libntl-dev 10.5.0-2 / usr / include / NTL / config.h

#ifndef NTL_config__H
#define NTL_config__H

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

                          NTL Configuration File
                          ----------------------

This file may be modified prior to building NTL so as to specify
some basic configuration options, and to customize
how code is generated so as to improve performance.

The Basic Configuration Options must be set by hand.  If you use the
configuration wizard, then these flags should be set before
the installation process begins;  their values will be retained
by the wizard.

The Performance Options can be set either by hand, by editing this 
file, or (on most Unix platforms) can be set automatically using
the configuration wizard which runs when NTL is installed.

All NTL header files include this file.
By setting these flags here, instead of on the compiler command line,
it is easier to guarantee that NTL library and client code use
consistent settings.  


                                How to do it
                                ------------

To set a flag, just replace the pre-processor directive 
'if 0' by 'if 1' for that flag, which causes the appropriate macro 
to be defined.  Of course,  to unset a flag, just replace the 
'if 1' by an 'if 0'.

You can also do this more conveniently via the command line
using the configure script.


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



/*************************************************************************
 *
 * Basic Configuration Options
 *
 *************************************************************************/


 /* None of these flags are set by the configuration wizard;
  * they must be set by hand, before installation begins.
  */


#if 0
#define NTL_LEGACY_NO_NAMESPACE

/* 
 * By default, NTL components are declared inside the namespace NTL.
 * Set this flag if you want to instead have these components
 * declared in the global namespace.  This is for backward
 * compatibility only -- not recommended.
 *
 */

#endif


#if 0
#define NTL_LEGACY_INPUT_ERROR

/*
 * Also for backward compatibility.  Set if you want input 
 * operations to abort on error, instead of just setting the
 * "fail bit" of the input stream.
 *
 */


#endif

#if 0
#define NTL_DISABLE_TLS_HACK

/* Set if you want to compile NTL without "TLS hack"
 *
 */

#endif

#if 0
#define NTL_ENABLE_TLS_HACK

/* Set if you want to compile NTL with "TLS hack"
 *
 */

#endif

#if 0
#define NTL_THREADS

/* Set if you want to compile NTL as a thread-safe library.
 *
 */

#endif


#if 0
#define NTL_EXCEPTIONS

/* Set if you want to compile NTL with exceptions enabled
 *
 */

#endif

#if 0
#define NTL_THREAD_BOOST

/* Set if you want to compile NTL to exploit threads internally.
 *
 */

#endif


#if 1
#define NTL_GMP_LIP

/* 
 * Use this flag if you want to use GMP as the long integer package.
 * This can result in significantly faster code on some platforms.
 * It requires that the GMP package (version >= 3.1) has already been
 * installed.  You will also have to set the variables GMP_OPT_INCDIR,
 * GMP_OPT_LIBDIR, GMP_OPT_LIB in the makefile (these are set automatically
 * by the confiuration script when you pass the flag NTL_GMP_LIP=on
 * to that script.
 *
 * Beware that setting this flag can break some very old NTL codes.
 *
 * You may also have to edit the makefile to modify the variables
 * GMP_OPT_INCDIR, GMP_OPT_LIBDIR, and GMP_OPT_LIB.
 */

#endif

#if 1
#define NTL_GF2X_LIB

/* 
 * Use this flag if you want to use the gf2x library for
 * faster GF2X arithmetic.
 * This can result in significantly faster code, especially
 * when working with polynomials of huge degree.
 * You will also have to set the variables GF2X_OPT_INCDIR,
 * GF2X_OPT_LIBDIR, GF2X_OPT_LIB in the makefile (these are set automatically
 * by the confiuration script when you pass the flag NTL_GF2X_LIB=on
 * to that script.
 *
 * You may also have to edit the makefile to modify the variables
 * GF2X_OPT_INCDIR, GF2X_OPT_LIBDIR, and GF2X_OPT_LIB.
 */

