random.h source code [include/c++/8/bits/random.h]

1	// random number generation -- C++ --
2
3	// Copyright (C) 2009-2018 Free Software Foundation, Inc.
4	//
5	// This file is part of the GNU ISO C++ Library. This library is free
6	// software; you can redistribute it and/or modify it under the
7	// terms of the GNU General Public License as published by the
8	// Free Software Foundation; either version 3, or (at your option)
9	// any later version.
10
11	// This library is distributed in the hope that it will be useful,
12	// but WITHOUT ANY WARRANTY; without even the implied warranty of
13	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	// GNU General Public License for more details.
15
16	// Under Section 7 of GPL version 3, you are granted additional
17	// permissions described in the GCC Runtime Library Exception, version
18	// 3.1, as published by the Free Software Foundation.
19
20	// You should have received a copy of the GNU General Public License and
21	// a copy of the GCC Runtime Library Exception along with this program;
22	// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
23	// <http://www.gnu.org/licenses/>.
24
25	/**
26	* @file bits/random.h
27	* This is an internal header file, included by other library headers.
28	* Do not attempt to use it directly. @headername{random}
29	*/
30
31	#ifndef _RANDOM_H
32	#define _RANDOM_H 1
33
34	#include <vector>
35	#include <bits/uniform_int_dist.h>
36
37	namespace std _GLIBCXX_VISIBILITY(default)
38	{
39	_GLIBCXX_BEGIN_NAMESPACE_VERSION
40
41	// [26.4] Random number generation
42
43	/**
44	* @defgroup random Random Number Generation
45	* @ingroup numerics
46	*
47	* A facility for generating random numbers on selected distributions.
48	* @{
49	*/
50
51	/**
52	* @brief A function template for converting the output of a (integral)
53	* uniform random number generator to a floatng point result in the range
54	* [0-1).
55	*/
56	template<typename _RealType, size_t __bits,
57	typename _UniformRandomNumberGenerator>
58	_RealType
59	generate_canonical(_UniformRandomNumberGenerator& __g);
60
61	/*
62	* Implementation-space details.
63	*/
64	namespace __detail
65	{
66	template<typename _UIntType, size_t __w,
67	bool = __w < static_cast<size_t>
68	(std::numeric_limits<_UIntType>::digits)>
69	struct _Shift
70	{ static const _UIntType __value = `0`; };
71
72	template<typename _UIntType, size_t __w>
73	struct _Shift<_UIntType, __w, true>
74	{ static const _UIntType __value = _UIntType(`1`) << __w; };
75
76	template<int __s,
77	int __which = ((__s <= __CHAR_BIT__ * sizeof (int))
78	+ (__s <= __CHAR_BIT__ * sizeof (long))
79	+ (__s <= __CHAR_BIT__ * sizeof (long long))
80	/ assume long long no bigger than __int128 /
81	+ (__s <= `128`))>
82	struct _Select_uint_least_t
83	{
84	static_assert(__which < `0`, / needs to be dependent /
85	"sorry, would be too much trouble for a slow result");
86	};
87
88	template<int __s>
89	struct _Select_uint_least_t<__s, `4`>
90	{ typedef unsigned int type; };
91
92	template<int __s>
93	struct _Select_uint_least_t<__s, `3`>
94	{ typedef unsigned long type; };
95
96	template<int __s>
97	struct _Select_uint_least_t<__s, `2`>
98	{ typedef unsigned long long type; };
99
100	#ifdef _GLIBCXX_USE_INT128
101	template<int __s>
102	struct _Select_uint_least_t<__s, `1`>
103	{ typedef unsigned __int128 type; };
104	#endif
105
106	// Assume a != 0, a < m, c < m, x < m.
107	template<typename _Tp, _Tp __m, _Tp __a, _Tp __c,
108	bool __big_enough = (!(__m & (__m - `1`))
109	\|\| (_Tp(-`1`) - __c) / __a >= __m - `1`),
110	bool __schrage_ok = __m % __a < __m / __a>
111	struct _Mod
112	{
113	typedef typename _Select_uint_least_t<std::__lg(__a)
114	+ std::__lg(__m) + `2`>::type _Tp2;
115	static _Tp
116	__calc(_Tp __x)
117	{ return static_cast<_Tp>((_Tp2(__a) * __x + __c) % __m); }
118	};
119
120	// Schrage.
121	template<typename _Tp, _Tp __m, _Tp __a, _Tp __c>
122	struct _Mod<_Tp, __m, __a, __c, false, true>
123	{
124	static _Tp
125	__calc(_Tp __x);
126	};
127
128	// Special cases:
129	// - for m == 2^n or m == 0, unsigned integer overflow is safe.
130	// - a (m - 1) + c fits in _Tp, there is no overflow.*
131	template<typename _Tp, _Tp __m, _Tp __a, _Tp __c, bool __s>
132	struct _Mod<_Tp, __m, __a, __c, true, __s>
133	{
134	static _Tp
135	__calc(_Tp __x)
136	{
137	_Tp __res = __a * __x + __c;
138	if (__m)
139	__res %= __m;
140	return __res;
141	}
142	};
143
144	template<typename _Tp, _Tp __m, _Tp __a = `1`, _Tp __c = `0`>
145	inline _Tp
146	__mod(_Tp __x)
147	{ return _Mod<_Tp, __m, __a, __c>::__calc(__x); }
148
149	/*
150	* An adaptor class for converting the output of any Generator into
151	* the input for a specific Distribution.
152	*/
153	template<typename _Engine, typename _DInputType>
154	struct _Adaptor
155	{
156	static_assert(std::is_floating_point<_DInputType>::value,
157	"template argument must be a floating point type");
158
159	public:
160	_Adaptor(_Engine& __g)
161	: _M_g(__g) { }
162
163	_DInputType
164	min() const
165	{ return _DInputType(`0`); }
166
167	_DInputType
168	max() const
169	{ return _DInputType(`1`); }
170
171	/*
172	* Converts a value generated by the adapted random number generator
173	* into a value in the input domain for the dependent random number
174	* distribution.
175	*/
176	_DInputType
177	operator()()
178	{
179	return std::generate_canonical<_DInputType,
180	std::numeric_limits<_DInputType>::digits,
181	_Engine>(_M_g);
182	}
183
184	private:
185	_Engine& _M_g;
186	};
187
188	} // namespace __detail
189
190	/**
191	* @addtogroup random_generators Random Number Generators
192	* @ingroup random
193	*
194	* These classes define objects which provide random or pseudorandom
195	* numbers, either from a discrete or a continuous interval. The
196	* random number generator supplied as a part of this library are
197	* all uniform random number generators which provide a sequence of
198	* random number uniformly distributed over their range.
199	*
200	* A number generator is a function object with an operator() that
201	* takes zero arguments and returns a number.
202	*
203	* A compliant random number generator must satisfy the following
204	* requirements. <table border=1 cellpadding=10 cellspacing=0>
205	* <caption align=top>Random Number Generator Requirements</caption>
206	* <tr><td>To be documented.</td></tr> </table>
207	*
208	* @{
209	*/
210
211	/**
212	* @brief A model of a linear congruential random number generator.
213	*
214	* A random number generator that produces pseudorandom numbers via
215	* linear function:
216	* @f[
217	* x_{i+1}\leftarrow(ax_{i} + c) \bmod m
218	* @f]
219	*
220	* The template parameter @p _UIntType must be an unsigned integral type
221	* large enough to store values up to (__m-1). If the template parameter
222	* @p __m is 0, the modulus @p __m used is
223	* std::numeric_limits<_UIntType>::max() plus 1. Otherwise, the template
224	* parameters @p __a and @p __c must be less than @p __m.
225	*
226	* The size of the state is @f$1@f$.
227	*/
228	template<typename _UIntType, _UIntType __a, _UIntType __c, _UIntType __m>
229	class linear_congruential_engine
230	{
231	static_assert(std::is_unsigned<_UIntType>::value,
232	"result_type must be an unsigned integral type");
233	static_assert(__m == `0u` \|\| (__a < __m && __c < __m),
234	"template argument substituting __m out of bounds");
235
236	public:
237	/* The type of the generated random value. /
238	typedef _UIntType result_type;
239
240	/* The multiplier. /
241	static constexpr result_type multiplier = __a;
242	/* An increment. /
243	static constexpr result_type increment = __c;
244	/* The modulus. /
245	static constexpr result_type modulus = __m;
246	static constexpr result_type default_seed = `1u`;
247
248	/**
249	* @brief Constructs a %linear_congruential_engine random number
250	* generator engine with seed @p __s. The default seed value
251	* is 1.
252	*
253	* @param __s The initial seed value.
254	*/
255	explicit
256	linear_congruential_engine(result_type __s = default_seed)
257	{ seed(__s); }
258
259	/**
260	* @brief Constructs a %linear_congruential_engine random number
261	* generator engine seeded from the seed sequence @p __q.
262	*
263	* @param __q the seed sequence.
264	*/
265	template<typename _Sseq, typename = typename
266	std::enable_if<!std::is_same<_Sseq, linear_congruential_engine>::value>
267	::type>
268	explicit
269	linear_congruential_engine(_Sseq& __q)
270	{ seed(__q); }
271
272	/**
273	* @brief Reseeds the %linear_congruential_engine random number generator
274	* engine sequence to the seed @p __s.
275	*
276	* @param __s The new seed.
277	*/
278	void
279	seed(result_type __s = default_seed);
280
281	/**
282	* @brief Reseeds the %linear_congruential_engine random number generator
283	* engine
284	* sequence using values from the seed sequence @p __q.
285	*
286	* @param __q the seed sequence.
287	*/
288	template<typename _Sseq>
289	typename std::enable_if<std::is_class<_Sseq>::value>::type
290	seed(_Sseq& __q);
291
292	/**
293	* @brief Gets the smallest possible value in the output range.
294	*
295	* The minimum depends on the @p __c parameter: if it is zero, the
296	* minimum generated must be > 0, otherwise 0 is allowed.
297	*/
298	static constexpr result_type
299	min()
300	{ return __c == `0u` ? `1u` : `0u`; }
301
302	/**
303	* @brief Gets the largest possible value in the output range.
