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// Copyright 2014 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.

#ifndef V8_BASE_MACROS_H_
#define V8_BASE_MACROS_H_

#include "src/base/compiler-specific.h"
#include "src/base/format-macros.h"
#include "src/base/logging.h"


// TODO(all) Replace all uses of this macro with C++'s offsetof. To do that, we
// have to make sure that only standard-layout types and simple field
// designators are used.
#define OFFSET_OF(type, field) \
  (reinterpret_cast<intptr_t>(&(reinterpret_cast<type*>(16)->field)) - 16)


// The arraysize(arr) macro returns the # of elements in an array arr.
// The expression is a compile-time constant, and therefore can be
// used in defining new arrays, for example.  If you use arraysize on
// a pointer by mistake, you will get a compile-time error.
#define arraysize(array) (sizeof(ArraySizeHelper(array)))


// This template function declaration is used in defining arraysize.
// Note that the function doesn't need an implementation, as we only
// use its type.
template <typename T, size_t N>
char (&ArraySizeHelper(T (&array)[N]))[N];


#if !V8_CC_MSVC
// That gcc wants both of these prototypes seems mysterious. VC, for
// its part, can't decide which to use (another mystery). Matching of
// template overloads: the final frontier.
template <typename T, size_t N>
char (&ArraySizeHelper(const T (&array)[N]))[N];
#endif


// bit_cast<Dest,Source> is a template function that implements the
// equivalent of "*reinterpret_cast<Dest*>(&source)".  We need this in
// very low-level functions like the protobuf library and fast math
// support.
//
//   float f = 3.14159265358979;
//   int i = bit_cast<int32>(f);
//   // i = 0x40490fdb
//
// The classical address-casting method is:
//
//   // WRONG
//   float f = 3.14159265358979;            // WRONG
//   int i = * reinterpret_cast<int*>(&f);  // WRONG
//
// The address-casting method actually produces undefined behavior
// according to ISO C++ specification section 3.10 -15 -.  Roughly, this
// section says: if an object in memory has one type, and a program
// accesses it with a different type, then the result is undefined
// behavior for most values of "different type".
//
// This is true for any cast syntax, either *(int*)&f or
// *reinterpret_cast<int*>(&f).  And it is particularly true for
// conversions between integral lvalues and floating-point lvalues.
//
// The purpose of 3.10 -15- is to allow optimizing compilers to assume
// that expressions with different types refer to different memory.  gcc
// 4.0.1 has an optimizer that takes advantage of this.  So a
// non-conforming program quietly produces wildly incorrect output.
//
// The problem is not the use of reinterpret_cast.  The problem is type
// punning: holding an object in memory of one type and reading its bits
// back using a different type.
//
// The C++ standard is more subtle and complex than this, but that
// is the basic idea.
//
// Anyways ...
//
// bit_cast<> calls memcpy() which is blessed by the standard,
// especially by the example in section 3.9 .  Also, of course,
// bit_cast<> wraps up the nasty logic in one place.
//
// Fortunately memcpy() is very fast.  In optimized mode, with a
// constant size, gcc 2.95.3, gcc 4.0.1, and msvc 7.1 produce inline
// code with the minimal amount of data movement.  On a 32-bit system,
// memcpy(d,s,4) compiles to one load and one store, and memcpy(d,s,8)
// compiles to two loads and two stores.
//
// I tested this code with gcc 2.95.3, gcc 4.0.1, icc 8.1, and msvc 7.1.
//
// WARNING: if Dest or Source is a non-POD type, the result of the memcpy
// is likely to surprise you.
template <class Dest, class Source>
V8_INLINE Dest bit_cast(Source const& source) {
  static_assert(sizeof(Dest) == sizeof(Source),
                "source and dest must be same size");
  Dest dest;
  memcpy(&dest, &source, sizeof(dest));
  return dest;
}


// Put this in the private: declarations for a class to be unassignable.
#define DISALLOW_ASSIGN(TypeName) void operator=(const TypeName&)


// A macro to disallow the evil copy constructor and operator= functions
// This should be used in the private: declarations for a class
#define DISALLOW_COPY_AND_ASSIGN(TypeName) \
  TypeName(const TypeName&) = delete;      \
  void operator=(const TypeName&) = delete


// A macro to disallow all the implicit constructors, namely the
// default constructor, copy constructor and operator= functions.
//
// This should be used in the private: declarations for a class
// that wants to prevent anyone from instantiating it. This is
// especially useful for classes containing only static methods.
#define DISALLOW_IMPLICIT_CONSTRUCTORS(TypeName) \
  TypeName() = delete;                           \
  DISALLOW_COPY_AND_ASSIGN(TypeName)


// Newly written code should use V8_INLINE and V8_NOINLINE directly.
#define INLINE(declarator)    V8_INLINE declarator
#define NO_INLINE(declarator) V8_NOINLINE declarator


// Newly written code should use WARN_UNUSED_RESULT.
#define MUST_USE_RESULT WARN_UNUSED_RESULT


// Define V8_USE_ADDRESS_SANITIZER macros.
#if defined(__has_feature)
#if __has_feature(address_sanitizer)
#define V8_USE_ADDRESS_SANITIZER 1
#endif
#endif

