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Don't fail environmental check if README.md exists (but .txt and no-suffix don't)
author Chris Cannam
date Tue, 30 Jul 2019 12:25:44 +0100
parents c530137014c0
children
rev   line source
Chris@16 1 // (C) Copyright John Maddock 2008.
Chris@16 2 // Use, modification and distribution are subject to the
Chris@16 3 // Boost Software License, Version 1.0. (See accompanying file
Chris@16 4 // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
Chris@16 5
Chris@16 6 #ifndef BOOST_MATH_SPECIAL_NEXT_HPP
Chris@16 7 #define BOOST_MATH_SPECIAL_NEXT_HPP
Chris@16 8
Chris@16 9 #ifdef _MSC_VER
Chris@16 10 #pragma once
Chris@16 11 #endif
Chris@16 12
Chris@101 13 #include <boost/math/special_functions/math_fwd.hpp>
Chris@16 14 #include <boost/math/policies/error_handling.hpp>
Chris@16 15 #include <boost/math/special_functions/fpclassify.hpp>
Chris@16 16 #include <boost/math/special_functions/sign.hpp>
Chris@16 17 #include <boost/math/special_functions/trunc.hpp>
Chris@16 18
Chris@16 19 #include <float.h>
Chris@101 20
Chris@101 21 #if !defined(_CRAYC) && !defined(__CUDACC__) && (!defined(__GNUC__) || (__GNUC__ > 3) || ((__GNUC__ == 3) && (__GNUC_MINOR__ > 3)))
Chris@101 22 #if (defined(_M_IX86_FP) && (_M_IX86_FP >= 2)) || defined(__SSE2__)
Chris@101 23 #include "xmmintrin.h"
Chris@101 24 #define BOOST_MATH_CHECK_SSE2
Chris@101 25 #endif
Chris@16 26 #endif
Chris@16 27
Chris@16 28 namespace boost{ namespace math{
Chris@16 29
Chris@16 30 namespace detail{
Chris@16 31
Chris@16 32 template <class T>
Chris@16 33 inline T get_smallest_value(mpl::true_ const&)
Chris@16 34 {
Chris@16 35 //
Chris@16 36 // numeric_limits lies about denorms being present - particularly
Chris@16 37 // when this can be turned on or off at runtime, as is the case
Chris@16 38 // when using the SSE2 registers in DAZ or FTZ mode.
Chris@16 39 //
Chris@16 40 static const T m = std::numeric_limits<T>::denorm_min();
Chris@101 41 #ifdef BOOST_MATH_CHECK_SSE2
Chris@101 42 return (_mm_getcsr() & (_MM_FLUSH_ZERO_ON | 0x40)) ? tools::min_value<T>() : m;;
Chris@101 43 #else
Chris@101 44 return ((tools::min_value<T>() / 2) == 0) ? tools::min_value<T>() : m;
Chris@101 45 #endif
Chris@16 46 }
Chris@16 47
Chris@16 48 template <class T>
Chris@16 49 inline T get_smallest_value(mpl::false_ const&)
Chris@16 50 {
Chris@16 51 return tools::min_value<T>();
Chris@16 52 }
Chris@16 53
Chris@16 54 template <class T>
Chris@16 55 inline T get_smallest_value()
Chris@16 56 {
Chris@16 57 #if defined(BOOST_MSVC) && (BOOST_MSVC <= 1310)
Chris@16 58 return get_smallest_value<T>(mpl::bool_<std::numeric_limits<T>::is_specialized && (std::numeric_limits<T>::has_denorm == 1)>());
Chris@16 59 #else
Chris@16 60 return get_smallest_value<T>(mpl::bool_<std::numeric_limits<T>::is_specialized && (std::numeric_limits<T>::has_denorm == std::denorm_present)>());
Chris@16 61 #endif
Chris@16 62 }
Chris@16 63
Chris@16 64 //
Chris@16 65 // Returns the smallest value that won't generate denorms when
Chris@16 66 // we calculate the value of the least-significant-bit:
Chris@16 67 //
Chris@16 68 template <class T>
Chris@16 69 T get_min_shift_value();
Chris@16 70
Chris@16 71 template <class T>
Chris@16 72 struct min_shift_initializer
Chris@16 73 {
Chris@16 74 struct init
Chris@16 75 {
Chris@16 76 init()
Chris@16 77 {
Chris@16 78 do_init();
Chris@16 79 }