#endif


#if 0
#define NTL_STD_CXX11

/*
 * Set this flag if you want to enable C++11 features within NTL.
 */

#elif 0
#define NTL_STD_CXX14

/*
 * Set this flag if you want to enable C++14 features within NTL.
 */

#endif


#if 0
#define NTL_UNSIGNED_LONG_LONG_TYPE unsigned long long

/*
 *   NTL_UNSIGNED_LONG_LONG_TYPE will be used
 *   to declare 'double word' unsigned integer types.
 *   If left undefined, some "ifdef magic" will attempt
 *   to find the best choice for your platform, depending
 *   on the compiler and wordsize.  On 32-bit machines,
 *   this is usually 'unsigned long long'.
 *
 */

#endif


#if 0
#define NTL_CLEAN_INT

/*
 *   This will disallow the use of some non-standard integer arithmetic
 *   that may improve performance somewhat.
 *
 */

#endif

#if 0
#define NTL_CLEAN_PTR

/*
 *   This will disallow the use of some non-standard pointer arithmetic
 *   that may improve performance somewhat.
 *
 */

#endif

#if 0
#define NTL_SAFE_VECTORS

/*
 * This will compile NTL in "safe vector" mode, only assuming
 * the relocatability property for trivial types and types
 * explicitly declared relocatable.  See vector.txt for more details.
 */

#endif

 
#if 0
#define NTL_RANGE_CHECK

/*
 *   This will generate vector subscript range-check code.
 *   Useful for debugging, but it slows things down of course.
 *
 */

#endif





#if 0
#define NTL_NO_INIT_TRANS

/*
 *   Without this flag, NTL uses a special code sequence to avoid
 *   copying large objects in return statements.  However, if your
 *   compiler optimizes away the return of a *named* local object,
 *   this is not necessary, and setting this flag will result
 *   in *slightly* more compact and efficient code.  Although
 *   the emeriging C++ standard allows compilers to perform
 *   this optimization, I know of none that currently do.
 *   Most will avoid copying *temporary* objects in return statements,
 *   and NTL's default code sequence exploits this fact.
 *
 */

#endif


#if 0
#define NTL_X86_FIX

/*
 *  Forces the "x86 floating point fix", overriding the default behavior.
 *  By default, NTL will apply the "fix" if it looks like it is
 *  necessary, and if knows how to fix it.
 *  The problem addressed here is that x86 processors sometimes
 *  run in a mode where FP registers have more precision than doubles.
 *  This will cause code in quad_float.cpp some trouble.
 *  NTL can normally correctly detect the problem, and fix it,
 *  so you shouldn't need to worry about this or the next flag.
 *  
 */

#elif 0
#define NTL_NO_X86_FIX
/*
 *  Forces no "x86 floating point fix", overriding the default behavior.
 */

#endif



#if 0
#define NTL_LEGACY_SP_MULMOD

/* Forces legacy single-precision MulMod implementation.
 */

#endif


#if 0
#define NTL_DISABLE_LONGDOUBLE

/* Explicitly disables us of long double arithmetic
 */

#endif


#if 0
#define NTL_DISABLE_LONGLONG

/* Explicitly disables us of long long arithmetic 
 */

#endif

#if 0
#define NTL_DISABLE_LL_ASM

/* Explicitly disables us of inline assembly as a replacement
 * for long lobg arithmetic.
 */

#endif


#if 0
#define NTL_MAXIMIZE_SP_NBITS

/* Allows for 62-bit single-precision moduli on 64-bit platforms.
 * By default, such moduli are restricted to 60 bits, which
 * usually gives slightly better performance across a range of
 * of parameters.
 */

#endif

/*************************************************************************
 *
 *  Performance Options
 *
 *************************************************************************/



