the older form, the return type appears before the function name. For example:
int foo(int x);
The new form, introduced in C++11, uses the auto keyword before the function name and a trailing return type after the argument list. For
example, the declaration above could equivalently be written:
auto foo(int x) -> int;
Trailing Return Type Syntax
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The trailing return type is in the function's scope. This doesn't make a difference for a simple case like int but it matters for more complicated
cases, like types declared in class scope or types written in terms of the function parameters.
Pros:
Trailing return types are the only way to explicitly specify the return type of a lambda expression. In some cases the compiler is able to deduce
a lambda's return type, but not in all cases. Even when the compiler can deduce it automatically, sometimes specifying it explicitly would be
clearer for readers.
Sometimes it's easier and more readable to specify a return type after the function's parameter list has already appeared. This is particularly
true when the return type depends on template parameters. For example:
template <typename T, typename U>
auto add(T t, U u) -> decltype(t + u);
versus
template <typename T, typename U>
decltype(declval<T&>() + declval<U&>()) add(T t, U u);
Cons:
Trailing return type syntax is relatively new and it has no analogue in C++-like languages like C and Java, so some readers may find it
unfamiliar.
Existing code bases have an enormous number of function declarations that aren't going to get changed to use the new syntax, so the realistic
choices are using the old syntax only or using a mixture of the two. Using a single version is better for uniformity of style.
Decision:
In most cases, continue to use the older style of function declaration where the return type goes before the function name. Use the new trailing-
return-type form only in cases where it's required (such as lambdas) or where, by putting the type after the function's parameter list, it allows
you to write the type in a much more readable way. The latter case should be rare; it's mostly an issue in fairly complicated template code,
which is discouraged in most cases.
Google-Specific Magic
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There are various tricks and utilities that we use to make C++ code more robust, and various ways we use C++ that may differ from what you
see elsewhere.
Prefer to have single, fixed owners for dynamically allocated objects. Prefer to transfer ownership with smart pointers.
Definition:
"Ownership" is a bookkeeping technique for managing dynamically allocated memory (and other resources). The owner of a dynamically
allocated object is an object or function that is responsible for ensuring that it is deleted when no longer needed. Ownership can sometimes be
shared, in which case the last owner is typically responsible for deleting it. Even when ownership is not shared, it can be transferred from one
piece of code to another.
"Smart" pointers are classes that act like pointers, e.g. by overloading the * and -> operators. Some smart pointer types can be used to
automate ownership bookkeeping, to ensure these responsibilities are met. std::unique_ptr is a smart pointer type introduced in C++11,
which expresses exclusive ownership of a dynamically allocated object; the object is deleted when the std::unique_ptr goes out of scope.
It cannot be copied, but can be moved to represent ownership transfer. std::shared_ptr is a smart pointer type that expresses shared
ownership of a dynamically allocated object. std::shared_ptrs can be copied; ownership of the object is shared among all copies, and the
object is deleted when the last std::shared_ptr is destroyed.
Pros:
It's virtually impossible to manage dynamically allocated memory without some sort of ownership logic.
Transferring ownership of an object can be cheaper than copying it (if copying it is even possible).
Transferring ownership can be simpler than 'borrowing' a pointer or reference, because it reduces the need to coordinate the lifetime of
the object between the two users.
Smart pointers can improve readability by making ownership logic explicit, self-documenting, and unambiguous.
Smart pointers can eliminate manual ownership bookkeeping, simplifying the code and ruling out large classes of errors.
For const objects, shared ownership can be a simple and efficient alternative to deep copying.
Cons:
Ownership must be represented and transferred via pointers (whether smart or plain). Pointer semantics are more complicated than
value semantics, especially in APIs: you have to worry not just about ownership, but also aliasing, lifetime, and mutability, among other
issues.
Ownership and Smart Pointers
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The performance costs of value semantics are often overestimated, so the performance benefits of ownership transfer might not justify
the readability and complexity costs.
APIs that transfer ownership force their clients into a single memory management model.
Code using smart pointers is less explicit about where the resource releases take place.
std::unique_ptr expresses ownership transfer using C++11's move semantics, which are relatively new and may confuse some
programmers.
Shared ownership can be a tempting alternative to careful ownership design, obfuscating the design of a system.
Shared ownership requires explicit bookkeeping at run-time, which can be costly.
In some cases (e.g. cyclic references), objects with shared ownership may never be deleted.
Smart pointers are not perfect substitutes for plain pointers.
Decision:
If dynamic allocation is necessary, prefer to keep ownership with the code that allocated it. If other code needs access to the object, consider
passing it a copy, or passing a pointer or reference without transferring ownership. Prefer to use std::unique_ptr to make ownership
transfer explicit. For example:
std::unique_ptr<Foo> FooFactory();
void FooConsumer(std::unique_ptr<Foo> ptr);
Do not design your code to use shared ownership without a very good reason. One such reason is to avoid expensive copy operations, but you
should only do this if the performance benefits are significant, and the underlying object is immutable (i.e. std::shared_ptr<const Foo>).
If you do use shared ownership, prefer to use std::shared_ptr.
Never use std::auto_ptr. Instead, use std::unique_ptr.
Use cpplint.py to detect style errors.
cpplint.py is a tool that reads a source file and identifies many style errors. It is not perfect, and has both false positives and false
negatives, but it is still a valuable tool. False positives can be ignored by putting // NOLINT at the end of the line or // NOLINTNEXTLINE in
the previous line.
Some projects have instructions on how to run cpplint.py from their project tools. If the project you are contributing to does not, you can
download cpplint.py separately.
cpplint
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Use rvalue references only to define move constructors and move assignment operators, or for perfect forwarding.
Definition:
Rvalue references are a type of reference that can only bind to temporary objects. The syntax is similar to traditional reference syntax. For
example, void f(string&& s); declares a function whose argument is an rvalue reference to a string.
Pros:
Defining a move constructor (a constructor taking an rvalue reference to the class type) makes it possible to move a value instead of
copying it. If v1 is a std::vector<string>, for example, then auto v2(std::move(v1)) will probably just result in some simple
pointer manipulation instead of copying a large amount of data. In some cases this can result in a major performance improvement.
Rvalue references make it possible to write a generic function wrapper that forwards its arguments to another function, and works
whether or not its arguments are temporary objects. (This is sometimes called "perfect forwarding".)
Rvalue references make it possible to implement types that are movable but not copyable, which can be useful for types that have no
sensible definition of copying but where you might still want to pass them as function arguments, put them in containers, etc.
std::move is necessary to make effective use of some standard-library types, such as std::unique_ptr.
Cons:
Rvalue references are a relatively new feature (introduced as part of C++11), and not yet widely understood. Rules like reference
collapsing, and automatic synthesis of move constructors, are complicated.
Decision:
Use rvalue references only to define move constructors and move assignment operators (as described in Copyable and Movable Types) and,
in conjunction with std::forward, to support perfect forwarding. You may use std::move to express moving a value from one object to
another rather than copying it.
Other C++ Features
Rvalue References
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We allow use of friend classes and functions, within reason.
Friends should usually be defined in the same file so that the reader does not have to look in another file to find uses of the private members of
a class. A common use of friend is to have a FooBuilder class be a friend of Foo so that it can construct the inner state of Foo correctly,
without exposing this state to the world. In some cases it may be useful to make a unittest class a friend of the class it tests.
Friends extend, but do not break, the encapsulation boundary of a class. In some cases this is better than making a member public when you
want to give only one other class access to it. However, most classes should interact with other classes solely through their public members.
We do not use C++ exceptions.
Pros:
Exceptions allow higher levels of an application to decide how to handle "can't happen" failures in deeply nested functions, without the
obscuring and error-prone bookkeeping of error codes.
Exceptions are used by most other modern languages. Using them in C++ would make it more consistent with Python, Java, and the
C++ that others are familiar with.
Some third-party C++ libraries use exceptions, and turning them off internally makes it harder to integrate with those libraries.
Exceptions are the only way for a constructor to fail. We can simulate this with a factory function or an Init() method, but these
require heap allocation or a new "invalid" state, respectively.
Exceptions are really handy in testing frameworks.
Cons:
When you add a throw statement to an existing function, you must examine all of its transitive callers. Either they must make at least
the basic exception safety guarantee, or they must never catch the exception and be happy with the program terminating as a result. For
instance, if f() calls g() calls h(), and h throws an exception that f catches, g has to be careful or it may not clean up properly.
More generally, exceptions make the control flow of programs difficult to evaluate by looking at code: functions may return in places you
don't expect. This causes maintainability and debugging difficulties. You can minimize this cost via some rules on how and where
exceptions can be used, but at the cost of more that a developer needs to know and understand.
Friends
Exceptions
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Exception safety requires both RAII and different coding practices. Lots of supporting machinery is needed to make writing correct
exception-safe code easy. Further, to avoid requiring readers to understand the entire call graph, exception-safe code must isolate logic
that writes to persistent state into a "commit" phase. This will have both benefits and costs (perhaps where you're forced to obfuscate
code to isolate the commit). Allowing exceptions would force us to always pay those costs even when they're not worth it.
Turning on exceptions adds data to each binary produced, increasing compile time (probably slightly) and possibly increasing address
space pressure.
The availability of exceptions may encourage developers to throw them when they are not appropriate or recover from them when it's not
safe to do so. For example, invalid user input should not cause exceptions to be thrown. We would need to make the style guide even
longer to document these restrictions!
Decision:
On their face, the benefits of using exceptions outweigh the costs, especially in new projects. However, for existing code, the introduction of
exceptions has implications on all dependent code. If exceptions can be propagated beyond a new project, it also becomes problematic to
integrate the new project into existing exception-free code. Because most existing C++ code at Google is not prepared to deal with exceptions,
it is comparatively difficult to adopt new code that generates exceptions.
Given that Google's existing code is not exception-tolerant, the costs of using exceptions are somewhat greater than the costs in a new project.
The conversion process would be slow and error-prone. We don't believe that the available alternatives to exceptions, such as error codes and
assertions, introduce a significant burden.
Our advice against using exceptions is not predicated on philosophical or moral grounds, but practical ones. Because we'd like to use our
open-source projects at Google and it's difficult to do so if those projects use exceptions, we need to advise against exceptions in Google open-
source projects as well. Things would probably be different if we had to do it all over again from scratch.
This prohibition also applies to the exception handling related features added in C++11, such as std::exception_ptr and
std::nested_exception.
There is an exception to this rule (no pun intended) for Windows code.
Specify noexcept when it is useful and correct.
Definition:
The noexcept specifier is used to specify whether a function will throw exceptions or not. If an exception escapes from a function marked
noexcept, the program crashes via std::terminate.
noexcept
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The noexcept operator performs a compile-time check that returns true if an expression is declared to not throw any exceptions.
Pros:
Specifying move constructors as noexcept improves performance in some cases, e.g. std::vector<T>::resize() moves rather
than copies the objects if T's move constructor is noexcept.
Specifying noexcept on a function can trigger compiler optimizations in environments where exceptions are enabled, e.g. compiler
does not have to generate extra code for stack-unwinding, if it knows that no exceptions can be thrown due to a noexcept specifier.
Cons:
In projects following this guide that have exceptions disabled it is hard to ensure that noexcept specifiers are correct, and hard to
define what correctness even means.
It's hard, if not impossible, to undo noexcept because it eliminates a guarantee that callers may be relying on, in ways that are hard to
detect.
Decision:
You may use noexcept when it is useful for performance if it accurately reflects the intended semantics of your function, i.e. that if an
exception is somehow thrown from within the function body then it represents a fatal error. You can assume that noexcept on move
constructors has a meaningful performance benefit. If you think there is significant performance benefit from specifying noexcept on some
other function, please discuss it with your project leads.
