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packaging: isolate invocation of WiX to own function...

packaging: isolate invocation of WiX to own function Like we did for Inno, we want to split out the building of Mercurial from invoking the packaging tool so that we can introduce an alternate build mechanism. As part of this refactor, there are inconsequential changes to file layouts. Before, some shared files such as the WiX binaries and merge modules would be installed under build/. Now, they are installed under build/wix-*. This is to keep implementation simpler. But it also helps keep build state more isolated. Differential Revision: https://phab.mercurial-scm.org/D8474

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      /*

       * Copyright (c) 2016-present, Yann Collet, Facebook, Inc.

       * All rights reserved.

       *

       * This source code is licensed under both the BSD-style license (found in the

       * LICENSE file in the root directory of this source tree) and the GPLv2 (found

       * in the COPYING file in the root directory of this source tree).

       * You may select, at your option, one of the above-listed licenses.

       */

      #ifndef MEM_H_MODULE

      #define MEM_H_MODULE

      #if defined (__cplusplus)

      extern "C" {

      #endif

      /*-****************************************

      *  Dependencies

      ******************************************/

      #include <stddef.h>     /* size_t, ptrdiff_t */

      #include <string.h>     /* memcpy */

      /*-****************************************

      *  Compiler specifics

      ******************************************/

      #if defined(_MSC_VER)   /* Visual Studio */

      #   include <stdlib.h>  /* _byteswap_ulong */

      #   include <intrin.h>  /* _byteswap_* */

      #endif

      #if defined(__GNUC__)

      #  define MEM_STATIC static __inline __attribute__((unused))

      #elif defined (__cplusplus) || (defined (__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) /* C99 */)

      #  define MEM_STATIC static inline

      #elif defined(_MSC_VER)

      #  define MEM_STATIC static __inline

      #else

      #  define MEM_STATIC static  /* this version may generate warnings for unused static functions; disable the relevant warning */

      #endif

      #ifndef __has_builtin

      #  define __has_builtin(x) 0  /* compat. with non-clang compilers */

      #endif

      /* code only tested on 32 and 64 bits systems */

      #define MEM_STATIC_ASSERT(c)   { enum { MEM_static_assert = 1/(int)(!!(c)) }; }

      MEM_STATIC void MEM_check(void) { MEM_STATIC_ASSERT((sizeof(size_t)==4) || (sizeof(size_t)==8)); }

      /* detects whether we are being compiled under msan */

      #if defined (__has_feature)

      #  if __has_feature(memory_sanitizer)

      #    define MEMORY_SANITIZER 1

      #  endif

      #endif

      #if defined (MEMORY_SANITIZER)

      /* Not all platforms that support msan provide sanitizers/msan_interface.h.

       * We therefore declare the functions we need ourselves, rather than trying to

       * include the header file... */

      #include <stdint.h> /* intptr_t */

      /* Make memory region fully initialized (without changing its contents). */

      void __msan_unpoison(const volatile void *a, size_t size);

      /* Make memory region fully uninitialized (without changing its contents).

         This is a legacy interface that does not update origin information. Use

         __msan_allocated_memory() instead. */

      void __msan_poison(const volatile void *a, size_t size);

      /* Returns the offset of the first (at least partially) poisoned byte in the

         memory range, or -1 if the whole range is good. */

      intptr_t __msan_test_shadow(const volatile void *x, size_t size);

      #endif

      /* detects whether we are being compiled under asan */

      #if defined (__has_feature)

      #  if __has_feature(address_sanitizer)

      #    define ADDRESS_SANITIZER 1

      #  endif

      #elif defined(__SANITIZE_ADDRESS__)

      #  define ADDRESS_SANITIZER 1

      #endif

      #if defined (ADDRESS_SANITIZER)

      /* Not all platforms that support asan provide sanitizers/asan_interface.h.

       * We therefore declare the functions we need ourselves, rather than trying to

       * include the header file... */

      /**

       * Marks a memory region (<c>[addr, addr+size)</c>) as unaddressable.

       *

       * This memory must be previously allocated by your program. Instrumented

       * code is forbidden from accessing addresses in this region until it is

       * unpoisoned. This function is not guaranteed to poison the entire region -

       * it could poison only a subregion of <c>[addr, addr+size)</c> due to ASan

       * alignment restrictions.

       *

       * \note This function is not thread-safe because no two threads can poison or

       * unpoison memory in the same memory region simultaneously.

       *

       * \param addr Start of memory region.

       * \param size Size of memory region. */

      void __asan_poison_memory_region(void const volatile *addr, size_t size);

      /**

       * Marks a memory region (<c>[addr, addr+size)</c>) as addressable.

