Use a tuklib module for integer handling.

This replaces bswap.h and integer.h. The tuklib module uses <byteswap.h> on GNU, <sys/endian.h> on *BSDs and <sys/byteorder.h> on Solaris, which may contain optimized code like inline assembly.
2009-10-04 22:57:12 +03:00 · 2009-10-04 22:57:12 +03:00 · ebfb2c5e1f
parent 29fd321033
commit ebfb2c5e1f
28 changed files with 467 additions and 333 deletions
--- a/configure.ac
+++ b/configure.ac
@ -315,35 +315,6 @@ AM_CONDITIONAL(COND_ASM_X86, test "x$enable_assembler" = xx86)
 AM_CONDITIONAL(COND_ASM_X86_64, test "x$enable_assembler" = xx86_64)
 ################################
 # Fast unaligned memory access #
 ################################
 AC_MSG_CHECKING([if unaligned memory access should be used])
 AC_ARG_ENABLE([unaligned-access], AC_HELP_STRING([--enable-unaligned-access],
 		[Enable if the system supports *fast* unaligned memory access
 		with 16-bit and 32-bit integers. By default, this is enabled
 		only on x86, x86_64, and big endian PowerPC.]),
 	[], [enable_unaligned_access=auto])
 if test "x$enable_unaligned_access" = xauto ; then
 	case $host_cpu in
 		i?86|x86_64|powerpc|powerpc64)
 			enable_unaligned_access=yes
 			;;
 		*)
 			enable_unaligned_access=no
 			;;
 	esac
 fi
 if test "x$enable_unaligned_access" = xyes ; then
 	AC_DEFINE([HAVE_FAST_UNALIGNED_ACCESS], [1], [Define to 1 if
 		the system supports fast unaligned memory access.])
 	AC_MSG_RESULT([yes])
 else
 	AC_MSG_RESULT([no])
 fi
 #####################
 # Size optimization #
 #####################
@ -508,30 +479,6 @@ AC_CHECK_HEADERS([fcntl.h limits.h sys/time.h],
 	[],
 	[AC_MSG_ERROR([Required header file(s) are missing.])])
 # If any of these headers are missing, things should still work correctly:
 AC_CHECK_HEADERS([byteswap.h])
 # Even if we have byteswap.h, we may lack the specific macros/functions.
 if test x$ac_cv_header_byteswap_h = xyes ; then
 	m4_foreach([FUNC], [bswap_16,bswap_32,bswap_64], [
 		AC_MSG_CHECKING([if FUNC is available])
 		AC_LINK_IFELSE([AC_LANG_SOURCE([
 #include <byteswap.h>
 int
 main(void)
 {
 	FUNC[](42);
 	return 0;
 }
 		])], [
 			AC_DEFINE(HAVE_[]m4_toupper(FUNC), [1],
 					[Define to 1 if] FUNC [is available.])
 			AC_MSG_RESULT([yes])
 		], [AC_MSG_RESULT([no])])
 	])dnl
 fi
 ###############################################################################
 # Checks for typedefs, structures, and compiler characteristics.
@ -578,6 +525,7 @@ gl_GETOPT
 AC_CHECK_FUNCS([futimens futimes futimesat utimes utime], [break])
 TUKLIB_PROGNAME
 TUKLIB_INTEGER
 TUKLIB_PHYSMEM
 TUKLIB_CPUCORES
--- a/m4/tuklib_integer.m4
+++ b/m4/tuklib_integer.m4
@ -0,0 +1,74 @@
 #
 # SYNOPSIS
 #
 #   TUKLIB_INTEGER
 #
 # DESCRIPTION
 #
 #   Checks for tuklib_integer.h:
 #     - Endianness
 #     - Does operating system provide byte swapping macros
 #     - Does the hardware support fast unaligned access to 16-bit
 #       and 32-bit integers
 #
 # COPYING
 #
 #   Author: Lasse Collin
 #
 #   This file has been put into the public domain.
 #   You can do whatever you want with this file.
 #
 AC_DEFUN_ONCE([TUKLIB_INTEGER], [
 AC_REQUIRE([TUKLIB_COMMON])
 AC_REQUIRE([AC_C_BIGENDIAN])
 AC_CHECK_HEADERS([byteswap.h sys/endian.h sys/byteorder.h], [break])
 # Even if we have byteswap.h, we may lack the specific macros/functions.
 if test x$ac_cv_header_byteswap_h = xyes ; then
 	m4_foreach([FUNC], [bswap_16,bswap_32,bswap_64], [
 		AC_MSG_CHECKING([if FUNC is available])
 		AC_LINK_IFELSE([AC_LANG_SOURCE([
 #include <byteswap.h>
 int
 main(void)
 {
 	FUNC[](42);
 	return 0;
 }
 		])], [
 			AC_DEFINE(HAVE_[]m4_toupper(FUNC), [1],
 					[Define to 1 if] FUNC [is available.])
