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1 // Copyright 2014 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4 
5 // This file contains macros and macro-like constructs (e.g., templates) that
6 // are commonly used throughout Chromium source. (It may also contain things
7 // that are closely related to things that are commonly used that belong in this
8 // file.)
9 
10 #ifndef BASE_MACROS_H_
11 #define BASE_MACROS_H_
12 
13 #include <stddef.h>  // For size_t.
14 #include <string.h>  // For memcpy.
15 
16 #include "quipper/base/compiler_specific.h"  // For ALLOW_UNUSED.
17 
18 // Put this in the private: declarations for a class to be uncopyable.
19 #define DISALLOW_COPY(TypeName) \
20   TypeName(const TypeName&)
21 
22 // Put this in the private: declarations for a class to be unassignable.
23 #define DISALLOW_ASSIGN(TypeName) \
24   void operator=(const TypeName&)
25 
26 // A macro to disallow the copy constructor and operator= functions
27 // This should be used in the private: declarations for a class
28 #define DISALLOW_COPY_AND_ASSIGN(TypeName) \
29   TypeName(const TypeName&);               \
30   void operator=(const TypeName&)
31 
32 // An older, deprecated, politically incorrect name for the above.
33 // NOTE: The usage of this macro was banned from our code base, but some
34 // third_party libraries are yet using it.
35 // TODO(tfarina): Figure out how to fix the usage of this macro in the
36 // third_party libraries and get rid of it.
37 #define DISALLOW_EVIL_CONSTRUCTORS(TypeName) DISALLOW_COPY_AND_ASSIGN(TypeName)
38 
39 // A macro to disallow all the implicit constructors, namely the
40 // default constructor, copy constructor and operator= functions.
41 //
42 // This should be used in the private: declarations for a class
43 // that wants to prevent anyone from instantiating it. This is
44 // especially useful for classes containing only static methods.
45 #define DISALLOW_IMPLICIT_CONSTRUCTORS(TypeName) \
46   TypeName();                                    \
47   DISALLOW_COPY_AND_ASSIGN(TypeName)
48 
49 // The arraysize(arr) macro returns the # of elements in an array arr.
50 // The expression is a compile-time constant, and therefore can be
51 // used in defining new arrays, for example.  If you use arraysize on
52 // a pointer by mistake, you will get a compile-time error.
53 //
54 // One caveat is that arraysize() doesn't accept any array of an
55 // anonymous type or a type defined inside a function.  In these rare
56 // cases, you have to use the unsafe ARRAYSIZE_UNSAFE() macro below.  This is
57 // due to a limitation in C++'s template system.  The limitation might
58 // eventually be removed, but it hasn't happened yet.
59 
60 // This template function declaration is used in defining arraysize.
61 // Note that the function doesn't need an implementation, as we only
62 // use its type.
63 template <typename T, size_t N>
64 char (&ArraySizeHelper(T (&array)[N]))[N];
65 
66 // That gcc wants both of these prototypes seems mysterious. VC, for
67 // its part, can't decide which to use (another mystery). Matching of
68 // template overloads: the final frontier.
69 #ifndef _MSC_VER
70 template <typename T, size_t N>
71 char (&ArraySizeHelper(const T (&array)[N]))[N];
72 #endif
73 
74 #define arraysize(array) (sizeof(ArraySizeHelper(array)))
75 
76 // ARRAYSIZE_UNSAFE performs essentially the same calculation as arraysize,
77 // but can be used on anonymous types or types defined inside
78 // functions.  It's less safe than arraysize as it accepts some
79 // (although not all) pointers.  Therefore, you should use arraysize
80 // whenever possible.
81 //
82 // The expression ARRAYSIZE_UNSAFE(a) is a compile-time constant of type
83 // size_t.
84 //
85 // ARRAYSIZE_UNSAFE catches a few type errors.  If you see a compiler error
86 //
87 //   "warning: division by zero in ..."