       *

       * This memory must be previously allocated by your program. Accessing

       * addresses in this region is allowed until this region is poisoned again.

       * This function could unpoison a super-region of <c>[addr, addr+size)</c> due

       * to ASan alignment restrictions.

       *

       * \note This function is not thread-safe because no two threads can

       * poison or unpoison memory in the same memory region simultaneously.

       *

       * \param addr Start of memory region.

       * \param size Size of memory region. */

      void __asan_unpoison_memory_region(void const volatile *addr, size_t size);

      #endif

      /*-**************************************************************

      *  Basic Types

      *****************************************************************/

      #if  !defined (__VMS) && (defined (__cplusplus) || (defined (__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) /* C99 */) )

      # include <stdint.h>

        typedef   uint8_t BYTE;

        typedef  uint16_t U16;

        typedef   int16_t S16;

        typedef  uint32_t U32;

        typedef   int32_t S32;

        typedef  uint64_t U64;

        typedef   int64_t S64;

      #else

      # include <limits.h>

      #if CHAR_BIT != 8

      #  error "this implementation requires char to be exactly 8-bit type"

      #endif

        typedef unsigned char      BYTE;

      #if USHRT_MAX != 65535

      #  error "this implementation requires short to be exactly 16-bit type"

      #endif

        typedef unsigned short      U16;

        typedef   signed short      S16;

      #if UINT_MAX != 4294967295

      #  error "this implementation requires int to be exactly 32-bit type"

      #endif

        typedef unsigned int        U32;

        typedef   signed int        S32;

      /* note : there are no limits defined for long long type in C90.

       * limits exist in C99, however, in such case, <stdint.h> is preferred */

        typedef unsigned long long  U64;

        typedef   signed long long  S64;

      #endif

      /*-**************************************************************

      *  Memory I/O

      *****************************************************************/

      /* MEM_FORCE_MEMORY_ACCESS :

       * By default, access to unaligned memory is controlled by `memcpy()`, which is safe and portable.

       * Unfortunately, on some target/compiler combinations, the generated assembly is sub-optimal.

       * The below switch allow to select different access method for improved performance.

       * Method 0 (default) : use `memcpy()`. Safe and portable.

       * Method 1 : `__packed` statement. It depends on compiler extension (i.e., not portable).

       *            This method is safe if your compiler supports it, and *generally* as fast or faster than `memcpy`.

       * Method 2 : direct access. This method is portable but violate C standard.

       *            It can generate buggy code on targets depending on alignment.

       *            In some circumstances, it's the only known way to get the most performance (i.e. GCC + ARMv6)

       * See http://fastcompression.blogspot.fr/2015/08/accessing-unaligned-memory.html for details.

       * Prefer these methods in priority order (0 > 1 > 2)

       */

      #ifndef MEM_FORCE_MEMORY_ACCESS   /* can be defined externally, on command line for example */

      #  if defined(__GNUC__) && ( defined(__ARM_ARCH_6__) || defined(__ARM_ARCH_6J__) || defined(__ARM_ARCH_6K__) || defined(__ARM_ARCH_6Z__) || defined(__ARM_ARCH_6ZK__) || defined(__ARM_ARCH_6T2__) )

      #    define MEM_FORCE_MEMORY_ACCESS 2

      #  elif defined(__INTEL_COMPILER) || defined(__GNUC__) || defined(__ICCARM__)

      #    define MEM_FORCE_MEMORY_ACCESS 1

      #  endif

      #endif

      MEM_STATIC unsigned MEM_32bits(void) { return sizeof(size_t)==4; }

      MEM_STATIC unsigned MEM_64bits(void) { return sizeof(size_t)==8; }

      MEM_STATIC unsigned MEM_isLittleEndian(void)

      {

          const union { U32 u; BYTE c[4]; } one = { 1 };   /* don't use static : performance detrimental  */

          return one.c[0];

      }

      #if defined(MEM_FORCE_MEMORY_ACCESS) && (MEM_FORCE_MEMORY_ACCESS==2)

      /* violates C standard, by lying on structure alignment.