 			AC_MSG_RESULT([yes])
 		], [AC_MSG_RESULT([no])])
 	])dnl
 fi
 AC_MSG_CHECKING([if unaligned memory access should be used])
 AC_ARG_ENABLE([unaligned-access], AC_HELP_STRING([--enable-unaligned-access],
 		[Enable if the system supports *fast* unaligned memory access
 		with 16-bit and 32-bit integers. By default, this is enabled
 		only on x86, x86_64, and big endian PowerPC.]),
 	[], [enable_unaligned_access=auto])
 if test "x$enable_unaligned_access" = xauto ; then
 	# TODO: There may be other architectures, on which unaligned access
 	# is OK.
 	case $host_cpu in
 		i?86|x86_64|powerpc|powerpc64)
 			enable_unaligned_access=yes
 			;;
 		*)
 			enable_unaligned_access=no
 			;;
 	esac
 fi
 if test "x$enable_unaligned_access" = xyes ; then
 	AC_DEFINE([TUKLIB_FAST_UNALIGNED_ACCESS], [1], [Define to 1 if
 		the system supports fast unaligned access to 16-bit and
 		32-bit integers.])
 	AC_MSG_RESULT([yes])
 else
 	AC_MSG_RESULT([no])
 fi
 ])dnl
--- a/src/common/bswap.h
+++ b/src/common/bswap.h
@ -1,52 +0,0 @@
 ///////////////////////////////////////////////////////////////////////////////
 //
 /// \file       bswap.h
 /// \brief      Byte swapping
 //
 //  Author:     Lasse Collin
 //
 //  This file has been put into the public domain.
 //  You can do whatever you want with this file.
 //
 ///////////////////////////////////////////////////////////////////////////////
 #ifndef LZMA_BSWAP_H
 #define LZMA_BSWAP_H
 // NOTE: We assume that config.h is already #included.
 // At least glibc has byteswap.h which contains inline assembly code for
 // byteswapping. Some systems have byteswap.h but lack one or more of the
 // bswap_xx macros/functions, which is why we check them separately even
 // if byteswap.h is available.
 #ifdef HAVE_BYTESWAP_H
 #	include <byteswap.h>
 #endif
 #ifndef HAVE_BSWAP_16
 #	define bswap_16(num) \
 		(((num) << 8) | ((num) >> 8))
 #endif
 #ifndef HAVE_BSWAP_32
 #	define bswap_32(num) \
 		( (((num) << 24)                       ) \
 		| (((num) <<  8) & UINT32_C(0x00FF0000)) \
 		| (((num) >>  8) & UINT32_C(0x0000FF00)) \
 		| (((num) >> 24)                       ) )
 #endif
 #ifndef HAVE_BSWAP_64
 #	define bswap_64(num) \
 		( (((num) << 56)                               ) \
 		| (((num) << 40) & UINT64_C(0x00FF000000000000)) \
 		| (((num) << 24) & UINT64_C(0x0000FF0000000000)) \
 		| (((num) <<  8) & UINT64_C(0x000000FF00000000)) \
 		| (((num) >>  8) & UINT64_C(0x00000000FF000000)) \
 		| (((num) >> 24) & UINT64_C(0x0000000000FF0000)) \
 		| (((num) >> 40) & UINT64_C(0x000000000000FF00)) \
 		| (((num) >> 56)                               ) )
 #endif
 #endif
--- a/src/common/integer.h
+++ b/src/common/integer.h
@ -1,170 +0,0 @@
 ///////////////////////////////////////////////////////////////////////////////
 //
 /// \file       integer.h
 /// \brief      Reading and writing integers from and to buffers
 //
 //  Author:     Lasse Collin
 //
 //  This file has been put into the public domain.
 //  You can do whatever you want with this file.
 //
 ///////////////////////////////////////////////////////////////////////////////
 #ifndef LZMA_INTEGER_H
 #define LZMA_INTEGER_H
 // On big endian, we need byte swapping. These macros may be used outside
 // this file, so don't put these inside HAVE_FAST_UNALIGNED_ACCESS.
 #ifdef WORDS_BIGENDIAN
 #	include "bswap.h"
 #	define integer_le_16(n) bswap_16(n)
 #	define integer_le_32(n) bswap_32(n)
 #	define integer_le_64(n) bswap_64(n)
 #else
 #	define integer_le_16(n) (n)
 #	define integer_le_32(n) (n)
 #	define integer_le_64(n) (n)
 #endif
 // I'm aware of AC_CHECK_ALIGNED_ACCESS_REQUIRED from Autoconf archive, but
 // it's not useful here. We don't care if unaligned access is supported,
 // we care if it is fast. Some systems can emulate unaligned access in
 // software, which is horribly slow; we want to use byte-by-byte access on
 // such systems but the Autoconf test would detect such a system as
 // supporting unaligned access.
 //
 // NOTE: HAVE_FAST_UNALIGNED_ACCESS indicates only support for 16-bit and
 // 32-bit integer loads and stores. 64-bit integers may or may not work.
 // That's why 64-bit functions are commented out.
 //
 // TODO: Big endian PowerPC supports byte swapping load and store instructions
 // that also allow unaligned access. Inline assembler could be OK for that.
 //
 // Performance of these functions isn't that important until LZMA3, but it
 // doesn't hurt to have these ready already.
