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gcc/libstdc++-v3/include/ext/random
Jonathan Wakely 5a7960da41 PR libstdc++/85749 constrain seed sequences for random number engines 
Constrain constructors and member functions of random number engines so
that functions taking seed sequences can only be called with types that
meet the seed sequence requirements.

	PR libstdc++/85749
	* include/bits/random.h (__detail::__is_seed_seq): New SFINAE helper.
	(linear_congruential_engine, mersenne_twister_engine)
	(subtract_with_carry_engine, discard_block_engine)
	(independent_bits_engine, shuffle_order_engine): Use __is_seed_seq to
	constrain function templates taking seed sequences.
	* include/bits/random.tcc (linear_congruential_engine::seed(_Sseq&))
	(mersenne_twister_engine::seed(_Sseq&))
	(subtract_with_carry_engine::seed(_Sseq&)): Change return types to
	match declarations.
	* include/ext/random (simd_fast_mersenne_twister_engine): Use
	__is_seed_seq to constrain function templates taking seed sequences.
	* include/ext/random.tcc (simd_fast_mersenne_twister_engine::seed):
	Change return type to match declaration.
	* testsuite/26_numerics/random/discard_block_engine/cons/seed_seq2.cc:
	New.
	* testsuite/26_numerics/random/independent_bits_engine/cons/
	seed_seq2.cc: New.
	* testsuite/26_numerics/random/linear_congruential_engine/cons/
	seed_seq2.cc: New.
	* testsuite/26_numerics/random/mersenne_twister_engine/cons/
	seed_seq2.cc: New.
	* testsuite/26_numerics/random/pr60037-neg.cc: Adjust dg-error lineno.
	* testsuite/26_numerics/random/shuffle_order_engine/cons/seed_seq2.cc:
	New.
	* testsuite/26_numerics/random/subtract_with_carry_engine/cons/
	seed_seq2.cc: New.
	* testsuite/ext/random/simd_fast_mersenne_twister_engine/cons/
	seed_seq2.cc: New.

From-SVN: r260263
2018-05-15 16:36:46 +01:00

3792 lines
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// Random number extensions -*- C++ -*-
// Copyright (C) 2012-2018 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library. This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, or (at your option)
// any later version.
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.
// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
// <http://www.gnu.org/licenses/>.
/** @file ext/random
* This file is a GNU extension to the Standard C++ Library.
*/
#ifndef _EXT_RANDOM
#define _EXT_RANDOM 1
#pragma GCC system_header
#if __cplusplus < 201103L
# include <bits/c++0x_warning.h>
#else
#include <random>
#include <algorithm>
#include <array>
#include <ext/cmath>
#ifdef __SSE2__
# include <emmintrin.h>
#endif
#if defined(_GLIBCXX_USE_C99_STDINT_TR1) && defined(UINT32_C)
namespace __gnu_cxx _GLIBCXX_VISIBILITY(default)
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
/* Mersenne twister implementation optimized for vector operations.
*
* Reference: http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/SFMT/
*/
template<typename _UIntType, size_t __m,
size_t __pos1, size_t __sl1, size_t __sl2,
size_t __sr1, size_t __sr2,
uint32_t __msk1, uint32_t __msk2,
uint32_t __msk3, uint32_t __msk4,
uint32_t __parity1, uint32_t __parity2,
uint32_t __parity3, uint32_t __parity4>
class simd_fast_mersenne_twister_engine
{
static_assert(std::is_unsigned<_UIntType>::value, "template argument "
"substituting _UIntType not an unsigned integral type");
static_assert(__sr1 < 32, "first right shift too large");
static_assert(__sr2 < 16, "second right shift too large");
static_assert(__sl1 < 32, "first left shift too large");
static_assert(__sl2 < 16, "second left shift too large");
public:
typedef _UIntType result_type;
private:
static constexpr size_t m_w = sizeof(result_type) * 8;
static constexpr size_t _M_nstate = __m / 128 + 1;
static constexpr size_t _M_nstate32 = _M_nstate * 4;
static_assert(std::is_unsigned<_UIntType>::value, "template argument "
"substituting _UIntType not an unsigned integral type");
static_assert(__pos1 < _M_nstate, "POS1 not smaller than state size");
static_assert(16 % sizeof(_UIntType) == 0,
"UIntType size must divide 16");
template<typename _Sseq>
using _If_seed_seq
= typename std::enable_if<std::__detail::__is_seed_seq<
_Sseq, simd_fast_mersenne_twister_engine, result_type>::value
>::type;
public:
static constexpr size_t state_size = _M_nstate * (16
/ sizeof(result_type));
static constexpr result_type default_seed = 5489u;
// constructors and member function
explicit
simd_fast_mersenne_twister_engine(result_type __sd = default_seed)
{ seed(__sd); }
template<typename _Sseq, typename = _If_seed_seq<_Sseq>>
explicit
simd_fast_mersenne_twister_engine(_Sseq& __q)
{ seed(__q); }
void
seed(result_type __sd = default_seed);
template<typename _Sseq>
_If_seed_seq<_Sseq>
seed(_Sseq& __q);
static constexpr result_type
min()
{ return 0; }
static constexpr result_type
max()
{ return std::numeric_limits<result_type>::max(); }
void
discard(unsigned long long __z);
result_type
operator()()
{
if (__builtin_expect(_M_pos >= state_size, 0))
_M_gen_rand();
return _M_stateT[_M_pos++];
}
template<typename _UIntType_2, size_t __m_2,
size_t __pos1_2, size_t __sl1_2, size_t __sl2_2,
size_t __sr1_2, size_t __sr2_2,
uint32_t __msk1_2, uint32_t __msk2_2,
uint32_t __msk3_2, uint32_t __msk4_2,
uint32_t __parity1_2, uint32_t __parity2_2,
uint32_t __parity3_2, uint32_t __parity4_2>
friend bool
operator==(const simd_fast_mersenne_twister_engine<_UIntType_2,
__m_2, __pos1_2, __sl1_2, __sl2_2, __sr1_2, __sr2_2,
__msk1_2, __msk2_2, __msk3_2, __msk4_2,
__parity1_2, __parity2_2, __parity3_2, __parity4_2>& __lhs,
const simd_fast_mersenne_twister_engine<_UIntType_2,
__m_2, __pos1_2, __sl1_2, __sl2_2, __sr1_2, __sr2_2,
__msk1_2, __msk2_2, __msk3_2, __msk4_2,
__parity1_2, __parity2_2, __parity3_2, __parity4_2>& __rhs);
template<typename _UIntType_2, size_t __m_2,
size_t __pos1_2, size_t __sl1_2, size_t __sl2_2,
size_t __sr1_2, size_t __sr2_2,
uint32_t __msk1_2, uint32_t __msk2_2,
uint32_t __msk3_2, uint32_t __msk4_2,
uint32_t __parity1_2, uint32_t __parity2_2,
uint32_t __parity3_2, uint32_t __parity4_2,
typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::simd_fast_mersenne_twister_engine
<_UIntType_2,
__m_2, __pos1_2, __sl1_2, __sl2_2, __sr1_2, __sr2_2,
__msk1_2, __msk2_2, __msk3_2, __msk4_2,
__parity1_2, __parity2_2, __parity3_2, __parity4_2>& __x);
template<typename _UIntType_2, size_t __m_2,
size_t __pos1_2, size_t __sl1_2, size_t __sl2_2,
size_t __sr1_2, size_t __sr2_2,
uint32_t __msk1_2, uint32_t __msk2_2,
uint32_t __msk3_2, uint32_t __msk4_2,
uint32_t __parity1_2, uint32_t __parity2_2,
uint32_t __parity3_2, uint32_t __parity4_2,
typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::simd_fast_mersenne_twister_engine<_UIntType_2,
__m_2, __pos1_2, __sl1_2, __sl2_2, __sr1_2, __sr2_2,
__msk1_2, __msk2_2, __msk3_2, __msk4_2,
__parity1_2, __parity2_2, __parity3_2, __parity4_2>& __x);
private:
union
{
#ifdef __SSE2__
__m128i _M_state[_M_nstate];
#endif
#ifdef __ARM_NEON
#ifdef __aarch64__
__Uint32x4_t _M_state[_M_nstate];
#endif
#endif
uint32_t _M_state32[_M_nstate32];
result_type _M_stateT[state_size];
} __attribute__ ((__aligned__ (16)));
size_t _M_pos;
void _M_gen_rand(void);
void _M_period_certification();
};
template<typename _UIntType, size_t __m,
size_t __pos1, size_t __sl1, size_t __sl2,
size_t __sr1, size_t __sr2,
uint32_t __msk1, uint32_t __msk2,
uint32_t __msk3, uint32_t __msk4,
uint32_t __parity1, uint32_t __parity2,
uint32_t __parity3, uint32_t __parity4>
inline bool
operator!=(const __gnu_cxx::simd_fast_mersenne_twister_engine<_UIntType,
__m, __pos1, __sl1, __sl2, __sr1, __sr2, __msk1, __msk2, __msk3,
__msk4, __parity1, __parity2, __parity3, __parity4>& __lhs,
const __gnu_cxx::simd_fast_mersenne_twister_engine<_UIntType,
__m, __pos1, __sl1, __sl2, __sr1, __sr2, __msk1, __msk2, __msk3,
__msk4, __parity1, __parity2, __parity3, __parity4>& __rhs)
{ return !(__lhs == __rhs); }
/* Definitions for the SIMD-oriented Fast Mersenne Twister as defined
* in the C implementation by Daito and Matsumoto, as both a 32-bit
* and 64-bit version.
