1079 lines
24 KiB
C
1079 lines
24 KiB
C
/*************************************************************************
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* *
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* YAP Prolog *
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* *
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* Yap Prolog was developed at NCCUP - Universidade do Porto *
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* *
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* Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 *
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* *
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**************************************************************************
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* *
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* File: arith1.c *
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* Last rev: *
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* mods: *
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* comments: arithmetical expression evaluation *
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* *
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*************************************************************************/
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#ifdef SCCS
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static char SccsId[] = "%W% %G%";
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#endif
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/**
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@file arith1.c
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@addtogroup arithmetic_operators
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- <b>exp( _X_) [ISO]</b><p> @anchor exp_1
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Natural exponential.
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- <b>log( _X_) [ISO]</b><p> @anchor log_1
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Natural logarithm.
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- <b>log10( _X_)</b><p> @anchor log10_1
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Decimal logarithm.
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- <b>sqrt( _X_) [ISO]</b><p> @anchor sqrt_1
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Square root.
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- <b>sin( _X_) [ISO]</b><p> @anchor sin_1
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Sine.
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- <b>cos( _X_) [ISO]</b><p> @anchor cos_1
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Cosine.
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- <b>tan( _X_) [ISO]</b><p> @anchor tan_1
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Tangent.
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- <b>asin( _X_) [ISO]</b><p> @anchor asin_1
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Arc sine.
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- <b>acos( _X_) [ISO]</b><p> @anchor acos_1
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Arc cosine.
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- <b>atan( _X_) [ISO]</b><p> @anchor atan_1
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Arc tangent.
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- <b>sinh( _X_)</b><p> @anchor sinh_1
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Hyperbolic sine.
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- <b>cosh( _X_)</b><p> @anchor cosh_1
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Hyperbolic cosine.
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- <b>tanh( _X_)</b><p> @anchor tanh_1
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Hyperbolic tangent.
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- <b>asinh( _X_)</b><p> @anchor asinh_1
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Hyperbolic arc sine.
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- <b>acosh( _X_)</b><p> @anchor acosh_1
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Hyperbolic arc cosine.
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- <b>atanh( _X_)</b><p> @anchor atanh_1
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Hyperbolic arc tangent.
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- <b>lgamma( _X_)</b><p> @anchor lgamma_1
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Logarithm of gamma function.
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- <b>erf( _X_)</b><p> @anchor erf_1
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Gaussian error function.
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- <b>erfc( _X_)</b><p> @anchor erfc_1
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Complementary gaussian error function.
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- <b>random( _X_) [ISO]</b><p> @anchor random_1_op
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An integer random number between 0 and _X_.
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In `iso` language mode the argument must be a floating
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point-number, the result is an integer and it the float is equidistant
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it is rounded up, that is, to the least integer greater than _X_.
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- <b>integer( _X_)</b><p> @anchor integer_1_op
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If _X_ evaluates to a float, the integer between the value of _X_ and 0 closest to the value of _X_, else if _X_ evaluates to an
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integer, the value of _X_.
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- <b>float( _X_) [ISO]</b><p> @anchor float_1_op
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If _X_ evaluates to an integer, the corresponding float, else the float itself.
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- <b>float_fractional_part( _X_) [ISO]</b><p> @anchor float_fractional_part_1
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The fractional part of the floating point number _X_, or `0.0` if _X_ is an integer. In the `iso` language mode, _X_ must be an integer.
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- <b>float_integer_part( _X_) [ISO]</b><p> @anchor float_integer_part_1
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The float giving the integer part of the floating point number _X_, or _X_ if _X_ is an integer. In the `iso` language mode, _X_ must be an integer.
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- <b>abs( _X_) [ISO]</b><p> @anchor abs_1
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The absolute value of _X_.
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- <b>ceiling( _X_) [ISO]</b><p> @anchor ceiling_1
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The integer that is the smallest integral value not smaller than _X_.
