runtime/cpp/emboss_defines.h - third_party/github.com/google/emboss - Git at Google

 // Copyright 2019 Google LLC
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 // This header contains #defines that are used to control Emboss's generated
 // code.
 //
 // These #defines are global, and *must* be defined the same way in every
 // translation unit.  In particular, if you use `-D` (or your compiler's
 // equivalent) to define some of them on the command line, you *must* pass the
 // *exact* same definition when compiling *every* file that #includes any
 // Emboss-generated or Emboss-related file, directly or indirectly.  Failure to
 // do so will lead to ODR violations and strange behavior.
 //
 // Rather than using the command line, the Emboss authors recommend that you
 // insert an #include of a custom site_defines.h between the two markers below.
 //
 // If you are using [Copybara][1] to import Emboss into your environment, you
 // can use a transform like:
 //
 //     core.replace(
 //         before = '${start_of_line}// #include "MY_SITE_DEFINES.h"',
 //         after = '${start_of_line}#include "MY_SITE_DEFINES.h"',
 //         paths = ['public/emboss_defines.h'],
 //         regex_groups = {
 //             'start_of_line': '^',
 //         },
 //     ),
 //
 // [1]: https://github.com/google/copybara
 //
 // If you are using [Bazel][2], be sure to add a dependency from the
 // //public:cpp_utils target to a target exporting your custom header:
 //
 //     core.replace(
 //         before = '${leading_whitespace}# "//MY_SITE_DEFINES:TARGET",',
 //         after = '${leading_whitespace}"//MY_SITE_DEFINES:TARGET",',
 //         paths = ['public/BUILD'],
 //         regex_groups = {
 //             'leading_whitespace': '^ *',
 //         },
 //     ),
 //
 // [2]: https://bazel.build
 #ifndef EMBOSS_PUBLIC_EMBOSS_DEFINES_H_
 #define EMBOSS_PUBLIC_EMBOSS_DEFINES_H_

 #include <cassert>

 // START INSERT_INCLUDE_SITE_DEFINES_HERE
 // #include "MY_SITE_DEFINES.h"
 // END INSERT_INCLUDE_SITE_DEFINES_HERE

 // EMBOSS_CHECK should abort the program if the given expression evaluates to
 // false.
 //
 // By default, checks are only enabled on non-NDEBUG builds.  (Note that all
 // translation units MUST be built with the same value of NDEBUG!)
 #if !defined(EMBOSS_CHECK)
 #define EMBOSS_CHECK(x) assert((x))
 #endif  // !defined(EMBOSS_CHECK)

 #if !defined(EMBOSS_CHECK_LE)
 #define EMBOSS_CHECK_LE(x, y) EMBOSS_CHECK((x) <= (y))
 #endif  // !defined(EMBOSS_CHECK_LE)

 #if !defined(EMBOSS_CHECK_LT)
 #define EMBOSS_CHECK_LT(x, y) EMBOSS_CHECK((x) < (y))
 #endif  // !defined(EMBOSS_CHECK_LT)

 #if !defined(EMBOSS_CHECK_GE)
 #define EMBOSS_CHECK_GE(x, y) EMBOSS_CHECK((x) >= (y))
 #endif  // !defined(EMBOSS_CHECK_GE)

 #if !defined(EMBOSS_CHECK_GT)
 #define EMBOSS_CHECK_GT(x, y) EMBOSS_CHECK((x) > (y))
 #endif  // !defined(EMBOSS_CHECK_GT)

 #if !defined(EMBOSS_CHECK_EQ)
 #define EMBOSS_CHECK_EQ(x, y) EMBOSS_CHECK((x) == (y))
 #endif  // !defined(EMBOSS_CHECK_EQ)

 #if !defined(EMBOSS_CHECK_NE)
 #define EMBOSS_CHECK_NE(x, y) EMBOSS_CHECK((x) == (y))
 #endif  // !defined(EMBOSS_CHECK_NE)