*/
typedef simd_fast_mersenne_twister_engine<uint32_t, 607, 2,
15, 3, 13, 3,
0xfdff37ffU, 0xef7f3f7dU,
0xff777b7dU, 0x7ff7fb2fU,
0x00000001U, 0x00000000U,
0x00000000U, 0x5986f054U>
sfmt607;
typedef simd_fast_mersenne_twister_engine<uint64_t, 607, 2,
15, 3, 13, 3,
0xfdff37ffU, 0xef7f3f7dU,
0xff777b7dU, 0x7ff7fb2fU,
0x00000001U, 0x00000000U,
0x00000000U, 0x5986f054U>
sfmt607_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 1279, 7,
14, 3, 5, 1,
0xf7fefffdU, 0x7fefcfffU,
0xaff3ef3fU, 0xb5ffff7fU,
0x00000001U, 0x00000000U,
0x00000000U, 0x20000000U>
sfmt1279;
typedef simd_fast_mersenne_twister_engine<uint64_t, 1279, 7,
14, 3, 5, 1,
0xf7fefffdU, 0x7fefcfffU,
0xaff3ef3fU, 0xb5ffff7fU,
0x00000001U, 0x00000000U,
0x00000000U, 0x20000000U>
sfmt1279_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 2281, 12,
19, 1, 5, 1,
0xbff7ffbfU, 0xfdfffffeU,
0xf7ffef7fU, 0xf2f7cbbfU,
0x00000001U, 0x00000000U,
0x00000000U, 0x41dfa600U>
sfmt2281;
typedef simd_fast_mersenne_twister_engine<uint64_t, 2281, 12,
19, 1, 5, 1,
0xbff7ffbfU, 0xfdfffffeU,
0xf7ffef7fU, 0xf2f7cbbfU,
0x00000001U, 0x00000000U,
0x00000000U, 0x41dfa600U>
sfmt2281_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 4253, 17,
20, 1, 7, 1,
0x9f7bffffU, 0x9fffff5fU,
0x3efffffbU, 0xfffff7bbU,
0xa8000001U, 0xaf5390a3U,
0xb740b3f8U, 0x6c11486dU>
sfmt4253;
typedef simd_fast_mersenne_twister_engine<uint64_t, 4253, 17,
20, 1, 7, 1,
0x9f7bffffU, 0x9fffff5fU,
0x3efffffbU, 0xfffff7bbU,
0xa8000001U, 0xaf5390a3U,
0xb740b3f8U, 0x6c11486dU>
sfmt4253_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 11213, 68,
14, 3, 7, 3,
0xeffff7fbU, 0xffffffefU,
0xdfdfbfffU, 0x7fffdbfdU,
0x00000001U, 0x00000000U,
0xe8148000U, 0xd0c7afa3U>
sfmt11213;
typedef simd_fast_mersenne_twister_engine<uint64_t, 11213, 68,
14, 3, 7, 3,
0xeffff7fbU, 0xffffffefU,
0xdfdfbfffU, 0x7fffdbfdU,
0x00000001U, 0x00000000U,
0xe8148000U, 0xd0c7afa3U>
sfmt11213_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 19937, 122,
18, 1, 11, 1,
0xdfffffefU, 0xddfecb7fU,
0xbffaffffU, 0xbffffff6U,
0x00000001U, 0x00000000U,
0x00000000U, 0x13c9e684U>
sfmt19937;
typedef simd_fast_mersenne_twister_engine<uint64_t, 19937, 122,
18, 1, 11, 1,
0xdfffffefU, 0xddfecb7fU,
0xbffaffffU, 0xbffffff6U,
0x00000001U, 0x00000000U,
0x00000000U, 0x13c9e684U>
sfmt19937_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 44497, 330,
5, 3, 9, 3,
0xeffffffbU, 0xdfbebfffU,
0xbfbf7befU, 0x9ffd7bffU,
0x00000001U, 0x00000000U,
0xa3ac4000U, 0xecc1327aU>
sfmt44497;
typedef simd_fast_mersenne_twister_engine<uint64_t, 44497, 330,
5, 3, 9, 3,
0xeffffffbU, 0xdfbebfffU,
0xbfbf7befU, 0x9ffd7bffU,
0x00000001U, 0x00000000U,
0xa3ac4000U, 0xecc1327aU>
sfmt44497_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 86243, 366,
6, 7, 19, 1,
0xfdbffbffU, 0xbff7ff3fU,
0xfd77efffU, 0xbf9ff3ffU,
0x00000001U, 0x00000000U,
0x00000000U, 0xe9528d85U>
sfmt86243;
typedef simd_fast_mersenne_twister_engine<uint64_t, 86243, 366,
6, 7, 19, 1,
0xfdbffbffU, 0xbff7ff3fU,
0xfd77efffU, 0xbf9ff3ffU,
0x00000001U, 0x00000000U,
0x00000000U, 0xe9528d85U>
sfmt86243_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 132049, 110,
19, 1, 21, 1,
0xffffbb5fU, 0xfb6ebf95U,
0xfffefffaU, 0xcff77fffU,
0x00000001U, 0x00000000U,
0xcb520000U, 0xc7e91c7dU>
sfmt132049;
typedef simd_fast_mersenne_twister_engine<uint64_t, 132049, 110,
19, 1, 21, 1,
0xffffbb5fU, 0xfb6ebf95U,
0xfffefffaU, 0xcff77fffU,
0x00000001U, 0x00000000U,
0xcb520000U, 0xc7e91c7dU>
sfmt132049_64;
typedef simd_fast_mersenne_twister_engine<uint32_t, 216091, 627,
11, 3, 10, 1,
0xbff7bff7U, 0xbfffffffU,
0xbffffa7fU, 0xffddfbfbU,
0xf8000001U, 0x89e80709U,
0x3bd2b64bU, 0x0c64b1e4U>
sfmt216091;
typedef simd_fast_mersenne_twister_engine<uint64_t, 216091, 627,
11, 3, 10, 1,
0xbff7bff7U, 0xbfffffffU,
0xbffffa7fU, 0xffddfbfbU,
0xf8000001U, 0x89e80709U,
0x3bd2b64bU, 0x0c64b1e4U>
sfmt216091_64;
#endif // __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
/**
* @brief A beta continuous distribution for random numbers.
*
* The formula for the beta probability density function is:
* @f[
* p(x|\alpha,\beta) = \frac{1}{B(\alpha,\beta)}
* x^{\alpha - 1} (1 - x)^{\beta - 1}
* @f]
*/
template<typename _RealType = double>
class beta_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef beta_distribution<_RealType> distribution_type;
friend class beta_distribution<_RealType>;
explicit
param_type(_RealType __alpha_val = _RealType(1),
_RealType __beta_val = _RealType(1))
: _M_alpha(__alpha_val), _M_beta(__beta_val)
{
__glibcxx_assert(_M_alpha > _RealType(0));
__glibcxx_assert(_M_beta > _RealType(0));
}
_RealType
alpha() const
{ return _M_alpha; }
_RealType
beta() const
{ return _M_beta; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return (__p1._M_alpha == __p2._M_alpha
&& __p1._M_beta == __p2._M_beta); }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void
_M_initialize();
_RealType _M_alpha;
_RealType _M_beta;
};
public:
/**
* @brief Constructs a beta distribution with parameters
* @f$\alpha@f$ and @f$\beta@f$.