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In `iso` language mode the argument must be a floating point-number and the result is an integer.
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- <b>floor( _X_) [ISO]</b><p> @anchor floor_1
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The integer that is the greatest integral value not greater than _X_.
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In `iso` language mode the argument must be a floating
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point-number and the result is an integer.
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- <b>round( _X_) [ISO]</b><p> @anchor round_1
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The nearest integral value to _X_. If _X_ is equidistant to two integers, it will be rounded to the closest even integral value.
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In `iso` language mode the argument must be a floating point-number, the result is an integer and it the float is equidistant it is rounded up, that is, to the least integer greater than _X_.
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- <b>sign( _X_) [ISO]</b><p> @anchor sign_1
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Return 1 if the _X_ evaluates to a positive integer, 0 it if evaluates to 0, and -1 if it evaluates to a negative integer. If _X_
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evaluates to a floating-point number return 1.0 for a positive _X_, 0.0 for 0.0, and -1.0 otherwise.
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- <b>truncate( _X_) [ISO]</b><p> @anchor truncate_1
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The integral value between _X_ and 0 closest to _X_.
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- <b>rational( _X_)</b><p> @anchor rational_1_op
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Convert the expression _X_ to a rational number or integer. The function returns the input on integers and rational numbers. For
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floating point numbers, the returned rational number exactly represents
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the float. As floats cannot exactly represent all decimal numbers the
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results may be surprising. In the examples below, doubles can represent
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`0.25` and the result is as expected, in contrast to the result of
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`rational(0.1)`. The function `rationalize/1` gives a more
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intuitive result.
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~prolog
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?- A is rational(0.25).
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A is 1 rdiv 4
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?- A is rational(0.1).
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A = 3602879701896397 rdiv 36028797018963968
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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- <b>rationalize( _X_)</b><p> @anchor rationalize_1
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Convert the expression _X_ to a rational number or integer. The function is
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similar to [rational/1](@ref rational_1), but the result is only accurate within the
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rounding error of floating point numbers, generally producing a much
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smaller denominator.
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~prolog
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?- A is rationalize(0.25).
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A = 1 rdiv 4
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?- A is rationalize(0.1).
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A = 1 rdiv 10
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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- <b>\\ _X_ [ISO]</b><p>
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Integer bitwise negation.
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- <b>msb( _X_)</b><p> @anchor msb_1
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The most significant bit of the non-negative integer _X_.
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- <b>lsb( _X_)</b><p> @anchor lsb_1
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The least significant bit of the non-negative integer _X_.
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- <b>popcount( _X_)</b><p> @anchor popcount_1
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The number of bits set to `1` in the binary representation of the non-negative integer _X_.
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- <b>[ _X_]</b><p>
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Evaluates to _X_ for expression _X_. Useful because character
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strings in Prolog are lists of character codes.
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~{.prolog}
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X is Y*10+C-"0"
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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is the same as
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~{.prolog}
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X is Y*10+C-[48].
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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which would be evaluated as:
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~{.prolog}
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X is Y*10+C-48.