 #ifdef HAVE_FAST_UNALIGNED_ACCESS
 static inline uint16_t
 integer_read_16(const uint8_t buf[static 2])
 {
 	uint16_t ret = *(const uint16_t *)(buf);
 	return integer_le_16(ret);
 }
 static inline uint32_t
 integer_read_32(const uint8_t buf[static 4])
 {
 	uint32_t ret = *(const uint32_t *)(buf);
 	return integer_le_32(ret);
 }
 /*
 static inline uint64_t
 integer_read_64(const uint8_t buf[static 8])
 {
 	uint64_t ret = *(const uint64_t *)(buf);
 	return integer_le_64(ret);
 }
 */
 static inline void
 integer_write_16(uint8_t buf[static 2], uint16_t num)
 {
 	*(uint16_t *)(buf) = integer_le_16(num);
 }
 static inline void
 integer_write_32(uint8_t buf[static 4], uint32_t num)
 {
 	*(uint32_t *)(buf) = integer_le_32(num);
 }
 /*
 static inline void
 integer_write_64(uint8_t buf[static 8], uint64_t num)
 {
 	*(uint64_t *)(buf) = integer_le_64(num);
 }
 */
 #else
 static inline uint16_t
 integer_read_16(const uint8_t buf[static 2])
 {
 	uint16_t ret = buf[0] | (buf[1] << 8);
 	return ret;
 }
 static inline uint32_t
 integer_read_32(const uint8_t buf[static 4])
 {
 	uint32_t ret = buf[0];
 	ret |= (uint32_t)(buf[1]) << 8;
 	ret |= (uint32_t)(buf[2]) << 16;
 	ret |= (uint32_t)(buf[3]) << 24;
 	return ret;
 }
 /*
 static inline uint64_t
 integer_read_64(const uint8_t buf[static 8])
 {
 	uint64_t ret = buf[0];
 	ret |= (uint64_t)(buf[1]) << 8;
 	ret |= (uint64_t)(buf[2]) << 16;
 	ret |= (uint64_t)(buf[3]) << 24;
 	ret |= (uint64_t)(buf[4]) << 32;
 	ret |= (uint64_t)(buf[5]) << 40;
 	ret |= (uint64_t)(buf[6]) << 48;
 	ret |= (uint64_t)(buf[7]) << 56;
 	return ret;
 }
 */
 static inline void
 integer_write_16(uint8_t buf[static 2], uint16_t num)
 {
 	buf[0] = (uint8_t)(num);
 	buf[1] = (uint8_t)(num >> 8);
 }
 static inline void
 integer_write_32(uint8_t buf[static 4], uint32_t num)
 {
 	buf[0] = (uint8_t)(num);
 	buf[1] = (uint8_t)(num >> 8);
 	buf[2] = (uint8_t)(num >> 16);
 	buf[3] = (uint8_t)(num >> 24);
 }
 /*
 static inline void
 integer_write_64(uint8_t buf[static 8], uint64_t num)
 {
 	buf[0] = (uint8_t)(num);
 	buf[1] = (uint8_t)(num >> 8);
 	buf[2] = (uint8_t)(num >> 16);
 	buf[3] = (uint8_t)(num >> 24);
 	buf[4] = (uint8_t)(num >> 32);
 	buf[5] = (uint8_t)(num >> 40);
 	buf[6] = (uint8_t)(num >> 48);
 	buf[7] = (uint8_t)(num >> 56);
 }
 */
 #endif
 #endif
--- a/src/common/tuklib_config.h
+++ b/src/common/tuklib_config.h
@ -1 +1,7 @@
-#include "sysdefs.h"
+#ifdef HAVE_CONFIG_H
 #	include "sysdefs.h"
 #else
 #	include <stddef.h>
 #	include <inttypes.h>
 #	include <limits.h>
 #endif
--- a/src/common/tuklib_integer.h
+++ b/src/common/tuklib_integer.h
@ -0,0 +1,350 @@
 ///////////////////////////////////////////////////////////////////////////////
 //
 /// \file       tuklib_integer.h
 /// \brief      Byte swapping and endianness related macros and functions
 ///
 /// This file provides macros or functions to do basic endianness related
 /// integer operations (XX = 16, 32, or 64; Y = b or l):
 ///   - Byte swapping: bswapXX(num)
 ///   - Byte order conversions to/from native: convXXYe(num)
 ///   - Aligned reads: readXXYe(ptr)
 ///   - Aligned writes: writeXXYe(ptr, num)
 ///   - Unaligned reads (16/32-bit only): unaligned_readXXYe(ptr)
 ///   - Unaligned writes (16/32-bit only): unaligned_writeXXYe(ptr, num)
 ///
 /// Since they can macros, the arguments should have no side effects since
 /// they may be evaluated more than once.
 ///
 /// \todo       PowerPC and possibly some other architectures support
 ///             byte swapping load and store instructions. This file
 ///             doesn't take advantage of those instructions.
 //
 //  Author:     Lasse Collin
 //
 //  This file has been put into the public domain.
 //  You can do whatever you want with this file.