*/
explicit
beta_distribution(_RealType __alpha_val = _RealType(1),
_RealType __beta_val = _RealType(1))
: _M_param(__alpha_val, __beta_val)
{ }
explicit
beta_distribution(const param_type& __p)
: _M_param(__p)
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ }
/**
* @brief Returns the @f$\alpha@f$ of the distribution.
*/
_RealType
alpha() const
{ return _M_param.alpha(); }
/**
* @brief Returns the @f$\beta@f$ of the distribution.
*/
_RealType
beta() const
{ return _M_param.beta(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return result_type(0); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return result_type(1); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two beta distributions have the same
* parameters and the sequences that would be generated
* are equal.
*/
friend bool
operator==(const beta_distribution& __d1,
const beta_distribution& __d2)
{ return __d1._M_param == __d2._M_param; }
/**
* @brief Inserts a %beta_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %beta_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::beta_distribution<_RealType1>& __x);
/**
* @brief Extracts a %beta_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %beta_distribution random number generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::beta_distribution<_RealType1>& __x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
};
/**
* @brief Return true if two beta distributions are different.
*/
template<typename _RealType>
inline bool
operator!=(const __gnu_cxx::beta_distribution<_RealType>& __d1,
const __gnu_cxx::beta_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A multi-variate normal continuous distribution for random numbers.
*
* The formula for the normal probability density function is
* @f[
* p(\overrightarrow{x}|\overrightarrow{\mu },\Sigma) =
* \frac{1}{\sqrt{(2\pi )^k\det(\Sigma))}}
* e^{-\frac{1}{2}(\overrightarrow{x}-\overrightarrow{\mu})^\text{T}
* \Sigma ^{-1}(\overrightarrow{x}-\overrightarrow{\mu})}
* @f]
*
* where @f$\overrightarrow{x}@f$ and @f$\overrightarrow{\mu}@f$ are
* vectors of dimension @f$k@f$ and @f$\Sigma@f$ is the covariance
* matrix (which must be positive-definite).
*/
template<std::size_t _Dimen, typename _RealType = double>
class normal_mv_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
static_assert(_Dimen != 0, "dimension is zero");
public:
/** The type of the range of the distribution. */
typedef std::array<_RealType, _Dimen> result_type;
/** Parameter type. */
class param_type
{
static constexpr size_t _M_t_size = _Dimen * (_Dimen + 1) / 2;
public:
typedef normal_mv_distribution<_Dimen, _RealType> distribution_type;
friend class normal_mv_distribution<_Dimen, _RealType>;
param_type()
{
std::fill(_M_mean.begin(), _M_mean.end(), _RealType(0));
auto __it = _M_t.begin();
for (size_t __i = 0; __i < _Dimen; ++__i)
{
std::fill_n(__it, __i, _RealType(0));
__it += __i;
*__it++ = _RealType(1);
}
}
template<typename _ForwardIterator1, typename _ForwardIterator2>
param_type(_ForwardIterator1 __meanbegin,
_ForwardIterator1 __meanend,
_ForwardIterator2 __varcovbegin,
_ForwardIterator2 __varcovend)
{
__glibcxx_function_requires(_ForwardIteratorConcept<
_ForwardIterator1>)
__glibcxx_function_requires(_ForwardIteratorConcept<
_ForwardIterator2>)
_GLIBCXX_DEBUG_ASSERT(std::distance(__meanbegin, __meanend)
<= _Dimen);
const auto __dist = std::distance(__varcovbegin, __varcovend);
_GLIBCXX_DEBUG_ASSERT(__dist == _Dimen * _Dimen
|| __dist == _Dimen * (_Dimen + 1) / 2
|| __dist == _Dimen);
if (__dist == _Dimen * _Dimen)
_M_init_full(__meanbegin, __meanend, __varcovbegin, __varcovend);
else if (__dist == _Dimen * (_Dimen + 1) / 2)
_M_init_lower(__meanbegin, __meanend, __varcovbegin, __varcovend);
else
{
__glibcxx_assert(__dist == _Dimen);
_M_init_diagonal(__meanbegin, __meanend,
__varcovbegin, __varcovend);
}
}
param_type(std::initializer_list<_RealType> __mean,
std::initializer_list<_RealType> __varcov)
{
_GLIBCXX_DEBUG_ASSERT(__mean.size() <= _Dimen);
_GLIBCXX_DEBUG_ASSERT(__varcov.size() == _Dimen * _Dimen
|| __varcov.size() == _Dimen * (_Dimen + 1) / 2
|| __varcov.size() == _Dimen);
if (__varcov.size() == _Dimen * _Dimen)
_M_init_full(__mean.begin(), __mean.end(),
__varcov.begin(), __varcov.end());
else if (__varcov.size() == _Dimen * (_Dimen + 1) / 2)
_M_init_lower(__mean.begin(), __mean.end(),
__varcov.begin(), __varcov.end());
else
{
__glibcxx_assert(__varcov.size() == _Dimen);
_M_init_diagonal(__mean.begin(), __mean.end(),
__varcov.begin(), __varcov.end());
}
}
std::array<_RealType, _Dimen>
mean() const
{ return _M_mean; }
std::array<_RealType, _M_t_size>
varcov() const
{ return _M_t; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_mean == __p2._M_mean && __p1._M_t == __p2._M_t; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
template <typename _InputIterator1, typename _InputIterator2>
void _M_init_full(_InputIterator1 __meanbegin,
_InputIterator1 __meanend,
_InputIterator2 __varcovbegin,
_InputIterator2 __varcovend);
template <typename _InputIterator1, typename _InputIterator2>
void _M_init_lower(_InputIterator1 __meanbegin,
_InputIterator1 __meanend,
_InputIterator2 __varcovbegin,
_InputIterator2 __varcovend);
template <typename _InputIterator1, typename _InputIterator2>
void _M_init_diagonal(_InputIterator1 __meanbegin,
_InputIterator1 __meanend,
_InputIterator2 __varbegin,
_InputIterator2 __varend);
std::array<_RealType, _Dimen> _M_mean;
std::array<_RealType, _M_t_size> _M_t;
};
public:
normal_mv_distribution()
: _M_param(), _M_nd()
{ }
template<typename _ForwardIterator1, typename _ForwardIterator2>
normal_mv_distribution(_ForwardIterator1 __meanbegin,
_ForwardIterator1 __meanend,
_ForwardIterator2 __varcovbegin,
_ForwardIterator2 __varcovend)
: _M_param(__meanbegin, __meanend, __varcovbegin, __varcovend),
_M_nd()
{ }
normal_mv_distribution(std::initializer_list<_RealType> __mean,
std::initializer_list<_RealType> __varcov)
: _M_param(__mean, __varcov), _M_nd()
{ }
explicit
normal_mv_distribution(const param_type& __p)
: _M_param(__p), _M_nd()
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ _M_nd.reset(); }
/**
* @brief Returns the mean of the distribution.
*/
result_type
mean() const
{ return _M_param.mean(); }
/**
* @brief Returns the compact form of the variance/covariance
* matrix of the distribution.
*/
std::array<_RealType, _Dimen * (_Dimen + 1) / 2>
varcov() const
{ return _M_param.varcov(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ result_type __res;
__res.fill(std::numeric_limits<_RealType>::lowest());
return __res; }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ result_type __res;
__res.fill(std::numeric_limits<_RealType>::max());
return __res; }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ return this->__generate_impl(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ return this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two multi-variant normal distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
template<size_t _Dimen1, typename _RealType1>
friend bool
operator==(const
__gnu_cxx::normal_mv_distribution<_Dimen1, _RealType1>&
__d1,
const
__gnu_cxx::normal_mv_distribution<_Dimen1, _RealType1>&
__d2);
/**
* @brief Inserts a %normal_mv_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %normal_mv_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<size_t _Dimen1, typename _RealType1,
typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const
__gnu_cxx::normal_mv_distribution<_Dimen1, _RealType1>&
__x);
/**
* @brief Extracts a %normal_mv_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %normal_mv_distribution random number generator engine.