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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*/
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#include "Yap.h"
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#include "Yatom.h"
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#include "YapHeap.h"
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#include "eval.h"
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static Term
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float_to_int(Float v USES_REGS)
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{
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#if USE_GMP
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Int i = (Int)v;
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if (i-v == 0.0) {
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return MkIntegerTerm(i);
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} else {
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return Yap_gmp_float_to_big(v);
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}
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#else
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return MkIntegerTerm(v);
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#endif
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}
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#define RBIG_FL(v) return(float_to_int(v PASS_REGS))
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typedef struct init_un_eval {
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char *OpName;
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arith1_op f;
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} InitUnEntry;
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/* Some compilers just don't get it */
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#ifdef __MINGW32__
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#undef HAVE_ASINH
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#undef HAVE_ACOSH
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#undef HAVE_ATANH
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#undef HAVE_FINITE
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#endif
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#if !HAVE_ASINH
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#define asinh(F) (log((F)+sqrt((F)*(F)+1)))
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#endif
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#if !HAVE_ACOSH
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#define acosh(F) (log((F)+sqrt((F)*(F)-1)))
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#endif
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#if !HAVE_ATANH
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#define atanh(F) (log((1+(F))/(1-(F)))/2)
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#endif
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static inline Float
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get_float(Term t) {
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if (IsFloatTerm(t)) {
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return FloatOfTerm(t);
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}
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if (IsIntTerm(t)) {
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return IntOfTerm(t);
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}
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if (IsLongIntTerm(t)) {
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return LongIntOfTerm(t);
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}
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#ifdef USE_GMP
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if (IsBigIntTerm(t)) {
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return Yap_gmp_to_float(t);
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}
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#endif
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return 0.0;
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}
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/* WIN32 machines do not necessarily have rint. This will do for now */
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#if HAVE_RINT
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#define my_rint(X) rint(X)
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#else
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static
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double my_rint(double x)
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{
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double y, z;
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Int n;
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if (x >= 0) {
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y = x + 0.5;
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z = floor(y);
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n = (Int) z;
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if (y == z && n % 2)
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return(z-1);
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} else {
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y = x - 0.5;
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z = ceil(y);
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n = (Int) z;