 // The EMBOSS_DCHECK macros, by default, work the same way as EMBOSS_CHECK;
 // EMBOSS_DCHECK is used as an assert() for logic embedded in Emboss, where
 // EMBOSS_CHECK is used to check preconditions on application logic.  Depending
 // on how much you trust the correctness of Emboss itself, you may wish to
 // disable EMBOSS_DCHECK in situations where you do not disable EMBOSS_CHECK.
 #if !defined(EMBOSS_DCHECK)
 #define EMBOSS_DCHECK(x) assert((x))
 #endif  // !defined(EMBOSS_DCHECK)

 #if !defined(EMBOSS_DCHECK_LE)
 #define EMBOSS_DCHECK_LE(x, y) EMBOSS_DCHECK((x) <= (y))
 #endif  // !defined(EMBOSS_DCHECK_LE)

 #if !defined(EMBOSS_DCHECK_LT)
 #define EMBOSS_DCHECK_LT(x, y) EMBOSS_DCHECK((x) < (y))
 #endif  // !defined(EMBOSS_DCHECK_LT)

 #if !defined(EMBOSS_DCHECK_GE)
 #define EMBOSS_DCHECK_GE(x, y) EMBOSS_DCHECK((x) >= (y))
 #endif  // !defined(EMBOSS_DCHECK_GE)

 #if !defined(EMBOSS_DCHECK_GT)
 #define EMBOSS_DCHECK_GT(x, y) EMBOSS_DCHECK((x) > (y))
 #endif  // !defined(EMBOSS_DCHECK_GT)

 #if !defined(EMBOSS_DCHECK_EQ)
 #define EMBOSS_DCHECK_EQ(x, y) EMBOSS_DCHECK((x) == (y))
 #endif  // !defined(EMBOSS_DCHECK_EQ)

 #if !defined(EMBOSS_DCHECK_NE)
 #define EMBOSS_DCHECK_NE(x, y) EMBOSS_DCHECK((x) == (y))
 #endif  // !defined(EMBOSS_DCHECK_NE)

 // Technically, the mapping from pointers to integers is implementation-defined,
 // but the standard states "[ Note: It is intended to be unsurprising to those
 // who know the addressing structure of the underlying machine. - end note ],"
 // so this should be a reasonably safe way to check that a pointer is aligned.
 #if !defined(EMBOSS_DCHECK_POINTER_ALIGNMENT)
 #define EMBOSS_DCHECK_POINTER_ALIGNMENT(p, align, offset)                  \
   EMBOSS_DCHECK_EQ(reinterpret_cast</**/ ::std::uintptr_t>((p)) % (align), \
                    (static_cast</**/ ::std::uintptr_t>((offset))))
 #endif  // !defined(EMBOSS_DCHECK_POINTER_ALIGNMENT)

 #if !defined(EMBOSS_CHECK_POINTER_ALIGNMENT)
 #define EMBOSS_CHECK_POINTER_ALIGNMENT(p, align, offset)                  \
   EMBOSS_CHECK_EQ(reinterpret_cast</**/ ::std::uintptr_t>((p)) % (align), \
                   static_cast</**/ ::std::uintptr_t>((offset)))
 #endif  // !defined(EMBOSS_CHECK_POINTER_ALIGNMENT)

 // EMBOSS_NO_OPTIMIZATIONS is used to turn off all system-specific
 // optimizations.  This is mostly intended for testing, but could be used if
 // optimizations are causing problems.
 #if !defined(EMBOSS_NO_OPTIMIZATIONS)
 #if defined(__GNUC__)  // GCC and "compatible" compilers, such as Clang.