Prefer unconditional noexcept if exceptions are completely disabled (i.e. most Google C++ environments). Otherwise, use conditional
noexcept specifiers with simple conditions, in ways that evaluate false only in the few cases where the function could potentially throw. The
tests might include type traits check on whether the involved operation might throw (e.g. std::is_nothrow_move_constructible for
move-constructing objects), or on whether allocation can throw (e.g. absl::default_allocator_is_nothrow for standard default
allocation). Note in many cases the only possible cause for an exception is allocation failure (we believe move constructors should not throw
except due to allocation failure), and there are many applications where it’s appropriate to treat memory exhaustion as a fatal error rather than
an exceptional condition that your program should attempt to recover from. Even for other potential failures you should prioritize interface
simplicity over supporting all possible exception throwing scenarios: instead of writing a complicated noexcept clause that depends on
whether a hash function can throw, for example, simply document that your component doesn’t support hash functions throwing and make it
unconditionally noexcept.
Avoid using Run Time Type Information (RTTI).
Definition:
Run-Time Type Information (RTTI)
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RTTI allows a programmer to query the C++ class of an object at run time. This is done by use of typeid or dynamic_cast.
Cons:
Querying the type of an object at run-time frequently means a design problem. Needing to know the type of an object at runtime is often an
indication that the design of your class hierarchy is flawed.
Undisciplined use of RTTI makes code hard to maintain. It can lead to type-based decision trees or switch statements scattered throughout the
code, all of which must be examined when making further changes.
Pros:
The standard alternatives to RTTI (described below) require modification or redesign of the class hierarchy in question. Sometimes such
modifications are infeasible or undesirable, particularly in widely-used or mature code.
RTTI can be useful in some unit tests. For example, it is useful in tests of factory classes where the test has to verify that a newly created
object has the expected dynamic type. It is also useful in managing the relationship between objects and their mocks.
RTTI is useful when considering multiple abstract objects. Consider
bool Base::Equal(Base* other) = 0;
bool Derived::Equal(Base* other) {
Derived* that = dynamic_cast<Derived*>(other);
if (that == nullptr)
return false;
...
}
Decision:
RTTI has legitimate uses but is prone to abuse, so you must be careful when using it. You may use it freely in unittests, but avoid it when
possible in other code. In particular, think twice before using RTTI in new code. If you find yourself needing to write code that behaves
differently based on the class of an object, consider one of the following alternatives to querying the type:
Virtual methods are the preferred way of executing different code paths depending on a specific subclass type. This puts the work within
the object itself.
If the work belongs outside the object and instead in some processing code, consider a double-dispatch solution, such as the Visitor
design pattern. This allows a facility outside the object itself to determine the type of class using the built-in type system.
When the logic of a program guarantees that a given instance of a base class is in fact an instance of a particular derived class, then a
dynamic_cast may be used freely on the object. Usually one can use a static_cast as an alternative in such situations.
Decision trees based on type are a strong indication that your code is on the wrong track.
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if (typeid(*data) == typeid(D1)) {
...
} else if (typeid(*data) == typeid(D2)) {
...
} else if (typeid(*data) == typeid(D3)) {
...
Code such as this usually breaks when additional subclasses are added to the class hierarchy. Moreover, when properties of a subclass
change, it is difficult to find and modify all the affected code segments.
Do not hand-implement an RTTI-like workaround. The arguments against RTTI apply just as much to workarounds like class hierarchies with
type tags. Moreover, workarounds disguise your true intent.
Use C++-style casts like static_cast<float>(double_value), or brace initialization for conversion of arithmetic types like
int64 y = int64{1} << 42. Do not use cast formats like int y = (int)x or int y = int(x) (but the latter is okay when invoking a
constructor of a class type).
Definition:
C++ introduced a different cast system from C that distinguishes the types of cast operations.
Pros:
The problem with C casts is the ambiguity of the operation; sometimes you are doing a conversion (e.g., (int)3.5) and sometimes you are
doing a cast (e.g., (int)"hello"). Brace initialization and C++ casts can often help avoid this ambiguity. Additionally, C++ casts are more
visible when searching for them.
Cons:
The C++-style cast syntax is verbose and cumbersome.
Decision:
Do not use C-style casts. Instead, use these C++-style casts when explicit type conversion is necessary.
Casting
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Use brace initialization to convert arithmetic types (e.g. int64{x}). This is the safest approach because code will not compile if
conversion can result in information loss. The syntax is also concise.
Use static_cast as the equivalent of a C-style cast that does value conversion, when you need to explicitly up-cast a pointer from a
class to its superclass, or when you need to explicitly cast a pointer from a superclass to a subclass. In this last case, you must be sure
your object is actually an instance of the subclass.
Use const_cast to remove the const qualifier (see const).
Use reinterpret_cast to do unsafe conversions of pointer types to and from integer and other pointer types. Use this only if you
know what you are doing and you understand the aliasing issues.
See the RTTI section for guidance on the use of dynamic_cast.
Use streams where appropriate, and stick to "simple" usages. Overload << for streaming only for types representing values, and write only the
user-visible value, not any implementation details.
Definition:
Streams are the standard I/O abstraction in C++, as exemplified by the standard header <iostream>. They are widely used in Google code,
but only for debug logging and test diagnostics.
Pros:
The << and >> stream operators provide an API for formatted I/O that is easily learned, portable, reusable, and extensible. printf, by
contrast, doesn't even support string, to say nothing of user-defined types, and is very difficult to use portably. printf also obliges you to
choose among the numerous slightly different versions of that function, and navigate the dozens of conversion specifiers.
Streams provide first-class support for console I/O via std::cin, std::cout, std::cerr, and std::clog. The C APIs do as well, but are
hampered by the need to manually buffer the input.
Cons:
Stream formatting can be configured by mutating the state of the stream. Such mutations are persistent, so the behavior of your code
can be affected by the entire previous history of the stream, unless you go out of your way to restore it to a known state every time other
code might have touched it. User code can not only modify the built-in state, it can add new state variables and behaviors through a
registration system.
It is difficult to precisely control stream output, due to the above issues, the way code and data are mixed in streaming code, and the use
of operator overloading (which may select a different overload than you expect).
Streams
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The practice of building up output through chains of << operators interferes with internationalization, because it bakes word order into
the code, and streams' support for localization is flawed.
The streams API is subtle and complex, so programmers must develop experience with it in order to use it effectively.
Resolving the many overloads of << is extremely costly for the compiler. When used pervasively in a large code base, it can consume as
much as 20% of the parsing and semantic analysis time.
Decision:
Use streams only when they are the best tool for the job. This is typically the case when the I/O is ad-hoc, local, human-readable, and targeted
at other developers rather than end-users. Be consistent with the code around you, and with the codebase as a whole; if there's an established
tool for your problem, use that tool instead. In particular, logging libraries are usually a better choice than std::cerr or std::clog for
diagnostic output, and the libraries in absl/strings or the equivalent are usually a better choice than std::stringstream.
Avoid using streams for I/O that faces external users or handles untrusted data. Instead, find and use the appropriate templating libraries to
handle issues like internationalization, localization, and security hardening.
If you do use streams, avoid the stateful parts of the streams API (other than error state), such as imbue(), xalloc(), and
register_callback(). Use explicit formatting functions (see e.g. absl/strings) rather than stream manipulators or formatting flags to
control formatting details such as number base, precision, or padding.
Overload << as a streaming operator for your type only if your type represents a value, and << writes out a human-readable string
representation of that value. Avoid exposing implementation details in the output of <<; if you need to print object internals for debugging, use
named functions instead (a method named DebugString() is the most common convention).
Use prefix form (++i) of the increment and decrement operators with iterators and other template objects.
Definition:
When a variable is incremented (++i or i++) or decremented (--i or i--) and the value of the expression is not used, one must decide
whether to preincrement (decrement) or postincrement (decrement).
Pros:
When the return value is ignored, the "pre" form (++i) is never less efficient than the "post" form (i++), and is often more efficient. This is
because post-increment (or decrement) requires a copy of i to be made, which is the value of the expression. If i is an iterator or other non-
scalar type, copying i could be expensive. Since the two types of increment behave the same when the value is ignored, why not just always
pre-increment?
Preincrement and Predecrement
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Cons:
The tradition developed, in C, of using post-increment when the expression value is not used, especially in for loops. Some find post-
increment easier to read, since the "subject" (i) precedes the "verb" (++), just like in English.
Decision:
For simple scalar (non-object) values there is no reason to prefer one form and we allow either. For iterators and other template types, use pre-
increment.
Use const whenever it makes sense. With C++11, constexpr is a better choice for some uses of const.
Definition:
Declared variables and parameters can be preceded by the keyword const to indicate the variables are not changed (e.g., const int foo).
Class functions can have the const qualifier to indicate the function does not change the state of the class member variables (e.g.,
class Foo { int Bar(char c) const; };).
Pros:
Easier for people to understand how variables are being used. Allows the compiler to do better type checking, and, conceivably, generate
better code. Helps people convince themselves of program correctness because they know the functions they call are limited in how they can
modify your variables. Helps people know what functions are safe to use without locks in multi-threaded programs.
Cons:
const is viral: if you pass a const variable to a function, that function must have const in its prototype (or the variable will need a
const_cast). This can be a particular problem when calling library functions.
Decision:
const variables, data members, methods and arguments add a level of compile-time type checking; it is better to detect errors as soon as
possible. Therefore we strongly recommend that you use const whenever it makes sense to do so:
If a function guarantees that it will not modify an argument passed by reference or by pointer, the corresponding function parameter
should be a reference-to-const (const T&) or pointer-to-const (const T*), respectively.
Use of const
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Declare methods to be const whenever possible. Accessors should almost always be const. Other methods should be const if they do
not modify any data members, do not call any non-const methods, and do not return a non-const pointer or non-const reference to a
data member.
Consider making data members const whenever they do not need to be modified after construction.
The mutable keyword is allowed but is unsafe when used with threads, so thread safety should be carefully considered first.
Where to put the const
Some people favor the form int const *foo to const int* foo. They argue that this is more readable because it's more consistent: it
keeps the rule that const always follows the object it's describing. However, this consistency argument doesn't apply in codebases with few
deeply-nested pointer expressions since most const expressions have only one const, and it applies to the underlying value. In such cases,
there's no consistency to maintain. Putting the const first is arguably more readable, since it follows English in putting the "adjective" (const)
before the "noun" (int).
That said, while we encourage putting const first, we do not require it. But be consistent with the code around you!
In C++11, use constexpr to define true constants or to ensure constant initialization.
Definition:
Some variables can be declared constexpr to indicate the variables are true constants, i.e. fixed at compilation/link time. Some functions and
constructors can be declared constexpr which enables them to be used in defining a constexpr variable.
Pros:
Use of constexpr enables definition of constants with floating-point expressions rather than just literals; definition of constants of user-defined
types; and definition of constants with function calls.
Cons:
Prematurely marking something as constexpr may cause migration problems if later on it has to be downgraded. Current restrictions on what is
allowed in constexpr functions and constructors may invite obscure workarounds in these definitions.
Use of constexpr
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Decision:
constexpr definitions enable a more robust specification of the constant parts of an interface. Use constexpr to specify true constants and
the functions that support their definitions. Avoid complexifying function definitions to enable their use with constexpr. Do not use
constexpr to force inlining.
Of the built-in C++ integer types, the only one used is int. If a program needs a variable of a different size, use a precise-width integer type
from <stdint.h>, such as int16_t. If your variable represents a value that could ever be greater than or equal to 2^31 (2GiB), use a 64-bit
type such as int64_t. Keep in mind that even if your value won't ever be too large for an int, it may be used in intermediate calculations
which may require a larger type. When in doubt, choose a larger type.