 //
 ///////////////////////////////////////////////////////////////////////////////
 #ifndef TUKLIB_INTEGER_H
 #define TUKLIB_INTEGER_H
 #include "tuklib_common.h"
 ////////////////////////////////////////
 // Operating system specific features //
 ////////////////////////////////////////
 #if defined(HAVE_BYTESWAP_H)
 	// glibc, uClibc, dietlibc
 #	include <byteswap.h>
 #	ifdef HAVE_BSWAP_16
 #		define bswap16(num) bswap_16(num)
 #	endif
 #	ifdef HAVE_BSWAP_32
 #		define bswap32(num) bswap_32(num)
 #	endif
 #	ifdef HAVE_BSWAP_64
 #		define bswap64(num) bswap_64(num)
 #	endif
 #elif defined(HAVE_SYS_ENDIAN_H)
 	// *BSDs and Darwin
 #	include <sys/endian.h>
 #elif defined(HAVE_SYS_BYTEORDER_H)
 	// Solaris
 #	include <sys/byteorder.h>
 #	ifdef BSWAP_16
 #		define bswap16(num) BSWAP_16(num)
 #	endif
 #	ifdef BSWAP_32
 #		define bswap32(num) BSWAP_32(num)
 #	endif
 #	ifdef BSWAP_64
 #		define bswap64(num) BSWAP_64(num)
 #	endif
 #	ifdef BE_16
 #		define conv16be(num) BE_16(num)
 #	endif
 #	ifdef BE_32
 #		define conv32be(num) BE_32(num)
 #	endif
 #	ifdef BE_64
 #		define conv64be(num) BE_64(num)
 #	endif
 #	ifdef LE_16
 #		define conv16le(num) LE_16(num)
 #	endif
 #	ifdef LE_32
 #		define conv32le(num) LE_32(num)
 #	endif
 #	ifdef LE_64
 #		define conv64le(num) LE_64(num)
 #	endif
 #endif
 ///////////////////
 // Byte swapping //
 ///////////////////
 #ifndef bswap16
 #	define bswap16(num) \
 		(((uint16_t)(num) << 8) | ((uint16_t)(num) >> 8))
 #endif
 #ifndef bswap32
 #	define bswap32(num) \
 		( (((uint32_t)(num) << 24)                       ) \
 		| (((uint32_t)(num) <<  8) & UINT32_C(0x00FF0000)) \
 		| (((uint32_t)(num) >>  8) & UINT32_C(0x0000FF00)) \
 		| (((uint32_t)(num) >> 24)                       ) )
 #endif
 #ifndef bswap64
 #	define bswap64(num) \
 		( (((uint64_t)(num) << 56)                               ) \
 		| (((uint64_t)(num) << 40) & UINT64_C(0x00FF000000000000)) \
 		| (((uint64_t)(num) << 24) & UINT64_C(0x0000FF0000000000)) \
 		| (((uint64_t)(num) <<  8) & UINT64_C(0x000000FF00000000)) \
 		| (((uint64_t)(num) >>  8) & UINT64_C(0x00000000FF000000)) \
 		| (((uint64_t)(num) >> 24) & UINT64_C(0x0000000000FF0000)) \
 		| (((uint64_t)(num) >> 40) & UINT64_C(0x000000000000FF00)) \
 		| (((uint64_t)(num) >> 56)                               ) )
 #endif
 // Define conversion macros using the basic byte swapping macros.
 #ifdef WORDS_BIGENDIAN
 #	ifndef conv16be
 #		define conv16be(num) ((uint16_t)(num))
 #	endif
 #	ifndef conv32be
 #		define conv32be(num) ((uint32_t)(num))
 #	endif
 #	ifndef conv64be
 #		define conv64be(num) ((uint64_t)(num))
 #	endif
 #	ifndef conv16le
 #		define conv16le(num) bswap16(num)
 #	endif
 #	ifndef conv32le
 #		define conv32le(num) bswap32(num)
 #	endif
 #	ifndef conv64le
 #		define conv64le(num) bswap64(num)
 #	endif
 #else
 #	ifndef conv16be
 #		define conv16be(num) bswap16(num)
 #	endif
 #	ifndef conv32be
 #		define conv32be(num) bswap32(num)
 #	endif
 #	ifndef conv64be
 #		define conv64be(num) bswap64(num)
 #	endif
 #	ifndef conv16le
 #		define conv16le(num) ((uint16_t)(num))
 #	endif
 #	ifndef conv32le
 #		define conv32le(num) ((uint32_t)(num))
 #	endif
 #	ifndef conv64le
 #		define conv64le(num) ((uint64_t)(num))
 #	endif
 #endif
 //////////////////////////////
 // Aligned reads and writes //
 //////////////////////////////
 static inline uint16_t
 read16be(const uint8_t *buf)
 {
 	uint16_t num = *(const uint16_t *)buf;
 	return conv16be(num);
 }
 static inline uint16_t
 read16le(const uint8_t *buf)
 {
 	uint16_t num = *(const uint16_t *)buf;
 	return conv16le(num);
 }
 static inline uint32_t
 read32be(const uint8_t *buf)
 {
 	uint32_t num = *(const uint32_t *)buf;
 	return conv32be(num);
 }
 static inline uint32_t
 read32le(const uint8_t *buf)
 {
 	uint32_t num = *(const uint32_t *)buf;
 	return conv32le(num);
 }
 static inline uint64_t
 read64be(const uint8_t *buf)
 {
 	uint64_t num = *(const uint64_t *)buf;
 	return conv64be(num);
 }
 static inline uint64_t
 read64le(const uint8_t *buf)
 {
 	uint64_t num = *(const uint64_t *)buf;
 	return conv64le(num);
 }
 // NOTE: Possible byte swapping must be done in a macro to allow GCC
 // to optimize byte swapping of constants when using glibc's or *BSD's
 // byte swapping macros. The actual write is done in an inline function
 // to make type checking of the buf pointer possible similarly to readXXYe()
 // functions. This also seems to silence a probably bogus GCC warning about
 // strict aliasing when buf points to the beginning of an uint8_t array.