 // GCC, Clang, and ICC only support two's-complement systems, so it is safe to
 // assume two's-complement for those systems.  In particular, this means that
 // static_cast<int>() will treat its argument as a two's-complement bit pattern,
 // which means that it is reasonable to static_cast<int>(some_unsigned_value).
 //
 // TODO(bolms): Are there actually any non-archaic systems that use any integer
 // types other than 2's-complement?
 #if !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)
 #define EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT 1
 #endif  // !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)

 #if !defined(__INTEL_COMPILER)
 // On systems with known host byte order, Emboss can always use memcpy to safely
 // and relatively efficiently read and write values from and to memory.
 // However, memcpy cannot assume that its pointers are aligned.  On common
 // platforms, particularly x86, this almost never matters; however, on some
 // systems this can add considerable overhead, as memcpy must either perform
 // byte-by-byte copies or perform tests to determine pointer alignment and then
 // dispatch to alignment-specific code.
 //
 // Platforms with no alignment restrictions:
 //
 // * x86 (except for a few SSE instructions like movdqa: see
 //   http://pzemtsov.github.io/2016/11/06/bug-story-alignment-on-x86.html)
 // * ARM systems with ARMv6 and later ISAs
 // * High-end POWER-based systems
 // * POWER-based systems with an alignment exception handler installed (but note
 //   that emulated unaligned reads are *very* slow)
 //
 // Platforms with alignment restrictions:
 //
 // * MicroBlaze
 // * Emscripten
 // * Low-end bare-metal POWER-based systems
 // * ARM systems with ARMv5 and earlier ISAs
 // * x86 with the AC bit of EEFLAGS enabled (but note that this is never enabled
 //   on any normal system, and, e.g., you will get crashes in glibc if you try
 //   to enable it)
 //
 // The naive solution is to reinterpret_cast to a type like uint32_t, then read
 // or write through that pointer; however, this can easily run afoul of C++'s
 // type aliasing rules and result in undefined behavior.
 //
 // On GCC, there is a solution to this: use the "__may_alias__" type attribute,
 // which essentially forces the type to have the same aliasing rules as char;
 // i.e., it is safe to read and write through a pointer derived from
 // reinterpret_cast<T __attribute__((__may_alias__)) *>, just as it is safe to
 // read and write through a pointer derived from reinterpret_cast<char *>.
 //
 // Note that even though ICC pretends to be compatible with GCC by defining
 // __GNUC__, it does *not* appear to support the __may_alias__ attribute.
 // (TODO(bolms): verify this if/when Emboss explicitly supports ICC.)
 //
 // Note the lack of parentheses around 't' in the expansion: unfortunately,
 // GCC's attribute syntax disallows parentheses in that particular position.
 #if !defined(EMBOSS_ALIAS_SAFE_POINTER_CAST)
 #define EMBOSS_ALIAS_SAFE_POINTER_CAST(t, x) \
   reinterpret_cast<t __attribute__((__may_alias__)) *>((x))
 #endif  // !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)
 #endif  // !defined(__INTEL_COMPILER)

 // GCC supports __BYTE_ORDER__ of __ORDER_LITTLE_ENDIAN__, __ORDER_BIG_ENDIAN__,
 // and __ORDER_PDP_ENDIAN__.  Since all available test systems are
 // __ORDER_LITTLE_ENDIAN__, only little-endian hosts get optimized code paths;
 // however, big-endian support ought to be trivial to add.
 //
 // There are no plans to support PDP-endian systems.
 #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
 // EMBOSS_LITTLE_ENDIAN_TO_NATIVE and EMBOSS_BIG_ENDIAN_TO_NATIVE can be used to
 // fix up integers after a little- or big-endian value has been memcpy'ed into
 // them.
 //
 // On little-endian systems, no fixup is needed for little-endian sources, but
 // big-endian sources require a byte swap.
 #if !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)
 #define EMBOSS_LITTLE_ENDIAN_TO_NATIVE(x) (x)
 #endif  // !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)

 #if !defined(EMBOSS_NATIVE_TO_LITTLE_ENDIAN)
 #define EMBOSS_NATIVE_TO_LITTLE_ENDIAN(x) (x)
 #endif  // !defined(EMBOSS_NATIVE_TO_LITTLE_ENDIAN)

 #if !defined(EMBOSS_BIG_ENDIAN_TO_NATIVE)
 #define EMBOSS_BIG_ENDIAN_TO_NATIVE(x) (::emboss::support::ByteSwap((x)))
 #endif  // !defined(EMBOSS_BIG_ENDIAN_TO_NATIVE)