Definition:
C++ does not specify the sizes of integer types like int. Typically people assume that short is 16 bits, int is 32 bits, long is 32 bits and
long long is 64 bits.
Pros:
Uniformity of declaration.
Cons:
The sizes of integral types in C++ can vary based on compiler and architecture.
Decision:
<stdint.h> defines types like int16_t, uint32_t, int64_t, etc. You should always use those in preference to short,
unsigned long long and the like, when you need a guarantee on the size of an integer. Of the C integer types, only int should be used.
When appropriate, you are welcome to use standard types like size_t and ptrdiff_t.
We use int very often, for integers we know are not going to be too big, e.g., loop counters. Use plain old int for such things. You should
assume that an int is at least 32 bits, but don't assume that it has more than 32 bits. If you need a 64-bit integer type, use int64_t or
uint64_t.
For integers we know can be "big", use int64_t.
Integer Types
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You should not use the unsigned integer types such as uint32_t, unless there is a valid reason such as representing a bit pattern rather than
a number, or you need defined overflow modulo 2^N. In particular, do not use unsigned types to say a number will never be negative. Instead,
use assertions for this.
If your code is a container that returns a size, be sure to use a type that will accommodate any possible usage of your container. When in
doubt, use a larger type rather than a smaller type.
Use care when converting integer types. Integer conversions and promotions can cause undefined behavior, leading to security bugs and other
problems.
On Unsigned Integers
Unsigned integers are good for representing bitfields and modular arithmetic. Because of historical accident, the C++ standard also uses
unsigned integers to represent the size of containers - many members of the standards body believe this to be a mistake, but it is effectively
impossible to fix at this point. The fact that unsigned arithmetic doesn't model the behavior of a simple integer, but is instead defined by the
standard to model modular arithmetic (wrapping around on overflow/underflow), means that a significant class of bugs cannot be diagnosed by
the compiler. In other cases, the defined behavior impedes optimization.
That said, mixing signedness of integer types is responsible for an equally large class of problems. The best advice we can provide: try to use
iterators and containers rather than pointers and sizes, try not to mix signedness, and try to avoid unsigned types (except for representing
bitfields or modular arithmetic). Do not use an unsigned type merely to assert that a variable is non-negative.
Code should be 64-bit and 32-bit friendly. Bear in mind problems of printing, comparisons, and structure alignment.
Correct portable printf() conversion specifiers for some integral typedefs rely on macro expansions that we find unpleasant to use
and impractical to require (the PRI macros from <cinttypes>). Unless there is no reasonable alternative for your particular case, try to
avoid or even upgrade APIs that rely on the printf family. Instead use a library supporting typesafe numeric formatting, such as
StrCat or Substitute for fast simple conversions, or std::ostream.
Unfortunately, the PRI macros are the only portable way to specify a conversion for the standard bitwidth typedefs (e.g. int64_t,
uint64_t, int32_t, uint32_t, etc). Where possible, avoid passing arguments of types specified by bitwidth typedefs to printf-
64-bit Portability
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based APIs. Note that it is acceptable to use typedefs for which printf has dedicated length modifiers, such as size_t (z), ptrdiff_t
(t), and maxint_t (j).
Remember that sizeof(void *) != sizeof(int). Use intptr_t if you want a pointer-sized integer.
You may need to be careful with structure alignments, particularly for structures being stored on disk. Any class/structure with a
int64_t/uint64_t member will by default end up being 8-byte aligned on a 64-bit system. If you have such structures being shared
on disk between 32-bit and 64-bit code, you will need to ensure that they are packed the same on both architectures. Most compilers
offer a way to alter structure alignment. For gcc, you can use __attribute__((packed)). MSVC offers #pragma pack() and
__declspec(align()).
Use braced-initialization as needed to create 64-bit constants. For example:
int64_t my_value{0x123456789};
uint64_t my_mask{3ULL << 48};
Avoid defining macros, especially in headers; prefer inline functions, enums, and const variables. Name macros with a project-specific prefix.
Do not use macros to define pieces of a C++ API.
Macros mean that the code you see is not the same as the code the compiler sees. This can introduce unexpected behavior, especially since
macros have global scope.
The problems introduced by macros are especially severe when they are used to define pieces of a C++ API, and still more so for public APIs.
Every error message from the compiler when developers incorrectly use that interface now must explain how the macros formed the interface.
Refactoring and analysis tools have a dramatically harder time updating the interface. As a consequence, we specifically disallow using macros
in this way. For example, avoid patterns like:
class WOMBAT_TYPE(Foo) {
// ...
public:
EXPAND_PUBLIC_WOMBAT_API(Foo)
EXPAND_WOMBAT_COMPARISONS(Foo, ==, <)
};
Preprocessor Macros
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Luckily, macros are not nearly as necessary in C++ as they are in C. Instead of using a macro to inline performance-critical code, use an inline
function. Instead of using a macro to store a constant, use a const variable. Instead of using a macro to "abbreviate" a long variable name,
use a reference. Instead of using a macro to conditionally compile code ... well, don't do that at all (except, of course, for the #define guards
to prevent double inclusion of header files). It makes testing much more difficult.
Macros can do things these other techniques cannot, and you do see them in the codebase, especially in the lower-level libraries. And some of
their special features (like stringifying, concatenation, and so forth) are not available through the language proper. But before using a macro,
consider carefully whether there's a non-macro way to achieve the same result. If you need to use a macro to define an interface, contact your
project leads to request a waiver of this rule.
The following usage pattern will avoid many problems with macros; if you use macros, follow it whenever possible:
Don't define macros in a .h file.
#define macros right before you use them, and #undef them right after.
Do not just #undef an existing macro before replacing it with your own; instead, pick a name that's likely to be unique.
Try not to use macros that expand to unbalanced C++ constructs, or at least document that behavior well.
Prefer not using ## to generate function/class/variable names.
Exporting macros from headers (i.e. defining them in a header without #undefing them before the end of the header) is extremely strongly
discouraged. If you do export a macro from a header, it must have a globally unique name. To achieve this, it must be named with a prefix
consisting of your project's namespace name (but upper case).
Use 0 for integers, 0.0 for reals, nullptr for pointers, and '\0' for chars.
Use 0 for integers and 0.0 for reals.
For pointers (address values), there is a choice between 0, NULL, and nullptr. For projects that allow C++11 features, use nullptr, as this
provides type-safety.
For C++03 projects, prefer NULL to 0. While the values are equivalent, NULL looks more like a pointer to the reader, and some C++ compilers
provide special definitions of NULL which enable them to give useful warnings.
Use '\0' for the null character. Using the correct type makes the code more readable.
0 and nullptr/NULL
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Prefer sizeof(varname) to sizeof(type).
Use sizeof(varname) when you take the size of a particular variable. sizeof(varname) will update appropriately if someone changes the
variable type either now or later. You may use sizeof(type) for code unrelated to any particular variable, such as code that manages an
external or internal data format where a variable of an appropriate C++ type is not convenient.
Struct data;
memset(&data, 0, sizeof(data));
memset(&data, 0, sizeof(Struct));
if (raw_size < sizeof(int)) {
LOG(ERROR) << "compressed record not big enough for count: " << raw_size;
return false;
}
Use auto to avoid type names that are noisy, obvious, or unimportant - cases where the type doesn't aid in clarity for the reader. Continue to
use manifest type declarations when it helps readability.
Pros:
C++ type names can be long and cumbersome, especially when they involve templates or namespaces.
When a C++ type name is repeated within a single declaration or a small code region, the repetition may not be aiding readability.
It is sometimes safer to let the type be specified by the type of the initialization expression, since that avoids the possibility of unintended
copies or type conversions.
Cons:
sizeof
auto
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Sometimes code is clearer when types are manifest, especially when a variable's initialization depends on things that were declared far away.
In expressions like:
auto foo = x.add_foo();
auto i = y.Find(key);
it may not be obvious what the resulting types are if the type of y isn't very well known, or if y was declared many lines earlier.
Programmers have to understand the difference between auto and const auto& or they'll get copies when they didn't mean to.
If an auto variable is used as part of an interface, e.g. as a constant in a header, then a programmer might change its type while only intending
to change its value, leading to a more radical API change than intended.
Decision:
auto is permitted when it increases readability, particularly as described below. Never initialize an auto-typed variable with a braced initializer
list.
Specific cases where auto is allowed or encouraged:
(Encouraged) For iterators and other long/cluttery type names, particularly when the type is clear from context (calls to find, begin, or
end for instance).
(Allowed) When the type is clear from local context (in the same expression or within a few lines). Initialization of a pointer or smart
pointer with calls to new and std::make_unique commonly falls into this category, as does use of auto in a range-based loop over a
container whose type is spelled out nearby.
(Allowed) When the type doesn't matter because it isn't being used for anything other than equality comparison.
(Encouraged) When iterating over a map with a range-based loop (because it is often assumed that the correct type is
std::pair<KeyType, ValueType> whereas it is actually std::pair<const KeyType, ValueType>). This is particularly well
paired with local key and value aliases for .first and .second (often const-ref).
for (const auto& item : some_map) {
const KeyType& key = item.first;
const ValType& value = item.second;
// The rest of the loop can now just refer to key and value,
// a reader can see the types in question, and we've avoided
// the too-common case of extra copies in this iteration.
}
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You may use braced initializer lists.
In C++03, aggregate types (arrays and structs with no constructor) could be initialized with braced initializer lists.
struct Point { int x; int y; };
Point p = {1, 2};
In C++11, this syntax was generalized, and any object type can now be created with a braced initializer list, known as a braced-init-list in the
C++ grammar. Here are a few examples of its use.
// Vector takes a braced-init-list of elements.
std::vector<string> v{"foo", "bar"};
// Basically the same, ignoring some small technicalities.
// You may choose to use either form.
std::vector<string> v = {"foo", "bar"};
// Usable with 'new' expressions.
auto p = new std::vector<string>{"foo", "bar"};
// A map can take a list of pairs. Nested braced-init-lists work.
std::map<int, string> m = {{1, "one"}, {2, "2"}};
// A braced-init-list can be implicitly converted to a return type.
std::vector<int> test_function() { return {1, 2, 3}; }
// Iterate over a braced-init-list.
for (int i : {-1, -2, -3}) {}
// Call a function using a braced-init-list.
void TestFunction2(std::vector<int> v) {}
TestFunction2({1, 2, 3});
A user-defined type can also define a constructor and/or assignment operator that take std::initializer_list<T>, which is automatically
created from braced-init-list:
Braced Initializer List
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class MyType {
public:
// std::initializer_list references the underlying init list.
// It should be passed by value.
MyType(std::initializer_list<int> init_list) {
for (int i : init_list) append(i);
}
MyType& operator=(std::initializer_list<int> init_list) {
clear();
for (int i : init_list) append(i);
}
};
MyType m{2, 3, 5, 7};
Finally, brace initialization can also call ordinary constructors of data types, even if they do not have std::initializer_list<T>
constructors.
double d{1.23};
// Calls ordinary constructor as long as MyOtherType has no
// std::initializer_list constructor.
class MyOtherType {
public:
explicit MyOtherType(string);
MyOtherType(int, string);
};
MyOtherType m = {1, "b"};
// If the constructor is explicit, you can't use the "= {}" form.
MyOtherType m{"b"};
Never assign a braced-init-list to an auto local variable. In the single element case, what this means can be confusing.
auto d = {1.23}; // d is a std::initializer_list<double>
auto d = double{1.23}; // Good -- d is a double, not a std::initializer_list.