// Define DISABLE_ASAN macros.
#ifdef V8_USE_ADDRESS_SANITIZER
#define DISABLE_ASAN __attribute__((no_sanitize_address))
#else
#define DISABLE_ASAN
#endif

// DISABLE_CFI_PERF -- Disable Control Flow Integrity checks for Perf reasons.
#if !defined(DISABLE_CFI_PERF)
#if defined(__clang__) && defined(__has_attribute)
#if __has_attribute(no_sanitize)
#define DISABLE_CFI_PERF __attribute__((no_sanitize("cfi")))
#endif
#endif
#endif
#if !defined(DISABLE_CFI_PERF)
#define DISABLE_CFI_PERF
#endif

#if V8_CC_GNU
#define V8_IMMEDIATE_CRASH() __builtin_trap()
#else
#define V8_IMMEDIATE_CRASH() ((void(*)())0)()
#endif


// TODO(all) Replace all uses of this macro with static_assert, remove macro.
#define STATIC_ASSERT(test) static_assert(test, #test)


// The USE(x) template is used to silence C++ compiler warnings
// issued for (yet) unused variables (typically parameters).
template <typename T>
inline void USE(T) { }


#define IS_POWER_OF_TWO(x) ((x) != 0 && (((x) & ((x) - 1)) == 0))


// Define our own macros for writing 64-bit constants.  This is less fragile
// than defining __STDC_CONSTANT_MACROS before including <stdint.h>, and it
// works on compilers that don't have it (like MSVC).
#if V8_CC_MSVC
# define V8_UINT64_C(x)   (x ## UI64)
# define V8_INT64_C(x)    (x ## I64)
# if V8_HOST_ARCH_64_BIT
#  define V8_INTPTR_C(x)  (x ## I64)
#  define V8_PTR_PREFIX   "ll"
# else
#  define V8_INTPTR_C(x)  (x)
#  define V8_PTR_PREFIX   ""
# endif  // V8_HOST_ARCH_64_BIT
#elif V8_CC_MINGW64
# define V8_UINT64_C(x)   (x ## ULL)
# define V8_INT64_C(x)    (x ## LL)
# define V8_INTPTR_C(x)   (x ## LL)
# define V8_PTR_PREFIX    "I64"
#elif V8_HOST_ARCH_64_BIT
# if V8_OS_MACOSX || V8_OS_OPENBSD
#  define V8_UINT64_C(x)   (x ## ULL)
#  define V8_INT64_C(x)    (x ## LL)
# else
#  define V8_UINT64_C(x)   (x ## UL)
#  define V8_INT64_C(x)    (x ## L)
# endif
# define V8_INTPTR_C(x)   (x ## L)
# define V8_PTR_PREFIX    "l"
#else
# define V8_UINT64_C(x)   (x ## ULL)
# define V8_INT64_C(x)    (x ## LL)
# define V8_INTPTR_C(x)   (x)
#if V8_OS_AIX
#define V8_PTR_PREFIX "l"
#else
# define V8_PTR_PREFIX    ""
#endif
#endif

#define V8PRIxPTR V8_PTR_PREFIX "x"
#define V8PRIdPTR V8_PTR_PREFIX "d"
#define V8PRIuPTR V8_PTR_PREFIX "u"

// ptrdiff_t is 't' according to the standard, but MSVC uses 'I'.
#if V8_CC_MSVC
#define V8PRIxPTRDIFF "Ix"
#define V8PRIdPTRDIFF "Id"
#define V8PRIuPTRDIFF "Iu"
#else
#define V8PRIxPTRDIFF "tx"
#define V8PRIdPTRDIFF "td"
#define V8PRIuPTRDIFF "tu"
#endif

// Fix for Mac OS X defining uintptr_t as "unsigned long":
#if V8_OS_MACOSX
#undef V8PRIxPTR
#define V8PRIxPTR "lx"
#undef V8PRIdPTR
#define V8PRIdPTR "ld"
#undef V8PRIuPTR
#define V8PRIuPTR "lxu"
#endif

// The following macro works on both 32 and 64-bit platforms.
// Usage: instead of writing 0x1234567890123456
//      write V8_2PART_UINT64_C(0x12345678,90123456);
#define V8_2PART_UINT64_C(a, b) (((static_cast<uint64_t>(a) << 32) + 0x##b##u))


// Compute the 0-relative offset of some absolute value x of type T.
// This allows conversion of Addresses and integral types into
// 0-relative int offsets.
template <typename T>
inline intptr_t OffsetFrom(T x) {
  return x - static_cast<T>(0);
}


// Compute the absolute value of type T for some 0-relative offset x.
// This allows conversion of 0-relative int offsets into Addresses and
// integral types.
template <typename T>
inline T AddressFrom(intptr_t x) {
  return static_cast<T>(static_cast<T>(0) + x);
}


// Return the largest multiple of m which is <= x.
template <typename T>
inline T RoundDown(T x, intptr_t m) {
  DCHECK(IS_POWER_OF_TWO(m));
  return AddressFrom<T>(OffsetFrom(x) & -m);
}


// Return the smallest multiple of m which is >= x.
template <typename T>
inline T RoundUp(T x, intptr_t m) {
  return RoundDown<T>(static_cast<T>(x + m - 1), m);
}

#endif   // V8_BASE_MACROS_H_