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if (y == z && n % 2)
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return(z+1);
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}
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return(z);
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}
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#endif
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static Int
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msb(Int inp USES_REGS) /* calculate the most significant bit for an integer */
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{
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/* the obvious solution: do it by using binary search */
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Int out = 0;
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if (inp < 0) {
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return Yap_ArithError(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, MkIntegerTerm(inp),
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"msb/1 received %d", inp);
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}
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#if 0
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#else
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int off = sizeof(CELL)*4;
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while (off) {
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Int limit = ((CELL)1) << (off);
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if (inp >= limit) {
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out += off;
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inp >>= off;
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}
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off >>= 1;
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}
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#endif
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return(out);
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}
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static Int
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lsb(Int inp USES_REGS) /* calculate the least significant bit for an integer */
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{
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/* the obvious solution: do it by using binary search */
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Int out = 0;
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if (inp < 0) {
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return Yap_ArithError(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, MkIntegerTerm(inp),
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"msb/1 received %d", inp);
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}
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if (inp==0)
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return 0L;
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#if SIZEOF_INT_P == 8
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if (!(inp & 0xffffffffLL)) {inp >>= 32; out += 32;}
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#endif
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if (!(inp & 0xffffL)) {inp >>= 16; out += 16;}
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if (!(inp & 0xffL)) {inp >>= 8; out += 8;}
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if (!(inp & 0xfL)) {inp >>= 4; out += 4;}
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if (!(inp & 0x3L)) {inp >>= 2; out += 2;}
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if (!(inp & ((CELL)0x1))) out++;
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return out;
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}
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static Int
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popcount(Int inp USES_REGS) /* calculate the least significant bit for an integer */
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{
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/* the obvious solution: do it by using binary search */
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Int c = 0, j = 0, m = ((CELL)1);
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if (inp < 0) {
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return Yap_ArithError(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, MkIntegerTerm(inp),
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"popcount/1 received %d", inp);
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}
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if (inp==0)
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return 0L;
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for(j=0,c=0; j<sizeof(inp)*8; j++, m<<=1)
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{ if ( inp&m )
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c++;
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}
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return c;
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}
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static Term
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eval1(Int fi, Term t USES_REGS) {
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arith1_op f = fi;
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switch (f) {