See Braced_Initializer_List_Format for formatting.
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Use lambda expressions where appropriate. Prefer explicit captures when the lambda will escape the current scope.
Definition:
Lambda expressions are a concise way of creating anonymous function objects. They're often useful when passing functions as arguments.
For example:
std::sort(v.begin(), v.end(), [](int x, int y) {
return Weight(x) < Weight(y);
});
They further allow capturing variables from the enclosing scope either explicitly by name, or implicitly using a default capture. Explicit captures
require each variable to be listed, as either a value or reference capture:
int weight = 3;
int sum = 0;
// Captures `weight` by value and `sum` by reference.
std::for_each(v.begin(), v.end(), [weight, &sum](int x) {
sum += weight * x;
});
Default captures implicitly capture any variable referenced in the lambda body, including this if any members are used:
const std::vector<int> lookup_table = ...;
std::vector<int> indices = ...;
// Captures `lookup_table` by reference, sorts `indices` by the value
// of the associated element in `lookup_table`.
std::sort(indices.begin(), indices.end(), [&](int a, int b) {
return lookup_table[a] < lookup_table[b];
});
Lambdas were introduced in C++11 along with a set of utilities for working with function objects, such as the polymorphic wrapper
std::function.
Pros:
Lambda expressions
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Lambdas are much more concise than other ways of defining function objects to be passed to STL algorithms, which can be a
readability improvement.
Appropriate use of default captures can remove redundancy and highlight important exceptions from the default.
Lambdas, std::function, and std::bind can be used in combination as a general purpose callback mechanism; they make it easy
to write functions that take bound functions as arguments.
Cons:
Variable capture in lambdas can be a source of dangling-pointer bugs, particularly if a lambda escapes the current scope.
Default captures by value can be misleading because they do not prevent dangling-pointer bugs. Capturing a pointer by value doesn't
cause a deep copy, so it often has the same lifetime issues as capture by reference. This is especially confusing when capturing 'this' by
value, since the use of 'this' is often implicit.
It's possible for use of lambdas to get out of hand; very long nested anonymous functions can make code harder to understand.
Decision:
Use lambda expressions where appropriate, with formatting as described below.
Prefer explicit captures if the lambda may escape the current scope. For example, instead of:
{
Foo foo;
...
executor->Schedule([&] { Frobnicate(foo); })
...
}
// BAD! The fact that the lambda makes use of a reference to `foo` and
// possibly `this` (if `Frobnicate` is a member function) may not be
// apparent on a cursory inspection. If the lambda is invoked after
// the function returns, that would be bad, because both `foo`
// and the enclosing object could have been destroyed.
prefer to write:
{
Foo foo;
...
executor->Schedule([&foo] { Frobnicate(foo); })
...
}
// BETTER - The compile will fail if `Frobnicate` is a member
// function, and it's clearer that `foo` is dangerously captured by
// reference.
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Use default capture by reference ([&]) only when the lifetime of the lambda is obviously shorter than any potential captures.
Use default capture by value ([=]) only as a means of binding a few variables for a short lambda, where the set of captured variables is
obvious at a glance. Prefer not to write long or complex lambdas with default capture by value.
Keep unnamed lambdas short. If a lambda body is more than maybe five lines long, prefer to give the lambda a name, or to use a
named function instead of a lambda.
Specify the return type of the lambda explicitly if that will make it more obvious to readers, as with auto.
Avoid complicated template programming.
Definition:
Template metaprogramming refers to a family of techniques that exploit the fact that the C++ template instantiation mechanism is Turing
complete and can be used to perform arbitrary compile-time computation in the type domain.
Pros:
Template metaprogramming allows extremely flexible interfaces that are type safe and high performance. Facilities like Google Test,
std::tuple, std::function, and Boost.Spirit would be impossible without it.
Cons:
The techniques used in template metaprogramming are often obscure to anyone but language experts. Code that uses templates in
complicated ways is often unreadable, and is hard to debug or maintain.
Template metaprogramming often leads to extremely poor compiler time error messages: even if an interface is simple, the complicated
implementation details become visible when the user does something wrong.
Template metaprogramming interferes with large scale refactoring by making the job of refactoring tools harder. First, the template code is
expanded in multiple contexts, and it's hard to verify that the transformation makes sense in all of them. Second, some refactoring tools work
with an AST that only represents the structure of the code after template expansion. It can be difficult to automatically work back to the original
source construct that needs to be rewritten.
Decision:
Template metaprogramming
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Template metaprogramming sometimes allows cleaner and easier-to-use interfaces than would be possible without it, but it's also often a
temptation to be overly clever. It's best used in a small number of low level components where the extra maintenance burden is spread out over
a large number of uses.
Think twice before using template metaprogramming or other complicated template techniques; think about whether the average member of
your team will be able to understand your code well enough to maintain it after you switch to another project, or whether a non-C++
programmer or someone casually browsing the code base will be able to understand the error messages or trace the flow of a function they
want to call. If you're using recursive template instantiations or type lists or metafunctions or expression templates, or relying on SFINAE or on
the sizeof trick for detecting function overload resolution, then there's a good chance you've gone too far.
If you use template metaprogramming, you should expect to put considerable effort into minimizing and isolating the complexity. You should
hide metaprogramming as an implementation detail whenever possible, so that user-facing headers are readable, and you should make sure
that tricky code is especially well commented. You should carefully document how the code is used, and you should say something about what
the "generated" code looks like. Pay extra attention to the error messages that the compiler emits when users make mistakes. The error
messages are part of your user interface, and your code should be tweaked as necessary so that the error messages are understandable and
actionable from a user point of view.
Use only approved libraries from the Boost library collection.
Definition:
The Boost library collection is a popular collection of peer-reviewed, free, open-source C++ libraries.
Pros:
Boost code is generally very high-quality, is widely portable, and fills many important gaps in the C++ standard library, such as type traits and
better binders.
Cons:
Some Boost libraries encourage coding practices which can hamper readability, such as metaprogramming and other advanced template
techniques, and an excessively "functional" style of programming.
Decision:
In order to maintain a high level of readability for all contributors who might read and maintain code, we only allow an approved subset of Boost
features. Currently, the following libraries are permitted:
Boost
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Call Traits from boost/call_traits.hpp
Compressed Pair from boost/compressed_pair.hpp
The Boost Graph Library (BGL) from boost/graph, except serialization (adj_list_serialize.hpp) and parallel/distributed
algorithms and data structures (boost/graph/parallel/* and boost/graph/distributed/*).
Property Map from boost/property_map, except parallel/distributed property maps (boost/property_map/parallel/*).
Iterator from boost/iterator
The part of Polygon that deals with Voronoi diagram construction and doesn't depend on the rest of Polygon:
boost/polygon/voronoi_builder.hpp, boost/polygon/voronoi_diagram.hpp, and
boost/polygon/voronoi_geometry_type.hpp
Bimap from boost/bimap
Statistical Distributions and Functions from boost/math/distributions
Special Functions from boost/math/special_functions
Multi-index from boost/multi_index
Heap from boost/heap
The flat containers from Container: boost/container/flat_map, and boost/container/flat_set
Intrusive from boost/intrusive.
The boost/sort library.
Preprocessor from boost/preprocessor.
We are actively considering adding other Boost features to the list, so this list may be expanded in the future.
The following libraries are permitted, but their use is discouraged because they've been superseded by standard libraries in C++11:
Array from boost/array.hpp: use std::array instead.
Pointer Container from boost/ptr_container: use containers of std::unique_ptr instead.
Do not define specializations of std::hash.
Definition:
std::hash<T> is the function object that the C++11 hash containers use to hash keys of type T, unless the user explicitly specifies a different
hash function. For example, std::unordered_map<int, string> is a hash map that uses std::hash<int> to hash its keys, whereas
std::unordered_map<int, string, MyIntHash> uses MyIntHash.
std::hash is defined for all integral, floating-point, pointer, and enum types, as well as some standard library types such as string and
unique_ptr. Users can enable it to work for their own types by defining specializations of it for those types.
std::hash
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Pros:
std::hash is easy to use, and simplifies the code since you don't have to name it explicitly. Specializing std::hash is the standard way of
specifying how to hash a type, so it's what outside resources will teach, and what new engineers will expect.
Cons:
std::hash is hard to specialize. It requires a lot of boilerplate code, and more importantly, it combines responsibility for identifying the hash
inputs with responsibility for executing the hashing algorithm itself. The type author has to be responsible for the former, but the latter requires
expertise that a type author usually doesn't have, and shouldn't need. The stakes here are high because low-quality hash functions can be
security vulnerabilities, due to the emergence of hash flooding attacks.
Even for experts, std::hash specializations are inordinately difficult to implement correctly for compound types, because the implementation
cannot recursively call std::hash on data members. High-quality hash algorithms maintain large amounts of internal state, and reducing that
state to the size_t bytes that std::hash returns is usually the slowest part of the computation, so it should not be done more than once.
Due to exactly that issue, std::hash does not work with std::pair or std::tuple, and the language does not allow us to extend it to
support them.
Decision:
You can use std::hash with the types that it supports "out of the box", but do not specialize it to support additional types. If you need a hash
table with a key type that std::hash does not support, consider using legacy hash containers (e.g. hash_map) for now; they use a different
default hasher, which is unaffected by this prohibition.
If you want to use the standard hash containers anyway, you will need to specify a custom hasher for the key type, e.g.
std::unordered_map<MyKeyType, Value, MyKeyTypeHasher> my_map;
Consult with the type's owners to see if there is an existing hasher that you can use; otherwise work with them to provide one, or roll your own.
We are planning to provide a hash function that can work with any type, using a new customization mechanism that doesn't have the
drawbacks of std::hash.
Use libraries and language extensions from C++11 when appropriate. Consider portability to other environments before using C++11 features
in your project.
C++11
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Definition:
C++11 contains significant changes both to the language and libraries.
Pros:
C++11 was the official standard until august 2014, and is supported by most C++ compilers. It standardizes some common C++ extensions
that we use already, allows shorthands for some operations, and has some performance and safety improvements.
Cons:
The C++11 standard is substantially more complex than its predecessor (1,300 pages versus 800 pages), and is unfamiliar to many
developers. The long-term effects of some features on code readability and maintenance are unknown. We cannot predict when its various
features will be implemented uniformly by tools that may be of interest, particularly in the case of projects that are forced to use older versions
of tools.
As with Boost, some C++11 extensions encourage coding practices that hamper readability—for example by removing checked redundancy
(such as type names) that may be helpful to readers, or by encouraging template metaprogramming. Other extensions duplicate functionality
available through existing mechanisms, which may lead to confusion and conversion costs.
Decision:
C++11 features may be used unless specified otherwise. In addition to what's described in the rest of the style guide, the following C++11
features may not be used:
Compile-time rational numbers (<ratio>), because of concerns that it's tied to a more template-heavy interface style.
The <cfenv> and <fenv.h> headers, because many compilers do not support those features reliably.
Ref-qualifiers on member functions, such as void X::Foo() & or void X::Foo() &&, because of concerns that they're an overly
obscure feature.
Nonstandard extensions to C++ may not be used unless otherwise specified.
Definition:
Compilers support various extensions that are not part of standard C++. Such extensions include GCC's __attribute__, intrinsic functions
such as __builtin_prefetch, designated initializers (e.g. Foo f = {.field = 3}), inline assembly, __COUNTER__,
Nonstandard Extensions
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__PRETTY_FUNCTION__, compound statement expressions (e.g. foo = ({ int x; Bar(&x); x }), variable-length arrays and
alloca(), and the "Elvis Operator" a?:b.