/* There are three strategies to implmement single-precision
 * modular multiplication with preconditioning (see the MulModPrecon
 * function in the ZZ module): the default and NTL_SPMM_ULL.
 * This plays a crucial role in the  "small prime FFT" used to 
 * implement polynomial arithmetic, and in other CRT-based methods 
 * (such as linear  algebra over ZZ), as well as polynomial and matrix 
 * arithmetic over zz_p.  
 */



#if 1
#define NTL_SPMM_ULL

/*    This also causes an "all integer"
 *    implementation of MulModPrecon to be used.
 *    It us usually a faster implementation,
 *    but it is not enturely portable.
 *    It relies on double-word unsigned multiplication
 *    (see NTL_UNSIGNED_LONG_LONG_TYPE above). 
 *
 */


#endif



/*
 * The following two flags provide additional control for how the 
 * FFT modulo single-precision primes is implemented.
 */

#if 1
#define NTL_FFT_BIGTAB

/*
 * Precomputed tables are used to store all the roots of unity
 * used in FFT computations. 
 *
 */


#endif


#if 1
#define  NTL_FFT_LAZYMUL

/*
 * When set, a "lazy multiplication" strategy due to David Harvey:
 * see his paper "FASTER ARITHMETIC FOR NUMBER-THEORETIC TRANSFORMS".
 *
 */


#endif



#if 1
#define NTL_AVOID_BRANCHING

/*
 *   With this option, branches are replaced at several 
 *   key points with equivalent code using shifts and masks.
 *   It may speed things up on machines with 
 *   deep pipelines and high branch penalities.
 *   This flag mainly affects the implementation of the
 *   single-precision modular arithmetic routines.
 *
 */

#endif



#if 1
#define NTL_TBL_REM

/*
 *
 *   With this flag, some divisions are avoided in the
 *   ZZ_pX multiplication routines.  
 *
 */

#endif



#if 1
#define NTL_CRT_ALTCODE

/*
 * Employs an alternative CRT strategy.
 * Only relevant with GMP.
 * Seems to be marginally faster on some x86_64 platforms.
 *
 */

#endif

#if 0
#define NTL_CRT_ALTCODE_SMALL

/*
 * Employs an alternative CRT strategy for small moduli.
 * Only relevant with GMP.
 * Seems to be marginally faster on some x86_64 platforms.
 *
 */

#endif


#if 0
#define NTL_GF2X_ALTCODE

/*
 * With this option, the default strategy for implmenting low-level
 * GF2X multiplication is replaced with an alternative strategy.
 * This alternative strategy seems to work better on RISC machines
 * with deep pipelines and high branch penalties (like a powerpc),
 * but does no better (or even worse) on x86s.
 *
 */

#elif 1
#define NTL_GF2X_ALTCODE1


/*
 * Yest another alternative strategy for implementing GF2X
 * multiplication.
 *
 */


#endif

#if 0
#define NTL_GF2X_NOINLINE

/*
 * By default, the low-level GF2X multiplication routine in inlined.
 * This can potentially lead to some trouble on some platforms,
 * and you can override the default by setting this flag.
 *
 */

#endif



/* sanity checks */

#if (defined(NTL_THREAD_BOOST) && !defined(NTL_THREADS))
#error "NTL_THREAD_BOOST defined but not NTL_THREADS"
#endif

#if (defined(NTL_THREADS) && !(defined(NTL_STD_CXX11) || defined(NTL_STD_CXX14)))
#error "NTL_THREADS defined but not NTL_STD_CXX11 or NTL_STD_CXX14"
#endif


#if (defined(NTL_EXCEPTIONS) && !(defined(NTL_STD_CXX11) || defined(NTL_STD_CXX14)))
#error "NTL_EXCEPTIONS defined but not NTL_STD_CXX11 or NTL_STD_CXX14"
#endif


#if (defined(NTL_SAFE_VECTORS) && !(defined(NTL_STD_CXX11) || defined(NTL_STD_CXX14)))
#error "NTL_SAFE_VECTORS defined but not NTL_STD_CXX11 or NTL_STD_CXX14"
#endif





#endif