      Only use if no other choice to achieve best performance on target platform */

      MEM_STATIC U16 MEM_read16(const void* memPtr) { return *(const U16*) memPtr; }

      MEM_STATIC U32 MEM_read32(const void* memPtr) { return *(const U32*) memPtr; }

      MEM_STATIC U64 MEM_read64(const void* memPtr) { return *(const U64*) memPtr; }

      MEM_STATIC size_t MEM_readST(const void* memPtr) { return *(const size_t*) memPtr; }

      MEM_STATIC void MEM_write16(void* memPtr, U16 value) { *(U16*)memPtr = value; }

      MEM_STATIC void MEM_write32(void* memPtr, U32 value) { *(U32*)memPtr = value; }

      MEM_STATIC void MEM_write64(void* memPtr, U64 value) { *(U64*)memPtr = value; }

      #elif defined(MEM_FORCE_MEMORY_ACCESS) && (MEM_FORCE_MEMORY_ACCESS==1)

      /* __pack instructions are safer, but compiler specific, hence potentially problematic for some compilers */

      /* currently only defined for gcc and icc */

      #if defined(_MSC_VER) || (defined(__INTEL_COMPILER) && defined(WIN32))

          __pragma( pack(push, 1) )

          typedef struct { U16 v; } unalign16;

          typedef struct { U32 v; } unalign32;

          typedef struct { U64 v; } unalign64;

          typedef struct { size_t v; } unalignArch;

          __pragma( pack(pop) )

      #else

          typedef struct { U16 v; } __attribute__((packed)) unalign16;

          typedef struct { U32 v; } __attribute__((packed)) unalign32;

          typedef struct { U64 v; } __attribute__((packed)) unalign64;

          typedef struct { size_t v; } __attribute__((packed)) unalignArch;

      #endif

      MEM_STATIC U16 MEM_read16(const void* ptr) { return ((const unalign16*)ptr)->v; }

      MEM_STATIC U32 MEM_read32(const void* ptr) { return ((const unalign32*)ptr)->v; }

      MEM_STATIC U64 MEM_read64(const void* ptr) { return ((const unalign64*)ptr)->v; }

      MEM_STATIC size_t MEM_readST(const void* ptr) { return ((const unalignArch*)ptr)->v; }

      MEM_STATIC void MEM_write16(void* memPtr, U16 value) { ((unalign16*)memPtr)->v = value; }

      MEM_STATIC void MEM_write32(void* memPtr, U32 value) { ((unalign32*)memPtr)->v = value; }

      MEM_STATIC void MEM_write64(void* memPtr, U64 value) { ((unalign64*)memPtr)->v = value; }

      #else

      /* default method, safe and standard.

         can sometimes prove slower */

      MEM_STATIC U16 MEM_read16(const void* memPtr)

      {

          U16 val; memcpy(&val, memPtr, sizeof(val)); return val;

      }

      MEM_STATIC U32 MEM_read32(const void* memPtr)

      {

          U32 val; memcpy(&val, memPtr, sizeof(val)); return val;

      }

      MEM_STATIC U64 MEM_read64(const void* memPtr)

      {

          U64 val; memcpy(&val, memPtr, sizeof(val)); return val;

      }

      MEM_STATIC size_t MEM_readST(const void* memPtr)

      {

          size_t val; memcpy(&val, memPtr, sizeof(val)); return val;

      }

      MEM_STATIC void MEM_write16(void* memPtr, U16 value)

      {

          memcpy(memPtr, &value, sizeof(value));

      }

      MEM_STATIC void MEM_write32(void* memPtr, U32 value)

      {

          memcpy(memPtr, &value, sizeof(value));

      }

      MEM_STATIC void MEM_write64(void* memPtr, U64 value)

      {

          memcpy(memPtr, &value, sizeof(value));

      }

      #endif /* MEM_FORCE_MEMORY_ACCESS */

      MEM_STATIC U32 MEM_swap32(U32 in)

      {

      #if defined(_MSC_VER)     /* Visual Studio */

          return _byteswap_ulong(in);

      #elif (defined (__GNUC__) && (__GNUC__ * 100 + __GNUC_MINOR__ >= 403)) \

        || (defined(__clang__) && __has_builtin(__builtin_bswap32))

          return __builtin_bswap32(in);

      #else

          return  ((in << 24) & 0xff000000 ) |

                  ((in <<  8) & 0x00ff0000 ) |

                  ((in >>  8) & 0x0000ff00 ) |

                  ((in >> 24) & 0x000000ff );

      #endif

      }

      MEM_STATIC U64 MEM_swap64(U64 in)

      {

      #if defined(_MSC_VER)     /* Visual Studio */

          return _byteswap_uint64(in);

      #elif (defined (__GNUC__) && (__GNUC__ * 100 + __GNUC_MINOR__ >= 403)) \

        || (defined(__clang__) && __has_builtin(__builtin_bswap64))

          return __builtin_bswap64(in);