Pros:
Nonstandard extensions may provide useful features that do not exist in standard C++. For example, some people think that designated
initializers are more readable than standard C++ features like constructors.
Important performance guidance to the compiler can only be specified using extensions.
Cons:
Nonstandard extensions do not work in all compilers. Use of nonstandard extensions reduces portability of code.
Even if they are supported in all targeted compilers, the extensions are often not well-specified, and there may be subtle behavior
differences between compilers.
Nonstandard extensions add to the language features that a reader must know to understand the code.
Decision:
Do not use nonstandard extensions. You may use portability wrappers that are implemented using nonstandard extensions, so long as those
wrappers are provided by a designated project-wide portability header.
Public aliases are for the benefit of an API's user, and should be clearly documented.
Definition:
There are several ways to create names that are aliases of other entities:
typedef Foo Bar;
using Bar = Foo;
using other_namespace::Foo;
In new code, using is preferable to typedef, because it provides a more consistent syntax with the rest of C++ and works with templates.
Like other declarations, aliases declared in a header file are part of that header's public API unless they're in a function definition, in the private
portion of a class, or in an explicitly-marked internal namespace. Aliases in such areas or in .cc files are implementation details (because client
code can't refer to them), and are not restricted by this rule.
Aliases
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Pros:
Aliases can improve readability by simplifying a long or complicated name.
Aliases can reduce duplication by naming in one place a type used repeatedly in an API, which might make it easier to change the type
later.
Cons:
When placed in a header where client code can refer to them, aliases increase the number of entities in that header's API, increasing its
complexity.
Clients can easily rely on unintended details of public aliases, making changes difficult.
It can be tempting to create a public alias that is only intended for use in the implementation, without considering its impact on the API,
or on maintainability.
Aliases can create risk of name collisions
Aliases can reduce readability by giving a familiar construct an unfamiliar name
Type aliases can create an unclear API contract: it is unclear whether the alias is guaranteed to be identical to the type it aliases, to have
the same API, or only to be usable in specified narrow ways
Decision:
Don't put an alias in your public API just to save typing in the implementation; do so only if you intend it to be used by your clients.
When defining a public alias, document the intent of the new name, including whether it is guaranteed to always be the same as the type it's
currently aliased to, or whether a more limited compatibility is intended. This lets the user know whether they can treat the types as
substitutable or whether more specific rules must be followed, and can help the implementation retain some degree of freedom to change the
alias.
Don't put namespace aliases in your public API. (See also Namespaces).
For example, these aliases document how they are intended to be used in client code:
namespace mynamespace {
// Used to store field measurements. DataPoint may change from Bar* to some internal type.
// Client code should treat it as an opaque pointer.
using DataPoint = foo::Bar*;
// A set of measurements. Just an alias for user convenience.
using TimeSeries = std::unordered_set<DataPoint, std::hash<DataPoint>, DataPointComparator>;
} // namespace mynamespace
These aliases don't document intended use, and half of them aren't meant for client use:
{
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namespace mynamespace {
// Bad: none of these say how they should be used.
using DataPoint = foo::Bar*;
using std::unordered_set; // Bad: just for local convenience
using std::hash; // Bad: just for local convenience
typedef unordered_set<DataPoint, hash<DataPoint>, DataPointComparator> TimeSeries;
} // namespace mynamespace
However, local convenience aliases are fine in function definitions, private sections of classes, explicitly marked internal namespaces, and in
.cc files:
// In a .cc file
using foo::Bar;
The most important consistency rules are those that govern naming. The style of a name immediately informs us what sort of thing the named
entity is: a type, a variable, a function, a constant, a macro, etc., without requiring us to search for the declaration of that entity. The pattern-
matching engine in our brains relies a great deal on these naming rules.
Naming rules are pretty arbitrary, but we feel that consistency is more important than individual preferences in this area, so regardless of
whether you find them sensible or not, the rules are the rules.
Names should be descriptive; avoid abbreviation.
Give as descriptive a name as possible, within reason. Do not worry about saving horizontal space as it is far more important to make your
code immediately understandable by a new reader. Do not use abbreviations that are ambiguous or unfamiliar to readers outside your project,
and do not abbreviate by deleting letters within a word. Abbreviations that would be familiar to someone outside your project with relevant
domain knowledge are OK. As a rule of thumb, an abbreviation is probably OK if it's listed in Wikipedia.
Naming
General Naming Rules
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int price_count_reader; // No abbreviation.
int num_errors; // "num" is a widespread convention.
int num_dns_connections; // Most people know what "DNS" stands for.
int lstm_size; // "LSTM" is a common machine learning abbreviation.
int n; // Meaningless.
int nerr; // Ambiguous abbreviation.
int n_comp_conns; // Ambiguous abbreviation.
int wgc_connections; // Only your group knows what this stands for.
int pc_reader; // Lots of things can be abbreviated "pc".
int cstmr_id; // Deletes internal letters.
FooBarRequestInfo fbri; // Not even a word.
Note that certain universally-known abbreviations are OK, such as i for an iteration variable and T for a template parameter.
For some symbols, this style guide recommends names to start with a capital letter and to have a capital letter for each new word (a.k.a.
"Camel Case" or "Pascal case"). When abbreviations appear in such names, prefer to capitalize the abbreviations as single words (i.e.
StartRpc(), not StartRPC()).
Template parameters should follow the naming style for their category: type template parameters should follow the rules for type names, and
non-type template parameters should follow the rules for variable names.
Filenames should be all lowercase and can include underscores (_) or dashes (-). Follow the convention that your project uses. If there is no
consistent local pattern to follow, prefer "_".
Examples of acceptable file names:
my_useful_class.cc
my-useful-class.cc
myusefulclass.cc
myusefulclass_test.cc // _unittest and _regtest are deprecated.
C++ files should end in .cc and header files should end in .h. Files that rely on being textually included at specific points should end in .inc
(see also the section on self-contained headers).
File Names
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Do not use filenames that already exist in /usr/include, such as db.h.
In general, make your filenames very specific. For example, use http_server_logs.h rather than logs.h. A very common case is to have
a pair of files called, e.g., foo_bar.h and foo_bar.cc, defining a class called FooBar.
Inline functions must be in a .h file. If your inline functions are very short, they should go directly into your .h file.
Type names start with a capital letter and have a capital letter for each new word, with no underscores: MyExcitingClass,
MyExcitingEnum.
The names of all types — classes, structs, type aliases, enums, and type template parameters — have the same naming convention. Type
names should start with a capital letter and have a capital letter for each new word. No underscores. For example:
// classes and structs
class UrlTable { ...
class UrlTableTester { ...
struct UrlTableProperties { ...
// typedefs
typedef hash_map<UrlTableProperties *, string> PropertiesMap;
// using aliases
using PropertiesMap = hash_map<UrlTableProperties *, string>;
// enums
enum UrlTableErrors { ...
The names of variables (including function parameters) and data members are all lowercase, with underscores between words. Data members
of classes (but not structs) additionally have trailing underscores. For instance: a_local_variable, a_struct_data_member,
Type Names
Variable Names
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a_class_data_member_.
Common Variable names
For example:
string table_name; // OK - uses underscore.
string tablename; // OK - all lowercase.
string tableName; // Bad - mixed case.
Class Data Members
Data members of classes, both static and non-static, are named like ordinary nonmember variables, but with a trailing underscore.
class TableInfo {
...
private:
string table_name_; // OK - underscore at end.
string tablename_; // OK.
static Pool<TableInfo>* pool_; // OK.
};
Struct Data Members
Data members of structs, both static and non-static, are named like ordinary nonmember variables. They do not have the trailing underscores
that data members in classes have.
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struct UrlTableProperties {
string name;
int num_entries;
static Pool<UrlTableProperties>* pool;
};
See Structs vs. Classes for a discussion of when to use a struct versus a class.
Variables declared constexpr or const, and whose value is fixed for the duration of the program, are named with a leading "k" followed by mixed
case. For example:
const int kDaysInAWeek = 7;
All such variables with static storage duration (i.e. statics and globals, see Storage Duration for details) should be named this way. This
convention is optional for variables of other storage classes, e.g. automatic variables, otherwise the usual variable naming rules apply.
Regular functions have mixed case; accessors and mutators may be named like variables.
Ordinarily, functions should start with a capital letter and have a capital letter for each new word.
AddTableEntry()
DeleteUrl()
OpenFileOrDie()
(The same naming rule applies to class- and namespace-scope constants that are exposed as part of an API and that are intended to look like
functions, because the fact that they're objects rather than functions is an unimportant implementation detail.)
Constant Names
Function Names
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Accessors and mutators (get and set functions) may be named like variables. These often correspond to actual member variables, but this is
not required. For example, int count() and void set_count(int count).
Namespace names are all lower-case. Top-level namespace names are based on the project name . Avoid collisions between nested
namespaces and well-known top-level namespaces.
The name of a top-level namespace should usually be the name of the project or team whose code is contained in that namespace. The code
in that namespace should usually be in a directory whose basename matches the namespace name (or in subdirectories thereof).
Keep in mind that the rule against abbreviated names applies to namespaces just as much as variable names. Code inside the namespace
seldom needs to mention the namespace name, so there's usually no particular need for abbreviation anyway.
Avoid nested namespaces that match well-known top-level namespaces. Collisions between namespace names can lead to surprising build
breaks because of name lookup rules. In particular, do not create any nested std namespaces. Prefer unique project identifiers
(websearch::index, websearch::index_util) over collision-prone names like websearch::util.
For internal namespaces, be wary of other code being added to the same internal namespace causing a collision (internal helpers within
a team tend to be related and may lead to collisions). In such a situation, using the filename to make a unique internal name is helpful
(websearch::index::frobber_internal for use in frobber.h)
Enumerators (for both scoped and unscoped enums) should be named either like constants or like macros: either kEnumName or ENUM_NAME.
Preferably, the individual enumerators should be named like constants. However, it is also acceptable to name them like macros. The
enumeration name, UrlTableErrors (and AlternateUrlTableErrors), is a type, and therefore mixed case.
enum UrlTableErrors {
kOK = 0,
kErrorOutOfMemory,
kErrorMalformedInput,
};
Namespace Names
Enumerator Names
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enum AlternateUrlTableErrors {
OK = 0,
OUT_OF_MEMORY = 1,
MALFORMED_INPUT = 2,
};
Until January 2009, the style was to name enum values like macros. This caused problems with name collisions between enum values and
macros. Hence, the change to prefer constant-style naming was put in place. New code should prefer constant-style naming if possible.
However, there is no reason to change old code to use constant-style names, unless the old names are actually causing a compile-time
problem.
You're not really going to define a macro, are you? If you do, they're like this:
MY_MACRO_THAT_SCARES_SMALL_CHILDREN_AND_ADULTS_ALIKE.
Please see the description of macros; in general macros should not be used. However, if they are absolutely needed, then they should be
named with all capitals and underscores.
#define ROUND(x) ...
#define PI_ROUNDED 3.0
If you are naming something that is analogous to an existing C or C++ entity then you can follow the existing naming convention scheme.
bigopen()
function name, follows form of open()
uint
typedef
bigpos
struct or class, follows form of pos
Macro Names
Exceptions to Naming Rules
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sparse_hash_map
STL-like entity; follows STL naming conventions
LONGLONG_MAX
a constant, as in INT_MAX
Though a pain to write, comments are absolutely vital to keeping our code readable. The following rules describe what you should comment
and where. But remember: while comments are very important, the best code is self-documenting. Giving sensible names to types and
variables is much better than using obscure names that you must then explain through comments.
When writing your comments, write for your audience: the next contributor who will need to understand your code. Be generous — the next one
may be you!
Use either the // or /* */ syntax, as long as you are consistent.