*
* @returns The input stream with @p __x extracted or in an error
* state.
*/
template<size_t _Dimen1, typename _RealType1,
typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::normal_mv_distribution<_Dimen1, _RealType1>&
__x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::normal_distribution<_RealType> _M_nd;
};
/**
* @brief Return true if two multi-variate normal distributions are
* different.
*/
template<size_t _Dimen, typename _RealType>
inline bool
operator!=(const __gnu_cxx::normal_mv_distribution<_Dimen, _RealType>&
__d1,
const __gnu_cxx::normal_mv_distribution<_Dimen, _RealType>&
__d2)
{ return !(__d1 == __d2); }
/**
* @brief A Rice continuous distribution for random numbers.
*
* The formula for the Rice probability density function is
* @f[
* p(x|\nu,\sigma) = \frac{x}{\sigma^2}
* \exp\left(-\frac{x^2+\nu^2}{2\sigma^2}\right)
* I_0\left(\frac{x \nu}{\sigma^2}\right)
* @f]
* where @f$I_0(z)@f$ is the modified Bessel function of the first kind
* of order 0 and @f$\nu >= 0@f$ and @f$\sigma > 0@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$\sqrt{\pi/2}L_{1/2}(-\nu^2/2\sigma^2)@f$</td></tr>
* <tr><td>Variance</td><td>@f$2\sigma^2 + \nu^2
* + (\pi\sigma^2/2)L^2_{1/2}(-\nu^2/2\sigma^2)@f$</td></tr>
* <tr><td>Range</td><td>@f$[0, \infty)@f$</td></tr>
* </table>
* where @f$L_{1/2}(x)@f$ is the Laguerre polynomial of order 1/2.
*/
template<typename _RealType = double>
class
rice_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef rice_distribution<result_type> distribution_type;
param_type(result_type __nu_val = result_type(0),
result_type __sigma_val = result_type(1))
: _M_nu(__nu_val), _M_sigma(__sigma_val)
{
__glibcxx_assert(_M_nu >= result_type(0));
__glibcxx_assert(_M_sigma > result_type(0));
}
result_type
nu() const
{ return _M_nu; }
result_type
sigma() const
{ return _M_sigma; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_nu == __p2._M_nu && __p1._M_sigma == __p2._M_sigma; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_nu;
result_type _M_sigma;
};
/**
* @brief Constructors.
*/
explicit
rice_distribution(result_type __nu_val = result_type(0),
result_type __sigma_val = result_type(1))
: _M_param(__nu_val, __sigma_val),
_M_ndx(__nu_val, __sigma_val),
_M_ndy(result_type(0), __sigma_val)
{ }
explicit
rice_distribution(const param_type& __p)
: _M_param(__p),
_M_ndx(__p.nu(), __p.sigma()),
_M_ndy(result_type(0), __p.sigma())
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{
_M_ndx.reset();
_M_ndy.reset();
}
/**
* @brief Return the parameters of the distribution.
*/
result_type
nu() const
{ return _M_param.nu(); }
result_type
sigma() const
{ return _M_param.sigma(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return result_type(0); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{
result_type __x = this->_M_ndx(__urng);
result_type __y = this->_M_ndy(__urng);
#if _GLIBCXX_USE_C99_MATH_TR1
return std::hypot(__x, __y);
#else
return std::sqrt(__x * __x + __y * __y);
#endif
}
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{
typename std::normal_distribution<result_type>::param_type
__px(__p.nu(), __p.sigma()), __py(result_type(0), __p.sigma());
result_type __x = this->_M_ndx(__px, __urng);
result_type __y = this->_M_ndy(__py, __urng);
#if _GLIBCXX_USE_C99_MATH_TR1
return std::hypot(__x, __y);
#else
return std::sqrt(__x * __x + __y * __y);
#endif
}
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two Rice distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const rice_distribution& __d1,
const rice_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_ndx == __d2._M_ndx
&& __d1._M_ndy == __d2._M_ndy); }
/**
* @brief Inserts a %rice_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %rice_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const rice_distribution<_RealType1>&);
/**
* @brief Extracts a %rice_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %rice_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
rice_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::normal_distribution<result_type> _M_ndx;
std::normal_distribution<result_type> _M_ndy;
};
/**
* @brief Return true if two Rice distributions are not equal.
*/
template<typename _RealType1>
inline bool
operator!=(const rice_distribution<_RealType1>& __d1,
const rice_distribution<_RealType1>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A Nakagami continuous distribution for random numbers.
*
* The formula for the Nakagami probability density function is
* @f[
* p(x|\mu,\omega) = \frac{2\mu^\mu}{\Gamma(\mu)\omega^\mu}
* x^{2\mu-1}e^{-\mu x / \omega}
* @f]
* where @f$\Gamma(z)@f$ is the gamma function and @f$\mu >= 0.5@f$
* and @f$\omega > 0@f$.
*/
template<typename _RealType = double>
class
nakagami_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef nakagami_distribution<result_type> distribution_type;
param_type(result_type __mu_val = result_type(1),
result_type __omega_val = result_type(1))
: _M_mu(__mu_val), _M_omega(__omega_val)
{
__glibcxx_assert(_M_mu >= result_type(0.5L));
__glibcxx_assert(_M_omega > result_type(0));
}
result_type
mu() const
{ return _M_mu; }
result_type
omega() const
{ return _M_omega; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_mu == __p2._M_mu && __p1._M_omega == __p2._M_omega; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_mu;
result_type _M_omega;
};
/**
* @brief Constructors.
*/
explicit
nakagami_distribution(result_type __mu_val = result_type(1),
result_type __omega_val = result_type(1))
: _M_param(__mu_val, __omega_val),
_M_gd(__mu_val, __omega_val / __mu_val)
{ }
explicit
nakagami_distribution(const param_type& __p)
: _M_param(__p),
_M_gd(__p.mu(), __p.omega() / __p.mu())
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ _M_gd.reset(); }
/**
* @brief Return the parameters of the distribution.
*/
result_type
mu() const
{ return _M_param.mu(); }
result_type
omega() const
{ return _M_param.omega(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return result_type(0); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return std::sqrt(this->_M_gd(__urng)); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{
typename std::gamma_distribution<result_type>::param_type
__pg(__p.mu(), __p.omega() / __p.mu());
return std::sqrt(this->_M_gd(__pg, __urng));
}
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two Nakagami distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const nakagami_distribution& __d1,
const nakagami_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_gd == __d2._M_gd); }
/**
* @brief Inserts a %nakagami_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %nakagami_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const nakagami_distribution<_RealType1>&);
/**
* @brief Extracts a %nakagami_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %nakagami_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
nakagami_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::gamma_distribution<result_type> _M_gd;
};
/**
* @brief Return true if two Nakagami distributions are not equal.
*/
template<typename _RealType>
inline bool
operator!=(const nakagami_distribution<_RealType>& __d1,
const nakagami_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A Pareto continuous distribution for random numbers.
*
* The formula for the Pareto cumulative probability function is
* @f[
* P(x|\alpha,\mu) = 1 - \left(\frac{\mu}{x}\right)^\alpha
* @f]
* The formula for the Pareto probability density function is
* @f[
* p(x|\alpha,\mu) = \frac{\alpha + 1}{\mu}
* \left(\frac{\mu}{x}\right)^{\alpha + 1}
* @f]
* where @f$x >= \mu@f$ and @f$\mu > 0@f$, @f$\alpha > 0@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$\alpha \mu / (\alpha - 1)@f$
* for @f$\alpha > 1@f$</td></tr>
* <tr><td>Variance</td><td>@f$\alpha \mu^2 / [(\alpha - 1)^2(\alpha - 2)]@f$
* for @f$\alpha > 2@f$</td></tr>
* <tr><td>Range</td><td>@f$[\mu, \infty)@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class
pareto_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef pareto_distribution<result_type> distribution_type;
param_type(result_type __alpha_val = result_type(1),
result_type __mu_val = result_type(1))
: _M_alpha(__alpha_val), _M_mu(__mu_val)
{
__glibcxx_assert(_M_alpha > result_type(0));
__glibcxx_assert(_M_mu > result_type(0));
}
result_type
alpha() const
{ return _M_alpha; }
result_type
mu() const
{ return _M_mu; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_alpha == __p2._M_alpha && __p1._M_mu == __p2._M_mu; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_alpha;
result_type _M_mu;
};
/**
* @brief Constructors.