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case op_uplus:
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return t;
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case op_uminus:
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switch (ETypeOfTerm(t)) {
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case long_int_e:
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{
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#ifdef USE_GMP
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Int i = IntegerOfTerm(t);
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if (i == Int_MIN) {
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return Yap_gmp_neg_int(i);
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}
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else
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#endif
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RINT(-IntegerOfTerm(t));
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}
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case double_e:
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RFLOAT(-FloatOfTerm(t));
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case big_int_e:
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#ifdef USE_GMP
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return Yap_gmp_neg_big(t);
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#endif
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default:
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RERROR();
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}
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case op_unot:
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switch (ETypeOfTerm(t)) {
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case long_int_e:
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RINT(~IntegerOfTerm(t));
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case double_e:
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return Yap_ArithError(TYPE_ERROR_INTEGER, t, "\\(%f)", FloatOfTerm(t));
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case big_int_e:
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#ifdef USE_GMP
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return Yap_gmp_unot_big(t);
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#endif
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default:
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RERROR();
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}
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case op_exp:
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RFLOAT(exp(get_float(t)));
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case op_log:
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{
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Float dbl = get_float(t);
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if (dbl >= 0) {
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RFLOAT(log(dbl));
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} else {
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return Yap_ArithError(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t, "log(%f)", dbl);
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}
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}
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case op_log10:
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{
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Float dbl = get_float(t);
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if (dbl >= 0) {
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RFLOAT(log10(dbl));
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} else {
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return Yap_ArithError(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t, "log(%f)", dbl);
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}
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}
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case op_sqrt:
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{
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Float dbl = get_float(t), out;
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out = sqrt(dbl);
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#if HAVE_ISNAN
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if (isnan(out)) {
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return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "acos(%f)", dbl);
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}
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#endif
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RFLOAT(out);
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}
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case op_sin:
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{
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Float dbl = get_float(t), out;
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out = sin(dbl);
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RFLOAT(out);
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}
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case op_cos:
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{
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Float dbl = get_float(t), out;