You can use either the // or the /* */ syntax; however, // is much more common. Be consistent with how you comment and what style you
use where.
Start each file with license boilerplate.
File comments describe the contents of a file. If a file declares, implements, or tests exactly one abstraction that is documented by a comment
at the point of declaration, file comments are not required. All other files must have file comments.
Comments
Comment Style
File Comments
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Legal Notice and Author Line
Every file should contain license boilerplate. Choose the appropriate boilerplate for the license used by the project (for example, Apache 2.0,
BSD, LGPL, GPL).
If you make significant changes to a file with an author line, consider deleting the author line. New files should usually not contain copyright
notice or author line.
File Contents
If a .h declares multiple abstractions, the file-level comment should broadly describe the contents of the file, and how the abstractions are
related. A 1 or 2 sentence file-level comment may be sufficient. The detailed documentation about individual abstractions belongs with those
abstractions, not at the file level.
Do not duplicate comments in both the .h and the .cc. Duplicated comments diverge.
Every non-obvious class declaration should have an accompanying comment that describes what it is for and how it should be used.
// Iterates over the contents of a GargantuanTable.
// Example:
// GargantuanTableIterator* iter = table->NewIterator();
// for (iter->Seek("foo"); !iter->done(); iter->Next()) {
// process(iter->key(), iter->value());
// }
// delete iter;
class GargantuanTableIterator {
...
};
Class Comments
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The class comment should provide the reader with enough information to know how and when to use the class, as well as any additional
considerations necessary to correctly use the class. Document the synchronization assumptions the class makes, if any. If an instance of the
class can be accessed by multiple threads, take extra care to document the rules and invariants surrounding multithreaded use.
The class comment is often a good place for a small example code snippet demonstrating a simple and focused usage of the class.
When sufficiently separated (e.g. .h and .cc files), comments describing the use of the class should go together with its interface definition;
comments about the class operation and implementation should accompany the implementation of the class's methods.
Declaration comments describe use of the function (when it is non-obvious); comments at the definition of a function describe operation.
Function Declarations
Almost every function declaration should have comments immediately preceding it that describe what the function does and how to use it.
These comments may be omitted only if the function is simple and obvious (e.g. simple accessors for obvious properties of the class). These
comments should be descriptive ("Opens the file") rather than imperative ("Open the file"); the comment describes the function, it does not tell
the function what to do. In general, these comments do not describe how the function performs its task. Instead, that should be left to
comments in the function definition.
Types of things to mention in comments at the function declaration:
What the inputs and outputs are.
For class member functions: whether the object remembers reference arguments beyond the duration of the method call, and whether it
will free them or not.
If the function allocates memory that the caller must free.
Whether any of the arguments can be a null pointer.
If there are any performance implications of how a function is used.
If the function is re-entrant. What are its synchronization assumptions?
Here is an example:
Function Comments
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// Returns an iterator for this table. It is the client's
// responsibility to delete the iterator when it is done with it,
// and it must not use the iterator once the GargantuanTable object
// on which the iterator was created has been deleted.
//
// The iterator is initially positioned at the beginning of the table.
//
// This method is equivalent to:
// Iterator* iter = table->NewIterator();
// iter->Seek("");
// return iter;
// If you are going to immediately seek to another place in the
// returned iterator, it will be faster to use NewIterator()
// and avoid the extra seek.
Iterator* GetIterator() const;
However, do not be unnecessarily verbose or state the completely obvious.
When documenting function overrides, focus on the specifics of the override itself, rather than repeating the comment from the overridden
function. In many of these cases, the override needs no additional documentation and thus no comment is required.
When commenting constructors and destructors, remember that the person reading your code knows what constructors and destructors are for,
so comments that just say something like "destroys this object" are not useful. Document what constructors do with their arguments (for
example, if they take ownership of pointers), and what cleanup the destructor does. If this is trivial, just skip the comment. It is quite common
for destructors not to have a header comment.
Function Definitions
If there is anything tricky about how a function does its job, the function definition should have an explanatory comment. For example, in the
definition comment you might describe any coding tricks you use, give an overview of the steps you go through, or explain why you chose to
implement the function in the way you did rather than using a viable alternative. For instance, you might mention why it must acquire a lock for
the first half of the function but why it is not needed for the second half.
Note you should not just repeat the comments given with the function declaration, in the .h file or wherever. It's okay to recapitulate briefly what
the function does, but the focus of the comments should be on how it does it.
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In general the actual name of the variable should be descriptive enough to give a good idea of what the variable is used for. In certain cases,
more comments are required.
Class Data Members
The purpose of each class data member (also called an instance variable or member variable) must be clear. If there are any invariants
(special values, relationships between members, lifetime requirements) not clearly expressed by the type and name, they must be commented.
However, if the type and name suffice (int num_events_;), no comment is needed.
In particular, add comments to describe the existence and meaning of sentinel values, such as nullptr or -1, when they are not obvious. For
example:
private:
// Used to bounds-check table accesses. -1 means
// that we don't yet know how many entries the table has.
int num_total_entries_;
Global Variables
All global variables should have a comment describing what they are, what they are used for, and (if unclear) why it needs to be global. For
example:
// The total number of tests cases that we run through in this regression test.
const int kNumTestCases = 6;
Variable Comments
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In your implementation you should have comments in tricky, non-obvious, interesting, or important parts of your code.
Explanatory Comments
Tricky or complicated code blocks should have comments before them. Example:
// Divide result by two, taking into account that x
// contains the carry from the add.
for (int i = 0; i < result->size(); i++) {
x = (x << 8) + (*result)[i];
(*result)[i] = x >> 1;
x &= 1;
}
Line Comments
Also, lines that are non-obvious should get a comment at the end of the line. These end-of-line comments should be separated from the code
by 2 spaces. Example:
// If we have enough memory, mmap the data portion too.
mmap_budget = max<int64>(0, mmap_budget - index_->length());
if (mmap_budget >= data_size_ && !MmapData(mmap_chunk_bytes, mlock))
return; // Error already logged.
Note that there are both comments that describe what the code is doing, and comments that mention that an error has already been logged
when the function returns.
Implementation Comments
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If you have several comments on subsequent lines, it can often be more readable to line them up:
DoSomething(); // Comment here so the comments line up.
DoSomethingElseThatIsLonger(); // Two spaces between the code and the comment.
{ // One space before comment when opening a new scope is allowed,
// thus the comment lines up with the following comments and code.
DoSomethingElse(); // Two spaces before line comments normally.
}
std::vector<string> list{
// Comments in braced lists describe the next element...
"First item",
// .. and should be aligned appropriately.
"Second item"};
DoSomething(); /* For trailing block comments, one space is fine. */
Function Argument Comments
When the meaning of a function argument is nonobvious, consider one of the following remedies:
If the argument is a literal constant, and the same constant is used in multiple function calls in a way that tacitly assumes they're the
same, you should use a named constant to make that constraint explicit, and to guarantee that it holds.
Consider changing the function signature to replace a bool argument with an enum argument. This will make the argument values self-
describing.
For functions that have several configuration options, consider defining a single class or struct to hold all the options , and pass an
instance of that. This approach has several advantages. Options are referenced by name at the call site, which clarifies their meaning. It
also reduces function argument count, which makes function calls easier to read and write. As an added benefit, you don't have to
change call sites when you add another option.
Replace large or complex nested expressions with named variables.
As a last resort, use comments to clarify argument meanings at the call site.
Consider the following example:
// What are these arguments?
const DecimalNumber product = CalculateProduct(values, 7, false, nullptr);
versus:
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ProductOptions options;
options.set_precision_decimals(7);
options.set_use_cache(ProductOptions::kDontUseCache);
const DecimalNumber product =
CalculateProduct(values, options, /*completion_callback=*/nullptr);
Don'ts
Do not state the obvious. In particular, don't literally describe what code does, unless the behavior is nonobvious to a reader who understands
C++ well. Instead, provide higher level comments that describe why the code does what it does, or make the code self describing.
Compare this:
// Find the element in the vector. <-- Bad: obvious!
auto iter = std::find(v.begin(), v.end(), element);
if (iter != v.end()) {
Process(element);
}
To this:
// Process "element" unless it was already processed.
auto iter = std::find(v.begin(), v.end(), element);
if (iter != v.end()) {
Process(element);
}
Self-describing code doesn't need a comment. The comment from the example above would be obvious:
if (!IsAlreadyProcessed(element)) {
Process(element);
}
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Pay attention to punctuation, spelling, and grammar; it is easier to read well-written comments than badly written ones.
Comments should be as readable as narrative text, with proper capitalization and punctuation. In many cases, complete sentences are more
readable than sentence fragments. Shorter comments, such as comments at the end of a line of code, can sometimes be less formal, but you
should be consistent with your style.
Although it can be frustrating to have a code reviewer point out that you are using a comma when you should be using a semicolon, it is very
important that source code maintain a high level of clarity and readability. Proper punctuation, spelling, and grammar help with that goal.
Use TODO comments for code that is temporary, a short-term solution, or good-enough but not perfect.
TODOs should include the string TODO in all caps, followed by the name, e-mail address, bug ID, or other identifier of the person or issue with
the best context about the problem referenced by the TODO. The main purpose is to have a consistent TODO that can be searched to find out
how to get more details upon request. A TODO is not a commitment that the person referenced will fix the problem. Thus when you create a
TODO with a name, it is almost always your name that is given.
// TODO(kl@gmail.com): Use a "*" here for concatenation operator.
// TODO(Zeke) change this to use relations.
// TODO(bug 12345): remove the "Last visitors" feature
If your TODO is of the form "At a future date do something" make sure that you either include a very specific date ("Fix by November 2005") or a
very specific event ("Remove this code when all clients can handle XML responses.").
Punctuation, Spelling and Grammar
TODO Comments
Deprecation Comments
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Mark deprecated interface points with DEPRECATED comments.
You can mark an interface as deprecated by writing a comment containing the word DEPRECATED in all caps. The comment goes either before
the declaration of the interface or on the same line as the declaration.
After the word DEPRECATED, write your name, e-mail address, or other identifier in parentheses.
A deprecation comment must include simple, clear directions for people to fix their callsites. In C++, you can implement a deprecated function
as an inline function that calls the new interface point.
Marking an interface point DEPRECATED will not magically cause any callsites to change. If you want people to actually stop using the
deprecated facility, you will have to fix the callsites yourself or recruit a crew to help you.
New code should not contain calls to deprecated interface points. Use the new interface point instead. If you cannot understand the directions,
find the person who created the deprecation and ask them for help using the new interface point.
Coding style and formatting are pretty arbitrary, but a project is much easier to follow if everyone uses the same style. Individuals may not
agree with every aspect of the formatting rules, and some of the rules may take some getting used to, but it is important that all project
contributors follow the style rules so that they can all read and understand everyone's code easily.
To help you format code correctly, we've created a settings file for emacs.
Each line of text in your code should be at most 80 characters long.
We recognize that this rule is controversial, but so much existing code already adheres to it, and we feel that consistency is important.
Pros:
Formatting
Line Length
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Those who favor this rule argue that it is rude to force them to resize their windows and there is no need for anything longer. Some folks are
used to having several code windows side-by-side, and thus don't have room to widen their windows in any case. People set up their work
environment assuming a particular maximum window width, and 80 columns has been the traditional standard. Why change it?
Cons:
Proponents of change argue that a wider line can make code more readable. The 80-column limit is an hidebound throwback to 1960s
mainframes; modern equipment has wide screens that can easily show longer lines.
Decision:
80 characters is the maximum.
Exception:
Comment lines can be longer than 80 characters if it is not feasible to split them without harming readability, ease of cut and paste or auto-
linking -- e.g. if a line contains an example command or a literal URL longer than 80 characters.