304	*/
305	static constexpr result_type
306	max()
307	{ return __m - `1u`; }
308
309	/**
310	* @brief Discard a sequence of random numbers.
311	*/
312	void
313	discard(unsigned long long __z)
314	{
315	for (; __z != `0ULL`; --__z)
316	(*this)();
317	}
318
319	/**
320	* @brief Gets the next random number in the sequence.
321	*/
322	result_type
323	operator()()
324	{
325	_M_x = __detail::__mod<_UIntType, __m, __a, __c>(_M_x);
326	return _M_x;
327	}
328
329	/**
330	* @brief Compares two linear congruential random number generator
331	* objects of the same type for equality.
332	*
333	* @param __lhs A linear congruential random number generator object.
334	* @param __rhs Another linear congruential random number generator
335	* object.
336	*
337	* @returns true if the infinite sequences of generated values
338	* would be equal, false otherwise.
339	*/
340	friend bool
341	operator==(const linear_congruential_engine& __lhs,
342	const linear_congruential_engine& __rhs)
343	{ return __lhs._M_x == __rhs._M_x; }
344
345	/**
346	* @brief Writes the textual representation of the state x(i) of x to
347	* @p __os.
348	*
349	* @param __os The output stream.
350	* @param __lcr A % linear_congruential_engine random number generator.
351	* @returns __os.
352	*/
353	template<typename _UIntType1, _UIntType1 __a1, _UIntType1 __c1,
354	_UIntType1 __m1, typename _CharT, typename _Traits>
355	friend std::basic_ostream<_CharT, _Traits>&
356	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
357	const std::linear_congruential_engine<_UIntType1,
358	__a1, __c1, __m1>& __lcr);
359
360	/**
361	* @brief Sets the state of the engine by reading its textual
362	* representation from @p __is.
363	*
364	* The textual representation must have been previously written using
365	* an output stream whose imbued locale and whose type's template
366	* specialization arguments _CharT and _Traits were the same as those
367	* of @p __is.
368	*
369	* @param __is The input stream.
370	* @param __lcr A % linear_congruential_engine random number generator.
371	* @returns __is.
372	*/
373	template<typename _UIntType1, _UIntType1 __a1, _UIntType1 __c1,
374	_UIntType1 __m1, typename _CharT, typename _Traits>
375	friend std::basic_istream<_CharT, _Traits>&
376	operator>>(std::basic_istream<_CharT, _Traits>& __is,
377	std::linear_congruential_engine<_UIntType1, __a1,
378	__c1, __m1>& __lcr);
379
380	private:
381	_UIntType _M_x;
382	};
383
384	/**
385	* @brief Compares two linear congruential random number generator
386	* objects of the same type for inequality.
387	*
388	* @param __lhs A linear congruential random number generator object.
389	* @param __rhs Another linear congruential random number generator
390	* object.
391	*
392	* @returns true if the infinite sequences of generated values
393	* would be different, false otherwise.
394	*/
395	template<typename _UIntType, _UIntType __a, _UIntType __c, _UIntType __m>
396	inline bool
397	operator!=(const std::linear_congruential_engine<_UIntType, __a,
398	__c, __m>& __lhs,
399	const std::linear_congruential_engine<_UIntType, __a,
400	__c, __m>& __rhs)
401	{ return !(__lhs == __rhs); }
402
403
404	/**
405	* A generalized feedback shift register discrete random number generator.
406	*
407	* This algorithm avoids multiplication and division and is designed to be
408	* friendly to a pipelined architecture. If the parameters are chosen
409	* correctly, this generator will produce numbers with a very long period and
410	* fairly good apparent entropy, although still not cryptographically strong.
411	*
412	* The best way to use this generator is with the predefined mt19937 class.
413	*
414	* This algorithm was originally invented by Makoto Matsumoto and
415	* Takuji Nishimura.
416	*
417	* @tparam __w Word size, the number of bits in each element of
418	* the state vector.
419	* @tparam __n The degree of recursion.
420	* @tparam __m The period parameter.
421	* @tparam __r The separation point bit index.
422	* @tparam __a The last row of the twist matrix.
423	* @tparam __u The first right-shift tempering matrix parameter.
424	* @tparam __d The first right-shift tempering matrix mask.
425	* @tparam __s The first left-shift tempering matrix parameter.
426	* @tparam __b The first left-shift tempering matrix mask.
427	* @tparam __t The second left-shift tempering matrix parameter.
428	* @tparam __c The second left-shift tempering matrix mask.
429	* @tparam __l The second right-shift tempering matrix parameter.
430	* @tparam __f Initialization multiplier.
431	*/
432	template<typename _UIntType, size_t __w,
433	size_t __n, size_t __m, size_t __r,
434	_UIntType __a, size_t __u, _UIntType __d, size_t __s,
435	_UIntType __b, size_t __t,
436	_UIntType __c, size_t __l, _UIntType __f>
437	class mersenne_twister_engine
438	{
439	static_assert(std::is_unsigned<_UIntType>::value,
440	"result_type must be an unsigned integral type");
441	static_assert(`1u` <= __m && __m <= __n,
442	"template argument substituting __m out of bounds");
443	static_assert(__r <= __w, "template argument substituting "
444	"__r out of bound");
445	static_assert(__u <= __w, "template argument substituting "
446	"__u out of bound");
447	static_assert(__s <= __w, "template argument substituting "
448	"__s out of bound");
449	static_assert(__t <= __w, "template argument substituting "
450	"__t out of bound");
451	static_assert(__l <= __w, "template argument substituting "
452	"__l out of bound");
453	static_assert(__w <= std::numeric_limits<_UIntType>::digits,
454	"template argument substituting __w out of bound");
455	static_assert(__a <= (__detail::_Shift<_UIntType, __w>::__value - `1`),
456	"template argument substituting __a out of bound");
457	static_assert(__b <= (__detail::_Shift<_UIntType, __w>::__value - `1`),
458	"template argument substituting __b out of bound");
459	static_assert(__c <= (__detail::_Shift<_UIntType, __w>::__value - `1`),
460	"template argument substituting __c out of bound");
461	static_assert(__d <= (__detail::_Shift<_UIntType, __w>::__value - `1`),
462	"template argument substituting __d out of bound");
463	static_assert(__f <= (__detail::_Shift<_UIntType, __w>::__value - `1`),
464	"template argument substituting __f out of bound");
465
466	public:
467	/* The type of the generated random value. /
468	typedef _UIntType result_type;
469
470	// parameter values
471	static constexpr size_t word_size = __w;
472	static constexpr size_t state_size = __n;
473	static constexpr size_t shift_size = __m;
474	static constexpr size_t mask_bits = __r;
475	static constexpr result_type xor_mask = __a;
476	static constexpr size_t tempering_u = __u;
477	static constexpr result_type tempering_d = __d;
478	static constexpr size_t tempering_s = __s;
479	static constexpr result_type tempering_b = __b;
480	static constexpr size_t tempering_t = __t;
481	static constexpr result_type tempering_c = __c;
482	static constexpr size_t tempering_l = __l;
483	static constexpr result_type initialization_multiplier = __f;
484	static constexpr result_type default_seed = `5489u`;
485
486	// constructors and member function
487	explicit
488	mersenne_twister_engine(result_type __sd = default_seed)
489	{ seed(__sd); }
490
491	/**
492	* @brief Constructs a %mersenne_twister_engine random number generator
493	* engine seeded from the seed sequence @p __q.
494	*
495	* @param __q the seed sequence.
496	*/
497	template<typename _Sseq, typename = typename
498	std::enable_if<!std::is_same<_Sseq, mersenne_twister_engine>::value>
499	::type>
500	explicit
501	mersenne_twister_engine(_Sseq& __q)
502	{ seed(__q); }
503
504	void
505	seed(result_type __sd = default_seed);
506
507	template<typename _Sseq>
508	typename std::enable_if<std::is_class<_Sseq>::value>::type
509	seed(_Sseq& __q);
510
511	/**
512	* @brief Gets the smallest possible value in the output range.
513	*/
514	static constexpr result_type
515	min()
516	{ return `0`; }
517
518	/**
519	* @brief Gets the largest possible value in the output range.
520	*/
521	static constexpr result_type
522	max()
523	{ return __detail::_Shift<_UIntType, __w>::__value - `1`; }
524
525	/**
526	* @brief Discard a sequence of random numbers.
527	*/
528	void
529	discard(unsigned long long __z);
530
531	result_type
532	operator()();
533
534	/**
535	* @brief Compares two % mersenne_twister_engine random number generator
536	* objects of the same type for equality.
537	*
538	* @param __lhs A % mersenne_twister_engine random number generator
539	* object.
540	* @param __rhs Another % mersenne_twister_engine random number
541	* generator object.
542	*
543	* @returns true if the infinite sequences of generated values
544	* would be equal, false otherwise.
545	*/
546	friend bool
547	operator==(const mersenne_twister_engine& __lhs,
548	const mersenne_twister_engine& __rhs)
549	{ return (std::equal(__lhs._M_x, __lhs._M_x + state_size, __rhs._M_x)
550	&& __lhs._M_p == __rhs._M_p); }
551
552	/**
553	* @brief Inserts the current state of a % mersenne_twister_engine
554	* random number generator engine @p __x into the output stream
555	* @p __os.
556	*
557	* @param __os An output stream.
558	* @param __x A % mersenne_twister_engine random number generator
559	* engine.
560	*
561	* @returns The output stream with the state of @p __x inserted or in
562	* an error state.
563	*/
564	template<typename _UIntType1,
565	size_t __w1, size_t __n1,
566	size_t __m1, size_t __r1,
567	_UIntType1 __a1, size_t __u1,
568	_UIntType1 __d1, size_t __s1,
569	_UIntType1 __b1, size_t __t1,
570	_UIntType1 __c1, size_t __l1, _UIntType1 __f1,
571	typename _CharT, typename _Traits>
572	friend std::basic_ostream<_CharT, _Traits>&
573	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
574	const std::mersenne_twister_engine<_UIntType1, __w1, __n1,
575	__m1, __r1, __a1, __u1, __d1, __s1, __b1, __t1, __c1,
576	__l1, __f1>& __x);
577
578	/**
579	* @brief Extracts the current state of a % mersenne_twister_engine
580	* random number generator engine @p __x from the input stream
581	* @p __is.