      #else

          return  ((in << 56) & 0xff00000000000000ULL) |

                  ((in << 40) & 0x00ff000000000000ULL) |

                  ((in << 24) & 0x0000ff0000000000ULL) |

                  ((in << 8)  & 0x000000ff00000000ULL) |

                  ((in >> 8)  & 0x00000000ff000000ULL) |

                  ((in >> 24) & 0x0000000000ff0000ULL) |

                  ((in >> 40) & 0x000000000000ff00ULL) |

                  ((in >> 56) & 0x00000000000000ffULL);

      #endif

      }

      MEM_STATIC size_t MEM_swapST(size_t in)

      {

          if (MEM_32bits())

              return (size_t)MEM_swap32((U32)in);

          else

              return (size_t)MEM_swap64((U64)in);

      }

      /*=== Little endian r/w ===*/

      MEM_STATIC U16 MEM_readLE16(const void* memPtr)

      {

          if (MEM_isLittleEndian())

              return MEM_read16(memPtr);

          else {

              const BYTE* p = (const BYTE*)memPtr;

              return (U16)(p[0] + (p[1]<<8));

          }

      }

      MEM_STATIC void MEM_writeLE16(void* memPtr, U16 val)

      {

          if (MEM_isLittleEndian()) {

              MEM_write16(memPtr, val);

          } else {

              BYTE* p = (BYTE*)memPtr;

              p[0] = (BYTE)val;

              p[1] = (BYTE)(val>>8);

          }

      }

      MEM_STATIC U32 MEM_readLE24(const void* memPtr)

      {

          return MEM_readLE16(memPtr) + (((const BYTE*)memPtr)[2] << 16);

      }

      MEM_STATIC void MEM_writeLE24(void* memPtr, U32 val)

      {

          MEM_writeLE16(memPtr, (U16)val);

          ((BYTE*)memPtr)[2] = (BYTE)(val>>16);

      }

      MEM_STATIC U32 MEM_readLE32(const void* memPtr)

      {

          if (MEM_isLittleEndian())

              return MEM_read32(memPtr);

          else

              return MEM_swap32(MEM_read32(memPtr));

      }

      MEM_STATIC void MEM_writeLE32(void* memPtr, U32 val32)

      {

          if (MEM_isLittleEndian())

              MEM_write32(memPtr, val32);

          else

              MEM_write32(memPtr, MEM_swap32(val32));

      }

      MEM_STATIC U64 MEM_readLE64(const void* memPtr)

      {

          if (MEM_isLittleEndian())

              return MEM_read64(memPtr);

          else

              return MEM_swap64(MEM_read64(memPtr));

      }

      MEM_STATIC void MEM_writeLE64(void* memPtr, U64 val64)

      {

          if (MEM_isLittleEndian())

              MEM_write64(memPtr, val64);

          else

              MEM_write64(memPtr, MEM_swap64(val64));

      }

      MEM_STATIC size_t MEM_readLEST(const void* memPtr)

      {

          if (MEM_32bits())

              return (size_t)MEM_readLE32(memPtr);

          else

              return (size_t)MEM_readLE64(memPtr);

      }

      MEM_STATIC void MEM_writeLEST(void* memPtr, size_t val)

      {

          if (MEM_32bits())

              MEM_writeLE32(memPtr, (U32)val);

          else

              MEM_writeLE64(memPtr, (U64)val);

      }

      /*=== Big endian r/w ===*/

      MEM_STATIC U32 MEM_readBE32(const void* memPtr)

      {

          if (MEM_isLittleEndian())

              return MEM_swap32(MEM_read32(memPtr));

          else

              return MEM_read32(memPtr);

      }

      MEM_STATIC void MEM_writeBE32(void* memPtr, U32 val32)

      {

          if (MEM_isLittleEndian())

              MEM_write32(memPtr, MEM_swap32(val32));

          else

              MEM_write32(memPtr, val32);

      }

      MEM_STATIC U64 MEM_readBE64(const void* memPtr)

      {

          if (MEM_isLittleEndian())

              return MEM_swap64(MEM_read64(memPtr));

          else

              return MEM_read64(memPtr);

      }

      MEM_STATIC void MEM_writeBE64(void* memPtr, U64 val64)

      {

          if (MEM_isLittleEndian())

              MEM_write64(memPtr, MEM_swap64(val64));

          else

              MEM_write64(memPtr, val64);

      }

      MEM_STATIC size_t MEM_readBEST(const void* memPtr)

      {

          if (MEM_32bits())

              return (size_t)MEM_readBE32(memPtr);

          else

              return (size_t)MEM_readBE64(memPtr);