Chris@16 80 static void do_init()
Chris@16 81 {
Chris@16 82 get_min_shift_value<T>();
Chris@16 83 }
Chris@16 84 void force_instantiate()const{}
Chris@16 85 };
Chris@16 86 static const init initializer;
Chris@16 87 static void force_instantiate()
Chris@16 88 {
Chris@16 89 initializer.force_instantiate();
Chris@16 90 }
Chris@16 91 };
Chris@16 92
Chris@16 93 template <class T>
Chris@16 94 const typename min_shift_initializer<T>::init min_shift_initializer<T>::initializer;
Chris@16 95
Chris@16 96
Chris@16 97 template <class T>
Chris@16 98 inline T get_min_shift_value()
Chris@16 99 {
Chris@16 100 BOOST_MATH_STD_USING
Chris@16 101 static const T val = ldexp(tools::min_value<T>(), tools::digits<T>() + 1);
Chris@16 102 min_shift_initializer<T>::force_instantiate();
Chris@16 103
Chris@16 104 return val;
Chris@16 105 }
Chris@16 106
Chris@16 107 template <class T, class Policy>
Chris@16 108 T float_next_imp(const T& val, const Policy& pol)
Chris@16 109 {
Chris@16 110 BOOST_MATH_STD_USING
Chris@16 111 int expon;
Chris@16 112 static const char* function = "float_next<%1%>(%1%)";
Chris@16 113
Chris@16 114 int fpclass = (boost::math::fpclassify)(val);
Chris@16 115
Chris@101 116 if((fpclass == (int)FP_NAN) || (fpclass == (int)FP_INFINITE))
Chris@16 117 {
Chris@16 118 if(val < 0)
Chris@16 119 return -tools::max_value<T>();
Chris@16 120 return policies::raise_domain_error<T>(
Chris@16 121 function,
Chris@16 122 "Argument must be finite, but got %1%", val, pol);
Chris@16 123 }
Chris@16 124
Chris@16 125 if(val >= tools::max_value<T>())
Chris@16 126 return policies::raise_overflow_error<T>(function, 0, pol);
Chris@16 127
Chris@16 128 if(val == 0)
Chris@16 129 return detail::get_smallest_value<T>();
Chris@16 130
Chris@101 131 if((fpclass != (int)FP_SUBNORMAL) && (fpclass != (int)FP_ZERO) && (fabs(val) < detail::get_min_shift_value<T>()) && (val != -tools::min_value<T>()))
Chris@16 132 {
Chris@16 133 //
Chris@16 134 // Special case: if the value of the least significant bit is a denorm, and the result
Chris@16 135 // would not be a denorm, then shift the input, increment, and shift back.
Chris@16 136 // This avoids issues with the Intel SSE2 registers when the FTZ or DAZ flags are set.
Chris@16 137 //
Chris@16 138 return ldexp(float_next(T(ldexp(val, 2 * tools::digits<T>())), pol), -2 * tools::digits<T>());
Chris@16 139 }
Chris@16 140
Chris@16 141 if(-0.5f == frexp(val, &expon))
Chris@16 142 --expon; // reduce exponent when val is a power of two, and negative.
Chris@16 143 T diff = ldexp(T(1), expon - tools::digits<T>());
Chris@16 144 if(diff == 0)
Chris@16 145 diff = detail::get_smallest_value<T>();
Chris@16 146 return val + diff;
Chris@16 147 }
Chris@16 148
Chris@16 149 }
Chris@16 150
Chris@16 151 template <class T, class Policy>
Chris@16 152 inline typename tools::promote_args<T>::type float_next(const T& val, const Policy& pol)
Chris@16 153 {
Chris@16 154 typedef typename tools::promote_args<T>::type result_type;
Chris@16 155 return detail::float_next_imp(static_cast<result_type>(val), pol);
Chris@16 156 }
Chris@16 157
Chris@16 158 #if 0 //def BOOST_MSVC
Chris@16 159 //
Chris@16 160 // We used to use ::_nextafter here, but doing so fails when using
Chris@16 161 // the SSE2 registers if the FTZ or DAZ flags are set, so use our own
Chris@16 162 // - albeit slower - code instead as at least that gives the correct answer.