Exception:
A raw-string literal may have content that exceeds 80 characters. Except for test code, such literals should appear near the top of a file.
Exception:
An #include statement with a long path may exceed 80 columns.
Exception:
You needn't be concerned about header guards that exceed the maximum length.
Non-ASCII characters should be rare, and must use UTF-8 formatting.
You shouldn't hard-code user-facing text in source, even English, so use of non-ASCII characters should be rare. However, in certain cases it is
appropriate to include such words in your code. For example, if your code parses data files from foreign sources, it may be appropriate to hard-
code the non-ASCII string(s) used in those data files as delimiters. More commonly, unittest code (which does not need to be localized) might
contain non-ASCII strings. In such cases, you should use UTF-8, since that is an encoding understood by most tools able to handle more than
just ASCII.
Non-ASCII Characters
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Hex encoding is also OK, and encouraged where it enhances readability — for example, "\xEF\xBB\xBF", or, even more simply,
u8"\uFEFF", is the Unicode zero-width no-break space character, which would be invisible if included in the source as straight UTF-8.
Use the u8 prefix to guarantee that a string literal containing \uXXXX escape sequences is encoded as UTF-8. Do not use it for strings
containing non-ASCII characters encoded as UTF-8, because that will produce incorrect output if the compiler does not interpret the source file
as UTF-8.
You shouldn't use the C++11 char16_t and char32_t character types, since they're for non-UTF-8 text. For similar reasons you also
shouldn't use wchar_t (unless you're writing code that interacts with the Windows API, which uses wchar_t extensively).
Use only spaces, and indent 2 spaces at a time.
We use spaces for indentation. Do not use tabs in your code. You should set your editor to emit spaces when you hit the tab key.
Return type on the same line as function name, parameters on the same line if they fit. Wrap parameter lists which do not fit on a single line as
you would wrap arguments in a function call.
Functions look like this:
ReturnType ClassName::FunctionName(Type par_name1, Type par_name2) {
DoSomething();
...
}
If you have too much text to fit on one line:
ReturnType ClassName::ReallyLongFunctionName(Type par_name1, Type par_name2,
Type par_name3) {
DoSomething();
Spaces vs. Tabs
Function Declarations and Definitions
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...
}
or if you cannot fit even the first parameter:
ReturnType LongClassName::ReallyReallyReallyLongFunctionName(
Type par_name1, // 4 space indent
Type par_name2,
Type par_name3) {
DoSomething(); // 2 space indent
...
}
Some points to note:
Choose good parameter names.
A parameter name may be omitted only if the parameter is not used in the function's definition.
If you cannot fit the return type and the function name on a single line, break between them.
If you break after the return type of a function declaration or definition, do not indent.
The open parenthesis is always on the same line as the function name.
There is never a space between the function name and the open parenthesis.
There is never a space between the parentheses and the parameters.
The open curly brace is always on the end of the last line of the function declaration, not the start of the next line.
The close curly brace is either on the last line by itself or on the same line as the open curly brace.
There should be a space between the close parenthesis and the open curly brace.
All parameters should be aligned if possible.
Default indentation is 2 spaces.
Wrapped parameters have a 4 space indent.
Unused parameters that are obvious from context may be omitted:
class Foo {
public:
Foo(Foo&&);
Foo(const Foo&);
Foo& operator=(Foo&&);
Foo& operator=(const Foo&);
};
Unused parameters that might not be obvious should comment out the variable name in the function definition:
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class Shape {
public:
virtual void Rotate(double radians) = 0;
};
class Circle : public Shape {
public:
void Rotate(double radians) override;
};
void Circle::Rotate(double /*radians*/) {}
// Bad - if someone wants to implement later, it's not clear what the
// variable means.
void Circle::Rotate(double) {}
Attributes, and macros that expand to attributes, appear at the very beginning of the function declaration or definition, before the return type:
MUST_USE_RESULT bool IsOK();
Format parameters and bodies as for any other function, and capture lists like other comma-separated lists.
For by-reference captures, do not leave a space between the ampersand (&) and the variable name.
int x = 0;
auto x_plus_n = [&x](int n) -> int { return x + n; }
Short lambdas may be written inline as function arguments.
std::set<int> blacklist = {7, 8, 9};
std::vector<int> digits = {3, 9, 1, 8, 4, 7, 1};
digits.erase(std::remove_if(digits.begin(), digits.end(), [&blacklist](int i) {
return blacklist.find(i) != blacklist.end();
Lambda Expressions
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e u b ac s d( ) b ac s e d();
}),
digits.end());
Either write the call all on a single line, wrap the arguments at the parenthesis, or start the arguments on a new line indented by four spaces
and continue at that 4 space indent. In the absence of other considerations, use the minimum number of lines, including placing multiple
arguments on each line where appropriate.
Function calls have the following format:
bool result = DoSomething(argument1, argument2, argument3);
If the arguments do not all fit on one line, they should be broken up onto multiple lines, with each subsequent line aligned with the first
argument. Do not add spaces after the open paren or before the close paren:
bool result = DoSomething(averyveryveryverylongargument1,
argument2, argument3);
Arguments may optionally all be placed on subsequent lines with a four space indent:
if (...) {
...
...
if (...) {
bool result = DoSomething(
argument1, argument2, // 4 space indent
argument3, argument4);
...
}
Put multiple arguments on a single line to reduce the number of lines necessary for calling a function unless there is a specific readability
problem. Some find that formatting with strictly one argument on each line is more readable and simplifies editing of the arguments. However,
we prioritize for the reader over the ease of editing arguments, and most readability problems are better addressed with the following
techniques.
Function Calls
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If having multiple arguments in a single line decreases readability due to the complexity or confusing nature of the expressions that make up
some arguments, try creating variables that capture those arguments in a descriptive name:
int my_heuristic = scores[x] * y + bases[x];
bool result = DoSomething(my_heuristic, x, y, z);
Or put the confusing argument on its own line with an explanatory comment:
bool result = DoSomething(scores[x] * y + bases[x], // Score heuristic.
x, y, z);
If there is still a case where one argument is significantly more readable on its own line, then put it on its own line. The decision should be
specific to the argument which is made more readable rather than a general policy.
Sometimes arguments form a structure that is important for readability. In those cases, feel free to format the arguments according to that
structure:
// Transform the widget by a 3x3 matrix.
my_widget.Transform(x1, x2, x3,
y1, y2, y3,
z1, z2, z3);
Format a braced initializer list exactly like you would format a function call in its place.
If the braced list follows a name (e.g. a type or variable name), format as if the {} were the parentheses of a function call with that name. If
there is no name, assume a zero-length name.
// Examples of braced init list on a single line.
return {foo, bar};
functioncall({foo, bar});
std::pair<int, int> p{foo, bar};
// When you have to wrap.
Braced Initializer List Format
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SomeFunction(
{"assume a zero-length name before {"},
some_other_function_parameter);
SomeType variable{
some, other, values,
{"assume a zero-length name before {"},
SomeOtherType{
"Very long string requiring the surrounding breaks.",
some, other values},
SomeOtherType{"Slightly shorter string",
some, other, values}};
SomeType variable{
"This is too long to fit all in one line"};
MyType m = { // Here, you could also break before {.
superlongvariablename1,
superlongvariablename2,
{short, interior, list},
{interiorwrappinglist,
interiorwrappinglist2}};
Prefer no spaces inside parentheses. The if and else keywords belong on separate lines.
There are two acceptable formats for a basic conditional statement. One includes spaces between the parentheses and the condition, and one
does not.
The most common form is without spaces. Either is fine, but be consistent. If you are modifying a file, use the format that is already present. If
you are writing new code, use the format that the other files in that directory or project use. If in doubt and you have no personal preference, do
not add the spaces.
if (condition) { // no spaces inside parentheses
... // 2 space indent.
} else if (...) { // The else goes on the same line as the closing brace.
...
} else {
Conditionals
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...
}
If you prefer you may add spaces inside the parentheses:
if ( condition ) { // spaces inside parentheses - rare
... // 2 space indent.
} else { // The else goes on the same line as the closing brace.
...
}
Note that in all cases you must have a space between the if and the open parenthesis. You must also have a space between the close
parenthesis and the curly brace, if you're using one.
if(condition) { // Bad - space missing after IF.
if (condition){ // Bad - space missing before {.
if(condition){ // Doubly bad.
if (condition) { // Good - proper space after IF and before {.
Short conditional statements may be written on one line if this enhances readability. You may use this only when the line is brief and the
statement does not use the else clause.
if (x == kFoo) return new Foo();
if (x == kBar) return new Bar();
This is not allowed when the if statement has an else:
// Not allowed - IF statement on one line when there is an ELSE clause
if (x) DoThis();
else DoThat();
In general, curly braces are not required for single-line statements, but they are allowed if you like them; conditional or loop statements with
complex conditions or statements may be more readable with curly braces. Some projects require that an if must always have an
accompanying brace.
if (condition)
DoSomething(); // 2 space indent.
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if (condition) {
DoSomething(); // 2 space indent.
}
However, if one part of an if-else statement uses curly braces, the other part must too:
// Not allowed - curly on IF but not ELSE
if (condition) {
foo;
} else
bar;
// Not allowed - curly on ELSE but not IF
if (condition)
foo;
else {
bar;
}
// Curly braces around both IF and ELSE required because
// one of the clauses used braces.
if (condition) {
foo;
} else {
bar;
}
Switch statements may use braces for blocks. Annotate non-trivial fall-through between cases. Braces are optional for single-statement loops.
Empty loop bodies should use either empty braces or continue.
case blocks in switch statements can have curly braces or not, depending on your preference. If you do include curly braces they should be
placed as shown below.
Loops and Switch Statements
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If not conditional on an enumerated value, switch statements should always have a default case (in the case of an enumerated value, the
compiler will warn you if any values are not handled). If the default case should never execute, treat this as an error. For example:
switch (var) {
case 0: { // 2 space indent
... // 4 space indent
break;
}
case 1: {
...
break;
}
default: {
assert(false);
}
}
Fall-through from one case label to another must be annotated using the ABSL_FALLTHROUGH_INTENDED; macro (defined in
absl/base/macros.h). ABSL_FALLTHROUGH_INTENDED; should be placed at a point of execution where a fall-through to the next case
label occurs. A common exception is consecutive case labels without intervening code, in which case no annotation is needed.
switch (x) {
case 41: // No annotation needed here.
case 43:
if (dont_be_picky) {
// Use this instead of or along with annotations in comments.
ABSL_FALLTHROUGH_INTENDED;
} else {
CloseButNoCigar();
break;
}
case 42:
DoSomethingSpecial();
ABSL_FALLTHROUGH_INTENDED;
default:
DoSomethingGeneric();
break;
}
Braces are optional for single-statement loops.
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for (int i = 0; i < kSomeNumber; ++i)
printf("I love you\n");
for (int i = 0; i < kSomeNumber; ++i) {
printf("I take it back\n");
}
Empty loop bodies should use either an empty pair of braces or continue with no braces, rather than a single semicolon.
while (condition) {
// Repeat test until it returns false.
}
for (int i = 0; i < kSomeNumber; ++i) {} // Good - one newline is also OK.
while (condition) continue; // Good - continue indicates no logic.
while (condition); // Bad - looks like part of do/while loop.
No spaces around period or arrow. Pointer operators do not have trailing spaces.
The following are examples of correctly-formatted pointer and reference expressions:
x = *p;
p = &x;
x = r.y;
x = r->y;
Note that:
There are no spaces around the period or arrow when accessing a member.
Pointer operators have no space after the * or &.