582	*
583	* @param __is An input stream.
584	* @param __x A % mersenne_twister_engine random number generator
585	* engine.
586	*
587	* @returns The input stream with the state of @p __x extracted or in
588	* an error state.
589	*/
590	template<typename _UIntType1,
591	size_t __w1, size_t __n1,
592	size_t __m1, size_t __r1,
593	_UIntType1 __a1, size_t __u1,
594	_UIntType1 __d1, size_t __s1,
595	_UIntType1 __b1, size_t __t1,
596	_UIntType1 __c1, size_t __l1, _UIntType1 __f1,
597	typename _CharT, typename _Traits>
598	friend std::basic_istream<_CharT, _Traits>&
599	operator>>(std::basic_istream<_CharT, _Traits>& __is,
600	std::mersenne_twister_engine<_UIntType1, __w1, __n1, __m1,
601	__r1, __a1, __u1, __d1, __s1, __b1, __t1, __c1,
602	__l1, __f1>& __x);
603
604	private:
605	void _M_gen_rand();
606
607	_UIntType _M_x[state_size];
608	size_t _M_p;
609	};
610
611	/**
612	* @brief Compares two % mersenne_twister_engine random number generator
613	* objects of the same type for inequality.
614	*
615	* @param __lhs A % mersenne_twister_engine random number generator
616	* object.
617	* @param __rhs Another % mersenne_twister_engine random number
618	* generator object.
619	*
620	* @returns true if the infinite sequences of generated values
621	* would be different, false otherwise.
622	*/
623	template<typename _UIntType, size_t __w,
624	size_t __n, size_t __m, size_t __r,
625	_UIntType __a, size_t __u, _UIntType __d, size_t __s,
626	_UIntType __b, size_t __t,
627	_UIntType __c, size_t __l, _UIntType __f>
628	inline bool
629	operator!=(const std::mersenne_twister_engine<_UIntType, __w, __n, __m,
630	__r, __a, __u, __d, __s, __b, __t, __c, __l, __f>& __lhs,
631	const std::mersenne_twister_engine<_UIntType, __w, __n, __m,
632	__r, __a, __u, __d, __s, __b, __t, __c, __l, __f>& __rhs)
633	{ return !(__lhs == __rhs); }
634
635
636	/**
637	* @brief The Marsaglia-Zaman generator.
638	*
639	* This is a model of a Generalized Fibonacci discrete random number
640	* generator, sometimes referred to as the SWC generator.
641	*
642	* A discrete random number generator that produces pseudorandom
643	* numbers using:
644	* @f[
645	* x_{i}\leftarrow(x_{i - s} - x_{i - r} - carry_{i-1}) \bmod m
646	* @f]
647	*
648	* The size of the state is @f$r@f$
649	* and the maximum period of the generator is @f$(m^r - m^s - 1)@f$.
650	*/
651	template<typename _UIntType, size_t __w, size_t __s, size_t __r>
652	class subtract_with_carry_engine
653	{
654	static_assert(std::is_unsigned<_UIntType>::value,
655	"result_type must be an unsigned integral type");
656	static_assert(`0u` < __s && __s < __r,
657	"0 < s < r");
658	static_assert(`0u` < __w && __w <= std::numeric_limits<_UIntType>::digits,
659	"template argument substituting __w out of bounds");
660
661	public:
662	/* The type of the generated random value. /
663	typedef _UIntType result_type;
664
665	// parameter values
666	static constexpr size_t word_size = __w;
667	static constexpr size_t short_lag = __s;
668	static constexpr size_t long_lag = __r;
669	static constexpr result_type default_seed = `19780503u`;
670
671	/**
672	* @brief Constructs an explicitly seeded % subtract_with_carry_engine
673	* random number generator.
674	*/
675	explicit
676	subtract_with_carry_engine(result_type __sd = default_seed)
677	{ seed(__sd); }
678
679	/**
680	* @brief Constructs a %subtract_with_carry_engine random number engine
681	* seeded from the seed sequence @p __q.
682	*
683	* @param __q the seed sequence.
684	*/
685	template<typename _Sseq, typename = typename
686	std::enable_if<!std::is_same<_Sseq, subtract_with_carry_engine>::value>
687	::type>
688	explicit
689	subtract_with_carry_engine(_Sseq& __q)
690	{ seed(__q); }
691
692	/**
693	* @brief Seeds the initial state @f$x_0@f$ of the random number
694	* generator.
695	*
696	* N1688[4.19] modifies this as follows. If @p __value == 0,
697	* sets value to 19780503. In any case, with a linear
698	* congruential generator lcg(i) having parameters @f$ m_{lcg} =
699	* 2147483563, a_{lcg} = 40014, c_{lcg} = 0, and lcg(0) = value
700	* @f$, sets @f$ x_{-r} \dots x_{-1} @f$ to @f$ lcg(1) \bmod m
701	* \dots lcg(r) \bmod m @f$ respectively. If @f$ x_{-1} = 0 @f$
702	* set carry to 1, otherwise sets carry to 0.
703	*/
704	void
705	seed(result_type __sd = default_seed);
706
707	/**
708	* @brief Seeds the initial state @f$x_0@f$ of the
709	* % subtract_with_carry_engine random number generator.
710	*/
711	template<typename _Sseq>
712	typename std::enable_if<std::is_class<_Sseq>::value>::type
713	seed(_Sseq& __q);
714
715	/**
716	* @brief Gets the inclusive minimum value of the range of random
717	* integers returned by this generator.
718	*/
719	static constexpr result_type
720	min()
721	{ return `0`; }
722
723	/**
724	* @brief Gets the inclusive maximum value of the range of random
725	* integers returned by this generator.
726	*/
727	static constexpr result_type
728	max()
729	{ return __detail::_Shift<_UIntType, __w>::__value - `1`; }
730
731	/**
732	* @brief Discard a sequence of random numbers.
733	*/
734	void
735	discard(unsigned long long __z)
736	{
737	for (; __z != `0ULL`; --__z)
738	(*this)();
739	}
740
741	/**
742	* @brief Gets the next random number in the sequence.
743	*/
744	result_type
745	operator()();
746
747	/**
748	* @brief Compares two % subtract_with_carry_engine random number
749	* generator objects of the same type for equality.
750	*
751	* @param __lhs A % subtract_with_carry_engine random number generator
752	* object.
753	* @param __rhs Another % subtract_with_carry_engine random number
754	* generator object.
755	*
756	* @returns true if the infinite sequences of generated values
757	* would be equal, false otherwise.
758	*/
759	friend bool
760	operator==(const subtract_with_carry_engine& __lhs,
761	const subtract_with_carry_engine& __rhs)
762	{ return (std::equal(__lhs._M_x, __lhs._M_x + long_lag, __rhs._M_x)
763	&& __lhs._M_carry == __rhs._M_carry
764	&& __lhs._M_p == __rhs._M_p); }
765
766	/**
767	* @brief Inserts the current state of a % subtract_with_carry_engine
768	* random number generator engine @p __x into the output stream
769	* @p __os.
770	*
771	* @param __os An output stream.
772	* @param __x A % subtract_with_carry_engine random number generator
773	* engine.
774	*
775	* @returns The output stream with the state of @p __x inserted or in
776	* an error state.
777	*/
778	template<typename _UIntType1, size_t __w1, size_t __s1, size_t __r1,
779	typename _CharT, typename _Traits>
780	friend std::basic_ostream<_CharT, _Traits>&
781	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
782	const std::subtract_with_carry_engine<_UIntType1, __w1,
783	__s1, __r1>& __x);
784
785	/**
786	* @brief Extracts the current state of a % subtract_with_carry_engine
787	* random number generator engine @p __x from the input stream
788	* @p __is.
789	*
790	* @param __is An input stream.
791	* @param __x A % subtract_with_carry_engine random number generator
792	* engine.
793	*
794	* @returns The input stream with the state of @p __x extracted or in
795	* an error state.
796	*/
797	template<typename _UIntType1, size_t __w1, size_t __s1, size_t __r1,
798	typename _CharT, typename _Traits>
799	friend std::basic_istream<_CharT, _Traits>&
800	operator>>(std::basic_istream<_CharT, _Traits>& __is,
801	std::subtract_with_carry_engine<_UIntType1, __w1,
802	__s1, __r1>& __x);
803
804	private:
805	/// The state of the generator. This is a ring buffer.
806	_UIntType _M_x[long_lag];
807	_UIntType _M_carry; ///< The carry
808	size_t _M_p; ///< Current index of x(i - r).
809	};
810
811	/**
812	* @brief Compares two % subtract_with_carry_engine random number
813	* generator objects of the same type for inequality.
814	*
815	* @param __lhs A % subtract_with_carry_engine random number generator
816	* object.
817	* @param __rhs Another % subtract_with_carry_engine random number
818	* generator object.
819	*
820	* @returns true if the infinite sequences of generated values
821	* would be different, false otherwise.
822	*/
823	template<typename _UIntType, size_t __w, size_t __s, size_t __r>
824	inline bool
825	operator!=(const std::subtract_with_carry_engine<_UIntType, __w,
826	__s, __r>& __lhs,
827	const std::subtract_with_carry_engine<_UIntType, __w,
828	__s, __r>& __rhs)
829	{ return !(__lhs == __rhs); }
830
831
832	/**
833	* Produces random numbers from some base engine by discarding blocks of
834	* data.
835	*
836	* 0 <= @p __r <= @p __p
837	*/
838	template<typename _RandomNumberEngine, size_t __p, size_t __r>
839	class discard_block_engine
840	{
841	static_assert(`1` <= __r && __r <= __p,
842	"template argument substituting __r out of bounds");
843
844	public:
845	/* The type of the generated random value. /
846	typedef typename _RandomNumberEngine::result_type result_type;
847
848	// parameter values
849	static constexpr size_t block_size = __p;
850	static constexpr size_t used_block = __r;
851
852	/**
853	* @brief Constructs a default %discard_block_engine engine.