*/
explicit
pareto_distribution(result_type __alpha_val = result_type(1),
result_type __mu_val = result_type(1))
: _M_param(__alpha_val, __mu_val),
_M_ud()
{ }
explicit
pareto_distribution(const param_type& __p)
: _M_param(__p),
_M_ud()
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{
_M_ud.reset();
}
/**
* @brief Return the parameters of the distribution.
*/
result_type
alpha() const
{ return _M_param.alpha(); }
result_type
mu() const
{ return _M_param.mu(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return this->mu(); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{
return this->mu() * std::pow(this->_M_ud(__urng),
-result_type(1) / this->alpha());
}
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{
return __p.mu() * std::pow(this->_M_ud(__urng),
-result_type(1) / __p.alpha());
}
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two Pareto distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const pareto_distribution& __d1,
const pareto_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_ud == __d2._M_ud); }
/**
* @brief Inserts a %pareto_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %pareto_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const pareto_distribution<_RealType1>&);
/**
* @brief Extracts a %pareto_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %pareto_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
pareto_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::uniform_real_distribution<result_type> _M_ud;
};
/**
* @brief Return true if two Pareto distributions are not equal.
*/
template<typename _RealType>
inline bool
operator!=(const pareto_distribution<_RealType>& __d1,
const pareto_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A K continuous distribution for random numbers.
*
* The formula for the K probability density function is
* @f[
* p(x|\lambda, \mu, \nu) = \frac{2}{x}
* \left(\frac{\lambda\nu x}{\mu}\right)^{\frac{\lambda + \nu}{2}}
* \frac{1}{\Gamma(\lambda)\Gamma(\nu)}
* K_{\nu - \lambda}\left(2\sqrt{\frac{\lambda\nu x}{\mu}}\right)
* @f]
* where @f$I_0(z)@f$ is the modified Bessel function of the second kind
* of order @f$\nu - \lambda@f$ and @f$\lambda > 0@f$, @f$\mu > 0@f$
* and @f$\nu > 0@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$\mu@f$</td></tr>
* <tr><td>Variance</td><td>@f$\mu^2\frac{\lambda + \nu + 1}{\lambda\nu}@f$</td></tr>
* <tr><td>Range</td><td>@f$[0, \infty)@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class
k_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef k_distribution<result_type> distribution_type;
param_type(result_type __lambda_val = result_type(1),
result_type __mu_val = result_type(1),
result_type __nu_val = result_type(1))
: _M_lambda(__lambda_val), _M_mu(__mu_val), _M_nu(__nu_val)
{
__glibcxx_assert(_M_lambda > result_type(0));
__glibcxx_assert(_M_mu > result_type(0));
__glibcxx_assert(_M_nu > result_type(0));
}
result_type
lambda() const
{ return _M_lambda; }
result_type
mu() const
{ return _M_mu; }
result_type
nu() const
{ return _M_nu; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{
return __p1._M_lambda == __p2._M_lambda
&& __p1._M_mu == __p2._M_mu
&& __p1._M_nu == __p2._M_nu;
}
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_lambda;
result_type _M_mu;
result_type _M_nu;
};
/**
* @brief Constructors.
*/
explicit
k_distribution(result_type __lambda_val = result_type(1),
result_type __mu_val = result_type(1),
result_type __nu_val = result_type(1))
: _M_param(__lambda_val, __mu_val, __nu_val),
_M_gd1(__lambda_val, result_type(1) / __lambda_val),
_M_gd2(__nu_val, __mu_val / __nu_val)
{ }
explicit
k_distribution(const param_type& __p)
: _M_param(__p),
_M_gd1(__p.lambda(), result_type(1) / __p.lambda()),
_M_gd2(__p.nu(), __p.mu() / __p.nu())
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{
_M_gd1.reset();
_M_gd2.reset();
}
/**
* @brief Return the parameters of the distribution.
*/
result_type
lambda() const
{ return _M_param.lambda(); }
result_type
mu() const
{ return _M_param.mu(); }
result_type
nu() const
{ return _M_param.nu(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return result_type(0); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator&);
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator&, const param_type&);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two K distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const k_distribution& __d1,
const k_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_gd1 == __d2._M_gd1
&& __d1._M_gd2 == __d2._M_gd2); }
/**
* @brief Inserts a %k_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %k_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const k_distribution<_RealType1>&);
/**
* @brief Extracts a %k_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %k_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
k_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::gamma_distribution<result_type> _M_gd1;
std::gamma_distribution<result_type> _M_gd2;
};
/**
* @brief Return true if two K distributions are not equal.
*/
template<typename _RealType>
inline bool
operator!=(const k_distribution<_RealType>& __d1,
const k_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief An arcsine continuous distribution for random numbers.
*
* The formula for the arcsine probability density function is
* @f[
* p(x|a,b) = \frac{1}{\pi \sqrt{(x - a)(b - x)}}
* @f]
* where @f$x >= a@f$ and @f$x <= b@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$ (a + b) / 2 @f$</td></tr>
* <tr><td>Variance</td><td>@f$ (b - a)^2 / 8 @f$</td></tr>
* <tr><td>Range</td><td>@f$[a, b]@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class
arcsine_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef arcsine_distribution<result_type> distribution_type;
param_type(result_type __a = result_type(0),
result_type __b = result_type(1))
: _M_a(__a), _M_b(__b)
{
__glibcxx_assert(_M_a <= _M_b);
}
result_type
a() const
{ return _M_a; }
result_type
b() const
{ return _M_b; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_a;
result_type _M_b;
};
/**
* @brief Constructors.
*/
explicit
arcsine_distribution(result_type __a = result_type(0),
result_type __b = result_type(1))
: _M_param(__a, __b),
_M_ud(-1.5707963267948966192313216916397514L,
+1.5707963267948966192313216916397514L)
{ }
explicit
arcsine_distribution(const param_type& __p)
: _M_param(__p),
_M_ud(-1.5707963267948966192313216916397514L,
+1.5707963267948966192313216916397514L)
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ _M_ud.reset(); }
/**
* @brief Return the parameters of the distribution.
*/
result_type
a() const
{ return _M_param.a(); }
result_type
b() const
{ return _M_param.b(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return this->a(); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return this->b(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{
result_type __x = std::sin(this->_M_ud(__urng));
return (__x * (this->b() - this->a())
+ this->a() + this->b()) / result_type(2);
}
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{
result_type __x = std::sin(this->_M_ud(__urng));
return (__x * (__p.b() - __p.a())
+ __p.a() + __p.b()) / result_type(2);
}
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two arcsine distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const arcsine_distribution& __d1,
const arcsine_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_ud == __d2._M_ud); }
/**
* @brief Inserts a %arcsine_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %arcsine_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const arcsine_distribution<_RealType1>&);
/**
* @brief Extracts a %arcsine_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %arcsine_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
arcsine_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::uniform_real_distribution<result_type> _M_ud;
};
/**
* @brief Return true if two arcsine distributions are not equal.
*/
template<typename _RealType>
inline bool
operator!=(const arcsine_distribution<_RealType>& __d1,
const arcsine_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A Hoyt continuous distribution for random numbers.
*
* The formula for the Hoyt probability density function is
* @f[
* p(x|q,\omega) = \frac{(1 + q^2)x}{q\omega}
* \exp\left(-\frac{(1 + q^2)^2 x^2}{4 q^2 \omega}\right)
* I_0\left(\frac{(1 - q^4) x^2}{4 q^2 \omega}\right)
* @f]
* where @f$I_0(z)@f$ is the modified Bessel function of the first kind
* of order 0 and @f$0 < q < 1@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$ \sqrt{\frac{2}{\pi}} \sqrt{\frac{\omega}{1 + q^2}}
* E(1 - q^2) @f$</td></tr>
* <tr><td>Variance</td><td>@f$ \omega \left(1 - \frac{2E^2(1 - q^2)}
* {\pi (1 + q^2)}\right) @f$</td></tr>
* <tr><td>Range</td><td>@f$[0, \infty)@f$</td></tr>
* </table>
* where @f$E(x)@f$ is the elliptic function of the second kind.