Chris@16 163 //
Chris@16 164 template <class Policy>
Chris@16 165 inline double float_next(const double& val, const Policy& pol)
Chris@16 166 {
Chris@16 167 static const char* function = "float_next<%1%>(%1%)";
Chris@16 168
Chris@16 169 if(!(boost::math::isfinite)(val) && (val > 0))
Chris@16 170 return policies::raise_domain_error<double>(
Chris@16 171 function,
Chris@16 172 "Argument must be finite, but got %1%", val, pol);
Chris@16 173
Chris@16 174 if(val >= tools::max_value<double>())
Chris@16 175 return policies::raise_overflow_error<double>(function, 0, pol);
Chris@16 176
Chris@16 177 return ::_nextafter(val, tools::max_value<double>());
Chris@16 178 }
Chris@16 179 #endif
Chris@16 180
Chris@16 181 template <class T>
Chris@16 182 inline typename tools::promote_args<T>::type float_next(const T& val)
Chris@16 183 {
Chris@16 184 return float_next(val, policies::policy<>());
Chris@16 185 }
Chris@16 186
Chris@16 187 namespace detail{
Chris@16 188
Chris@16 189 template <class T, class Policy>
Chris@16 190 T float_prior_imp(const T& val, const Policy& pol)
Chris@16 191 {
Chris@16 192 BOOST_MATH_STD_USING
Chris@16 193 int expon;
Chris@16 194 static const char* function = "float_prior<%1%>(%1%)";
Chris@16 195
Chris@16 196 int fpclass = (boost::math::fpclassify)(val);
Chris@16 197
Chris@101 198 if((fpclass == (int)FP_NAN) || (fpclass == (int)FP_INFINITE))
Chris@16 199 {
Chris@16 200 if(val > 0)
Chris@16 201 return tools::max_value<T>();
Chris@16 202 return policies::raise_domain_error<T>(
Chris@16 203 function,
Chris@16 204 "Argument must be finite, but got %1%", val, pol);
Chris@16 205 }
Chris@16 206
Chris@16 207 if(val <= -tools::max_value<T>())
Chris@16 208 return -policies::raise_overflow_error<T>(function, 0, pol);
Chris@16 209
Chris@16 210 if(val == 0)
Chris@16 211 return -detail::get_smallest_value<T>();
Chris@16 212
Chris@101 213 if((fpclass != (int)FP_SUBNORMAL) && (fpclass != (int)FP_ZERO) && (fabs(val) < detail::get_min_shift_value<T>()) && (val != tools::min_value<T>()))
Chris@16 214 {
Chris@16 215 //
Chris@16 216 // Special case: if the value of the least significant bit is a denorm, and the result
Chris@16 217 // would not be a denorm, then shift the input, increment, and shift back.
Chris@16 218 // This avoids issues with the Intel SSE2 registers when the FTZ or DAZ flags are set.
Chris@16 219 //
Chris@16 220 return ldexp(float_prior(T(ldexp(val, 2 * tools::digits<T>())), pol), -2 * tools::digits<T>());
Chris@16 221 }
Chris@16 222
Chris@16 223 T remain = frexp(val, &expon);
Chris@16 224 if(remain == 0.5)
Chris@16 225 --expon; // when val is a power of two we must reduce the exponent
Chris@16 226 T diff = ldexp(T(1), expon - tools::digits<T>());
Chris@16 227 if(diff == 0)
Chris@16 228 diff = detail::get_smallest_value<T>();
Chris@16 229 return val - diff;
Chris@16 230 }
Chris@16 231
Chris@16 232 }
Chris@16 233
Chris@16 234 template <class T, class Policy>
Chris@16 235 inline typename tools::promote_args<T>::type float_prior(const T& val, const Policy& pol)
Chris@16 236 {
Chris@16 237 typedef typename tools::promote_args<T>::type result_type;
Chris@16 238 return detail::float_prior_imp(static_cast<result_type>(val), pol);
Chris@16 239 }
Chris@16 240
Chris@16 241 #if 0 //def BOOST_MSVC
Chris@16 242 //
Chris@16 243 // We used to use ::_nextafter here, but doing so fails when using
Chris@16 244 // the SSE2 registers if the FTZ or DAZ flags are set, so use our own
Chris@16 245 // - albeit slower - code instead as at least that gives the correct answer.