854	*
855	* The underlying engine is default constructed as well.
856	*/
857	discard_block_engine()
858	: _M_b(), _M_n(`0`) { }
859
860	/**
861	* @brief Copy constructs a %discard_block_engine engine.
862	*
863	* Copies an existing base class random number generator.
864	* @param __rng An existing (base class) engine object.
865	*/
866	explicit
867	discard_block_engine(const _RandomNumberEngine& __rng)
868	: _M_b(__rng), _M_n(`0`) { }
869
870	/**
871	* @brief Move constructs a %discard_block_engine engine.
872	*
873	* Copies an existing base class random number generator.
874	* @param __rng An existing (base class) engine object.
875	*/
876	explicit
877	discard_block_engine(_RandomNumberEngine&& __rng)
878	: _M_b(std::move(__rng)), _M_n(`0`) { }
879
880	/**
881	* @brief Seed constructs a %discard_block_engine engine.
882	*
883	* Constructs the underlying generator engine seeded with @p __s.
884	* @param __s A seed value for the base class engine.
885	*/
886	explicit
887	discard_block_engine(result_type __s)
888	: _M_b(__s), _M_n(`0`) { }
889
890	/**
891	* @brief Generator construct a %discard_block_engine engine.
892	*
893	* @param __q A seed sequence.
894	*/
895	template<typename _Sseq, typename = typename
896	std::enable_if<!std::is_same<_Sseq, discard_block_engine>::value
897	&& !std::is_same<_Sseq, _RandomNumberEngine>::value>
898	::type>
899	explicit
900	discard_block_engine(_Sseq& __q)
901	: _M_b(__q), _M_n(`0`)
902	{ }
903
904	/**
905	* @brief Reseeds the %discard_block_engine object with the default
906	* seed for the underlying base class generator engine.
907	*/
908	void
909	seed()
910	{
911	_M_b.seed();
912	_M_n = `0`;
913	}
914
915	/**
916	* @brief Reseeds the %discard_block_engine object with the default
917	* seed for the underlying base class generator engine.
918	*/
919	void
920	seed(result_type __s)
921	{
922	_M_b.seed(__s);
923	_M_n = `0`;
924	}
925
926	/**
927	* @brief Reseeds the %discard_block_engine object with the given seed
928	* sequence.
929	* @param __q A seed generator function.
930	*/
931	template<typename _Sseq>
932	void
933	seed(_Sseq& __q)
934	{
935	_M_b.seed(__q);
936	_M_n = `0`;
937	}
938
939	/**
940	* @brief Gets a const reference to the underlying generator engine
941	* object.
942	*/
943	const _RandomNumberEngine&
944	base() const noexcept
945	{ return _M_b; }
946
947	/**
948	* @brief Gets the minimum value in the generated random number range.
949	*/
950	static constexpr result_type
951	min()
952	{ return _RandomNumberEngine::min(); }
953
954	/**
955	* @brief Gets the maximum value in the generated random number range.
956	*/
957	static constexpr result_type
958	max()
959	{ return _RandomNumberEngine::max(); }
960
961	/**
962	* @brief Discard a sequence of random numbers.
963	*/
964	void
965	discard(unsigned long long __z)
966	{
967	for (; __z != `0ULL`; --__z)
968	(*this)();
969	}
970
971	/**
972	* @brief Gets the next value in the generated random number sequence.
973	*/
974	result_type
975	operator()();
976
977	/**
978	* @brief Compares two %discard_block_engine random number generator
979	* objects of the same type for equality.
980	*
981	* @param __lhs A %discard_block_engine random number generator object.
982	* @param __rhs Another %discard_block_engine random number generator
983	* object.
984	*
985	* @returns true if the infinite sequences of generated values
986	* would be equal, false otherwise.
987	*/
988	friend bool
989	operator==(const discard_block_engine& __lhs,
990	const discard_block_engine& __rhs)
991	{ return __lhs._M_b == __rhs._M_b && __lhs._M_n == __rhs._M_n; }
992
993	/**
994	* @brief Inserts the current state of a %discard_block_engine random
995	* number generator engine @p __x into the output stream
996	* @p __os.
997	*
998	* @param __os An output stream.
999	* @param __x A %discard_block_engine random number generator engine.
1000	*
1001	* @returns The output stream with the state of @p __x inserted or in
1002	* an error state.
1003	*/
1004	template<typename _RandomNumberEngine1, size_t __p1, size_t __r1,
1005	typename _CharT, typename _Traits>
1006	friend std::basic_ostream<_CharT, _Traits>&
1007	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
1008	const std::discard_block_engine<_RandomNumberEngine1,
1009	__p1, __r1>& __x);
1010
1011	/**
1012	* @brief Extracts the current state of a % subtract_with_carry_engine
1013	* random number generator engine @p __x from the input stream
1014	* @p __is.
1015	*
1016	* @param __is An input stream.
1017	* @param __x A %discard_block_engine random number generator engine.
1018	*
1019	* @returns The input stream with the state of @p __x extracted or in
1020	* an error state.
1021	*/
1022	template<typename _RandomNumberEngine1, size_t __p1, size_t __r1,
1023	typename _CharT, typename _Traits>
1024	friend std::basic_istream<_CharT, _Traits>&
1025	operator>>(std::basic_istream<_CharT, _Traits>& __is,
1026	std::discard_block_engine<_RandomNumberEngine1,
1027	__p1, __r1>& __x);
1028
1029	private:
1030	_RandomNumberEngine _M_b;
1031	size_t _M_n;
1032	};
1033
1034	/**
1035	* @brief Compares two %discard_block_engine random number generator
1036	* objects of the same type for inequality.
1037	*
1038	* @param __lhs A %discard_block_engine random number generator object.
1039	* @param __rhs Another %discard_block_engine random number generator
1040	* object.
1041	*
1042	* @returns true if the infinite sequences of generated values
1043	* would be different, false otherwise.
1044	*/
1045	template<typename _RandomNumberEngine, size_t __p, size_t __r>
1046	inline bool
1047	operator!=(const std::discard_block_engine<_RandomNumberEngine, __p,
1048	__r>& __lhs,
1049	const std::discard_block_engine<_RandomNumberEngine, __p,
1050	__r>& __rhs)
1051	{ return !(__lhs == __rhs); }
1052
1053
1054	/**
1055	* Produces random numbers by combining random numbers from some base
1056	* engine to produce random numbers with a specifies number of bits @p __w.
1057	*/
1058	template<typename _RandomNumberEngine, size_t __w, typename _UIntType>
1059	class independent_bits_engine
1060	{
1061	static_assert(std::is_unsigned<_UIntType>::value,
1062	"result_type must be an unsigned integral type");
1063	static_assert(`0u` < __w && __w <= std::numeric_limits<_UIntType>::digits,
1064	"template argument substituting __w out of bounds");
1065
1066	public:
1067	/* The type of the generated random value. /
1068	typedef _UIntType result_type;
1069
1070	/**
1071	* @brief Constructs a default %independent_bits_engine engine.
1072	*
1073	* The underlying engine is default constructed as well.
1074	*/
1075	independent_bits_engine()
1076	: _M_b() { }
1077
1078	/**
1079	* @brief Copy constructs a %independent_bits_engine engine.
1080	*
1081	* Copies an existing base class random number generator.
1082	* @param __rng An existing (base class) engine object.
1083	*/
1084	explicit
1085	independent_bits_engine(const _RandomNumberEngine& __rng)
1086	: _M_b(__rng) { }
1087
1088	/**
1089	* @brief Move constructs a %independent_bits_engine engine.
1090	*
1091	* Copies an existing base class random number generator.
1092	* @param __rng An existing (base class) engine object.
1093	*/
1094	explicit
1095	independent_bits_engine(_RandomNumberEngine&& __rng)
1096	: _M_b(std::move(__rng)) { }
1097
1098	/**
1099	* @brief Seed constructs a %independent_bits_engine engine.
1100	*
1101	* Constructs the underlying generator engine seeded with @p __s.
1102	* @param __s A seed value for the base class engine.
1103	*/
1104	explicit
1105	independent_bits_engine(result_type __s)
1106	: _M_b(__s) { }
1107
1108	/**
1109	* @brief Generator construct a %independent_bits_engine engine.
1110	*
1111	* @param __q A seed sequence.
1112	*/
1113	template<typename _Sseq, typename = typename
1114	std::enable_if<!std::is_same<_Sseq, independent_bits_engine>::value
1115	&& !std::is_same<_Sseq, _RandomNumberEngine>::value>
1116	::type>
1117	explicit
1118	independent_bits_engine(_Sseq& __q)
1119	: _M_b(__q)
1120	{ }
1121
1122	/**
1123	* @brief Reseeds the %independent_bits_engine object with the default
1124	* seed for the underlying base class generator engine.
1125	*/
1126	void
1127	seed()
1128	{ _M_b.seed(); }
1129
1130	/**
1131	* @brief Reseeds the %independent_bits_engine object with the default
1132	* seed for the underlying base class generator engine.
1133	*/
1134	void
1135	seed(result_type __s)
1136	{ _M_b.seed(__s); }
1137
1138	/**
1139	* @brief Reseeds the %independent_bits_engine object with the given
1140	* seed sequence.
1141	* @param __q A seed generator function.
1142	*/
1143	template<typename _Sseq>
1144	void
1145	seed(_Sseq& __q)
1146	{ _M_b.seed(__q); }
1147
1148	/**
1149	* @brief Gets a const reference to the underlying generator engine
1150	* object.
1151	*/
1152	const _RandomNumberEngine&
1153	base() const noexcept
1154	{ return _M_b; }
1155
1156	/**
1157	* @brief Gets the minimum value in the generated random number range.
1158	*/
1159	static constexpr result_type
1160	min()
1161	{ return `0U`; }
1162
1163	/**
1164	* @brief Gets the maximum value in the generated random number range.
1165	*/
1166	static constexpr result_type
1167	max()
1168	{ return __detail::_Shift<_UIntType, __w>::__value - `1`; }
1169
1170	/**
1171	* @brief Discard a sequence of random numbers.