*/
template<typename _RealType = double>
class
hoyt_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef hoyt_distribution<result_type> distribution_type;
param_type(result_type __q = result_type(0.5L),
result_type __omega = result_type(1))
: _M_q(__q), _M_omega(__omega)
{
__glibcxx_assert(_M_q > result_type(0));
__glibcxx_assert(_M_q < result_type(1));
}
result_type
q() const
{ return _M_q; }
result_type
omega() const
{ return _M_omega; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_q == __p2._M_q && __p1._M_omega == __p2._M_omega; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_q;
result_type _M_omega;
};
/**
* @brief Constructors.
*/
explicit
hoyt_distribution(result_type __q = result_type(0.5L),
result_type __omega = result_type(1))
: _M_param(__q, __omega),
_M_ad(result_type(0.5L) * (result_type(1) + __q * __q),
result_type(0.5L) * (result_type(1) + __q * __q)
/ (__q * __q)),
_M_ed(result_type(1))
{ }
explicit
hoyt_distribution(const param_type& __p)
: _M_param(__p),
_M_ad(result_type(0.5L) * (result_type(1) + __p.q() * __p.q()),
result_type(0.5L) * (result_type(1) + __p.q() * __p.q())
/ (__p.q() * __p.q())),
_M_ed(result_type(1))
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{
_M_ad.reset();
_M_ed.reset();
}
/**
* @brief Return the parameters of the distribution.
*/
result_type
q() const
{ return _M_param.q(); }
result_type
omega() const
{ return _M_param.omega(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return result_type(0); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng);
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two Hoyt distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
friend bool
operator==(const hoyt_distribution& __d1,
const hoyt_distribution& __d2)
{ return (__d1._M_param == __d2._M_param
&& __d1._M_ad == __d2._M_ad
&& __d1._M_ed == __d2._M_ed); }
/**
* @brief Inserts a %hoyt_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %hoyt_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const hoyt_distribution<_RealType1>&);
/**
* @brief Extracts a %hoyt_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %hoyt_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
hoyt_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
__gnu_cxx::arcsine_distribution<result_type> _M_ad;
std::exponential_distribution<result_type> _M_ed;
};
/**
* @brief Return true if two Hoyt distributions are not equal.
*/
template<typename _RealType>
inline bool
operator!=(const hoyt_distribution<_RealType>& __d1,
const hoyt_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A triangular distribution for random numbers.
*
* The formula for the triangular probability density function is
* @f[
* / 0 for x < a
* p(x|a,b,c) = | \frac{2(x-a)}{(c-a)(b-a)} for a <= x <= b
* | \frac{2(c-x)}{(c-a)(c-b)} for b < x <= c
* \ 0 for c < x
* @f]
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$ \frac{a+b+c}{2} @f$</td></tr>
* <tr><td>Variance</td><td>@f$ \frac{a^2+b^2+c^2-ab-ac-bc}
* {18}@f$</td></tr>
* <tr><td>Range</td><td>@f$[a, c]@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class triangular_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
friend class triangular_distribution<_RealType>;
explicit
param_type(_RealType __a = _RealType(0),
_RealType __b = _RealType(0.5),
_RealType __c = _RealType(1))
: _M_a(__a), _M_b(__b), _M_c(__c)
{
__glibcxx_assert(_M_a <= _M_b);
__glibcxx_assert(_M_b <= _M_c);
__glibcxx_assert(_M_a < _M_c);
_M_r_ab = (_M_b - _M_a) / (_M_c - _M_a);
_M_f_ab_ac = (_M_b - _M_a) * (_M_c - _M_a);
_M_f_bc_ac = (_M_c - _M_b) * (_M_c - _M_a);
}
_RealType
a() const
{ return _M_a; }
_RealType
b() const
{ return _M_b; }
_RealType
c() const
{ return _M_c; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{
return (__p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b
&& __p1._M_c == __p2._M_c);
}
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
_RealType _M_a;
_RealType _M_b;
_RealType _M_c;
_RealType _M_r_ab;
_RealType _M_f_ab_ac;
_RealType _M_f_bc_ac;
};
/**
* @brief Constructs a triangle distribution with parameters
* @f$ a @f$, @f$ b @f$ and @f$ c @f$.
*/
explicit
triangular_distribution(result_type __a = result_type(0),
result_type __b = result_type(0.5),
result_type __c = result_type(1))
: _M_param(__a, __b, __c)
{ }
explicit
triangular_distribution(const param_type& __p)
: _M_param(__p)
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ }
/**
* @brief Returns the @f$ a @f$ of the distribution.
*/
result_type
a() const
{ return _M_param.a(); }
/**
* @brief Returns the @f$ b @f$ of the distribution.
*/
result_type
b() const
{ return _M_param.b(); }
/**
* @brief Returns the @f$ c @f$ of the distribution.
*/
result_type
c() const
{ return _M_param.c(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return _M_param._M_a; }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return _M_param._M_c; }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{
std::__detail::_Adaptor<_UniformRandomNumberGenerator, result_type>
__aurng(__urng);
result_type __rnd = __aurng();
if (__rnd <= __p._M_r_ab)
return __p.a() + std::sqrt(__rnd * __p._M_f_ab_ac);
else
return __p.c() - std::sqrt((result_type(1) - __rnd)
* __p._M_f_bc_ac);
}
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two triangle distributions have the same
* parameters and the sequences that would be generated
* are equal.
*/
friend bool
operator==(const triangular_distribution& __d1,
const triangular_distribution& __d2)
{ return __d1._M_param == __d2._M_param; }
/**
* @brief Inserts a %triangular_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %triangular_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::triangular_distribution<_RealType1>& __x);
/**
* @brief Extracts a %triangular_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %triangular_distribution random number generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::triangular_distribution<_RealType1>& __x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
};
/**
* @brief Return true if two triangle distributions are different.
*/
template<typename _RealType>
inline bool
operator!=(const __gnu_cxx::triangular_distribution<_RealType>& __d1,
const __gnu_cxx::triangular_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A von Mises distribution for random numbers.
*
* The formula for the von Mises probability density function is
* @f[
* p(x|\mu,\kappa) = \frac{e^{\kappa \cos(x-\mu)}}
* {2\pi I_0(\kappa)}
* @f]
*
* The generating functions use the method according to:
*
* D. J. Best and N. I. Fisher, 1979. "Efficient Simulation of the
* von Mises Distribution", Journal of the Royal Statistical Society.
* Series C (Applied Statistics), Vol. 28, No. 2, pp. 152-157.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$ \mu @f$</td></tr>
* <tr><td>Variance</td><td>@f$ 1-I_1(\kappa)/I_0(\kappa) @f$</td></tr>
* <tr><td>Range</td><td>@f$[-\pi, \pi]@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class von_mises_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
friend class von_mises_distribution<_RealType>;
explicit
param_type(_RealType __mu = _RealType(0),
_RealType __kappa = _RealType(1))
: _M_mu(__mu), _M_kappa(__kappa)
{
const _RealType __pi = __gnu_cxx::__math_constants<_RealType>::__pi;
__glibcxx_assert(_M_mu >= -__pi && _M_mu <= __pi);
__glibcxx_assert(_M_kappa >= _RealType(0));
auto __tau = std::sqrt(_RealType(4) * _M_kappa * _M_kappa
+ _RealType(1)) + _RealType(1);
auto __rho = ((__tau - std::sqrt(_RealType(2) * __tau))
/ (_RealType(2) * _M_kappa));
_M_r = (_RealType(1) + __rho * __rho) / (_RealType(2) * __rho);
}
_RealType
mu() const
{ return _M_mu; }
_RealType
kappa() const
{ return _M_kappa; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_mu == __p2._M_mu && __p1._M_kappa == __p2._M_kappa; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
_RealType _M_mu;
_RealType _M_kappa;
_RealType _M_r;
};
/**
* @brief Constructs a von Mises distribution with parameters
* @f$\mu@f$ and @f$\kappa@f$.
*/
explicit
von_mises_distribution(result_type __mu = result_type(0),
result_type __kappa = result_type(1))
: _M_param(__mu, __kappa)
{ }
explicit
von_mises_distribution(const param_type& __p)
: _M_param(__p)
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ }
/**
* @brief Returns the @f$ \mu @f$ of the distribution.