      }

      MEM_STATIC void MEM_writeBEST(void* memPtr, size_t val)

      {

          if (MEM_32bits())

              MEM_writeBE32(memPtr, (U32)val);

          else

              MEM_writeBE64(memPtr, (U64)val);

      }

      #if defined (__cplusplus)

      }

      #endif

      #endif /* MEM_H_MODULE */

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				/*
				* Copyright (c) 2016-present, Yann Collet, Facebook, Inc.
				* All rights reserved.
				*
				* This source code is licensed under both the BSD-style license (found in the
				* LICENSE file in the root directory of this source tree) and the GPLv2 (found
				* in the COPYING file in the root directory of this source tree).
				* You may select, at your option, one of the above-listed licenses.
				*/

				#ifndef MEM_H_MODULE
				#define MEM_H_MODULE

				#if defined (__cplusplus)
				extern "C" {
				#endif

				/-***************************************
				* Dependencies
				******************************************/
				#include <stddef.h> /* size_t, ptrdiff_t */
				#include <string.h> /* memcpy */


				/-***************************************
				* Compiler specifics
				******************************************/
				#if defined(_MSC_VER) /* Visual Studio */
				# include <stdlib.h> /* _byteswap_ulong */
				# include <intrin.h> /* _byteswap_* */
				#endif
				#if defined(__GNUC__)
				# define MEM_STATIC static __inline __attribute__((unused))
				#elif defined (__cplusplus) \|\| (defined (__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) /* C99 */)
				# define MEM_STATIC static inline
				#elif defined(_MSC_VER)
				# define MEM_STATIC static __inline
				#else
				# define MEM_STATIC static /* this version may generate warnings for unused static functions; disable the relevant warning */
				#endif

				#ifndef __has_builtin
				# define __has_builtin(x) 0 /* compat. with non-clang compilers */
				#endif

				/* code only tested on 32 and 64 bits systems */
				#define MEM_STATIC_ASSERT(c) { enum { MEM_static_assert = 1/(int)(!!(c)) }; }
				MEM_STATIC void MEM_check(void) { MEM_STATIC_ASSERT((sizeof(size_t)==4) \|\| (sizeof(size_t)==8)); }

				/* detects whether we are being compiled under msan */
				#if defined (__has_feature)
				# if __has_feature(memory_sanitizer)
				# define MEMORY_SANITIZER 1
				# endif
				#endif

				#if defined (MEMORY_SANITIZER)
				/* Not all platforms that support msan provide sanitizers/msan_interface.h.
				* We therefore declare the functions we need ourselves, rather than trying to
				* include the header file... */

				#include <stdint.h> /* intptr_t */

				/* Make memory region fully initialized (without changing its contents). */
				void __msan_unpoison(const volatile void *a, size_t size);

				/* Make memory region fully uninitialized (without changing its contents).
				This is a legacy interface that does not update origin information. Use
				__msan_allocated_memory() instead. */
				void __msan_poison(const volatile void *a, size_t size);

				/* Returns the offset of the first (at least partially) poisoned byte in the
				memory range, or -1 if the whole range is good. */
				intptr_t __msan_test_shadow(const volatile void *x, size_t size);
				#endif

				/* detects whether we are being compiled under asan */
				#if defined (__has_feature)
				# if __has_feature(address_sanitizer)
				# define ADDRESS_SANITIZER 1
				# endif
				#elif defined(__SANITIZE_ADDRESS__)
				# define ADDRESS_SANITIZER 1
				#endif

				#if defined (ADDRESS_SANITIZER)
				/* Not all platforms that support asan provide sanitizers/asan_interface.h.
				* We therefore declare the functions we need ourselves, rather than trying to
				* include the header file... */

				/**
				* Marks a memory region (<c>[addr, addr+size)</c>) as unaddressable.
				*
				* This memory must be previously allocated by your program. Instrumented
				* code is forbidden from accessing addresses in this region until it is
				* unpoisoned. This function is not guaranteed to poison the entire region -
				* it could poison only a subregion of <c>[addr, addr+size)</c> due to ASan
				* alignment restrictions.
				*
				* \note This function is not thread-safe because no two threads can poison or
				* unpoison memory in the same memory region simultaneously.
				*
				* \param addr Start of memory region.
				* \param size Size of memory region. */
				void __asan_poison_memory_region(void const volatile *addr, size_t size);