88 //
89 // when using ARRAYSIZE_UNSAFE, you are (wrongfully) giving it a pointer.
90 // You should only use ARRAYSIZE_UNSAFE on statically allocated arrays.
91 //
92 // The following comments are on the implementation details, and can
93 // be ignored by the users.
94 //
95 // ARRAYSIZE_UNSAFE(arr) works by inspecting sizeof(arr) (the # of bytes in
96 // the array) and sizeof(*(arr)) (the # of bytes in one array
97 // element).  If the former is divisible by the latter, perhaps arr is
98 // indeed an array, in which case the division result is the # of
99 // elements in the array.  Otherwise, arr cannot possibly be an array,
100 // and we generate a compiler error to prevent the code from
101 // compiling.
102 //
103 // Since the size of bool is implementation-defined, we need to cast
104 // !(sizeof(a) & sizeof(*(a))) to size_t in order to ensure the final
105 // result has type size_t.
106 //
107 // This macro is not perfect as it wrongfully accepts certain
108 // pointers, namely where the pointer size is divisible by the pointee
109 // size.  Since all our code has to go through a 32-bit compiler,
110 // where a pointer is 4 bytes, this means all pointers to a type whose
111 // size is 3 or greater than 4 will be (righteously) rejected.
112 
113 #define ARRAYSIZE_UNSAFE(a) \
114   ((sizeof(a) / sizeof(*(a))) / \
115    static_cast<size_t>(!(sizeof(a) % sizeof(*(a)))))
116 
117 
118 // Use implicit_cast as a safe version of static_cast or const_cast
119 // for upcasting in the type hierarchy (i.e. casting a pointer to Foo
120 // to a pointer to SuperclassOfFoo or casting a pointer to Foo to
121 // a const pointer to Foo).
122 // When you use implicit_cast, the compiler checks that the cast is safe.
123 // Such explicit implicit_casts are necessary in surprisingly many
124 // situations where C++ demands an exact type match instead of an
125 // argument type convertible to a target type.
126 //
127 // The From type can be inferred, so the preferred syntax for using
128 // implicit_cast is the same as for static_cast etc.:
129 //
130 //   implicit_cast<ToType>(expr)
131 //
132 // implicit_cast would have been part of the C++ standard library,
133 // but the proposal was submitted too late.  It will probably make
134 // its way into the language in the future.
135 template<typename To, typename From>
implicit_cast(From const & f)136 inline To implicit_cast(From const &f) {
137   return f;
138 }
139 
140 // The COMPILE_ASSERT macro can be used to verify that a compile time
141 // expression is true. For example, you could use it to verify the
142 // size of a static array:
143 //
144 //   COMPILE_ASSERT(ARRAYSIZE_UNSAFE(content_type_names) == CONTENT_NUM_TYPES,
145 //                  content_type_names_incorrect_size);
146 //
147 // or to make sure a struct is smaller than a certain size:
148 //
149 //   COMPILE_ASSERT(sizeof(foo) < 128, foo_too_large);
150 //
151 // The second argument to the macro is the name of the variable. If
152 // the expression is false, most compilers will issue a warning/error
153 // containing the name of the variable.
154 
155 #undef COMPILE_ASSERT
156 #define COMPILE_ASSERT(expr, msg) static_assert(expr, #msg)
157 
158 // bit_cast<Dest,Source> is a template function that implements the
159 // equivalent of "*reinterpret_cast<Dest*>(&source)".  We need this in
160 // very low-level functions like the protobuf library and fast math
161 // support.
162 //
163 //   float f = 3.14159265358979;
164 //   int i = bit_cast<int32>(f);
165 //   // i = 0x40490fdb
166 //
167 // The classical address-casting method is:
168 //
169 //   // WRONG
170 //   float f = 3.14159265358979;            // WRONG
171 //   int i = * reinterpret_cast<int*>(&f);  // WRONG
172 //
173 // The address-casting method actually produces undefined behavior
174 // according to ISO C++ specification section 3.10 -15 -.  Roughly, this
175 // section says: if an object in memory has one type, and a program
176 // accesses it with a different type, then the result is undefined
177 // behavior for most values of "different type".