 #define write16be(buf, num) write16ne((buf), conv16be(num))
 #define write16le(buf, num) write16ne((buf), conv16le(num))
 #define write32be(buf, num) write32ne((buf), conv32be(num))
 #define write32le(buf, num) write32ne((buf), conv32le(num))
 #define write64be(buf, num) write64ne((buf), conv64be(num))
 #define write64le(buf, num) write64ne((buf), conv64le(num))
 static inline void
 write16ne(uint8_t *buf, uint16_t num)
 {
 	*(uint16_t *)buf = num;
 	return;
 }
 static inline void
 write32ne(uint8_t *buf, uint32_t num)
 {
 	*(uint32_t *)buf = num;
 	return;
 }
 static inline void
 write64ne(uint8_t *buf, uint64_t num)
 {
 	*(uint64_t *)buf = num;
 	return;
 }
 ////////////////////////////////
 // Unaligned reads and writes //
 ////////////////////////////////
 // NOTE: TUKLIB_FAST_UNALIGNED_ACCESS indicates only support for 16-bit and
 // 32-bit unaligned integer loads and stores. It's possible that 64-bit
 // unaligned access doesn't work or is slower than byte-by-byte access.
 // Since unaligned 64-bit is probably not needed as often as 16-bit or
 // 32-bit, we simply don't support 64-bit unaligned access for now.
 #ifdef TUKLIB_FAST_UNALIGNED_ACCESS
 #	define unaligned_read16be read16be
 #	define unaligned_read16le read16le
 #	define unaligned_read32be read32be
 #	define unaligned_read32le read32le
 #	define unaligned_write16be write16be
 #	define unaligned_write16le write16le
 #	define unaligned_write32be write32be
 #	define unaligned_write32le write32le
 #else
 static inline uint16_t
 unaligned_read16be(const uint8_t *buf)
 {
 	uint16_t num = ((uint16_t)buf[0] << 8) | buf[1];
 	return num;
 }
 static inline uint16_t
 unaligned_read16le(const uint8_t *buf)
 {
 	uint16_t num = ((uint32_t)buf[0]) | ((uint16_t)buf[1] << 8);
 	return num;
 }
 static inline uint32_t
 unaligned_read32be(const uint8_t *buf)
 {
 	uint32_t num = (uint32_t)buf[0] << 24;
 	num |= (uint32_t)buf[1] << 16;
 	num |= (uint32_t)buf[2] << 8;
 	num |= (uint32_t)buf[3];
 	return num;
 }
 static inline uint32_t
 unaligned_read32le(const uint8_t *buf)
 {
 	uint32_t num = (uint32_t)buf[0];
 	num |= (uint32_t)buf[1] << 8;
 	num |= (uint32_t)buf[2] << 16;
 	num |= (uint32_t)buf[3] << 24;
 	return num;
 }
 static inline void
 unaligned_write16be(uint8_t *buf, uint16_t num)
 {
 	buf[0] = num >> 8;
 	buf[1] = num;
 	return;
 }
 static inline void
 unaligned_write16le(uint8_t *buf, uint16_t num)
 {
 	buf[0] = num;
 	buf[1] = num >> 8;
 	return;
 }
 static inline void
 unaligned_write32be(uint8_t *buf, uint32_t num)
 {
 	buf[0] = num >> 24;
 	buf[1] = num >> 16;
 	buf[2] = num >> 8;
 	buf[3] = num;
 	return;
 }
 static inline void
 unaligned_write32le(uint8_t *buf, uint32_t num)
 {
 	buf[0] = num;
 	buf[1] = num >> 8;
 	buf[2] = num >> 16;
 	buf[3] = num >> 24;
 	return;
 }
 #endif
 #endif
--- a/src/liblzma/check/check.c
+++ b/src/liblzma/check/check.c
@ -150,13 +150,13 @@ lzma_check_finish(lzma_check_state *check, lzma_check type)
 	switch (type) {
 #ifdef HAVE_CHECK_CRC32
 	case LZMA_CHECK_CRC32:
-		check->buffer.u32[0] = integer_le_32(check->state.crc32);
+		check->buffer.u32[0] = conv32le(check->state.crc32);
 		break;
 #endif
 #ifdef HAVE_CHECK_CRC64
 	case LZMA_CHECK_CRC64:
-		check->buffer.u64[0] = integer_le_64(check->state.crc64);
+		check->buffer.u64[0] = conv64le(check->state.crc64);
 		break;
 #endif
--- a/src/liblzma/check/crc32_fast.c
+++ b/src/liblzma/check/crc32_fast.c
@ -29,7 +29,7 @@ lzma_crc32(const uint8_t *buf, size_t size, uint32_t crc)
 	crc = ~crc;
 #ifdef WORDS_BIGENDIAN
-	crc = bswap_32(crc);
+	crc = bswap32(crc);
 #endif
 	if (size > 8) {
@ -75,7 +75,7 @@ lzma_crc32(const uint8_t *buf, size_t size, uint32_t crc)
 		crc = lzma_crc32_table[0][*buf++ ^ A(crc)] ^ S8(crc);
 #ifdef WORDS_BIGENDIAN
-	crc = bswap_32(crc);
+	crc = bswap32(crc);
 #endif
 	return ~crc;
--- a/src/liblzma/check/crc32_tablegen.c
+++ b/src/liblzma/check/crc32_tablegen.c
@ -14,12 +14,8 @@
 //
 ///////////////////////////////////////////////////////////////////////////////