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out = cos(dbl);
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RFLOAT(out);
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}
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case op_tan:
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{
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Float dbl = get_float(t), out;
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out = tan(dbl);
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RFLOAT(out);
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}
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case op_sinh:
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{
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Float dbl = get_float(t), out;
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out = sinh(dbl);
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RFLOAT(out);
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}
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case op_cosh:
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{
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Float dbl = get_float(t), out;
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out = cosh(dbl);
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RFLOAT(out);
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}
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case op_tanh:
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{
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Float dbl = get_float(t), out;
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out = tanh(dbl);
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RFLOAT(out);
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}
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case op_asin:
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{
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Float dbl, out;
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dbl = get_float(t);
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out = asin(dbl);
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#if HAVE_ISNAN
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if (isnan(out)) {
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return Yap_ArithError(EVALUATION_ERROR_UNDEFINED, t, "asin(%f)", dbl);
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}
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#endif
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RFLOAT(out);
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}
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case op_acos:
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{
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Float dbl, out;
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dbl = get_float(t);
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out = acos(dbl);
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#if HAVE_ISNAN
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if (isnan(out)) {
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return Yap_ArithError(EVALUATION_ERROR_UNDEFINED, t, "acos(%f)", dbl);
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}
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#endif
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RFLOAT(out);
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}
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case op_atan:
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{
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Float dbl, out;
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dbl = get_float(t);
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out = atan(dbl);
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#if HAVE_ISNAN
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if (isnan(out)) {
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return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "atanh(%f)", dbl);
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}
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#endif
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RFLOAT(out);
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}
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case op_asinh:
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{
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Float dbl, out;
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dbl = get_float(t);
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out = asinh(dbl);
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#if HAVE_ISNAN
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if (isnan(out)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "atanh(%f)", dbl);
|
|
}
|
|
#endif
|
|
RFLOAT(out);
|
|
}
|
|
case op_acosh:
|
|
{
|
|
Float dbl, out;
|
|
|
|
dbl = get_float(t);
|
|
out = acosh(dbl);
|
|
#if HAVE_ISNAN
|
|
if (isnan(out)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "atanh(%f)", dbl);
|
|
}
|
|
#endif
|
|
RFLOAT(out);
|
|
}
|
|
case op_atanh:
|
|
{
|
|
Float dbl, out;
|
|
|
|
dbl = get_float(t);
|
|
out = atanh(dbl);
|
|
#if HAVE_ISNAN
|
|
if (isnan(out)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "atanh(%f)", dbl);
|
|
}
|
|
#endif
|
|
RFLOAT(out);
|
|
}
|
|
case op_lgamma:
|
|
{
|
|
#if HAVE_LGAMMA
|
|
Float dbl;
|
|
|
|