				/**
				* Marks a memory region (<c>[addr, addr+size)</c>) as addressable.
				*
				* This memory must be previously allocated by your program. Accessing
				* addresses in this region is allowed until this region is poisoned again.
				* This function could unpoison a super-region of <c>[addr, addr+size)</c> due
				* to ASan alignment restrictions.
				*
				* \note This function is not thread-safe because no two threads can
				* poison or unpoison memory in the same memory region simultaneously.
				*
				* \param addr Start of memory region.
				* \param size Size of memory region. */
				void __asan_unpoison_memory_region(void const volatile *addr, size_t size);
				#endif


				/-*************************************************************
				* Basic Types
				*****************************************************************/
				#if !defined (__VMS) && (defined (__cplusplus) \|\| (defined (__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L) /* C99 */) )
				# include <stdint.h>
				typedef uint8_t BYTE;
				typedef uint16_t U16;
				typedef int16_t S16;
				typedef uint32_t U32;
				typedef int32_t S32;
				typedef uint64_t U64;
				typedef int64_t S64;
				#else
				# include <limits.h>
				#if CHAR_BIT != 8
				# error "this implementation requires char to be exactly 8-bit type"
				#endif
				typedef unsigned char BYTE;
				#if USHRT_MAX != 65535
				# error "this implementation requires short to be exactly 16-bit type"
				#endif
				typedef unsigned short U16;
				typedef signed short S16;
				#if UINT_MAX != 4294967295
				# error "this implementation requires int to be exactly 32-bit type"
				#endif
				typedef unsigned int U32;
				typedef signed int S32;
				/* note : there are no limits defined for long long type in C90.
				* limits exist in C99, however, in such case, <stdint.h> is preferred */
				typedef unsigned long long U64;
				typedef signed long long S64;
				#endif


				/-*************************************************************
				* Memory I/O
				*****************************************************************/
				/* MEM_FORCE_MEMORY_ACCESS :
				* By default, access to unaligned memory is controlled by `memcpy()`, which is safe and portable.
				* Unfortunately, on some target/compiler combinations, the generated assembly is sub-optimal.
				* The below switch allow to select different access method for improved performance.
				* Method 0 (default) : use `memcpy()`. Safe and portable.
				* Method 1 : `__packed` statement. It depends on compiler extension (i.e., not portable).
				* This method is safe if your compiler supports it, and generally as fast or faster than `memcpy`.
				* Method 2 : direct access. This method is portable but violate C standard.
				* It can generate buggy code on targets depending on alignment.
				* In some circumstances, it's the only known way to get the most performance (i.e. GCC + ARMv6)
				* See http://fastcompression.blogspot.fr/2015/08/accessing-unaligned-memory.html for details.
				* Prefer these methods in priority order (0 > 1 > 2)
				*/
				#ifndef MEM_FORCE_MEMORY_ACCESS /* can be defined externally, on command line for example */
				# if defined(__GNUC__) && ( defined(__ARM_ARCH_6__) \|\| defined(__ARM_ARCH_6J__) \|\| defined(__ARM_ARCH_6K__) \|\| defined(__ARM_ARCH_6Z__) \|\| defined(__ARM_ARCH_6ZK__) \|\| defined(__ARM_ARCH_6T2__) )
				# define MEM_FORCE_MEMORY_ACCESS 2
				# elif defined(__INTEL_COMPILER) \|\| defined(__GNUC__) \|\| defined(__ICCARM__)
				# define MEM_FORCE_MEMORY_ACCESS 1
				# endif
				#endif

				MEM_STATIC unsigned MEM_32bits(void) { return sizeof(size_t)==4; }
				MEM_STATIC unsigned MEM_64bits(void) { return sizeof(size_t)==8; }

				MEM_STATIC unsigned MEM_isLittleEndian(void)
				{
				const union { U32 u; BYTE c[4]; } one = { 1 }; /* don't use static : performance detrimental */
				return one.c[0];
				}

				#if defined(MEM_FORCE_MEMORY_ACCESS) && (MEM_FORCE_MEMORY_ACCESS==2)

				/* violates C standard, by lying on structure alignment.
				Only use if no other choice to achieve best performance on target platform */
				MEM_STATIC U16 MEM_read16(const void* memPtr) { return (const U16) memPtr; }
				MEM_STATIC U32 MEM_read32(const void* memPtr) { return (const U32) memPtr; }
				MEM_STATIC U64 MEM_read64(const void* memPtr) { return (const U64) memPtr; }
				MEM_STATIC size_t MEM_readST(const void* memPtr) { return (const size_t) memPtr; }

				MEM_STATIC void MEM_write16(void* memPtr, U16 value) { (U16)memPtr = value; }
				MEM_STATIC void MEM_write32(void* memPtr, U32 value) { (U32)memPtr = value; }
				MEM_STATIC void MEM_write64(void* memPtr, U64 value) { (U64)memPtr = value; }