 #include <inttypes.h>
 #include <stdio.h>
-
+#include "../../common/tuklib_integer.h"
 #ifdef WORDS_BIGENDIAN
 #	include "../../common/bswap.h"
 #endif
 static uint32_t crc32_table[8][256];
@ -48,7 +44,7 @@ init_crc32_table(void)
 #ifdef WORDS_BIGENDIAN
 	for (size_t s = 0; s < 8; ++s)
 		for (size_t b = 0; b < 256; ++b)
-			crc32_table[s][b] = bswap_32(crc32_table[s][b]);
+			crc32_table[s][b] = bswap32(crc32_table[s][b]);
 #endif
 	return;
--- a/src/liblzma/check/crc64_fast.c
+++ b/src/liblzma/check/crc64_fast.c
@ -32,7 +32,7 @@ lzma_crc64(const uint8_t *buf, size_t size, uint64_t crc)
 	crc = ~crc;
 #ifdef WORDS_BIGENDIAN
-	crc = bswap_64(crc);
+	crc = bswap64(crc);
 #endif
 	if (size > 4) {
@ -64,7 +64,7 @@ lzma_crc64(const uint8_t *buf, size_t size, uint64_t crc)
 		crc = lzma_crc64_table[0][*buf++ ^ A1(crc)] ^ S8(crc);
 #ifdef WORDS_BIGENDIAN
-	crc = bswap_64(crc);
+	crc = bswap64(crc);
 #endif
 	return ~crc;
--- a/src/liblzma/check/crc64_tablegen.c
+++ b/src/liblzma/check/crc64_tablegen.c
@ -13,12 +13,8 @@
 //
 ///////////////////////////////////////////////////////////////////////////////
 #include <inttypes.h>
 #include <stdio.h>
-
+#include "../../common/tuklib_integer.h"
 #ifdef WORDS_BIGENDIAN
 #	include "../../common/bswap.h"
 #endif
 static uint64_t crc64_table[4][256];
@ -47,7 +43,7 @@ init_crc64_table(void)
 #ifdef WORDS_BIGENDIAN
 	for (size_t s = 0; s < 4; ++s)
 		for (size_t b = 0; b < 256; ++b)
-			crc64_table[s][b] = bswap_64(crc64_table[s][b]);
+			crc64_table[s][b] = bswap64(crc64_table[s][b]);
 #endif
 	return;
--- a/src/liblzma/check/crc_macros.h
+++ b/src/liblzma/check/crc_macros.h
@ -11,8 +11,6 @@
 ///////////////////////////////////////////////////////////////////////////////
 #ifdef WORDS_BIGENDIAN
 #	include "../../common/bswap.h"
 #	define A(x) ((x) >> 24)
 #	define B(x) (((x) >> 16) & 0xFF)
 #	define C(x) (((x) >> 8) & 0xFF)
--- a/src/liblzma/check/sha256.c
+++ b/src/liblzma/check/sha256.c
@ -29,10 +29,6 @@
 #include "check.h"
 #ifndef WORDS_BIGENDIAN
 #	include "../../common/bswap.h"
 #endif
 // At least on x86, GCC is able to optimize this to a rotate instruction.
 #define rotr_32(num, amount) ((num) >> (amount) | (num) << (32 - (amount)))
@ -123,7 +119,7 @@ process(lzma_check_state *check)
 	uint32_t data[16];
 	for (size_t i = 0; i < 16; ++i)
-		data[i] = bswap_32(check->buffer.u32[i]);
+		data[i] = bswap32(check->buffer.u32[i]);
 	transform(check->state.sha256.state, data);
 #endif
@ -194,20 +190,12 @@ lzma_sha256_finish(lzma_check_state *check)
 	// Convert the message size from bytes to bits.
 	check->state.sha256.size *= 8;
-#ifdef WORDS_BIGENDIAN
+	check->buffer.u64[(64 - 8) / 8] = conv64be(check->state.sha256.size);
 	check->buffer.u64[(64 - 8) / 8] = check->state.sha256.size;
 #else
 	check->buffer.u64[(64 - 8) / 8] = bswap_64(check->state.sha256.size);
 #endif
 	process(check);
 	for (size_t i = 0; i < 8; ++i)
-#ifdef WORDS_BIGENDIAN
+		check->buffer.u32[i] = conv32be(check->state.sha256.state[i]);
 		check->buffer.u32[i] = check->state.sha256.state[i];
 #else
 		check->buffer.u32[i] = bswap_32(check->state.sha256.state[i]);
 #endif
 	return;
 }
--- a/src/liblzma/common/alone_encoder.c
+++ b/src/liblzma/common/alone_encoder.c
@ -116,7 +116,7 @@ alone_encoder_init(lzma_next_coder *next, lzma_allocator *allocator,
 	if (d != UINT32_MAX)
 		++d;
-	integer_write_32(next->coder->header + 1, d);
+	unaligned_write32le(next->coder->header + 1, d);
 	// - Uncompressed size (always unknown and using EOPM)
 	memset(next->coder->header + 1 + 4, 0xFF, 8);
--- a/src/liblzma/common/block_header_decoder.c
+++ b/src/liblzma/common/block_header_decoder.c
@ -59,7 +59,7 @@ lzma_block_header_decode(lzma_block *block,
 	const size_t in_size = block->header_size - 4;
 	// Verify CRC32
-	if (lzma_crc32(in, in_size, 0) != integer_read_32(in + in_size))
+	if (lzma_crc32(in, in_size, 0) != unaligned_read32le(in + in_size))
 		return LZMA_DATA_ERROR;
 	// Check for unsupported flags.