When declaring a pointer variable or argument, you may place the asterisk adjacent to either the type or to the variable name:
Pointer and Reference Expressions
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// These are fine, space preceding.
char *c;
const string &str;
// These are fine, space following.
char* c;
const string& str;
You should do this consistently within a single file, so, when modifying an existing file, use the style in that file.
It is allowed (if unusual) to declare multiple variables in the same declaration, but it is disallowed if any of those have pointer or reference
decorations. Such declarations are easily misread.
// Fine if helpful for readability.
int x, y;
int x, *y; // Disallowed - no & or * in multiple declaration
char * c; // Bad - spaces on both sides of *
const string & str; // Bad - spaces on both sides of &
When you have a boolean expression that is longer than the standard line length, be consistent in how you break up the lines.
In this example, the logical AND operator is always at the end of the lines:
if (this_one_thing > this_other_thing &&
a_third_thing == a_fourth_thing &&
yet_another && last_one) {
...
}
Note that when the code wraps in this example, both of the && logical AND operators are at the end of the line. This is more common in Google
code, though wrapping all operators at the beginning of the line is also allowed. Feel free to insert extra parentheses judiciously because they
Boolean Expressions
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can be very helpful in increasing readability when used appropriately. Also note that you should always use the punctuation operators, such as
&& and ~, rather than the word operators, such as and and compl.
Do not needlessly surround the return expression with parentheses.
Use parentheses in return expr; only where you would use them in x = expr;.
return result; // No parentheses in the simple case.
// Parentheses OK to make a complex expression more readable.
return (some_long_condition &&
another_condition);
return (value); // You wouldn't write var = (value);
return(result); // return is not a function!
Your choice of =, (), or {}.
You may choose between =, (), and {}; the following are all correct:
int x = 3;
int x(3);
int x{3};
string name = "Some Name";
string name("Some Name");
string name{"Some Name"};
Return Values
Variable and Array Initialization
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Be careful when using a braced initialization list {...} on a type with an std::initializer_list constructor. A nonempty braced-init-list
prefers the std::initializer_list constructor whenever possible. Note that empty braces {} are special, and will call a default
constructor if available. To force the non-std::initializer_list constructor, use parentheses instead of braces.
std::vector<int> v(100, 1); // A vector containing 100 items: All 1s.
std::vector<int> v{100, 1}; // A vector containing 2 items: 100 and 1.
Also, the brace form prevents narrowing of integral types. This can prevent some types of programming errors.
int pi(3.14); // OK -- pi == 3.
int pi{3.14}; // Compile error: narrowing conversion.
The hash mark that starts a preprocessor directive should always be at the beginning of the line.
Even when preprocessor directives are within the body of indented code, the directives should start at the beginning of the line.
// Good - directives at beginning of line
if (lopsided_score) {
#if DISASTER_PENDING // Correct -- Starts at beginning of line
DropEverything();
# if NOTIFY // OK but not required -- Spaces after #
NotifyClient();
# endif
#endif
BackToNormal();
}
// Bad - indented directives
if (lopsided_score) {
#if DISASTER_PENDING // Wrong! The "#if" should be at beginning of line
DropEverything();
#endif // Wrong! Do not indent "#endif"
BackToNormal();
}
Preprocessor Directives
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}
Sections in public, protected and private order, each indented one space.
The basic format for a class definition (lacking the comments, see Class Comments for a discussion of what comments are needed) is:
class MyClass : public OtherClass {
public: // Note the 1 space indent!
MyClass(); // Regular 2 space indent.
explicit MyClass(int var);
~MyClass() {}
void SomeFunction();
void SomeFunctionThatDoesNothing() {
}
void set_some_var(int var) { some_var_ = var; }
int some_var() const { return some_var_; }
private:
bool SomeInternalFunction();
int some_var_;
int some_other_var_;
};
Things to note:
Any base class name should be on the same line as the subclass name, subject to the 80-column limit.
The public:, protected:, and private: keywords should be indented one space.
Except for the first instance, these keywords should be preceded by a blank line. This rule is optional in small classes.
Do not leave a blank line after these keywords.
The public section should be first, followed by the protected and finally the private section.
See Declaration Order for rules on ordering declarations within each of these sections.
Class Format
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Constructor initializer lists can be all on one line or with subsequent lines indented four spaces.
The acceptable formats for initializer lists are:
// When everything fits on one line:
MyClass::MyClass(int var) : some_var_(var) {
DoSomething();
}
// If the signature and initializer list are not all on one line,
// you must wrap before the colon and indent 4 spaces:
MyClass::MyClass(int var)
: some_var_(var), some_other_var_(var + 1) {
DoSomething();
}
// When the list spans multiple lines, put each member on its own line
// and align them:
MyClass::MyClass(int var)
: some_var_(var), // 4 space indent
some_other_var_(var + 1) { // lined up
DoSomething();
}
// As with any other code block, the close curly can be on the same
// line as the open curly, if it fits.
MyClass::MyClass(int var)
: some_var_(var) {}
Constructor Initializer Lists
Namespace Formatting
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The contents of namespaces are not indented.
Namespaces do not add an extra level of indentation. For example, use:
namespace {
void foo() { // Correct. No extra indentation within namespace.
...
}
} // namespace
Do not indent within a namespace:
namespace {
// Wrong! Indented when it should not be.
void foo() {
...
}
} // namespace
When declaring nested namespaces, put each namespace on its own line.
namespace foo {
namespace bar {
Use of horizontal whitespace depends on location. Never put trailing whitespace at the end of a line.
General
Horizontal Whitespace
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void f(bool b) { // Open braces should always have a space before them.
...
int i = 0; // Semicolons usually have no space before them.
// Spaces inside braces for braced-init-list are optional. If you use them,
// put them on both sides!
int x[] = { 0 };
int x[] = {0};
// Spaces around the colon in inheritance and initializer lists.
class Foo : public Bar {
public:
// For inline function implementations, put spaces between the braces
// and the implementation itself.
Foo(int b) : Bar(), baz_(b) {} // No spaces inside empty braces.
void Reset() { baz_ = 0; } // Spaces separating braces from implementation.
...
Adding trailing whitespace can cause extra work for others editing the same file, when they merge, as can removing existing trailing
whitespace. So: Don't introduce trailing whitespace. Remove it if you're already changing that line, or do it in a separate clean-up operation
(preferably when no-one else is working on the file).
Loops and Conditionals
if (b) { // Space after the keyword in conditions and loops.
} else { // Spaces around else.
}
while (test) {} // There is usually no space inside parentheses.
switch (i) {
for (int i = 0; i < 5; ++i) {
// Loops and conditions may have spaces inside parentheses, but this
// is rare. Be consistent.
switch ( i ) {
if ( test ) {
for ( int i = 0; i < 5; ++i ) {
// For loops always have a space after the semicolon. They may have a space
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// before the semicolon, but this is rare.
for ( ; i < 5 ; ++i) {
...
// Range-based for loops always have a space before and after the colon.
for (auto x : counts) {
...
}
switch (i) {
case 1: // No space before colon in a switch case.
...
case 2: break; // Use a space after a colon if there's code after it.
Operators
// Assignment operators always have spaces around them.
x = 0;
// Other binary operators usually have spaces around them, but it's
// OK to remove spaces around factors. Parentheses should have no
// internal padding.
v = w * x + y / z;
v = w*x + y/z;
v = w * (x + z);
// No spaces separating unary operators and their arguments.
x = -5;
++x;
if (x && !y)
...
Templates and Casts
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// No spaces inside the angle brackets (< and >), before
// <, or between >( in a cast
std::vector<string> x;
y = static_cast<char*>(x);
// Spaces between type and pointer are OK, but be consistent.
std::vector<char *> x;
Minimize use of vertical whitespace.
This is more a principle than a rule: don't use blank lines when you don't have to. In particular, don't put more than one or two blank lines
between functions, resist starting functions with a blank line, don't end functions with a blank line, and be discriminating with your use of blank
lines inside functions.
The basic principle is: The more code that fits on one screen, the easier it is to follow and understand the control flow of the program. Of
course, readability can suffer from code being too dense as well as too spread out, so use your judgement. But in general, minimize use of
vertical whitespace.
Some rules of thumb to help when blank lines may be useful:
Blank lines at the beginning or end of a function very rarely help readability.
Blank lines inside a chain of if-else blocks may well help readability.
The coding conventions described above are mandatory. However, like all good rules, these sometimes have exceptions, which we discuss
here.
Vertical Whitespace
Exceptions to the Rules
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You may diverge from the rules when dealing with code that does not conform to this style guide.
If you find yourself modifying code that was written to specifications other than those presented by this guide, you may have to diverge from
these rules in order to stay consistent with the local conventions in that code. If you are in doubt about how to do this, ask the original author or
the person currently responsible for the code. Remember that consistency includes local consistency, too.
Windows programmers have developed their own set of coding conventions, mainly derived from the conventions in Windows headers and
other Microsoft code. We want to make it easy for anyone to understand your code, so we have a single set of guidelines for everyone writing
C++ on any platform.
It is worth reiterating a few of the guidelines that you might forget if you are used to the prevalent Windows style:
Do not use Hungarian notation (for example, naming an integer iNum). Use the Google naming conventions, including the .cc
extension for source files.
Windows defines many of its own synonyms for primitive types, such as DWORD, HANDLE, etc. It is perfectly acceptable, and encouraged,
that you use these types when calling Windows API functions. Even so, keep as close as you can to the underlying C++ types. For
example, use const TCHAR * instead of LPCTSTR.
When compiling with Microsoft Visual C++, set the compiler to warning level 3 or higher, and treat all warnings as errors.
Do not use #pragma once; instead use the standard Google include guards. The path in the include guards should be relative to the
top of your project tree.
In fact, do not use any nonstandard extensions, like #pragma and __declspec, unless you absolutely must. Using
__declspec(dllimport) and __declspec(dllexport) is allowed; however, you must use them through macros such as
DLLIMPORT and DLLEXPORT, so that someone can easily disable the extensions if they share the code.
However, there are just a few rules that we occasionally need to break on Windows:
Normally we forbid the use of multiple implementation inheritance; however, it is required when using COM and some ATL/WTL classes.
You may use multiple implementation inheritance to implement COM or ATL/WTL classes and interfaces.
Although you should not use exceptions in your own code, they are used extensively in the ATL and some STLs, including the one that
comes with Visual C++. When using the ATL, you should define _ATL_NO_EXCEPTIONS to disable exceptions. You should investigate
Existing Non-conformant Code
Windows Code
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whether you can also disable exceptions in your STL, but if not, it is OK to turn on exceptions in the compiler. (Note that this is only to
get the STL to compile. You should still not write exception handling code yourself.)
The usual way of working with precompiled headers is to include a header file at the top of each source file, typically with a name like
StdAfx.h or precompile.h. To make your code easier to share with other projects, avoid including this file explicitly (except in
precompile.cc), and use the /FI compiler option to include the file automatically.
Resource headers, which are usually named resource.h and contain only macros, do not need to conform to these style guidelines.
Use common sense and BE CONSISTENT.
If you are editing code, take a few minutes to look at the code around you and determine its style. If they use spaces around their if clauses,
you should, too. If their comments have little boxes of stars around them, make your comments have little boxes of stars around them too.
The point of having style guidelines is to have a common vocabulary of coding so people can concentrate on what you are saying, rather than
on how you are saying it. We present global style rules here so people know the vocabulary. But local style is also important. If code you add to
a file looks drastically different from the existing code around it, the discontinuity throws readers out of their rhythm when they go to read it. Try
to avoid this.
OK, enough writing about writing code; the code itself is much more interesting. Have fun!
Parting Words