*/
result_type
mu() const
{ return _M_param.mu(); }
/**
* @brief Returns the @f$ \kappa @f$ of the distribution.
*/
result_type
kappa() const
{ return _M_param.kappa(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{
return -__gnu_cxx::__math_constants<result_type>::__pi;
}
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{
return __gnu_cxx::__math_constants<result_type>::__pi;
}
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, _M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two von Mises distributions have the same
* parameters and the sequences that would be generated
* are equal.
*/
friend bool
operator==(const von_mises_distribution& __d1,
const von_mises_distribution& __d2)
{ return __d1._M_param == __d2._M_param; }
/**
* @brief Inserts a %von_mises_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %von_mises_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::von_mises_distribution<_RealType1>& __x);
/**
* @brief Extracts a %von_mises_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %von_mises_distribution random number generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::von_mises_distribution<_RealType1>& __x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
};
/**
* @brief Return true if two von Mises distributions are different.
*/
template<typename _RealType>
inline bool
operator!=(const __gnu_cxx::von_mises_distribution<_RealType>& __d1,
const __gnu_cxx::von_mises_distribution<_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A discrete hypergeometric random number distribution.
*
* The hypergeometric distribution is a discrete probability distribution
* that describes the probability of @p k successes in @p n draws @a without
* replacement from a finite population of size @p N containing exactly @p K
* successes.
*
* The formula for the hypergeometric probability density function is
* @f[
* p(k|N,K,n) = \frac{\binom{K}{k} \binom{N-K}{n-k}}{\binom{N}{n}}
* @f]
* where @f$N@f$ is the total population of the distribution,
* @f$K@f$ is the total population of the distribution.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$ n\frac{K}{N} @f$</td></tr>
* <tr><td>Variance</td><td>@f$ n\frac{K}{N}\frac{N-K}{N}\frac{N-n}{N-1}
* @f$</td></tr>
* <tr><td>Range</td><td>@f$[max(0, n+K-N), min(K, n)]@f$</td></tr>
* </table>
*/
template<typename _UIntType = unsigned int>
class hypergeometric_distribution
{
static_assert(std::is_unsigned<_UIntType>::value, "template argument "
"substituting _UIntType not an unsigned integral type");
public:
/** The type of the range of the distribution. */
typedef _UIntType result_type;
/** Parameter type. */
struct param_type
{
typedef hypergeometric_distribution<_UIntType> distribution_type;
friend class hypergeometric_distribution<_UIntType>;
explicit
param_type(result_type __N = 10, result_type __K = 5,
result_type __n = 1)
: _M_N{__N}, _M_K{__K}, _M_n{__n}
{
__glibcxx_assert(_M_N >= _M_K);
__glibcxx_assert(_M_N >= _M_n);
}
result_type
total_size() const
{ return _M_N; }
result_type
successful_size() const
{ return _M_K; }
result_type
unsuccessful_size() const
{ return _M_N - _M_K; }
result_type
total_draws() const
{ return _M_n; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return (__p1._M_N == __p2._M_N)
&& (__p1._M_K == __p2._M_K)
&& (__p1._M_n == __p2._M_n); }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
result_type _M_N;
result_type _M_K;
result_type _M_n;
};
// constructors and member function
explicit
hypergeometric_distribution(result_type __N = 10, result_type __K = 5,
result_type __n = 1)
: _M_param{__N, __K, __n}
{ }
explicit
hypergeometric_distribution(const param_type& __p)
: _M_param{__p}
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ }
/**
* @brief Returns the distribution parameter @p N,
* the total number of items.
*/
result_type
total_size() const
{ return this->_M_param.total_size(); }
/**
* @brief Returns the distribution parameter @p K,
* the total number of successful items.
*/
result_type
successful_size() const
{ return this->_M_param.successful_size(); }
/**
* @brief Returns the total number of unsuccessful items @f$ N - K @f$.
*/
result_type
unsuccessful_size() const
{ return this->_M_param.unsuccessful_size(); }
/**
* @brief Returns the distribution parameter @p n,
* the total number of draws.
*/
result_type
total_draws() const
{ return this->_M_param.total_draws(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return this->_M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ this->_M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{
using _IntType = typename std::make_signed<result_type>::type;
return static_cast<result_type>(std::max(static_cast<_IntType>(0),
static_cast<_IntType>(this->total_draws()
- this->unsuccessful_size())));
}
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::min(this->successful_size(), this->total_draws()); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, this->_M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, this->_M_param); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two hypergeometric distributions have the same
* parameters and the sequences that would be generated
* are equal.
*/
friend bool
operator==(const hypergeometric_distribution& __d1,
const hypergeometric_distribution& __d2)
{ return __d1._M_param == __d2._M_param; }
/**
* @brief Inserts a %hypergeometric_distribution random number
* distribution @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %hypergeometric_distribution random number
* distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _UIntType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::hypergeometric_distribution<_UIntType1>&
__x);
/**
* @brief Extracts a %hypergeometric_distribution random number
* distribution @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %hypergeometric_distribution random number generator
* distribution.
*
* @returns The input stream with @p __x extracted or in an error
* state.
*/
template<typename _UIntType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::hypergeometric_distribution<_UIntType1>& __x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
};
/**
* @brief Return true if two hypergeometric distributions are different.
*/
template<typename _UIntType>
inline bool
operator!=(const __gnu_cxx::hypergeometric_distribution<_UIntType>& __d1,
const __gnu_cxx::hypergeometric_distribution<_UIntType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A logistic continuous distribution for random numbers.
*
* The formula for the logistic probability density function is
* @f[
* p(x|\a,\b) = \frac{e^{(x - a)/b}}{b[1 + e^{(x - a)/b}]^2}
* @f]
* where @f$b > 0@f$.
*
* The formula for the logistic probability function is
* @f[
* cdf(x|\a,\b) = \frac{e^{(x - a)/b}}{1 + e^{(x - a)/b}}
* @f]
* where @f$b > 0@f$.
*
* <table border=1 cellpadding=10 cellspacing=0>
* <caption align=top>Distribution Statistics</caption>
* <tr><td>Mean</td><td>@f$a@f$</td></tr>
* <tr><td>Variance</td><td>@f$b^2\pi^2/3@f$</td></tr>
* <tr><td>Range</td><td>@f$[0, \infty)@f$</td></tr>
* </table>
*/
template<typename _RealType = double>
class
logistic_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
public:
/** The type of the range of the distribution. */
typedef _RealType result_type;
/** Parameter type. */
struct param_type
{
typedef logistic_distribution<result_type> distribution_type;
param_type(result_type __a = result_type(0),
result_type __b = result_type(1))
: _M_a(__a), _M_b(__b)
{
__glibcxx_assert(_M_b > result_type(0));
}
result_type
a() const
{ return _M_a; }
result_type
b() const
{ return _M_b; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
void _M_initialize();
result_type _M_a;
result_type _M_b;
};
/**
* @brief Constructors.
*/
explicit
logistic_distribution(result_type __a = result_type(0),
result_type __b = result_type(1))
: _M_param(__a, __b)
{ }
explicit
logistic_distribution(const param_type& __p)
: _M_param(__p)
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ }
/**
* @brief Return the parameters of the distribution.
*/
result_type
a() const
{ return _M_param.a(); }
result_type
b() const
{ return _M_param.b(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
*/
result_type
min() const
{ return -std::numeric_limits<result_type>::max(); }
/**
* @brief Returns the least upper bound value of the distribution.
*/
result_type
max() const
{ return std::numeric_limits<result_type>::max(); }
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, this->_M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator&,
const param_type&);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, this->param()); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two logistic distributions have
* the same parameters and the sequences that would
* be generated are equal.
*/
template<typename _RealType1>
friend bool
operator==(const logistic_distribution<_RealType1>& __d1,
const logistic_distribution<_RealType1>& __d2)
{ return __d1.param() == __d2.param(); }
/**
* @brief Inserts a %logistic_distribution random number distribution
* @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %logistic_distribution random number distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>&,
const logistic_distribution<_RealType1>&);
/**
* @brief Extracts a %logistic_distribution random number distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %logistic_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<typename _RealType1, typename _CharT, typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>&,
logistic_distribution<_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
};
/**
* @brief Return true if two logistic distributions are not equal.