1172	*/
1173	void
1174	discard(unsigned long long __z)
1175	{
1176	for (; __z != `0ULL`; --__z)
1177	(*this)();
1178	}
1179
1180	/**
1181	* @brief Gets the next value in the generated random number sequence.
1182	*/
1183	result_type
1184	operator()();
1185
1186	/**
1187	* @brief Compares two %independent_bits_engine random number generator
1188	* objects of the same type for equality.
1189	*
1190	* @param __lhs A %independent_bits_engine random number generator
1191	* object.
1192	* @param __rhs Another %independent_bits_engine random number generator
1193	* object.
1194	*
1195	* @returns true if the infinite sequences of generated values
1196	* would be equal, false otherwise.
1197	*/
1198	friend bool
1199	operator==(const independent_bits_engine& __lhs,
1200	const independent_bits_engine& __rhs)
1201	{ return __lhs._M_b == __rhs._M_b; }
1202
1203	/**
1204	* @brief Extracts the current state of a % subtract_with_carry_engine
1205	* random number generator engine @p __x from the input stream
1206	* @p __is.
1207	*
1208	* @param __is An input stream.
1209	* @param __x A %independent_bits_engine random number generator
1210	* engine.
1211	*
1212	* @returns The input stream with the state of @p __x extracted or in
1213	* an error state.
1214	*/
1215	template<typename _CharT, typename _Traits>
1216	friend std::basic_istream<_CharT, _Traits>&
1217	operator>>(std::basic_istream<_CharT, _Traits>& __is,
1218	std::independent_bits_engine<_RandomNumberEngine,
1219	__w, _UIntType>& __x)
1220	{
1221	__is >> __x._M_b;
1222	return __is;
1223	}
1224
1225	private:
1226	_RandomNumberEngine _M_b;
1227	};
1228
1229	/**
1230	* @brief Compares two %independent_bits_engine random number generator
1231	* objects of the same type for inequality.
1232	*
1233	* @param __lhs A %independent_bits_engine random number generator
1234	* object.
1235	* @param __rhs Another %independent_bits_engine random number generator
1236	* object.
1237	*
1238	* @returns true if the infinite sequences of generated values
1239	* would be different, false otherwise.
1240	*/
1241	template<typename _RandomNumberEngine, size_t __w, typename _UIntType>
1242	inline bool
1243	operator!=(const std::independent_bits_engine<_RandomNumberEngine, __w,
1244	_UIntType>& __lhs,
1245	const std::independent_bits_engine<_RandomNumberEngine, __w,
1246	_UIntType>& __rhs)
1247	{ return !(__lhs == __rhs); }
1248
1249	/**
1250	* @brief Inserts the current state of a %independent_bits_engine random
1251	* number generator engine @p __x into the output stream @p __os.
1252	*
1253	* @param __os An output stream.
1254	* @param __x A %independent_bits_engine random number generator engine.
1255	*
1256	* @returns The output stream with the state of @p __x inserted or in
1257	* an error state.
1258	*/
1259	template<typename _RandomNumberEngine, size_t __w, typename _UIntType,
1260	typename _CharT, typename _Traits>
1261	std::basic_ostream<_CharT, _Traits>&
1262	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
1263	const std::independent_bits_engine<_RandomNumberEngine,
1264	__w, _UIntType>& __x)
1265	{
1266	__os << __x.base();
1267	return __os;
1268	}
1269
1270
1271	/**
1272	* @brief Produces random numbers by combining random numbers from some
1273	* base engine to produce random numbers with a specifies number of bits
1274	* @p __k.
1275	*/
1276	template<typename _RandomNumberEngine, size_t __k>
1277	class shuffle_order_engine
1278	{
1279	static_assert(`1u` <= __k, "template argument substituting "
1280	"__k out of bound");
1281
1282	public:
1283	/* The type of the generated random value. /
1284	typedef typename _RandomNumberEngine::result_type result_type;
1285
1286	static constexpr size_t table_size = __k;
1287
1288	/**
1289	* @brief Constructs a default %shuffle_order_engine engine.
1290	*
1291	* The underlying engine is default constructed as well.
1292	*/
1293	shuffle_order_engine()
1294	: _M_b()
1295	{ _M_initialize(); }
1296
1297	/**
1298	* @brief Copy constructs a %shuffle_order_engine engine.
1299	*
1300	* Copies an existing base class random number generator.
1301	* @param __rng An existing (base class) engine object.
1302	*/
1303	explicit
1304	shuffle_order_engine(const _RandomNumberEngine& __rng)
1305	: _M_b(__rng)
1306	{ _M_initialize(); }
1307
1308	/**
1309	* @brief Move constructs a %shuffle_order_engine engine.
1310	*
1311	* Copies an existing base class random number generator.
1312	* @param __rng An existing (base class) engine object.
1313	*/
1314	explicit
1315	shuffle_order_engine(_RandomNumberEngine&& __rng)
1316	: _M_b(std::move(__rng))
1317	{ _M_initialize(); }
1318
1319	/**
1320	* @brief Seed constructs a %shuffle_order_engine engine.
1321	*
1322	* Constructs the underlying generator engine seeded with @p __s.
1323	* @param __s A seed value for the base class engine.
1324	*/
1325	explicit
1326	shuffle_order_engine(result_type __s)
1327	: _M_b(__s)
1328	{ _M_initialize(); }
1329
1330	/**
1331	* @brief Generator construct a %shuffle_order_engine engine.
1332	*
1333	* @param __q A seed sequence.
1334	*/
1335	template<typename _Sseq, typename = typename
1336	std::enable_if<!std::is_same<_Sseq, shuffle_order_engine>::value
1337	&& !std::is_same<_Sseq, _RandomNumberEngine>::value>
1338	::type>
1339	explicit
1340	shuffle_order_engine(_Sseq& __q)
1341	: _M_b(__q)
1342	{ _M_initialize(); }
1343
1344	/**
1345	* @brief Reseeds the %shuffle_order_engine object with the default seed
1346	for the underlying base class generator engine.
1347	*/
1348	void
1349	seed()
1350	{
1351	_M_b.seed();
1352	_M_initialize();
1353	}
1354
1355	/**
1356	* @brief Reseeds the %shuffle_order_engine object with the default seed
1357	* for the underlying base class generator engine.
1358	*/
1359	void
1360	seed(result_type __s)
1361	{
1362	_M_b.seed(__s);
1363	_M_initialize();
1364	}
1365
1366	/**
1367	* @brief Reseeds the %shuffle_order_engine object with the given seed
1368	* sequence.
1369	* @param __q A seed generator function.
1370	*/
1371	template<typename _Sseq>
1372	void
1373	seed(_Sseq& __q)
1374	{
1375	_M_b.seed(__q);
1376	_M_initialize();
1377	}
1378
1379	/**
1380	* Gets a const reference to the underlying generator engine object.
1381	*/
1382	const _RandomNumberEngine&
1383	base() const noexcept
1384	{ return _M_b; }
1385
1386	/**
1387	* Gets the minimum value in the generated random number range.
1388	*/
1389	static constexpr result_type
1390	min()
1391	{ return _RandomNumberEngine::min(); }
1392
1393	/**
1394	* Gets the maximum value in the generated random number range.
1395	*/
1396	static constexpr result_type
1397	max()
1398	{ return _RandomNumberEngine::max(); }
1399
1400	/**
1401	* Discard a sequence of random numbers.
1402	*/
1403	void
1404	discard(unsigned long long __z)
1405	{
1406	for (; __z != `0ULL`; --__z)
1407	(*this)();
1408	}
1409
1410	/**
1411	* Gets the next value in the generated random number sequence.
1412	*/
1413	result_type
1414	operator()();
1415
1416	/**
1417	* Compares two %shuffle_order_engine random number generator objects
1418	* of the same type for equality.
1419	*
1420	* @param __lhs A %shuffle_order_engine random number generator object.
1421	* @param __rhs Another %shuffle_order_engine random number generator
1422	* object.
1423	*
1424	* @returns true if the infinite sequences of generated values
1425	* would be equal, false otherwise.
1426	*/
1427	friend bool
1428	operator==(const shuffle_order_engine& __lhs,
1429	const shuffle_order_engine& __rhs)
1430	{ return (__lhs._M_b == __rhs._M_b
1431	&& std::equal(__lhs._M_v, __lhs._M_v + __k, __rhs._M_v)
1432	&& __lhs._M_y == __rhs._M_y); }
1433
1434	/**
1435	* @brief Inserts the current state of a %shuffle_order_engine random
1436	* number generator engine @p __x into the output stream
1437	@p __os.
1438	*
1439	* @param __os An output stream.
1440	* @param __x A %shuffle_order_engine random number generator engine.
1441	*
1442	* @returns The output stream with the state of @p __x inserted or in
1443	* an error state.
1444	*/
1445	template<typename _RandomNumberEngine1, size_t __k1,
1446	typename _CharT, typename _Traits>
1447	friend std::basic_ostream<_CharT, _Traits>&
1448	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
1449	const std::shuffle_order_engine<_RandomNumberEngine1,
1450	__k1>& __x);
1451
1452	/**
1453	* @brief Extracts the current state of a % subtract_with_carry_engine
1454	* random number generator engine @p __x from the input stream
1455	* @p __is.
1456	*
1457	* @param __is An input stream.
1458	* @param __x A %shuffle_order_engine random number generator engine.
1459	*
1460	* @returns The input stream with the state of @p __x extracted or in
1461	* an error state.
1462	*/
1463	template<typename _RandomNumberEngine1, size_t __k1,
1464	typename _CharT, typename _Traits>
1465	friend std::basic_istream<_CharT, _Traits>&
1466	operator>>(std::basic_istream<_CharT, _Traits>& __is,
1467	std::shuffle_order_engine<_RandomNumberEngine1, __k1>& __x);
1468
1469	private:
1470	void _M_initialize()
1471	{
1472	for (size_t __i = `0`; __i < __k; ++__i)
1473	_M_v[__i] = _M_b();
1474	_M_y = _M_b();
1475	}
1476
1477	_RandomNumberEngine _M_b;
1478	result_type _M_v[__k];
1479	result_type _M_y;
1480	};
1481
1482	/**
1483	* Compares two %shuffle_order_engine random number generator objects
1484	* of the same type for inequality.