Chris@16 246 //
Chris@16 247 template <class Policy>
Chris@16 248 inline double float_prior(const double& val, const Policy& pol)
Chris@16 249 {
Chris@16 250 static const char* function = "float_prior<%1%>(%1%)";
Chris@16 251
Chris@16 252 if(!(boost::math::isfinite)(val) && (val < 0))
Chris@16 253 return policies::raise_domain_error<double>(
Chris@16 254 function,
Chris@16 255 "Argument must be finite, but got %1%", val, pol);
Chris@16 256
Chris@16 257 if(val <= -tools::max_value<double>())
Chris@16 258 return -policies::raise_overflow_error<double>(function, 0, pol);
Chris@16 259
Chris@16 260 return ::_nextafter(val, -tools::max_value<double>());
Chris@16 261 }
Chris@16 262 #endif
Chris@16 263
Chris@16 264 template <class T>
Chris@16 265 inline typename tools::promote_args<T>::type float_prior(const T& val)
Chris@16 266 {
Chris@16 267 return float_prior(val, policies::policy<>());
Chris@16 268 }
Chris@16 269
Chris@16 270 template <class T, class U, class Policy>
Chris@16 271 inline typename tools::promote_args<T, U>::type nextafter(const T& val, const U& direction, const Policy& pol)
Chris@16 272 {
Chris@16 273 typedef typename tools::promote_args<T, U>::type result_type;
Chris@16 274 return val < direction ? boost::math::float_next<result_type>(val, pol) : val == direction ? val : boost::math::float_prior<result_type>(val, pol);
Chris@16 275 }
Chris@16 276
Chris@16 277 template <class T, class U>
Chris@16 278 inline typename tools::promote_args<T, U>::type nextafter(const T& val, const U& direction)
Chris@16 279 {
Chris@16 280 return nextafter(val, direction, policies::policy<>());
Chris@16 281 }
Chris@16 282
Chris@16 283 namespace detail{
Chris@16 284
Chris@16 285 template <class T, class Policy>
Chris@16 286 T float_distance_imp(const T& a, const T& b, const Policy& pol)
Chris@16 287 {
Chris@16 288 BOOST_MATH_STD_USING
Chris@16 289 //
Chris@16 290 // Error handling:
Chris@16 291 //
Chris@16 292 static const char* function = "float_distance<%1%>(%1%, %1%)";
Chris@16 293 if(!(boost::math::isfinite)(a))
Chris@16 294 return policies::raise_domain_error<T>(
Chris@16 295 function,
Chris@16 296 "Argument a must be finite, but got %1%", a, pol);
Chris@16 297 if(!(boost::math::isfinite)(b))
Chris@16 298 return policies::raise_domain_error<T>(
Chris@16 299 function,
Chris@16 300 "Argument b must be finite, but got %1%", b, pol);
Chris@16 301 //
Chris@16 302 // Special cases:
Chris@16 303 //
Chris@16 304 if(a > b)
Chris@16 305 return -float_distance(b, a, pol);
Chris@16 306 if(a == b)
Chris@16 307 return 0;
Chris@16 308 if(a == 0)
Chris@16 309 return 1 + fabs(float_distance(static_cast<T>((b < 0) ? T(-detail::get_smallest_value<T>()) : detail::get_smallest_value<T>()), b, pol));
Chris@16 310 if(b == 0)
Chris@16 311 return 1 + fabs(float_distance(static_cast<T>((a < 0) ? T(-detail::get_smallest_value<T>()) : detail::get_smallest_value<T>()), a, pol));
Chris@16 312 if(boost::math::sign(a) != boost::math::sign(b))
Chris@16 313 return 2 + fabs(float_distance(static_cast<T>((b < 0) ? T(-detail::get_smallest_value<T>()) : detail::get_smallest_value<T>()), b, pol))
Chris@16 314 + fabs(float_distance(static_cast<T>((a < 0) ? T(-detail::get_smallest_value<T>()) : detail::get_smallest_value<T>()), a, pol));
Chris@16 315 //
Chris@16 316 // By the time we get here, both a and b must have the same sign, we want
Chris@16 317 // b > a and both postive for the following logic:
Chris@16 318 //
Chris@16 319 if(a < 0)
Chris@16 320 return float_distance(static_cast<T>(-b), static_cast<T>(-a), pol);
Chris@16 321
Chris@16 322 BOOST_ASSERT(a >= 0);
Chris@16 323 BOOST_ASSERT(b >= a);
Chris@16 324
Chris@16 325 int expon;
Chris@16 326 //
Chris@16 327 // Note that if a is a denorm then the usual formula fails
Chris@16 328 // because we actually have fewer than tools::digits<T>()
Chris@16 329 // significant bits in the representation:
Chris@16 330 //
Chris@101 331 frexp(((boost::math::fpclassify)(a) == (int)FP_SUBNORMAL) ? tools::min_value<T>() : a, &expon);
Chris@16 332 T upper = ldexp(T(1), expon);
Chris@16 333 T result = 0;
Chris@16 334 expon = tools::digits<T>() - expon;
Chris@16 335 //
Chris@16 336 // If b is greater than upper, then we *must* split the calculation
Chris@16 337 // as the size of the ULP changes with each order of magnitude change:
Chris@16 338 //
Chris@16 339 if(b > upper)
Chris@16 340 {
Chris@16 341 result = float_distance(upper, b);
Chris@16 342 }
Chris@16 343 //
Chris@16 344 // Use compensated double-double addition to avoid rounding
Chris@16 345 // errors in the subtraction:
Chris@16 346 //
Chris@16 347 T mb, x, y, z;
Chris@101 348 if(((boost::math::fpclassify)(a) == (int)FP_SUBNORMAL) || (b - a < tools::min_value<T>()))
Chris@16 349 {
Chris@16 350 //
Chris@16 351 // Special case - either one end of the range is a denormal, or else the difference is.
Chris@16 352 // The regular code will fail if we're using the SSE2 registers on Intel and either
Chris@16 353 // the FTZ or DAZ flags are set.
Chris@16 354 //
Chris@16 355 T a2 = ldexp(a, tools::digits<T>());
Chris@16 356 T b2 = ldexp(b, tools::digits<T>());
Chris@16 357 mb = -(std::min)(T(ldexp(upper, tools::digits<T>())), b2);
Chris@16 358 x = a2 + mb;
Chris@16 359 z = x - a2;
Chris@16 360 y = (a2 - (x - z)) + (mb - z);
Chris@16 361
Chris@16 362 expon -= tools::digits<T>();
Chris@16 363 }
Chris@16 364 else
Chris@16 365 {
Chris@16 366 mb = -(std::min)(upper, b);
Chris@16 367 x = a + mb;
Chris@16 368 z = x - a;
Chris@16 369 y = (a - (x - z)) + (mb - z);
Chris@16 370 }
Chris@16 371 if(x < 0)
Chris@16 372 {
Chris@16 373 x = -x;
Chris@16 374 y = -y;
Chris@16 375 }
Chris@16 376 result += ldexp(x, expon) + ldexp(y, expon);
Chris@16 377 //
Chris@16 378 // Result must be an integer:
Chris@16 379 //
Chris@16 380 BOOST_ASSERT(result == floor(result));
Chris@16 381 return result;
Chris@16 382 }
Chris@16 383
Chris@16 384 }
Chris@16 385
Chris@16 386 template <class T, class U, class Policy>
Chris@16 387 inline typename tools::promote_args<T, U>::type float_distance(const T& a, const U& b, const Policy& pol)
Chris@16 388 {
Chris@16 389 typedef typename tools::promote_args<T, U>::type result_type;
Chris@16 390 return detail::float_distance_imp(static_cast<result_type>(a), static_cast<result_type>(b), pol);
Chris@16 391 }
Chris@16 392
Chris@16 393 template <class T, class U>
Chris@16 394 typename tools::promote_args<T, U>::type float_distance(const T& a, const U& b)
Chris@16 395 {
Chris@16 396 return boost::math::float_distance(a, b, policies::policy<>());
Chris@16 397 }
Chris@16 398
Chris@16 399 namespace detail{
Chris@16 400
Chris@16 401 template <class T, class Policy>
Chris@16 402 T float_advance_imp(T val, int distance, const Policy& pol)
Chris@16 403 {
Chris@16 404 BOOST_MATH_STD_USING
Chris@16 405 //
Chris@16 406 // Error handling:
Chris@16 407 //
Chris@16 408 static const char* function = "float_advance<%1%>(%1%, int)";
Chris@16 409
Chris@16 410 int fpclass = (boost::math::fpclassify)(val);
Chris@16 411
Chris@101 412 if((fpclass == (int)FP_NAN) || (fpclass == (int)FP_INFINITE))
Chris@16 413 return policies::raise_domain_error<T>(
Chris@16 414 function,
Chris@16 415 "Argument val must be finite, but got %1%", val, pol);
Chris@16 416
Chris@16 417 if(val < 0)
Chris@16 418 return -float_advance(-val, -distance, pol);
Chris@16 419 if(distance == 0)
Chris@16 420 return val;
Chris@16 421 if(distance == 1)
Chris@16 422 return float_next(val, pol);
Chris@16 423 if(distance == -1)
Chris@16 424 return float_prior(val, pol);
Chris@16 425
Chris@16 426 if(fabs(val) < detail::get_min_shift_value<T>())
Chris@16 427 {
Chris@16 428 //
Chris@16 429 // Special case: if the value of the least significant bit is a denorm,
Chris@16 430 // implement in terms of float_next/float_prior.