 #if !defined(EMBOSS_NATIVE_TO_BIG_ENDIAN)
 #define EMBOSS_NATIVE_TO_BIG_ENDIAN(x) (::emboss::support::ByteSwap((x)))
 #endif  // !defined(EMBOSS_NATIVE_TO_BIG_ENDIAN)

 // TODO(bolms): Find a way to test on a big-endian architecture, and add support
 // for __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
 #endif  // __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__

 // Prior to version 4.8, __builtin_bswap16 was not available on all platforms.
 // https://gcc.gnu.org/bugzilla/show_bug.cgi?id=52624
 //
 // Clang pretends to be an earlier GCC, but does support __builtin_bswap16.
 // Clang recommends using __has_builtin(__builtin_bswap16), but unfortunately
 // that fails to compile on GCC, even with defined(__has_builtin) &&
 // __has_builtin(__builtin_bswap16), so instead Emboss just checks for
 // defined(__clang__).
 #if !defined(EMBOSS_BYTESWAP16)
 #if __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8) || defined(__clang__)
 #define EMBOSS_BYTESWAP16(x) __builtin_bswap16((x))
 #endif  // __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
 #endif  // !defined(EMBOSS_BYTESWAP16)

 #if !defined(EMBOSS_BYTESWAP32)
 #define EMBOSS_BYTESWAP32(x) __builtin_bswap32((x))
 #endif  // !defined(EMBOSS_BYTESWAP32)

 #if !defined(EMBOSS_BYTESWAP64)
 #define EMBOSS_BYTESWAP64(x) __builtin_bswap64((x))
 #endif  // !defined(EMBOSS_BYTESWAP64)

 #endif  // defined(__GNUC__)
 #endif  // !defined(EMBOSS_NO_OPTIMIZATIONS)

 #if !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)
 #define EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT 0
 #endif  // !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)

 #endif  // EMBOSS_PUBLIC_EMBOSS_DEFINES_H_
	// Copyright 2019 Google LLC
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	// This header contains #defines that are used to control Emboss's generated
	// code.
	//
	// These #defines are global, and must be defined the same way in every
	// translation unit. In particular, if you use `-D` (or your compiler's
	// equivalent) to define some of them on the command line, you must pass the
	// exact same definition when compiling every file that #includes any
	// Emboss-generated or Emboss-related file, directly or indirectly. Failure to
	// do so will lead to ODR violations and strange behavior.
	//
	// Rather than using the command line, the Emboss authors recommend that you
	// insert an #include of a custom site_defines.h between the two markers below.
	//
	// If you are using [Copybara][1] to import Emboss into your environment, you
	// can use a transform like:
	//
	// core.replace(
	// before = '${start_of_line}// #include "MY_SITE_DEFINES.h"',
	// after = '${start_of_line}#include "MY_SITE_DEFINES.h"',
	// paths = ['public/emboss_defines.h'],
	// regex_groups = {
	// 'start_of_line': '^',
	// },
	// ),
	//
	// [1]: https://github.com/google/copybara
	//
	// If you are using [Bazel][2], be sure to add a dependency from the
	// //public:cpp_utils target to a target exporting your custom header:
	//
	// core.replace(
	// before = '${leading_whitespace}# "//MY_SITE_DEFINES:TARGET",',
	// after = '${leading_whitespace}"//MY_SITE_DEFINES:TARGET",',
	// paths = ['public/BUILD'],
	// regex_groups = {
	// 'leading_whitespace': '^ *',
	// },
	// ),
	//
	// [2]: https://bazel.build
	#ifndef EMBOSS_PUBLIC_EMBOSS_DEFINES_H_
	#define EMBOSS_PUBLIC_EMBOSS_DEFINES_H_