1485	*
1486	* @param __lhs A %shuffle_order_engine random number generator object.
1487	* @param __rhs Another %shuffle_order_engine random number generator
1488	* object.
1489	*
1490	* @returns true if the infinite sequences of generated values
1491	* would be different, false otherwise.
1492	*/
1493	template<typename _RandomNumberEngine, size_t __k>
1494	inline bool
1495	operator!=(const std::shuffle_order_engine<_RandomNumberEngine,
1496	__k>& __lhs,
1497	const std::shuffle_order_engine<_RandomNumberEngine,
1498	__k>& __rhs)
1499	{ return !(__lhs == __rhs); }
1500
1501
1502	/**
1503	* The classic Minimum Standard rand0 of Lewis, Goodman, and Miller.
1504	*/
1505	typedef linear_congruential_engine<uint_fast32_t, `16807UL`, `0UL`, `2147483647UL`>
1506	minstd_rand0;
1507
1508	/**
1509	* An alternative LCR (Lehmer Generator function).
1510	*/
1511	typedef linear_congruential_engine<uint_fast32_t, `48271UL`, `0UL`, `2147483647UL`>
1512	minstd_rand;
1513
1514	/**
1515	* The classic Mersenne Twister.
1516	*
1517	* Reference:
1518	* M. Matsumoto and T. Nishimura, Mersenne Twister: A 623-Dimensionally
1519	* Equidistributed Uniform Pseudo-Random Number Generator, ACM Transactions
1520	* on Modeling and Computer Simulation, Vol. 8, No. 1, January 1998, pp 3-30.
1521	*/
1522	typedef mersenne_twister_engine<
1523	uint_fast32_t,
1524	`32`, `624`, `397`, `31`,
1525	`0x9908b0dfUL`, `11`,
1526	`0xffffffffUL`, `7`,
1527	`0x9d2c5680UL`, `15`,
1528	`0xefc60000UL`, `18`, `1812433253UL`> mt19937;
1529
1530	/**
1531	* An alternative Mersenne Twister.
1532	*/
1533	typedef mersenne_twister_engine<
1534	uint_fast64_t,
1535	`64`, `312`, `156`, `31`,
1536	`0xb5026f5aa96619e9ULL`, `29`,
1537	`0x5555555555555555ULL`, `17`,
1538	`0x71d67fffeda60000ULL`, `37`,
1539	`0xfff7eee000000000ULL`, `43`,
1540	`6364136223846793005ULL`> mt19937_64;
1541
1542	typedef subtract_with_carry_engine<uint_fast32_t, `24`, `10`, `24`>
1543	ranlux24_base;
1544
1545	typedef subtract_with_carry_engine<uint_fast64_t, `48`, `5`, `12`>
1546	ranlux48_base;
1547
1548	typedef discard_block_engine<ranlux24_base, `223`, `23`> ranlux24;
1549
1550	typedef discard_block_engine<ranlux48_base, `389`, `11`> ranlux48;
1551
1552	typedef shuffle_order_engine<minstd_rand0, `256`> knuth_b;
1553
1554	typedef minstd_rand0 default_random_engine;
1555
1556	/**
1557	* A standard interface to a platform-specific non-deterministic
1558	* random number generator (if any are available).
1559	*/
1560	class random_device
1561	{
1562	public:
1563	/* The type of the generated random value. /
1564	typedef unsigned int result_type;
1565
1566	// constructors, destructors and member functions
1567
1568	#ifdef _GLIBCXX_USE_RANDOM_TR1
1569
1570	explicit
1571	random_device(const std::string& __token = "default")
1572	{
1573	_M_init(__token);
1574	}
1575
1576	~random_device()
1577	{ _M_fini(); }
1578
1579	#else
1580
1581	explicit
1582	random_device(const std::string& __token = "mt19937")
1583	{ _M_init_pretr1(__token); }
1584
1585	public:
1586
1587	#endif
1588
1589	static constexpr result_type
1590	min()
1591	{ return std::numeric_limits<result_type>::min(); }
1592
1593	static constexpr result_type
1594	max()
1595	{ return std::numeric_limits<result_type>::max(); }
1596
1597	double
1598	entropy() const noexcept
1599	{
1600	#ifdef _GLIBCXX_USE_RANDOM_TR1
1601	return this->_M_getentropy();
1602	#else
1603	return `0.0`;
1604	#endif
1605	}
1606
1607	result_type
1608	operator()()
1609	{
1610	#ifdef _GLIBCXX_USE_RANDOM_TR1
1611	return this->_M_getval();
1612	#else
1613	return this->_M_getval_pretr1();
1614	#endif
1615	}
1616
1617	// No copy functions.
1618	random_device(const random_device&) = delete;
1619	void operator=(const random_device&) = delete;
1620
1621	private:
1622
1623	void _M_init(const std::string& __token);
1624	void _M_init_pretr1(const std::string& __token);
1625	void _M_fini();
1626
1627	result_type _M_getval();
1628	result_type _M_getval_pretr1();
1629	double _M_getentropy() const noexcept;
1630
1631	union
1632	{
1633	void* _M_file;
1634	mt19937 _M_mt;
1635	};
1636	};
1637
1638	/ @} / // group random_generators
1639
1640	/**
1641	* @addtogroup random_distributions Random Number Distributions
1642	* @ingroup random
1643	* @{
1644	*/
1645
1646	/**
1647	* @addtogroup random_distributions_uniform Uniform Distributions
1648	* @ingroup random_distributions
1649	* @{
1650	*/
1651
1652	// std::uniform_int_distribution is defined in <bits/uniform_int_dist.h>
1653
1654	/**
1655	* @brief Return true if two uniform integer distributions have
1656	* different parameters.
1657	*/
1658	template<typename _IntType>
1659	inline bool
1660	operator!=(const std::uniform_int_distribution<_IntType>& __d1,
1661	const std::uniform_int_distribution<_IntType>& __d2)
1662	{ return !(__d1 == __d2); }
1663
1664	/**
1665	* @brief Inserts a %uniform_int_distribution random number
1666	* distribution @p __x into the output stream @p os.
1667	*
1668	* @param __os An output stream.
1669	* @param __x A %uniform_int_distribution random number distribution.
1670	*
1671	* @returns The output stream with the state of @p __x inserted or in
1672	* an error state.
1673	*/
1674	template<typename _IntType, typename _CharT, typename _Traits>
1675	std::basic_ostream<_CharT, _Traits>&
1676	operator<<(std::basic_ostream<_CharT, _Traits>&,
1677	const std::uniform_int_distribution<_IntType>&);
1678
1679	/**
1680	* @brief Extracts a %uniform_int_distribution random number distribution
1681	* @p __x from the input stream @p __is.
1682	*
1683	* @param __is An input stream.
1684	* @param __x A %uniform_int_distribution random number generator engine.
1685	*
1686	* @returns The input stream with @p __x extracted or in an error state.
1687	*/
1688	template<typename _IntType, typename _CharT, typename _Traits>
1689	std::basic_istream<_CharT, _Traits>&
1690	operator>>(std::basic_istream<_CharT, _Traits>&,
1691	std::uniform_int_distribution<_IntType>&);
1692
1693
1694	/**
1695	* @brief Uniform continuous distribution for random numbers.
1696	*
1697	* A continuous random distribution on the range [min, max) with equal
1698	* probability throughout the range. The URNG should be real-valued and
1699	* deliver number in the range [0, 1).
1700	*/
1701	template<typename _RealType = double>
1702	class uniform_real_distribution
1703	{
1704	static_assert(std::is_floating_point<_RealType>::value,
1705	"result_type must be a floating point type");
1706
1707	public:
1708	/* The type of the range of the distribution. /
1709	typedef _RealType result_type;
1710
1711	/* Parameter type. /
1712	struct param_type
1713	{
1714	typedef uniform_real_distribution<_RealType> distribution_type;
1715
1716	explicit
1717	param_type(_RealType __a = _RealType(`0`),
1718	_RealType __b = _RealType(`1`))
1719	: _M_a(__a), _M_b(__b)
1720	{
1721	__glibcxx_assert(_M_a <= _M_b);
1722	}
1723
1724	result_type
1725	a() const
1726	{ return _M_a; }
1727
1728	result_type
1729	b() const
1730	{ return _M_b; }
1731
1732	friend bool
1733	operator==(const param_type& __p1, const param_type& __p2)
1734	{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
1735
1736	friend bool
1737	operator!=(const param_type& __p1, const param_type& __p2)
1738	{ return !(__p1 == __p2); }
1739
1740	private:
1741	_RealType _M_a;
1742	_RealType _M_b;
1743	};
1744
1745	public:
1746	/**
1747	* @brief Constructs a uniform_real_distribution object.
1748	*
1749	* @param __a [IN] The lower bound of the distribution.
1750	* @param __b [IN] The upper bound of the distribution.
1751	*/
1752	explicit
1753	uniform_real_distribution(_RealType __a = _RealType(`0`),
1754	_RealType __b = _RealType(`1`))
1755	: _M_param(__a, __b)
1756	{ }
1757
1758	explicit
1759	uniform_real_distribution(const param_type& __p)
1760	: _M_param(__p)
1761	{ }
1762
1763	/**
1764	* @brief Resets the distribution state.
1765	*
1766	* Does nothing for the uniform real distribution.
1767	*/
1768	void
1769	reset() { }
1770
1771	result_type
1772	a() const
1773	{ return _M_param.a(); }
1774
1775	result_type
1776	b() const
1777	{ return _M_param.b(); }
1778
1779	/**
1780	* @brief Returns the parameter set of the distribution.
1781	*/
1782	param_type
1783	param() const
1784	{ return _M_param; }
1785
1786	/**
1787	* @brief Sets the parameter set of the distribution.
1788	* @param __param The new parameter set of the distribution.
1789	*/
1790	void
1791	param(const param_type& __param)
1792	{ _M_param = __param; }
1793
1794	/**
1795	* @brief Returns the inclusive lower bound of the distribution range.