--- a/src/liblzma/common/block_header_encoder.c
+++ b/src/liblzma/common/block_header_encoder.c
@ -126,7 +126,7 @@ lzma_block_header_encode(const lzma_block *block, uint8_t *out)
 	memzero(out + out_pos, out_size - out_pos);
 	// CRC32
-	integer_write_32(out + out_size, lzma_crc32(out, out_size, 0));
+	unaligned_write32le(out + out_size, lzma_crc32(out, out_size, 0));
 	return LZMA_OK;
 }
--- a/src/liblzma/common/common.h
+++ b/src/liblzma/common/common.h
@ -15,7 +15,7 @@
 #include "sysdefs.h"
 #include "mythread.h"
-#include "integer.h"
+#include "tuklib_integer.h"
 #if defined(_WIN32) || defined(__CYGWIN__)
 #	ifdef DLL_EXPORT
--- a/src/liblzma/common/stream_flags_decoder.c
+++ b/src/liblzma/common/stream_flags_decoder.c
@ -38,7 +38,7 @@ lzma_stream_header_decode(lzma_stream_flags *options, const uint8_t *in)
 	// and unsupported files.
 	const uint32_t crc = lzma_crc32(in + sizeof(lzma_header_magic),
 			LZMA_STREAM_FLAGS_SIZE, 0);
-	if (crc != integer_read_32(in + sizeof(lzma_header_magic)
+	if (crc != unaligned_read32le(in + sizeof(lzma_header_magic)
 			+ LZMA_STREAM_FLAGS_SIZE))
 		return LZMA_DATA_ERROR;
@ -67,7 +67,7 @@ lzma_stream_footer_decode(lzma_stream_flags *options, const uint8_t *in)
 	// CRC32
 	const uint32_t crc = lzma_crc32(in + sizeof(uint32_t),
 			sizeof(uint32_t) + LZMA_STREAM_FLAGS_SIZE, 0);
-	if (crc != integer_read_32(in))
+	if (crc != unaligned_read32le(in))
 		return LZMA_DATA_ERROR;
 	// Stream Flags
@ -75,7 +75,7 @@ lzma_stream_footer_decode(lzma_stream_flags *options, const uint8_t *in)
 		return LZMA_OPTIONS_ERROR;
 	// Backward Size
-	options->backward_size = integer_read_32(in + sizeof(uint32_t));
+	options->backward_size = unaligned_read32le(in + sizeof(uint32_t));
 	options->backward_size = (options->backward_size + 1) * 4;
 	return LZMA_OK;
--- a/src/liblzma/common/stream_flags_encoder.c
+++ b/src/liblzma/common/stream_flags_encoder.c
@ -46,7 +46,7 @@ lzma_stream_header_encode(const lzma_stream_flags *options, uint8_t *out)
 	const uint32_t crc = lzma_crc32(out + sizeof(lzma_header_magic),
 			LZMA_STREAM_FLAGS_SIZE, 0);
-	integer_write_32(out + sizeof(lzma_header_magic)
+	unaligned_write32le(out + sizeof(lzma_header_magic)
 			+ LZMA_STREAM_FLAGS_SIZE, crc);
 	return LZMA_OK;
@ -66,7 +66,7 @@ lzma_stream_footer_encode(const lzma_stream_flags *options, uint8_t *out)
 	if (!is_backward_size_valid(options))
 		return LZMA_PROG_ERROR;
-	integer_write_32(out + 4, options->backward_size / 4 - 1);
+	unaligned_write32le(out + 4, options->backward_size / 4 - 1);
 	// Stream Flags
 	if (stream_flags_encode(options, out + 2 * 4))
@ -76,7 +76,7 @@ lzma_stream_footer_encode(const lzma_stream_flags *options, uint8_t *out)
 	const uint32_t crc = lzma_crc32(
 			out + 4, 4 + LZMA_STREAM_FLAGS_SIZE, 0);
-	integer_write_32(out, crc);
+	unaligned_write32le(out, crc);
 	// Magic
 	memcpy(out + 2 * 4 + LZMA_STREAM_FLAGS_SIZE,
--- a/src/liblzma/lz/lz_encoder_hash.h
+++ b/src/liblzma/lz/lz_encoder_hash.h
@ -37,7 +37,7 @@
 #define FIX_5_HASH_SIZE (HASH_2_SIZE + HASH_3_SIZE + HASH_4_SIZE)
 // Endianness doesn't matter in hash_2_calc() (no effect on the output).
-#ifdef HAVE_FAST_UNALIGNED_ACCESS
+#ifdef TUKLIB_FAST_UNALIGNED_ACCESS
 #	define hash_2_calc() \
 		const uint32_t hash_value = *(const uint16_t *)(cur);
 #else
--- a/src/liblzma/lzma/lzma_decoder.c
+++ b/src/liblzma/lzma/lzma_decoder.c
@ -1042,7 +1042,7 @@ lzma_lzma_props_decode(void **options, lzma_allocator *allocator,
 	// All dictionary sizes are accepted, including zero. LZ decoder
 	// will automatically use a dictionary at least a few KiB even if
 	// a smaller dictionary is requested.