	#include <cassert>

	// START INSERT_INCLUDE_SITE_DEFINES_HERE
	// #include "MY_SITE_DEFINES.h"
	// END INSERT_INCLUDE_SITE_DEFINES_HERE

	// EMBOSS_CHECK should abort the program if the given expression evaluates to
	// false.
	//
	// By default, checks are only enabled on non-NDEBUG builds. (Note that all
	// translation units MUST be built with the same value of NDEBUG!)
	#if !defined(EMBOSS_CHECK)
	#define EMBOSS_CHECK(x) assert((x))
	#endif // !defined(EMBOSS_CHECK)

	#if !defined(EMBOSS_CHECK_LE)
	#define EMBOSS_CHECK_LE(x, y) EMBOSS_CHECK((x) <= (y))
	#endif // !defined(EMBOSS_CHECK_LE)

	#if !defined(EMBOSS_CHECK_LT)
	#define EMBOSS_CHECK_LT(x, y) EMBOSS_CHECK((x) < (y))
	#endif // !defined(EMBOSS_CHECK_LT)

	#if !defined(EMBOSS_CHECK_GE)
	#define EMBOSS_CHECK_GE(x, y) EMBOSS_CHECK((x) >= (y))
	#endif // !defined(EMBOSS_CHECK_GE)

	#if !defined(EMBOSS_CHECK_GT)
	#define EMBOSS_CHECK_GT(x, y) EMBOSS_CHECK((x) > (y))
	#endif // !defined(EMBOSS_CHECK_GT)

	#if !defined(EMBOSS_CHECK_EQ)
	#define EMBOSS_CHECK_EQ(x, y) EMBOSS_CHECK((x) == (y))
	#endif // !defined(EMBOSS_CHECK_EQ)

	#if !defined(EMBOSS_CHECK_NE)
	#define EMBOSS_CHECK_NE(x, y) EMBOSS_CHECK((x) == (y))
	#endif // !defined(EMBOSS_CHECK_NE)

	// The EMBOSS_DCHECK macros, by default, work the same way as EMBOSS_CHECK;
	// EMBOSS_DCHECK is used as an assert() for logic embedded in Emboss, where
	// EMBOSS_CHECK is used to check preconditions on application logic. Depending
	// on how much you trust the correctness of Emboss itself, you may wish to
	// disable EMBOSS_DCHECK in situations where you do not disable EMBOSS_CHECK.
	#if !defined(EMBOSS_DCHECK)
	#define EMBOSS_DCHECK(x) assert((x))
	#endif // !defined(EMBOSS_DCHECK)

	#if !defined(EMBOSS_DCHECK_LE)
	#define EMBOSS_DCHECK_LE(x, y) EMBOSS_DCHECK((x) <= (y))
	#endif // !defined(EMBOSS_DCHECK_LE)

	#if !defined(EMBOSS_DCHECK_LT)
	#define EMBOSS_DCHECK_LT(x, y) EMBOSS_DCHECK((x) < (y))
	#endif // !defined(EMBOSS_DCHECK_LT)

	#if !defined(EMBOSS_DCHECK_GE)
	#define EMBOSS_DCHECK_GE(x, y) EMBOSS_DCHECK((x) >= (y))
	#endif // !defined(EMBOSS_DCHECK_GE)

	#if !defined(EMBOSS_DCHECK_GT)
	#define EMBOSS_DCHECK_GT(x, y) EMBOSS_DCHECK((x) > (y))
	#endif // !defined(EMBOSS_DCHECK_GT)

	#if !defined(EMBOSS_DCHECK_EQ)
	#define EMBOSS_DCHECK_EQ(x, y) EMBOSS_DCHECK((x) == (y))
	#endif // !defined(EMBOSS_DCHECK_EQ)

	#if !defined(EMBOSS_DCHECK_NE)
	#define EMBOSS_DCHECK_NE(x, y) EMBOSS_DCHECK((x) == (y))
	#endif // !defined(EMBOSS_DCHECK_NE)