				#elif defined(MEM_FORCE_MEMORY_ACCESS) && (MEM_FORCE_MEMORY_ACCESS==1)

				/* __pack instructions are safer, but compiler specific, hence potentially problematic for some compilers */
				/* currently only defined for gcc and icc */
				#if defined(_MSC_VER) \|\| (defined(__INTEL_COMPILER) && defined(WIN32))
				__pragma( pack(push, 1) )
				typedef struct { U16 v; } unalign16;
				typedef struct { U32 v; } unalign32;
				typedef struct { U64 v; } unalign64;
				typedef struct { size_t v; } unalignArch;
				__pragma( pack(pop) )
				#else
				typedef struct { U16 v; } __attribute__((packed)) unalign16;
				typedef struct { U32 v; } __attribute__((packed)) unalign32;
				typedef struct { U64 v; } __attribute__((packed)) unalign64;
				typedef struct { size_t v; } __attribute__((packed)) unalignArch;
				#endif

				MEM_STATIC U16 MEM_read16(const void* ptr) { return ((const unalign16*)ptr)->v; }
				MEM_STATIC U32 MEM_read32(const void* ptr) { return ((const unalign32*)ptr)->v; }
				MEM_STATIC U64 MEM_read64(const void* ptr) { return ((const unalign64*)ptr)->v; }
				MEM_STATIC size_t MEM_readST(const void* ptr) { return ((const unalignArch*)ptr)->v; }

				MEM_STATIC void MEM_write16(void* memPtr, U16 value) { ((unalign16*)memPtr)->v = value; }
				MEM_STATIC void MEM_write32(void* memPtr, U32 value) { ((unalign32*)memPtr)->v = value; }
				MEM_STATIC void MEM_write64(void* memPtr, U64 value) { ((unalign64*)memPtr)->v = value; }

				#else

				/* default method, safe and standard.
				can sometimes prove slower */

				MEM_STATIC U16 MEM_read16(const void* memPtr)
				{
				U16 val; memcpy(&val, memPtr, sizeof(val)); return val;
				}

				MEM_STATIC U32 MEM_read32(const void* memPtr)
				{
				U32 val; memcpy(&val, memPtr, sizeof(val)); return val;
				}

				MEM_STATIC U64 MEM_read64(const void* memPtr)
				{
				U64 val; memcpy(&val, memPtr, sizeof(val)); return val;
				}

				MEM_STATIC size_t MEM_readST(const void* memPtr)
				{
				size_t val; memcpy(&val, memPtr, sizeof(val)); return val;
				}

				MEM_STATIC void MEM_write16(void* memPtr, U16 value)
				{
				memcpy(memPtr, &value, sizeof(value));
				}

				MEM_STATIC void MEM_write32(void* memPtr, U32 value)
				{
				memcpy(memPtr, &value, sizeof(value));
				}

				MEM_STATIC void MEM_write64(void* memPtr, U64 value)
				{
				memcpy(memPtr, &value, sizeof(value));
				}

				#endif /* MEM_FORCE_MEMORY_ACCESS */

				MEM_STATIC U32 MEM_swap32(U32 in)
				{
				#if defined(_MSC_VER) /* Visual Studio */
				return _byteswap_ulong(in);
				#elif (defined (__GNUC__) && (__GNUC__ * 100 + __GNUC_MINOR__ >= 403)) \
				\|\| (defined(__clang__) && __has_builtin(__builtin_bswap32))
				return __builtin_bswap32(in);
				#else
				return ((in << 24) & 0xff000000 ) \|
				((in << 8) & 0x00ff0000 ) \|
				((in >> 8) & 0x0000ff00 ) \|
				((in >> 24) & 0x000000ff );
				#endif
				}

				MEM_STATIC U64 MEM_swap64(U64 in)
				{
				#if defined(_MSC_VER) /* Visual Studio */
				return _byteswap_uint64(in);
				#elif (defined (__GNUC__) && (__GNUC__ * 100 + __GNUC_MINOR__ >= 403)) \
				\|\| (defined(__clang__) && __has_builtin(__builtin_bswap64))
				return __builtin_bswap64(in);
				#else
				return ((in << 56) & 0xff00000000000000ULL) \|
				((in << 40) & 0x00ff000000000000ULL) \|
				((in << 24) & 0x0000ff0000000000ULL) \|
				((in << 8) & 0x000000ff00000000ULL) \|
				((in >> 8) & 0x00000000ff000000ULL) \|
				((in >> 24) & 0x0000000000ff0000ULL) \|
				((in >> 40) & 0x000000000000ff00ULL) \|
				((in >> 56) & 0x00000000000000ffULL);
				#endif
				}