178 //
179 // This is true for any cast syntax, either *(int*)&f or
180 // *reinterpret_cast<int*>(&f).  And it is particularly true for
181 // conversions between integral lvalues and floating-point lvalues.
182 //
183 // The purpose of 3.10 -15- is to allow optimizing compilers to assume
184 // that expressions with different types refer to different memory.  gcc
185 // 4.0.1 has an optimizer that takes advantage of this.  So a
186 // non-conforming program quietly produces wildly incorrect output.
187 //
188 // The problem is not the use of reinterpret_cast.  The problem is type
189 // punning: holding an object in memory of one type and reading its bits
190 // back using a different type.
191 //
192 // The C++ standard is more subtle and complex than this, but that
193 // is the basic idea.
194 //
195 // Anyways ...
196 //
197 // bit_cast<> calls memcpy() which is blessed by the standard,
198 // especially by the example in section 3.9 .  Also, of course,
199 // bit_cast<> wraps up the nasty logic in one place.
200 //
201 // Fortunately memcpy() is very fast.  In optimized mode, with a
202 // constant size, gcc 2.95.3, gcc 4.0.1, and msvc 7.1 produce inline
203 // code with the minimal amount of data movement.  On a 32-bit system,
204 // memcpy(d,s,4) compiles to one load and one store, and memcpy(d,s,8)
205 // compiles to two loads and two stores.
206 //
207 // I tested this code with gcc 2.95.3, gcc 4.0.1, icc 8.1, and msvc 7.1.
208 //
209 // WARNING: if Dest or Source is a non-POD type, the result of the memcpy
210 // is likely to surprise you.
211 
212 template <class Dest, class Source>
bit_cast(const Source & source)213 inline Dest bit_cast(const Source& source) {
214   COMPILE_ASSERT(sizeof(Dest) == sizeof(Source), VerifySizesAreEqual);
215 
216   Dest dest;
217   memcpy(&dest, &source, sizeof(dest));
218   return dest;
219 }
220 
221 // Used to explicitly mark the return value of a function as unused. If you are
222 // really sure you don't want to do anything with the return value of a function
223 // that has been marked WARN_UNUSED_RESULT, wrap it with this. Example:
224 //
225 //   scoped_ptr<MyType> my_var = ...;
226 //   if (TakeOwnership(my_var.get()) == SUCCESS)
227 //     ignore_result(my_var.release());
228 //
229 template<typename T>
ignore_result(const T &)230 inline void ignore_result(const T&) {
231 }
232 
233 // The following enum should be used only as a constructor argument to indicate
234 // that the variable has static storage class, and that the constructor should
235 // do nothing to its state.  It indicates to the reader that it is legal to
236 // declare a static instance of the class, provided the constructor is given
237 // the base::LINKER_INITIALIZED argument.  Normally, it is unsafe to declare a
238 // static variable that has a constructor or a destructor because invocation
239 // order is undefined.  However, IF the type can be initialized by filling with
240 // zeroes (which the loader does for static variables), AND the destructor also
241 // does nothing to the storage, AND there are no virtual methods, then a
242 // constructor declared as
243 //       explicit MyClass(base::LinkerInitialized x) {}
244 // and invoked as
245 //       static MyClass my_variable_name(base::LINKER_INITIALIZED);
246 namespace base {
247 enum LinkerInitialized { LINKER_INITIALIZED };
248 
249 // Use these to declare and define a static local variable (static T;) so that
250 // it is leaked so that its destructors are not called at exit. If you need
251 // thread-safe initialization, use base/lazy_instance.h instead.
252 #define CR_DEFINE_STATIC_LOCAL(type, name, arguments) \
253   static type& name = *new type arguments /* NOLINT */
254 
255 }  // base
256 
257 #endif  // BASE_MACROS_H_
258