	// Technically, the mapping from pointers to integers is implementation-defined,
	// but the standard states "[ Note: It is intended to be unsurprising to those
	// who know the addressing structure of the underlying machine. - end note ],"
	// so this should be a reasonably safe way to check that a pointer is aligned.
	#if !defined(EMBOSS_DCHECK_POINTER_ALIGNMENT)
	#define EMBOSS_DCHECK_POINTER_ALIGNMENT(p, align, offset) \
	EMBOSS_DCHECK_EQ(reinterpret_cast</**/ ::std::uintptr_t>((p)) % (align), \
	(static_cast</**/ ::std::uintptr_t>((offset))))
	#endif // !defined(EMBOSS_DCHECK_POINTER_ALIGNMENT)

	#if !defined(EMBOSS_CHECK_POINTER_ALIGNMENT)
	#define EMBOSS_CHECK_POINTER_ALIGNMENT(p, align, offset) \
	EMBOSS_CHECK_EQ(reinterpret_cast</**/ ::std::uintptr_t>((p)) % (align), \
	static_cast</**/ ::std::uintptr_t>((offset)))
	#endif // !defined(EMBOSS_CHECK_POINTER_ALIGNMENT)

	// EMBOSS_NO_OPTIMIZATIONS is used to turn off all system-specific
	// optimizations. This is mostly intended for testing, but could be used if
	// optimizations are causing problems.
	#if !defined(EMBOSS_NO_OPTIMIZATIONS)
	#if defined(__GNUC__) // GCC and "compatible" compilers, such as Clang.

	// GCC, Clang, and ICC only support two's-complement systems, so it is safe to
	// assume two's-complement for those systems. In particular, this means that
	// static_cast<int>() will treat its argument as a two's-complement bit pattern,
	// which means that it is reasonable to static_cast<int>(some_unsigned_value).
	//
	// TODO(bolms): Are there actually any non-archaic systems that use any integer
	// types other than 2's-complement?
	#if !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)
	#define EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT 1
	#endif // !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)

	#if !defined(__INTEL_COMPILER)
	// On systems with known host byte order, Emboss can always use memcpy to safely
	// and relatively efficiently read and write values from and to memory.
	// However, memcpy cannot assume that its pointers are aligned. On common
	// platforms, particularly x86, this almost never matters; however, on some
	// systems this can add considerable overhead, as memcpy must either perform
	// byte-by-byte copies or perform tests to determine pointer alignment and then
	// dispatch to alignment-specific code.
	//
	// Platforms with no alignment restrictions:
	//
	// * x86 (except for a few SSE instructions like movdqa: see
	// http://pzemtsov.github.io/2016/11/06/bug-story-alignment-on-x86.html)
	// * ARM systems with ARMv6 and later ISAs
	// * High-end POWER-based systems
	// * POWER-based systems with an alignment exception handler installed (but note
	// that emulated unaligned reads are very slow)
	//
	// Platforms with alignment restrictions:
	//
	// * MicroBlaze
	// * Emscripten
	// * Low-end bare-metal POWER-based systems
	// * ARM systems with ARMv5 and earlier ISAs
	// * x86 with the AC bit of EEFLAGS enabled (but note that this is never enabled
	// on any normal system, and, e.g., you will get crashes in glibc if you try
	// to enable it)
	//
	// The naive solution is to reinterpret_cast to a type like uint32_t, then read
	// or write through that pointer; however, this can easily run afoul of C++'s
	// type aliasing rules and result in undefined behavior.
	//
	// On GCC, there is a solution to this: use the "__may_alias__" type attribute,
	// which essentially forces the type to have the same aliasing rules as char;
	// i.e., it is safe to read and write through a pointer derived from
	// reinterpret_cast<T __attribute__((__may_alias__)) *>, just as it is safe to
	// read and write through a pointer derived from reinterpret_cast<char *>.
	//
	// Note that even though ICC pretends to be compatible with GCC by defining
	// __GNUC__, it does not appear to support the __may_alias__ attribute.
	// (TODO(bolms): verify this if/when Emboss explicitly supports ICC.)
	//
	// Note the lack of parentheses around 't' in the expansion: unfortunately,
	// GCC's attribute syntax disallows parentheses in that particular position.
	#if !defined(EMBOSS_ALIAS_SAFE_POINTER_CAST)
	#define EMBOSS_ALIAS_SAFE_POINTER_CAST(t, x) \
	reinterpret_cast<t __attribute__((__may_alias__)) *>((x))
	#endif // !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)
	#endif // !defined(__INTEL_COMPILER)

