mirror of
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423 lines
15 KiB
C
423 lines
15 KiB
C
/*
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+----------------------------------------------------------------------+
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| Zend Engine |
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+----------------------------------------------------------------------+
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| Copyright (c) 1998-2009 Zend Technologies Ltd. (http://www.zend.com) |
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+----------------------------------------------------------------------+
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| This source file is subject to version 2.00 of the Zend license, |
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| that is bundled with this package in the file LICENSE, and is |
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| available through the world-wide-web at the following url: |
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| http://www.zend.com/license/2_00.txt. |
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| If you did not receive a copy of the Zend license and are unable to |
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| obtain it through the world-wide-web, please send a note to |
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| license@zend.com so we can mail you a copy immediately. |
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+----------------------------------------------------------------------+
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| Authors: Christian Seiler <chris_se@gmx.net> |
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+----------------------------------------------------------------------+
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*/
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/* $Id$ */
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#ifndef ZEND_FLOAT_H
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#define ZEND_FLOAT_H
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/*
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Define functions for FP initialization and de-initialization.
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*/
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extern ZEND_API void zend_init_fpu(TSRMLS_D);
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extern ZEND_API void zend_shutdown_fpu(TSRMLS_D);
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extern ZEND_API void zend_ensure_fpu_mode(TSRMLS_D);
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/* Copy of the contents of xpfpa.h (which is under public domain)
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See http://wiki.php.net/rfc/rounding for details.
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Cross Platform Floating Point Arithmetics
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This header file defines several platform-dependent macros that ensure
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equal and deterministic floating point behaviour across several platforms,
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compilers and architectures.
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The current macros are currently only used on x86 and x86_64 architectures,
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on every other architecture, these macros expand to NOPs. This assumes that
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other architectures do not have an internal precision and the operhand types
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define the computational precision of floating point operations. This
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assumption may be false, in that case, the author is interested in further
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details on the other platform.
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For further details, please visit:
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http://www.christian-seiler.de/projekte/fpmath/
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Version: 20090317 */
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/*
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Implementation notes:
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x86_64:
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- Since all x86_64 compilers use SSE by default, it is probably unecessary
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to use these macros there. We define them anyway since we are too lazy
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to differentiate the architecture. Also, the compiler option -mfpmath=i387
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justifies this decision.
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General:
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- It would be nice if one could detect whether SSE if used for math via some
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funky compiler defines and if so, make the macros go to NOPs. Any ideas
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on how to do that?
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MS Visual C:
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- Since MSVC users tipically don't use autoconf or CMake, we will detect
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MSVC via compile time define.
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*/
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/* MSVC detection (MSVC people usually don't use autoconf) */
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#ifdef _MSC_VER
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# if _MSC_VER >= 1500
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/* Visual C++ 2008 or higher, supports _controlfp_s */
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# define HAVE__CONTROLFP_S
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# else
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/* Visual C++ (up to 2005), supports _controlfp */
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# define HAVE__CONTROLFP
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# endif /* MSC_VER >= 1500 */
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/* Tell MSVC optimizer that we access FP environment */
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# pragma fenv_access (on)
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#endif /* _MSC_VER */
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#ifdef HAVE__CONTROLFP_S
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/* float.h defines _controlfp_s */
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# include <float.h>
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# define XPFPA_HAVE_CW 1
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# define XPFPA_CW_DATATYPE \