				MEM_STATIC size_t MEM_swapST(size_t in)
				{
				if (MEM_32bits())
				return (size_t)MEM_swap32((U32)in);
				else
				return (size_t)MEM_swap64((U64)in);
				}

				/=== Little endian r/w ===/

				MEM_STATIC U16 MEM_readLE16(const void* memPtr)
				{
				if (MEM_isLittleEndian())
				return MEM_read16(memPtr);
				else {
				const BYTE* p = (const BYTE*)memPtr;
				return (U16)(p[0] + (p[1]<<8));
				}
				}

				MEM_STATIC void MEM_writeLE16(void* memPtr, U16 val)
				{
				if (MEM_isLittleEndian()) {
				MEM_write16(memPtr, val);
				} else {
				BYTE* p = (BYTE*)memPtr;
				p[0] = (BYTE)val;
				p[1] = (BYTE)(val>>8);
				}
				}

				MEM_STATIC U32 MEM_readLE24(const void* memPtr)
				{
				return MEM_readLE16(memPtr) + (((const BYTE*)memPtr)[2] << 16);
				}

				MEM_STATIC void MEM_writeLE24(void* memPtr, U32 val)
				{
				MEM_writeLE16(memPtr, (U16)val);
				((BYTE*)memPtr)[2] = (BYTE)(val>>16);
				}

				MEM_STATIC U32 MEM_readLE32(const void* memPtr)
				{
				if (MEM_isLittleEndian())
				return MEM_read32(memPtr);
				else
				return MEM_swap32(MEM_read32(memPtr));
				}

				MEM_STATIC void MEM_writeLE32(void* memPtr, U32 val32)
				{
				if (MEM_isLittleEndian())
				MEM_write32(memPtr, val32);
				else
				MEM_write32(memPtr, MEM_swap32(val32));
				}

				MEM_STATIC U64 MEM_readLE64(const void* memPtr)
				{
				if (MEM_isLittleEndian())
				return MEM_read64(memPtr);
				else
				return MEM_swap64(MEM_read64(memPtr));
				}

				MEM_STATIC void MEM_writeLE64(void* memPtr, U64 val64)
				{
				if (MEM_isLittleEndian())
				MEM_write64(memPtr, val64);
				else
				MEM_write64(memPtr, MEM_swap64(val64));
				}

				MEM_STATIC size_t MEM_readLEST(const void* memPtr)
				{
				if (MEM_32bits())
				return (size_t)MEM_readLE32(memPtr);
				else
				return (size_t)MEM_readLE64(memPtr);
				}

				MEM_STATIC void MEM_writeLEST(void* memPtr, size_t val)
				{
				if (MEM_32bits())
				MEM_writeLE32(memPtr, (U32)val);
				else
				MEM_writeLE64(memPtr, (U64)val);
				}

				/=== Big endian r/w ===/

				MEM_STATIC U32 MEM_readBE32(const void* memPtr)
				{
				if (MEM_isLittleEndian())
				return MEM_swap32(MEM_read32(memPtr));
				else
				return MEM_read32(memPtr);
				}

				MEM_STATIC void MEM_writeBE32(void* memPtr, U32 val32)
				{
				if (MEM_isLittleEndian())
				MEM_write32(memPtr, MEM_swap32(val32));
				else
				MEM_write32(memPtr, val32);
				}

				MEM_STATIC U64 MEM_readBE64(const void* memPtr)
				{
				if (MEM_isLittleEndian())
				return MEM_swap64(MEM_read64(memPtr));
				else
				return MEM_read64(memPtr);
				}

				MEM_STATIC void MEM_writeBE64(void* memPtr, U64 val64)
				{
				if (MEM_isLittleEndian())
				MEM_write64(memPtr, MEM_swap64(val64));
				else
				MEM_write64(memPtr, val64);
				}

				MEM_STATIC size_t MEM_readBEST(const void* memPtr)
				{
				if (MEM_32bits())
				return (size_t)MEM_readBE32(memPtr);
				else
				return (size_t)MEM_readBE64(memPtr);
				}

				MEM_STATIC void MEM_writeBEST(void* memPtr, size_t val)
				{
				if (MEM_32bits())
				MEM_writeBE32(memPtr, (U32)val);
				else
				MEM_writeBE64(memPtr, (U64)val);
				}


				#if defined (__cplusplus)
				}
				#endif

				#endif /* MEM_H_MODULE */