*/
template<typename _RealType1>
inline bool
operator!=(const logistic_distribution<_RealType1>& __d1,
const logistic_distribution<_RealType1>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A distribution for random coordinates on a unit sphere.
*
* The method used in the generation function is attributed by Donald Knuth
* to G. W. Brown, Modern Mathematics for the Engineer (1956).
*/
template<std::size_t _Dimen, typename _RealType = double>
class uniform_on_sphere_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
static_assert(_Dimen != 0, "dimension is zero");
public:
/** The type of the range of the distribution. */
typedef std::array<_RealType, _Dimen> result_type;
/** Parameter type. */
struct param_type
{
explicit
param_type()
{ }
friend bool
operator==(const param_type&, const param_type&)
{ return true; }
friend bool
operator!=(const param_type&, const param_type&)
{ return false; }
};
/**
* @brief Constructs a uniform on sphere distribution.
*/
explicit
uniform_on_sphere_distribution()
: _M_param(), _M_nd()
{ }
explicit
uniform_on_sphere_distribution(const param_type& __p)
: _M_param(__p), _M_nd()
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ _M_nd.reset(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
* This function makes no sense for this distribution.
*/
result_type
min() const
{
result_type __res;
__res.fill(0);
return __res;
}
/**
* @brief Returns the least upper bound value of the distribution.
* This function makes no sense for this distribution.
*/
result_type
max() const
{
result_type __res;
__res.fill(0);
return __res;
}
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, this->param()); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two uniform on sphere distributions have
* the same parameters and the sequences that would be
* generated are equal.
*/
friend bool
operator==(const uniform_on_sphere_distribution& __d1,
const uniform_on_sphere_distribution& __d2)
{ return __d1._M_nd == __d2._M_nd; }
/**
* @brief Inserts a %uniform_on_sphere_distribution random number
* distribution @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %uniform_on_sphere_distribution random number
* distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<size_t _Dimen1, typename _RealType1, typename _CharT,
typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::uniform_on_sphere_distribution<_Dimen1,
_RealType1>&
__x);
/**
* @brief Extracts a %uniform_on_sphere_distribution random number
* distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %uniform_on_sphere_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<std::size_t _Dimen1, typename _RealType1, typename _CharT,
typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::uniform_on_sphere_distribution<_Dimen1,
_RealType1>& __x);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
std::normal_distribution<_RealType> _M_nd;
};
/**
* @brief Return true if two uniform on sphere distributions are different.
*/
template<std::size_t _Dimen, typename _RealType>
inline bool
operator!=(const __gnu_cxx::uniform_on_sphere_distribution<_Dimen,
_RealType>& __d1,
const __gnu_cxx::uniform_on_sphere_distribution<_Dimen,
_RealType>& __d2)
{ return !(__d1 == __d2); }
/**
* @brief A distribution for random coordinates inside a unit sphere.
*/
template<std::size_t _Dimen, typename _RealType = double>
class uniform_inside_sphere_distribution
{
static_assert(std::is_floating_point<_RealType>::value,
"template argument not a floating point type");
static_assert(_Dimen != 0, "dimension is zero");
public:
/** The type of the range of the distribution. */
using result_type = std::array<_RealType, _Dimen>;
/** Parameter type. */
struct param_type
{
using distribution_type
= uniform_inside_sphere_distribution<_Dimen, _RealType>;
friend class uniform_inside_sphere_distribution<_Dimen, _RealType>;
explicit
param_type(_RealType __radius = _RealType(1))
: _M_radius(__radius)
{
__glibcxx_assert(_M_radius > _RealType(0));
}
_RealType
radius() const
{ return _M_radius; }
friend bool
operator==(const param_type& __p1, const param_type& __p2)
{ return __p1._M_radius == __p2._M_radius; }
friend bool
operator!=(const param_type& __p1, const param_type& __p2)
{ return !(__p1 == __p2); }
private:
_RealType _M_radius;
};
/**
* @brief Constructors.
*/
explicit
uniform_inside_sphere_distribution(_RealType __radius = _RealType(1))
: _M_param(__radius), _M_uosd()
{ }
explicit
uniform_inside_sphere_distribution(const param_type& __p)
: _M_param(__p), _M_uosd()
{ }
/**
* @brief Resets the distribution state.
*/
void
reset()
{ _M_uosd.reset(); }
/**
* @brief Returns the @f$radius@f$ of the distribution.
*/
_RealType
radius() const
{ return _M_param.radius(); }
/**
* @brief Returns the parameter set of the distribution.
*/
param_type
param() const
{ return _M_param; }
/**
* @brief Sets the parameter set of the distribution.
* @param __param The new parameter set of the distribution.
*/
void
param(const param_type& __param)
{ _M_param = __param; }
/**
* @brief Returns the greatest lower bound value of the distribution.
* This function makes no sense for this distribution.
*/
result_type
min() const
{
result_type __res;
__res.fill(0);
return __res;
}
/**
* @brief Returns the least upper bound value of the distribution.
* This function makes no sense for this distribution.
*/
result_type
max() const
{
result_type __res;
__res.fill(0);
return __res;
}
/**
* @brief Generating functions.
*/
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng)
{ return this->operator()(__urng, _M_param); }
template<typename _UniformRandomNumberGenerator>
result_type
operator()(_UniformRandomNumberGenerator& __urng,
const param_type& __p);
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng)
{ this->__generate(__f, __t, __urng, this->param()); }
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
template<typename _UniformRandomNumberGenerator>
void
__generate(result_type* __f, result_type* __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p)
{ this->__generate_impl(__f, __t, __urng, __p); }
/**
* @brief Return true if two uniform on sphere distributions have
* the same parameters and the sequences that would be
* generated are equal.
*/
friend bool
operator==(const uniform_inside_sphere_distribution& __d1,
const uniform_inside_sphere_distribution& __d2)
{ return __d1._M_param == __d2._M_param && __d1._M_uosd == __d2._M_uosd; }
/**
* @brief Inserts a %uniform_inside_sphere_distribution random number
* distribution @p __x into the output stream @p __os.
*
* @param __os An output stream.
* @param __x A %uniform_inside_sphere_distribution random number
* distribution.
*
* @returns The output stream with the state of @p __x inserted or in
* an error state.
*/
template<size_t _Dimen1, typename _RealType1, typename _CharT,
typename _Traits>
friend std::basic_ostream<_CharT, _Traits>&
operator<<(std::basic_ostream<_CharT, _Traits>& __os,
const __gnu_cxx::uniform_inside_sphere_distribution<_Dimen1,
_RealType1>&
);
/**
* @brief Extracts a %uniform_inside_sphere_distribution random number
* distribution
* @p __x from the input stream @p __is.
*
* @param __is An input stream.
* @param __x A %uniform_inside_sphere_distribution random number
* generator engine.
*
* @returns The input stream with @p __x extracted or in an error state.
*/
template<std::size_t _Dimen1, typename _RealType1, typename _CharT,
typename _Traits>
friend std::basic_istream<_CharT, _Traits>&
operator>>(std::basic_istream<_CharT, _Traits>& __is,
__gnu_cxx::uniform_inside_sphere_distribution<_Dimen1,
_RealType1>&);
private:
template<typename _ForwardIterator,
typename _UniformRandomNumberGenerator>
void
__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
_UniformRandomNumberGenerator& __urng,
const param_type& __p);
param_type _M_param;
uniform_on_sphere_distribution<_Dimen, _RealType> _M_uosd;
};
/**
* @brief Return true if two uniform on sphere distributions are different.
*/
template<std::size_t _Dimen, typename _RealType>
inline bool
operator!=(const __gnu_cxx::uniform_inside_sphere_distribution<_Dimen,
_RealType>& __d1,
const __gnu_cxx::uniform_inside_sphere_distribution<_Dimen,
_RealType>& __d2)
{ return !(__d1 == __d2); }
_GLIBCXX_END_NAMESPACE_VERSION
} // namespace __gnu_cxx
#include "ext/opt_random.h"
#include "random.tcc"
#endif // _GLIBCXX_USE_C99_STDINT_TR1 && UINT32_C
#endif // C++11
#endif // _EXT_RANDOM
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