1796	*/
1797	result_type
1798	min() const
1799	{ return this->a(); }
1800
1801	/**
1802	* @brief Returns the inclusive upper bound of the distribution range.
1803	*/
1804	result_type
1805	max() const
1806	{ return this->b(); }
1807
1808	/**
1809	* @brief Generating functions.
1810	*/
1811	template<typename _UniformRandomNumberGenerator>
1812	result_type
1813	operator()(_UniformRandomNumberGenerator& __urng)
1814	{ return this->operator()(__urng, _M_param); }
1815
1816	template<typename _UniformRandomNumberGenerator>
1817	result_type
1818	operator()(_UniformRandomNumberGenerator& __urng,
1819	const param_type& __p)
1820	{
1821	__detail::_Adaptor<_UniformRandomNumberGenerator, result_type>
1822	__aurng(__urng);
1823	return (__aurng() * (__p.b() - __p.a())) + __p.a();
1824	}
1825
1826	template<typename _ForwardIterator,
1827	typename _UniformRandomNumberGenerator>
1828	void
1829	__generate(_ForwardIterator __f, _ForwardIterator __t,
1830	_UniformRandomNumberGenerator& __urng)
1831	{ this->__generate(__f, __t, __urng, _M_param); }
1832
1833	template<typename _ForwardIterator,
1834	typename _UniformRandomNumberGenerator>
1835	void
1836	__generate(_ForwardIterator __f, _ForwardIterator __t,
1837	_UniformRandomNumberGenerator& __urng,
1838	const param_type& __p)
1839	{ this->__generate_impl(__f, __t, __urng, __p); }
1840
1841	template<typename _UniformRandomNumberGenerator>
1842	void
1843	__generate(result_type* __f, result_type* __t,
1844	_UniformRandomNumberGenerator& __urng,
1845	const param_type& __p)
1846	{ this->__generate_impl(__f, __t, __urng, __p); }
1847
1848	/**
1849	* @brief Return true if two uniform real distributions have
1850	* the same parameters.
1851	*/
1852	friend bool
1853	operator==(const uniform_real_distribution& __d1,
1854	const uniform_real_distribution& __d2)
1855	{ return __d1._M_param == __d2._M_param; }
1856
1857	private:
1858	template<typename _ForwardIterator,
1859	typename _UniformRandomNumberGenerator>
1860	void
1861	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
1862	_UniformRandomNumberGenerator& __urng,
1863	const param_type& __p);
1864
1865	param_type _M_param;
1866	};
1867
1868	/**
1869	* @brief Return true if two uniform real distributions have
1870	* different parameters.
1871	*/
1872	template<typename _IntType>
1873	inline bool
1874	operator!=(const std::uniform_real_distribution<_IntType>& __d1,
1875	const std::uniform_real_distribution<_IntType>& __d2)
1876	{ return !(__d1 == __d2); }
1877
1878	/**
1879	* @brief Inserts a %uniform_real_distribution random number
1880	* distribution @p __x into the output stream @p __os.
1881	*
1882	* @param __os An output stream.
1883	* @param __x A %uniform_real_distribution random number distribution.
1884	*
1885	* @returns The output stream with the state of @p __x inserted or in
1886	* an error state.
1887	*/
1888	template<typename _RealType, typename _CharT, typename _Traits>
1889	std::basic_ostream<_CharT, _Traits>&
1890	operator<<(std::basic_ostream<_CharT, _Traits>&,
1891	const std::uniform_real_distribution<_RealType>&);
1892
1893	/**
1894	* @brief Extracts a %uniform_real_distribution random number distribution
1895	* @p __x from the input stream @p __is.
1896	*
1897	* @param __is An input stream.
1898	* @param __x A %uniform_real_distribution random number generator engine.
1899	*
1900	* @returns The input stream with @p __x extracted or in an error state.
1901	*/
1902	template<typename _RealType, typename _CharT, typename _Traits>
1903	std::basic_istream<_CharT, _Traits>&
1904	operator>>(std::basic_istream<_CharT, _Traits>&,
1905	std::uniform_real_distribution<_RealType>&);
1906
1907	/ @} / // group random_distributions_uniform
1908
1909	/**
1910	* @addtogroup random_distributions_normal Normal Distributions
1911	* @ingroup random_distributions
1912	* @{
1913	*/
1914
1915	/**
1916	* @brief A normal continuous distribution for random numbers.
1917	*
1918	* The formula for the normal probability density function is
1919	* @f[
1920	* p(x\|\mu,\sigma) = \frac{1}{\sigma \sqrt{2 \pi}}
1921	* e^{- \frac{{x - \mu}^ {2}}{2 \sigma ^ {2}} }
1922	* @f]
1923	*/
1924	template<typename _RealType = double>
1925	class normal_distribution
1926	{
1927	static_assert(std::is_floating_point<_RealType>::value,
1928	"result_type must be a floating point type");
1929
1930	public:
1931	/* The type of the range of the distribution. /
1932	typedef _RealType result_type;
1933
1934	/* Parameter type. /
1935	struct param_type
1936	{
1937	typedef normal_distribution<_RealType> distribution_type;
1938
1939	explicit
1940	param_type(_RealType __mean = _RealType(`0`),
1941	_RealType __stddev = _RealType(`1`))
1942	: _M_mean(__mean), _M_stddev(__stddev)
1943	{
1944	__glibcxx_assert(_M_stddev > _RealType(`0`));
1945	}
1946
1947	_RealType
1948	mean() const
1949	{ return _M_mean; }
1950
1951	_RealType
1952	stddev() const
1953	{ return _M_stddev; }
1954
1955	friend bool
1956	operator==(const param_type& __p1, const param_type& __p2)
1957	{ return (__p1._M_mean == __p2._M_mean
1958	&& __p1._M_stddev == __p2._M_stddev); }
1959
1960	friend bool
1961	operator!=(const param_type& __p1, const param_type& __p2)
1962	{ return !(__p1 == __p2); }
1963
1964	private:
1965	_RealType _M_mean;
1966	_RealType _M_stddev;
1967	};
1968
1969	public:
1970	/**
1971	* Constructs a normal distribution with parameters @f$mean@f$ and
1972	* standard deviation.
1973	*/
1974	explicit
1975	normal_distribution(result_type __mean = result_type(`0`),
1976	result_type __stddev = result_type(`1`))
1977	: _M_param(__mean, __stddev), _M_saved_available(false)
1978	{ }
1979
1980	explicit
1981	normal_distribution(const param_type& __p)
1982	: _M_param(__p), _M_saved_available(false)
1983	{ }
1984
1985	/**
1986	* @brief Resets the distribution state.
1987	*/
1988	void
1989	reset()
1990	{ _M_saved_available = false; }
1991
1992	/**
1993	* @brief Returns the mean of the distribution.
1994	*/
1995	_RealType
1996	mean() const
1997	{ return _M_param.mean(); }
1998
1999	/**
2000	* @brief Returns the standard deviation of the distribution.
2001	*/
2002	_RealType
2003	stddev() const
2004	{ return _M_param.stddev(); }
2005
2006	/**
2007	* @brief Returns the parameter set of the distribution.
2008	*/
2009	param_type
2010	param() const
2011	{ return _M_param; }
2012
2013	/**
2014	* @brief Sets the parameter set of the distribution.
2015	* @param __param The new parameter set of the distribution.
2016	*/
2017	void
2018	param(const param_type& __param)
2019	{ _M_param = __param; }
2020
2021	/**
2022	* @brief Returns the greatest lower bound value of the distribution.
2023	*/
2024	result_type
2025	min() const
2026	{ return std::numeric_limits<result_type>::lowest(); }
2027
2028	/**
2029	* @brief Returns the least upper bound value of the distribution.
2030	*/
2031	result_type
2032	max() const
2033	{ return std::numeric_limits<result_type>::max(); }
2034
2035	/**
2036	* @brief Generating functions.
2037	*/
2038	template<typename _UniformRandomNumberGenerator>
2039	result_type
2040	operator()(_UniformRandomNumberGenerator& __urng)
2041	{ return this->operator()(__urng, _M_param); }
2042
2043	template<typename _UniformRandomNumberGenerator>
2044	result_type
2045	operator()(_UniformRandomNumberGenerator& __urng,
2046	const param_type& __p);
2047
2048	template<typename _ForwardIterator,
2049	typename _UniformRandomNumberGenerator>
2050	void
2051	__generate(_ForwardIterator __f, _ForwardIterator __t,
2052	_UniformRandomNumberGenerator& __urng)
2053	{ this->__generate(__f, __t, __urng, _M_param); }
2054
2055	template<typename _ForwardIterator,
2056	typename _UniformRandomNumberGenerator>
2057	void
2058	__generate(_ForwardIterator __f, _ForwardIterator __t,
2059	_UniformRandomNumberGenerator& __urng,
2060	const param_type& __p)
2061	{ this->__generate_impl(__f, __t, __urng, __p); }
2062
2063	template<typename _UniformRandomNumberGenerator>
2064	void
2065	__generate(result_type* __f, result_type* __t,
2066	_UniformRandomNumberGenerator& __urng,
2067	const param_type& __p)
2068	{ this->__generate_impl(__f, __t, __urng, __p); }
2069
2070	/**
2071	* @brief Return true if two normal distributions have
2072	* the same parameters and the sequences that would
2073	* be generated are equal.
2074	*/
2075	template<typename _RealType1>
2076	friend bool
2077	operator==(const std::normal_distribution<_RealType1>& __d1,
2078	const std::normal_distribution<_RealType1>& __d2);
2079
2080	/**
2081	* @brief Inserts a %normal_distribution random number distribution
2082	* @p __x into the output stream @p __os.
2083	*
2084	* @param __os An output stream.
2085	* @param __x A %normal_distribution random number distribution.
2086	*
2087	* @returns The output stream with the state of @p __x inserted or in
2088	* an error state.
2089	*/
2090	template<typename _RealType1, typename _CharT, typename _Traits>
2091	friend std::basic_ostream<_CharT, _Traits>&
2092	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
2093	const std::normal_distribution<_RealType1>& __x);
2094
2095	/**
2096	* @brief Extracts a %normal_distribution random number distribution
2097	* @p __x from the input stream @p __is.