-	opt->dict_size = integer_read_32(props + 1);
+	opt->dict_size = unaligned_read32le(props + 1);
 	opt->preset_dict = NULL;
 	opt->preset_dict_size = 0;
--- a/src/liblzma/lzma/lzma_encoder.c
+++ b/src/liblzma/lzma/lzma_encoder.c
@ -661,7 +661,7 @@ lzma_lzma_props_encode(const void *options, uint8_t *out)
 	if (lzma_lzma_lclppb_encode(opt, out))
 		return LZMA_PROG_ERROR;
-	integer_write_32(out + 1, opt->dict_size);
+	unaligned_write32le(out + 1, opt->dict_size);
 	return LZMA_OK;
 }
--- a/src/liblzma/lzma/lzma_encoder_private.h
+++ b/src/liblzma/lzma/lzma_encoder_private.h
@ -24,7 +24,7 @@
 // needed in lzma_lzma_optimum_*() to test if the match is at least
 // MATCH_LEN_MIN bytes. Unaligned access gives tiny gain so there's no
 // reason to not use it when it is supported.
-#ifdef HAVE_FAST_UNALIGNED_ACCESS
+#ifdef TUKLIB_FAST_UNALIGNED_ACCESS
 #	define not_equal_16(a, b) \
 		(*(const uint16_t *)(a) != *(const uint16_t *)(b))
 #else
--- a/src/liblzma/simple/simple_decoder.c
+++ b/src/liblzma/simple/simple_decoder.c
@ -28,7 +28,7 @@ lzma_simple_props_decode(void **options, lzma_allocator *allocator,
 	if (opt == NULL)
 		return LZMA_MEM_ERROR;
-	opt->start_offset = integer_read_32(props);
+	opt->start_offset = unaligned_read32le(props);
 	// Don't leave an options structure allocated if start_offset is zero.
 	if (opt->start_offset == 0)
--- a/src/liblzma/simple/simple_encoder.c
+++ b/src/liblzma/simple/simple_encoder.c
@ -32,7 +32,7 @@ lzma_simple_props_encode(const void *options, uint8_t *out)
 	if (opt == NULL || opt->start_offset == 0)
 		return LZMA_OK;
-	integer_write_32(out, opt->start_offset);
+	unaligned_write32le(out, opt->start_offset);
 	return LZMA_OK;
 }
--- a/tests/test_block_header.c
+++ b/tests/test_block_header.c
@ -211,7 +211,7 @@ test3(void)
 	// Unsupported filter
 	// NOTE: This may need updating when new IDs become supported.
 	buf[2] ^= 0x1F;
-	integer_write_32(buf + known_options.header_size - 4,
+	unaligned_write32le(buf + known_options.header_size - 4,
 			lzma_crc32(buf, known_options.header_size - 4, 0));
 	expect(lzma_block_header_decode(&decoded_options, NULL, buf)
 			== LZMA_OPTIONS_ERROR);
@ -219,7 +219,7 @@ test3(void)
 	// Non-nul Padding
 	buf[known_options.header_size - 4 - 1] ^= 1;
-	integer_write_32(buf + known_options.header_size - 4,
+	unaligned_write32le(buf + known_options.header_size - 4,
 			lzma_crc32(buf, known_options.header_size - 4, 0));
 	expect(lzma_block_header_decode(&decoded_options, NULL, buf)
 			== LZMA_OPTIONS_ERROR);
--- a/tests/test_stream_flags.c
+++ b/tests/test_stream_flags.c
@ -133,13 +133,13 @@ test_decode_invalid(void)
 	// Test 2a (valid CRC32)
 	uint32_t crc = lzma_crc32(buffer + 6, 2, 0);
-	integer_write_32(buffer + 8, crc);
+	unaligned_write32le(buffer + 8, crc);
 	succeed(test_header_decoder(LZMA_OK));
 	// Test 2b (invalid Stream Flags with valid CRC32)
 	buffer[6] ^= 0x20;
 	crc = lzma_crc32(buffer + 6, 2, 0);
-	integer_write_32(buffer + 8, crc);
+	unaligned_write32le(buffer + 8, crc);
 	succeed(test_header_decoder(LZMA_OPTIONS_ERROR));
 	// Test 3 (invalid CRC32)
@ -151,7 +151,7 @@ test_decode_invalid(void)
 	expect(lzma_stream_footer_encode(&known_flags, buffer) == LZMA_OK);
 	buffer[9] ^= 0x40;
 	crc = lzma_crc32(buffer + 4, 6, 0);
-	integer_write_32(buffer, crc);
+	unaligned_write32le(buffer, crc);
 	succeed(test_footer_decoder(LZMA_OPTIONS_ERROR));
 	// Test 5 (invalid Magic Bytes)
--- a/tests/tests.h
+++ b/tests/tests.h
@ -14,7 +14,7 @@
 #define LZMA_TESTS_H
 #include "sysdefs.h"
-#include "integer.h"
+#include "tuklib_integer.h"
 #include "lzma.h"
 #include <stdio.h>