Chris@16 431 // This avoids issues with the Intel SSE2 registers when the FTZ or DAZ flags are set.
Chris@16 432 //
Chris@16 433 if(distance > 0)
Chris@16 434 {
Chris@16 435 do{ val = float_next(val, pol); } while(--distance);
Chris@16 436 }
Chris@16 437 else
Chris@16 438 {
Chris@16 439 do{ val = float_prior(val, pol); } while(++distance);
Chris@16 440 }
Chris@16 441 return val;
Chris@16 442 }
Chris@16 443
Chris@16 444 int expon;
Chris@16 445 frexp(val, &expon);
Chris@16 446 T limit = ldexp((distance < 0 ? T(0.5f) : T(1)), expon);
Chris@16 447 if(val <= tools::min_value<T>())
Chris@16 448 {
Chris@16 449 limit = sign(T(distance)) * tools::min_value<T>();
Chris@16 450 }
Chris@16 451 T limit_distance = float_distance(val, limit);
Chris@16 452 while(fabs(limit_distance) < abs(distance))
Chris@16 453 {
Chris@16 454 distance -= itrunc(limit_distance);
Chris@16 455 val = limit;
Chris@16 456 if(distance < 0)
Chris@16 457 {
Chris@16 458 limit /= 2;
Chris@16 459 expon--;
Chris@16 460 }
Chris@16 461 else
Chris@16 462 {
Chris@16 463 limit *= 2;
Chris@16 464 expon++;
Chris@16 465 }
Chris@16 466 limit_distance = float_distance(val, limit);
Chris@16 467 if(distance && (limit_distance == 0))
Chris@16 468 {
Chris@101 469 return policies::raise_evaluation_error<T>(function, "Internal logic failed while trying to increment floating point value %1%: most likely your FPU is in non-IEEE conforming mode.", val, pol);
Chris@16 470 }
Chris@16 471 }
Chris@16 472 if((0.5f == frexp(val, &expon)) && (distance < 0))
Chris@16 473 --expon;
Chris@16 474 T diff = 0;
Chris@16 475 if(val != 0)
Chris@16 476 diff = distance * ldexp(T(1), expon - tools::digits<T>());
Chris@16 477 if(diff == 0)
Chris@16 478 diff = distance * detail::get_smallest_value<T>();
Chris@16 479 return val += diff;
Chris@16 480 }
Chris@16 481
Chris@16 482 }
Chris@16 483
Chris@16 484 template <class T, class Policy>
Chris@16 485 inline typename tools::promote_args<T>::type float_advance(T val, int distance, const Policy& pol)
Chris@16 486 {
Chris@16 487 typedef typename tools::promote_args<T>::type result_type;
Chris@16 488 return detail::float_advance_imp(static_cast<result_type>(val), distance, pol);
Chris@16 489 }
Chris@16 490
Chris@16 491 template <class T>
Chris@16 492 inline typename tools::promote_args<T>::type float_advance(const T& val, int distance)
Chris@16 493 {
Chris@16 494 return boost::math::float_advance(val, distance, policies::policy<>());
Chris@16 495 }
Chris@16 496
Chris@16 497 }} // namespaces
Chris@16 498
Chris@16 499 #endif // BOOST_MATH_SPECIAL_NEXT_HPP
Chris@16 500