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unsigned int
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# define XPFPA_STORE_CW(vptr) do { \
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_controlfp_s((unsigned int *)(vptr), 0, 0); \
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} while (0)
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# define XPFPA_RESTORE_CW(vptr) do { \
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unsigned int _xpfpa_fpu_cw; \
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_controlfp_s(&_xpfpa_fpu_cw, *((unsigned int *)(vptr)), _MCW_PC); \
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} while (0)
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# define XPFPA_DECLARE \
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unsigned int _xpfpa_fpu_oldcw, _xpfpa_fpu_cw;
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# define XPFPA_SWITCH_DOUBLE() do { \
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_controlfp_s(&_xpfpa_fpu_cw, 0, 0); \
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_xpfpa_fpu_oldcw = _xpfpa_fpu_cw; \
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_controlfp_s(&_xpfpa_fpu_cw, _PC_53, _MCW_PC); \
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} while (0)
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# define XPFPA_SWITCH_SINGLE() do { \
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_controlfp_s(&_xpfpa_fpu_cw, 0, 0); \
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_xpfpa_fpu_oldcw = _xpfpa_fpu_cw; \
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_controlfp_s(&_xpfpa_fpu_cw, _PC_24, _MCW_PC); \
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} while (0)
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/* NOTE: This only sets internal precision. MSVC does NOT support double-
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extended precision! */
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() do { \
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_controlfp_s(&_xpfpa_fpu_cw, 0, 0); \
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_xpfpa_fpu_oldcw = _xpfpa_fpu_cw; \
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_controlfp_s(&_xpfpa_fpu_cw, _PC_64, _MCW_PC); \
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} while (0)
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# define XPFPA_RESTORE() \
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_controlfp_s(&_xpfpa_fpu_cw, _xpfpa_fpu_oldcw, _MCW_PC)
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/* We do NOT use the volatile return trick since _controlfp_s is a function
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call and thus FP registers are saved in memory anyway. However, we do use
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a variable to ensure that the expression passed into val will be evaluated
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*before* switching back contexts. */
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# define XPFPA_RETURN_DOUBLE(val) \
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do { \
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double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_SINGLE(val) \
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do { \
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float _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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/* This won't work, but we add a macro for it anyway. */
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) \
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do { \
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long double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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#elif defined(HAVE__CONTROLFP)
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/* float.h defines _controlfp */
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# include <float.h>
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# define XPFPA_DECLARE \
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unsigned int _xpfpa_fpu_oldcw;
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# define XPFPA_HAVE_CW 1
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# define XPFPA_CW_DATATYPE \
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unsigned int
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# define XPFPA_STORE_CW(vptr) do { \
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*((unsigned int *)(vptr)) = _controlfp(0, 0); \
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} while (0)
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# define XPFPA_RESTORE_CW(vptr) do { \
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_controlfp(*((unsigned int *)(vptr)), _MCW_PC); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE() do { \
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_xpfpa_fpu_oldcw = _controlfp(0, 0); \
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_controlfp(_PC_53, _MCW_PC); \
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} while (0)
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# define XPFPA_SWITCH_SINGLE() do { \
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_xpfpa_fpu_oldcw = _controlfp(0, 0); \
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_controlfp(_PC_24, _MCW_PC); \
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} while (0)
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/* NOTE: This will only work as expected on MinGW. */
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() do { \
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_xpfpa_fpu_oldcw = _controlfp(0, 0); \
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_controlfp(_PC_64, _MCW_PC); \
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} while (0)
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# define XPFPA_RESTORE() \
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_controlfp(_xpfpa_fpu_oldcw, _MCW_PC)
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/* We do NOT use the volatile return trick since _controlfp is a function
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call and thus FP registers are saved in memory anyway. However, we do use
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a variable to ensure that the expression passed into val will be evaluated
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*before* switching back contexts. */
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# define XPFPA_RETURN_DOUBLE(val) \
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do { \
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double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_SINGLE(val) \
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do { \
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float _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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/* This will only work on MinGW */
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) \