dbl = get_float(t);
|
|
RFLOAT(lgamma(dbl));
|
|
#else
|
|
RERROR();
|
|
#endif
|
|
}
|
|
case op_erf:
|
|
{
|
|
#if HAVE_ERF
|
|
Float dbl = get_float(t), out;
|
|
out = erf(dbl);
|
|
RFLOAT(out);
|
|
#else
|
|
RERROR();
|
|
#endif
|
|
}
|
|
case op_erfc:
|
|
{
|
|
#if HAVE_ERF
|
|
Float dbl = get_float(t), out;
|
|
out = erfc(dbl);
|
|
RFLOAT(out);
|
|
#else
|
|
RERROR();
|
|
#endif
|
|
}
|
|
/*
|
|
floor(x) maximum integer greatest or equal to X
|
|
|
|
There are really two built-ins:
|
|
SICStus converts from int/big/float -> float
|
|
ISO only converts from float -> int/big
|
|
|
|
*/
|
|
case op_floor:
|
|
{
|
|
Float dbl;
|
|
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
case double_e:
|
|
dbl = FloatOfTerm(t);
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_floor(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
#if HAVE_ISNAN
|
|
if (isnan(dbl)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "integer(%f)", dbl);
|
|
}
|
|
#endif
|
|
#if HAVE_ISINF
|
|
if (isinf(dbl)) {
|
|
return Yap_ArithError(EVALUATION_ERROR_INT_OVERFLOW, MkFloatTerm(dbl), "integer\
|
|
(%f)",dbl);
|
|
}
|
|
#endif
|
|
RBIG_FL(floor(dbl));
|
|
}
|
|
case op_ceiling:
|
|
{
|
|
Float dbl;
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
case double_e:
|
|
dbl = FloatOfTerm(t);
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_ceiling(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
#if HAVE_ISNAN
|
|
if (isnan(dbl)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "integer(%f)", dbl);
|
|
}
|
|
#endif
|
|
#if HAVE_ISINF
|
|
if (isinf(dbl)) {
|
|
return Yap_ArithError(EVALUATION_ERROR_INT_OVERFLOW, MkFloatTerm(dbl), "integer\
|
|
(%f)",dbl);
|
|
}
|
|
#endif
|
|
RBIG_FL(ceil(dbl));
|
|
}
|
|
case op_round:
|
|
{
|
|
Float dbl;
|
|
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
case double_e:
|
|
dbl = FloatOfTerm(t);
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_round(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
#if HAVE_ISNAN
|
|
if (isnan(dbl)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "integer(%f)", dbl);
|
|
}
|
|
#endif
|
|
#if HAVE_ISINF
|
|
if (isinf(dbl)) {
|
|
return Yap_ArithError(EVALUATION_ERROR_INT_OVERFLOW, MkFloatTerm(dbl), "integer\
|
|
(%f)",dbl);
|
|
}
|
|
#endif
|
|
RBIG_FL(my_rint(dbl));
|
|
}
|
|
case op_truncate:
|
|
case op_integer:
|
|
{
|
|
Float dbl;
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
case double_e:
|
|
dbl = FloatOfTerm(t);
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_trunc(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
#if HAVE_ISNAN
|
|
if (isnan(dbl)) {
|
|
return Yap_ArithError(DOMAIN_ERROR_OUT_OF_RANGE, t, "integer(%f)", dbl);
|
|
}
|
|
#endif
|
|
#if HAVE_ISINF
|
|
if (isinf(dbl)) {
|
|
return Yap_ArithError(EVALUATION_ERROR_INT_OVERFLOW, MkFloatTerm(dbl), "integer (%f)",dbl);
|
|
}
|
|
#endif
|
|
if (dbl < 0.0)
|
|
RBIG_FL(ceil(dbl));
|
|
else
|
|
RBIG_FL(floor(dbl));
|
|
}
|
|
case op_float:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RFLOAT(IntegerOfTerm(t));
|
|
case double_e:
|
|
return t;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
RFLOAT(Yap_gmp_to_float(t));
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_rational:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
#ifdef USE_GMP
|
|
case double_e:
|
|
return Yap_gmp_float_to_rational(FloatOfTerm(t));
|
|
#endif
|
|
case big_int_e:
|
|
return t;
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_rationalize:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return t;
|
|
#ifdef USE_GMP
|
|
case double_e:
|
|
return Yap_gmp_float_rationalize(FloatOfTerm(t));
|
|
#endif
|
|
case big_int_e:
|
|
return t;
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_abs:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RINT(labs(IntegerOfTerm(t)));
|
|
case double_e:
|
|
RFLOAT(fabs(FloatOfTerm(t)));
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_abs_big(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_msb:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RINT(msb(IntegerOfTerm(t) PASS_REGS));
|
|
case double_e:
|
|
return Yap_ArithError(TYPE_ERROR_INTEGER, t, "msb(%f)", FloatOfTerm(t));
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_msb(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_lsb:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RINT(lsb(IntegerOfTerm(t) PASS_REGS));
|
|
case double_e:
|
|
return Yap_ArithError(TYPE_ERROR_INTEGER, t, "lsb(%f)", FloatOfTerm(t));
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_lsb(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_popcount:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RINT(popcount(IntegerOfTerm(t) PASS_REGS));
|
|
case double_e:
|
|
return Yap_ArithError(TYPE_ERROR_INTEGER, t, "popcount(%f)", FloatOfTerm(t));
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_popcount(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_ffracp:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
if (yap_flags[LANGUAGE_MODE_FLAG] == 1) { /* iso */
|
|
return Yap_ArithError(TYPE_ERROR_FLOAT, t, "X is float_fractional_part(%f)", IntegerOfTerm(t));
|
|
} else {
|
|
RFLOAT(0.0);
|
|
}
|
|
case double_e:
|
|
{
|
|
Float dbl;
|
|
dbl = FloatOfTerm(t);
|
|
RFLOAT(dbl-ceil(dbl));
|
|
}
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_float_fractional_part(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_fintp:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