	// GCC supports __BYTE_ORDER__ of __ORDER_LITTLE_ENDIAN__, __ORDER_BIG_ENDIAN__,
	// and __ORDER_PDP_ENDIAN__. Since all available test systems are
	// __ORDER_LITTLE_ENDIAN__, only little-endian hosts get optimized code paths;
	// however, big-endian support ought to be trivial to add.
	//
	// There are no plans to support PDP-endian systems.
	#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
	// EMBOSS_LITTLE_ENDIAN_TO_NATIVE and EMBOSS_BIG_ENDIAN_TO_NATIVE can be used to
	// fix up integers after a little- or big-endian value has been memcpy'ed into
	// them.
	//
	// On little-endian systems, no fixup is needed for little-endian sources, but
	// big-endian sources require a byte swap.
	#if !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)
	#define EMBOSS_LITTLE_ENDIAN_TO_NATIVE(x) (x)
	#endif // !defined(EMBOSS_LITTLE_ENDIAN_TO_NATIVE)

	#if !defined(EMBOSS_NATIVE_TO_LITTLE_ENDIAN)
	#define EMBOSS_NATIVE_TO_LITTLE_ENDIAN(x) (x)
	#endif // !defined(EMBOSS_NATIVE_TO_LITTLE_ENDIAN)

	#if !defined(EMBOSS_BIG_ENDIAN_TO_NATIVE)
	#define EMBOSS_BIG_ENDIAN_TO_NATIVE(x) (::emboss::support::ByteSwap((x)))
	#endif // !defined(EMBOSS_BIG_ENDIAN_TO_NATIVE)

	#if !defined(EMBOSS_NATIVE_TO_BIG_ENDIAN)
	#define EMBOSS_NATIVE_TO_BIG_ENDIAN(x) (::emboss::support::ByteSwap((x)))
	#endif // !defined(EMBOSS_NATIVE_TO_BIG_ENDIAN)

	// TODO(bolms): Find a way to test on a big-endian architecture, and add support
	// for __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
	#endif // __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__

	// Prior to version 4.8, __builtin_bswap16 was not available on all platforms.
	// https://gcc.gnu.org/bugzilla/show_bug.cgi?id=52624
	//
	// Clang pretends to be an earlier GCC, but does support __builtin_bswap16.
	// Clang recommends using __has_builtin(__builtin_bswap16), but unfortunately
	// that fails to compile on GCC, even with defined(__has_builtin) &&
	// __has_builtin(__builtin_bswap16), so instead Emboss just checks for
	// defined(__clang__).
	#if !defined(EMBOSS_BYTESWAP16)
	#if __GNUC__ > 4 \|\| (__GNUC__ == 4 && __GNUC_MINOR__ >= 8) \|\| defined(__clang__)
	#define EMBOSS_BYTESWAP16(x) __builtin_bswap16((x))
	#endif // __GNUC__ > 4 \|\| (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
	#endif // !defined(EMBOSS_BYTESWAP16)

	#if !defined(EMBOSS_BYTESWAP32)
	#define EMBOSS_BYTESWAP32(x) __builtin_bswap32((x))
	#endif // !defined(EMBOSS_BYTESWAP32)

	#if !defined(EMBOSS_BYTESWAP64)
	#define EMBOSS_BYTESWAP64(x) __builtin_bswap64((x))
	#endif // !defined(EMBOSS_BYTESWAP64)

	#endif // defined(__GNUC__)
	#endif // !defined(EMBOSS_NO_OPTIMIZATIONS)

	#if !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)
	#define EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT 0
	#endif // !defined(EMBOSS_SYSTEM_IS_TWOS_COMPLEMENT)

	#endif // EMBOSS_PUBLIC_EMBOSS_DEFINES_H_