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do { \
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long double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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#elif defined(HAVE__FPU_SETCW) /* glibc systems */
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/* fpu_control.h defines _FPU_[GS]ETCW */
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# include <fpu_control.h>
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# define XPFPA_DECLARE \
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fpu_control_t _xpfpa_fpu_oldcw, _xpfpa_fpu_cw;
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# define XPFPA_HAVE_CW 1
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# define XPFPA_CW_DATATYPE \
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fpu_control_t
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# define XPFPA_STORE_CW(vptr) do { \
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_FPU_GETCW((*((fpu_control_t *)(vptr)))); \
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} while (0)
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# define XPFPA_RESTORE_CW(vptr) do { \
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_FPU_SETCW((*((fpu_control_t *)(vptr)))); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE() do { \
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_FPU_GETCW(_xpfpa_fpu_oldcw); \
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_xpfpa_fpu_cw = (_xpfpa_fpu_oldcw & ~_FPU_EXTENDED & ~_FPU_SINGLE) | _FPU_DOUBLE; \
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_FPU_SETCW(_xpfpa_fpu_cw); \
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} while (0)
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# define XPFPA_SWITCH_SINGLE() do { \
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_FPU_GETCW(_xpfpa_fpu_oldcw); \
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_xpfpa_fpu_cw = (_xpfpa_fpu_oldcw & ~_FPU_EXTENDED & ~_FPU_DOUBLE) | _FPU_SINGLE; \
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_FPU_SETCW(_xpfpa_fpu_cw); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() do { \
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_FPU_GETCW(_xpfpa_fpu_oldcw); \
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_xpfpa_fpu_cw = (_xpfpa_fpu_oldcw & ~_FPU_SINGLE & ~_FPU_DOUBLE) | _FPU_EXTENDED; \
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_FPU_SETCW(_xpfpa_fpu_cw); \
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} while (0)
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# define XPFPA_RESTORE() \
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_FPU_SETCW(_xpfpa_fpu_oldcw)
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/* We use a temporary volatile variable (in a new block) in order to ensure
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that the optimizer does not mis-optimize the instructions. Also, a volatile
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variable ensures truncation to correct precision. */
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# define XPFPA_RETURN_DOUBLE(val) \
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do { \
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volatile double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_SINGLE(val) \
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do { \
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volatile float _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) \
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do { \
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volatile long double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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#elif defined(HAVE_FPSETPREC) /* FreeBSD */
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/* fpu_control.h defines _FPU_[GS]ETCW */
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# include <machine/ieeefp.h>
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# define XPFPA_DECLARE \
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fp_prec_t _xpfpa_fpu_oldprec;
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# define XPFPA_HAVE_CW 1
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# define XPFPA_CW_DATATYPE \
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fp_prec_t
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# define XPFPA_STORE_CW(vptr) do { \
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*((fp_prec_t *)(vptr)) = fpgetprec(); \
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} while (0)
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# define XPFPA_RESTORE_CW(vptr) do { \
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fpsetprec(*((fp_prec_t *)(vptr))); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE() do { \
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_xpfpa_fpu_oldprec = fpgetprec(); \
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fpsetprec(FP_PD); \
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} while (0)
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# define XPFPA_SWITCH_SINGLE() do { \
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_xpfpa_fpu_oldprec = fpgetprec(); \
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fpsetprec(FP_PS); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() do { \
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_xpfpa_fpu_oldprec = fpgetprec(); \
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fpsetprec(FP_PE); \
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} while (0)
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# define XPFPA_RESTORE() \
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fpsetprec(_xpfpa_fpu_oldprec)
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/* We use a temporary volatile variable (in a new block) in order to ensure
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that the optimizer does not mis-optimize the instructions. Also, a volatile
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variable ensures truncation to correct precision. */
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# define XPFPA_RETURN_DOUBLE(val) \
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do { \
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volatile double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_SINGLE(val) \
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do { \
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volatile float _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) \
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do { \
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volatile long double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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#elif defined(HAVE_FPU_INLINE_ASM_X86)
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/*
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Custom x86 inline assembler implementation.