return Yap_ArithError(TYPE_ERROR_FLOAT, t, "X is float_integer_part(%f)", IntegerOfTerm(t));
|
|
case double_e:
|
|
RFLOAT(rint(FloatOfTerm(t)));
|
|
break;
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_float_integer_part(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_sign:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
{
|
|
Int x = IntegerOfTerm(t);
|
|
|
|
RINT((x > 0 ? 1 : (x < 0 ? -1 : 0)));
|
|
}
|
|
case double_e:
|
|
{
|
|
|
|
Float dbl = FloatOfTerm(t);
|
|
|
|
RINT((dbl > 0.0 ? 1 : (dbl < 0.0 ? -1 : 0)));
|
|
}
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_sign(t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
case op_random1:
|
|
switch (ETypeOfTerm(t)) {
|
|
case long_int_e:
|
|
RINT(Yap_random()*IntegerOfTerm(t));
|
|
case double_e:
|
|
return Yap_ArithError(TYPE_ERROR_INTEGER, t, "random(%f)", FloatOfTerm(t));
|
|
case big_int_e:
|
|
#ifdef USE_GMP
|
|
return Yap_gmp_mul_float_big(Yap_random(), t);
|
|
#endif
|
|
default:
|
|
RERROR();
|
|
}
|
|
}
|
|
/// end of switch
|
|
RERROR();
|
|
}
|
|
|
|
Term Yap_eval_unary(Int f, Term t)
|
|
{
|
|
CACHE_REGS
|
|
return eval1(f,t PASS_REGS);
|
|
}
|
|
|
|
static InitUnEntry InitUnTab[] = {
|
|
{"+", op_uplus},
|
|
{"-", op_uminus},
|
|
{"\\", op_unot},
|
|
{"exp", op_exp},
|
|
{"log", op_log},
|
|
{"log10", op_log10},
|
|
{"sqrt", op_sqrt},
|
|
{"sin", op_sin},
|
|
{"cos", op_cos},
|
|
{"tan", op_tan},
|
|
{"sinh", op_sinh},
|
|
{"cosh", op_cosh},
|
|
{"tanh", op_tanh},
|
|
{"asin", op_asin},
|
|
{"acos", op_acos},
|
|
{"atan", op_atan},
|
|
{"asinh", op_asinh},
|
|
{"acosh", op_acosh},
|
|
{"atanh", op_atanh},
|
|
{"floor", op_floor},
|
|
{"ceiling", op_ceiling},
|
|
{"round", op_round},
|
|
{"truncate", op_truncate},
|
|
{"integer", op_integer},
|
|
{"float", op_float},
|
|
{"abs", op_abs},
|
|
{"msb", op_msb},
|
|
{"lsb", op_lsb},
|
|
{"popcount", op_popcount},
|
|
{"float_fractional_part", op_ffracp},
|
|
{"float_integer_part", op_fintp},
|
|
{"sign", op_sign},
|
|
{"lgamma", op_lgamma},
|
|
{"erf",op_erf},
|
|
{"erfc",op_erfc},
|
|
{"rational",op_rational},
|
|
{"rationalize",op_rationalize},
|
|
{"random", op_random1}
|
|
};
|
|
|
|
Atom
|
|
Yap_NameOfUnaryOp(int i)
|
|
{
|
|
return Yap_LookupAtom(InitUnTab[i].OpName);
|
|
}
|
|
|
|
static Int
|
|
p_unary_is( USES_REGS1 )
|
|
{ /* X is Y */
|
|
Term t = Deref(ARG2);
|
|
Term top;
|
|
yap_error_number err;
|
|
|
|
if (IsVarTerm(t)) {
|
|
Yap_EvalError(INSTANTIATION_ERROR, t, "unbound unary operator");
|
|
return FALSE;
|
|
}
|
|
Yap_ClearExs();
|
|
top = Yap_Eval(Deref(ARG3));
|
|
if ((err=Yap_FoundArithError())) {
|
|
Yap_EvalError(err,ARG3,"X is op(Y): error in Y ");
|
|
return FALSE;
|
|
}
|
|
if (IsIntTerm(t)) {
|
|
Term tout;
|
|
Int i;
|
|
|
|
i = IntegerOfTerm(t);
|
|
tout = eval1(i, top PASS_REGS);
|
|
if ((err=Yap_FoundArithError())) {
|
|
Functor f = Yap_MkFunctor( Yap_NameOfUnaryOp(i), 1 );
|
|
Term t = Yap_MkApplTerm( f, 1, &top );
|
|
Yap_EvalError(err, t ,"error in %s/1 ", RepAtom(NameOfFunctor(f))->StrOfAE);
|
|
return FALSE;
|
|
}
|
|
return Yap_unify_constant(ARG1,tout);
|
|
} else if (IsAtomTerm(t)) {
|
|
Atom name = AtomOfTerm(t);
|
|
ExpEntry *p;
|
|
Term out;
|
|
|
|
if (EndOfPAEntr(p = RepExpProp(Yap_GetExpProp(name, 1)))) {
|
|
|
|
Term ti[2];
|
|
|
|
/* error */
|
|
ti[0] = t;
|
|
ti[1] = MkIntTerm(1);
|
|
t = Yap_MkApplTerm(FunctorSlash, 2, ti);
|
|
Yap_EvalError(TYPE_ERROR_EVALUABLE, t,
|
|
"functor %s/1 for arithmetic expression",
|
|
RepAtom(name)->StrOfAE);
|
|
return FALSE;
|
|
}
|
|
out= eval1(p->FOfEE, top PASS_REGS);
|
|
if ((err=Yap_FoundArithError())) {
|
|
Functor f = Yap_MkFunctor( name, 1 );
|
|
Term t = Yap_MkApplTerm( f, 1, &top );
|
|
Yap_EvalError(err, t ,"error in %s/1", RepAtom(name)->StrOfAE);
|
|
return FALSE;
|
|
}
|
|
return Yap_unify_constant(ARG1,out);
|
|
}
|
|
return(FALSE);
|
|
}
|
|
|
|
static Int
|
|
p_unary_op_as_integer( USES_REGS1 )
|
|
{ /* X is Y */
|
|
Term t = Deref(ARG1);
|
|
|
|
if (IsVarTerm(t)) {
|
|
Yap_EvalError(INSTANTIATION_ERROR,t, "X is _Y");
|
|
return(FALSE);
|
|
}
|
|
if (IsIntTerm(t)) {
|
|
return Yap_unify_constant(ARG2,t);
|
|
}
|
|
if (IsAtomTerm(t)) {
|
|
Atom name = AtomOfTerm(t);
|
|
ExpEntry *p;
|
|
|
|
if (EndOfPAEntr(p = RepExpProp(Yap_GetExpProp(name, 1)))) {
|
|
return Yap_unify(ARG1,ARG2);
|
|
}
|
|
return Yap_unify_constant(ARG2,MkIntTerm(p->FOfEE));
|
|
}
|
|
return(FALSE);
|
|
}
|
|
|
|
void
|
|
Yap_InitUnaryExps(void)
|
|
{
|
|
unsigned int i;
|
|
ExpEntry *p;
|
|
|
|
for (i = 0; i < sizeof(InitUnTab)/sizeof(InitUnEntry); ++i) {
|
|
AtomEntry *ae = RepAtom(Yap_LookupAtom(InitUnTab[i].OpName));
|
|
if (ae == NULL) {
|
|
Yap_EvalError(OUT_OF_HEAP_ERROR,TermNil,"at InitUnaryExps");
|
|
return;
|
|
}
|
|
WRITE_LOCK(ae->ARWLock);
|
|
if (Yap_GetExpPropHavingLock(ae, 1)) {
|
|
WRITE_UNLOCK(ae->ARWLock);
|
|
break;
|
|
}
|
|
p = (ExpEntry *) Yap_AllocAtomSpace(sizeof(ExpEntry));
|
|
p->KindOfPE = ExpProperty;
|
|
p->ArityOfEE = 1;
|
|
p->ENoOfEE = 1;
|
|
p->FOfEE = InitUnTab[i].f;
|
|
AddPropToAtom(ae, (PropEntry *)p);
|
|
WRITE_UNLOCK(ae->ARWLock);
|
|
}
|
|
Yap_InitCPred("is", 3, p_unary_is, TestPredFlag | SafePredFlag);
|
|
Yap_InitCPred("$unary_op_as_integer", 2, p_unary_op_as_integer, TestPredFlag|SafePredFlag);}
|
|
|
|
/* This routine is called from Restore to make sure we have the same arithmetic operators */
|
|
int
|
|
Yap_ReInitUnaryExps(void)
|
|
{
|
|
return TRUE;
|
|
}
|
|
|