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This implementation does not use predefined wrappers of the OS / compiler
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but rather uses x86/x87 inline assembler directly. Basic instructions:
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fnstcw - Store the FPU control word in a variable
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fldcw - Load the FPU control word from a variable
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Bits (only bits 8 and 9 are relevant, bits 0 to 7 are for other things):
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0x0yy: Single precision
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0x1yy: Reserved
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0x2yy: Double precision
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0x3yy: Double-extended precision
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We use an unsigned int for the datatype. glibc sources add __mode__ (__HI__)
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attribute to it (HI stands for half-integer according to docs). It is unclear
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what the does exactly and how portable it is.
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The assembly syntax works with GNU CC, Intel CC and Sun CC.
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*/
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# define XPFPA_DECLARE \
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unsigned int _xpfpa_fpu_oldcw, _xpfpa_fpu_cw;
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# define XPFPA_HAVE_CW 1
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# define XPFPA_CW_DATATYPE \
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unsigned int
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# define XPFPA_STORE_CW(vptr) do { \
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__asm__ __volatile__ ("fnstcw %0" : "=m" (*((unsigned int *)(vptr)))); \
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} while (0)
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# define XPFPA_RESTORE_CW(vptr) do { \
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__asm__ __volatile__ ("fldcw %0" : : "m" (*((unsigned int *)(vptr)))); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE() do { \
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__asm__ __volatile__ ("fnstcw %0" : "=m" (*&_xpfpa_fpu_oldcw)); \
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_xpfpa_fpu_cw = (_xpfpa_fpu_oldcw & ~0x100) | 0x200; \
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__asm__ __volatile__ ("fldcw %0" : : "m" (*&_xpfpa_fpu_cw)); \
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} while (0)
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# define XPFPA_SWITCH_SINGLE() do { \
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__asm__ __volatile__ ("fnstcw %0" : "=m" (*&_xpfpa_fpu_oldcw)); \
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_xpfpa_fpu_cw = (_xpfpa_fpu_oldcw & ~0x300); \
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__asm__ __volatile__ ("fldcw %0" : : "m" (*&_xpfpa_fpu_cw)); \
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} while (0)
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() do { \
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__asm__ __volatile__ ("fnstcw %0" : "=m" (*&_xpfpa_fpu_oldcw)); \
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_xpfpa_fpu_cw = _xpfpa_fpu_oldcw | 0x300; \
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__asm__ __volatile__ ("fldcw %0" : : "m" (*&_xpfpa_fpu_cw)); \
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} while (0)
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# define XPFPA_RESTORE() \
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__asm__ __volatile__ ("fldcw %0" : : "m" (*&_xpfpa_fpu_oldcw))
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/* We use a temporary volatile variable (in a new block) in order to ensure
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that the optimizer does not mis-optimize the instructions. Also, a volatile
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variable ensures truncation to correct precision. */
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# define XPFPA_RETURN_DOUBLE(val) \
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do { \
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volatile double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_SINGLE(val) \
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do { \
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volatile float _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) \
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do { \
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volatile long double _xpfpa_result = (val); \
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XPFPA_RESTORE(); \
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return _xpfpa_result; \
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} while (0)
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#else /* FPU CONTROL */
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/*
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This is either not an x87 FPU or the inline assembly syntax was not
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recognized. In any case, default to NOPs for the macros and hope the
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generated code will behave as planned.
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*/
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# define XPFPA_DECLARE /* NOP */
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# define XPFPA_HAVE_CW 0
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# define XPFPA_CW_DATATYPE unsigned int
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# define XPFPA_STORE_CW(variable) /* NOP */
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# define XPFPA_RESTORE_CW(variable) /* NOP */
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# define XPFPA_SWITCH_DOUBLE() /* NOP */
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# define XPFPA_SWITCH_SINGLE() /* NOP */
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# define XPFPA_SWITCH_DOUBLE_EXTENDED() /* NOP */
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# define XPFPA_RESTORE() /* NOP */
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# define XPFPA_RETURN_DOUBLE(val) return (val)
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# define XPFPA_RETURN_SINGLE(val) return (val)
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# define XPFPA_RETURN_DOUBLE_EXTENDED(val) return (val)
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#endif /* FPU CONTROL */
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#endif
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