2098	*
2099	* @param __is An input stream.
2100	* @param __x A %normal_distribution random number generator engine.
2101	*
2102	* @returns The input stream with @p __x extracted or in an error
2103	* state.
2104	*/
2105	template<typename _RealType1, typename _CharT, typename _Traits>
2106	friend std::basic_istream<_CharT, _Traits>&
2107	operator>>(std::basic_istream<_CharT, _Traits>& __is,
2108	std::normal_distribution<_RealType1>& __x);
2109
2110	private:
2111	template<typename _ForwardIterator,
2112	typename _UniformRandomNumberGenerator>
2113	void
2114	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2115	_UniformRandomNumberGenerator& __urng,
2116	const param_type& __p);
2117
2118	param_type _M_param;
2119	result_type _M_saved;
2120	bool _M_saved_available;
2121	};
2122
2123	/**
2124	* @brief Return true if two normal distributions are different.
2125	*/
2126	template<typename _RealType>
2127	inline bool
2128	operator!=(const std::normal_distribution<_RealType>& __d1,
2129	const std::normal_distribution<_RealType>& __d2)
2130	{ return !(__d1 == __d2); }
2131
2132
2133	/**
2134	* @brief A lognormal_distribution random number distribution.
2135	*
2136	* The formula for the normal probability mass function is
2137	* @f[
2138	* p(x\|m,s) = \frac{1}{sx\sqrt{2\pi}}
2139	* \exp{-\frac{(\ln{x} - m)^2}{2s^2}}
2140	* @f]
2141	*/
2142	template<typename _RealType = double>
2143	class lognormal_distribution
2144	{
2145	static_assert(std::is_floating_point<_RealType>::value,
2146	"result_type must be a floating point type");
2147
2148	public:
2149	/* The type of the range of the distribution. /
2150	typedef _RealType result_type;
2151
2152	/* Parameter type. /
2153	struct param_type
2154	{
2155	typedef lognormal_distribution<_RealType> distribution_type;
2156
2157	explicit
2158	param_type(_RealType __m = _RealType(`0`),
2159	_RealType __s = _RealType(`1`))
2160	: _M_m(__m), _M_s(__s)
2161	{ }
2162
2163	_RealType
2164	m() const
2165	{ return _M_m; }
2166
2167	_RealType
2168	s() const
2169	{ return _M_s; }
2170
2171	friend bool
2172	operator==(const param_type& __p1, const param_type& __p2)
2173	{ return __p1._M_m == __p2._M_m && __p1._M_s == __p2._M_s; }
2174
2175	friend bool
2176	operator!=(const param_type& __p1, const param_type& __p2)
2177	{ return !(__p1 == __p2); }
2178
2179	private:
2180	_RealType _M_m;
2181	_RealType _M_s;
2182	};
2183
2184	explicit
2185	lognormal_distribution(_RealType __m = _RealType(`0`),
2186	_RealType __s = _RealType(`1`))
2187	: _M_param(__m, __s), _M_nd()
2188	{ }
2189
2190	explicit
2191	lognormal_distribution(const param_type& __p)
2192	: _M_param(__p), _M_nd()
2193	{ }
2194
2195	/**
2196	* Resets the distribution state.
2197	*/
2198	void
2199	reset()
2200	{ _M_nd.reset(); }
2201
2202	/**
2203	*
2204	*/
2205	_RealType
2206	m() const
2207	{ return _M_param.m(); }
2208
2209	_RealType
2210	s() const
2211	{ return _M_param.s(); }
2212
2213	/**
2214	* @brief Returns the parameter set of the distribution.
2215	*/
2216	param_type
2217	param() const
2218	{ return _M_param; }
2219
2220	/**
2221	* @brief Sets the parameter set of the distribution.
2222	* @param __param The new parameter set of the distribution.
2223	*/
2224	void
2225	param(const param_type& __param)
2226	{ _M_param = __param; }
2227
2228	/**
2229	* @brief Returns the greatest lower bound value of the distribution.
2230	*/
2231	result_type
2232	min() const
2233	{ return result_type(`0`); }
2234
2235	/**
2236	* @brief Returns the least upper bound value of the distribution.
2237	*/
2238	result_type
2239	max() const
2240	{ return std::numeric_limits<result_type>::max(); }
2241
2242	/**
2243	* @brief Generating functions.
2244	*/
2245	template<typename _UniformRandomNumberGenerator>
2246	result_type
2247	operator()(_UniformRandomNumberGenerator& __urng)
2248	{ return this->operator()(__urng, _M_param); }
2249
2250	template<typename _UniformRandomNumberGenerator>
2251	result_type
2252	operator()(_UniformRandomNumberGenerator& __urng,
2253	const param_type& __p)
2254	{ return std::exp(__p.s() * _M_nd(__urng) + __p.m()); }
2255
2256	template<typename _ForwardIterator,
2257	typename _UniformRandomNumberGenerator>
2258	void
2259	__generate(_ForwardIterator __f, _ForwardIterator __t,
2260	_UniformRandomNumberGenerator& __urng)
2261	{ this->__generate(__f, __t, __urng, _M_param); }
2262
2263	template<typename _ForwardIterator,
2264	typename _UniformRandomNumberGenerator>
2265	void
2266	__generate(_ForwardIterator __f, _ForwardIterator __t,
2267	_UniformRandomNumberGenerator& __urng,
2268	const param_type& __p)
2269	{ this->__generate_impl(__f, __t, __urng, __p); }
2270
2271	template<typename _UniformRandomNumberGenerator>
2272	void
2273	__generate(result_type* __f, result_type* __t,
2274	_UniformRandomNumberGenerator& __urng,
2275	const param_type& __p)
2276	{ this->__generate_impl(__f, __t, __urng, __p); }
2277
2278	/**
2279	* @brief Return true if two lognormal distributions have
2280	* the same parameters and the sequences that would
2281	* be generated are equal.
2282	*/
2283	friend bool
2284	operator==(const lognormal_distribution& __d1,
2285	const lognormal_distribution& __d2)
2286	{ return (__d1._M_param == __d2._M_param
2287	&& __d1._M_nd == __d2._M_nd); }
2288
2289	/**
2290	* @brief Inserts a %lognormal_distribution random number distribution
2291	* @p __x into the output stream @p __os.
2292	*
2293	* @param __os An output stream.
2294	* @param __x A %lognormal_distribution random number distribution.
2295	*
2296	* @returns The output stream with the state of @p __x inserted or in
2297	* an error state.
2298	*/
2299	template<typename _RealType1, typename _CharT, typename _Traits>
2300	friend std::basic_ostream<_CharT, _Traits>&
2301	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
2302	const std::lognormal_distribution<_RealType1>& __x);
2303
2304	/**
2305	* @brief Extracts a %lognormal_distribution random number distribution
2306	* @p __x from the input stream @p __is.
2307	*
2308	* @param __is An input stream.
2309	* @param __x A %lognormal_distribution random number
2310	* generator engine.
2311	*
2312	* @returns The input stream with @p __x extracted or in an error state.
2313	*/
2314	template<typename _RealType1, typename _CharT, typename _Traits>
2315	friend std::basic_istream<_CharT, _Traits>&
2316	operator>>(std::basic_istream<_CharT, _Traits>& __is,
2317	std::lognormal_distribution<_RealType1>& __x);
2318
2319	private:
2320	template<typename _ForwardIterator,
2321	typename _UniformRandomNumberGenerator>
2322	void
2323	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2324	_UniformRandomNumberGenerator& __urng,
2325	const param_type& __p);
2326
2327	param_type _M_param;
2328
2329	std::normal_distribution<result_type> _M_nd;
2330	};
2331
2332	/**
2333	* @brief Return true if two lognormal distributions are different.
2334	*/
2335	template<typename _RealType>
2336	inline bool
2337	operator!=(const std::lognormal_distribution<_RealType>& __d1,
2338	const std::lognormal_distribution<_RealType>& __d2)
2339	{ return !(__d1 == __d2); }
2340
2341
2342	/**
2343	* @brief A gamma continuous distribution for random numbers.
2344	*
2345	* The formula for the gamma probability density function is:
2346	* @f[
2347	* p(x\|\alpha,\beta) = \frac{1}{\beta\Gamma(\alpha)}
2348	* (x/\beta)^{\alpha - 1} e^{-x/\beta}
2349	* @f]
2350	*/
2351	template<typename _RealType = double>
2352	class gamma_distribution
2353	{
2354	static_assert(std::is_floating_point<_RealType>::value,
2355	"result_type must be a floating point type");
2356
2357	public:
2358	/* The type of the range of the distribution. /
2359	typedef _RealType result_type;
2360
2361	/* Parameter type. /
2362	struct param_type
2363	{
2364	typedef gamma_distribution<_RealType> distribution_type;
2365	friend class gamma_distribution<_RealType>;
2366
2367	explicit
2368	param_type(_RealType __alpha_val = _RealType(`1`),
2369	_RealType __beta_val = _RealType(`1`))
2370	: _M_alpha(__alpha_val), _M_beta(__beta_val)
2371	{
2372	__glibcxx_assert(_M_alpha > _RealType(`0`));
2373	_M_initialize();
2374	}
2375
2376	_RealType
2377	alpha() const
2378	{ return _M_alpha; }
2379
2380	_RealType
2381	beta() const
2382	{ return _M_beta; }
2383
2384	friend bool
2385	operator==(const param_type& __p1, const param_type& __p2)
2386	{ return (__p1._M_alpha == __p2._M_alpha
2387	&& __p1._M_beta == __p2._M_beta); }
2388
2389	friend bool
2390	operator!=(const param_type& __p1, const param_type& __p2)
2391	{ return !(__p1 == __p2); }
2392
2393	private:
2394	void
2395	_M_initialize();
2396
2397	_RealType _M_alpha;
2398	_RealType _M_beta;
2399
2400	_RealType _M_malpha, _M_a2;
2401	};
2402
2403	public:
2404	/**
2405	* @brief Constructs a gamma distribution with parameters
2406	* @f$\alpha@f$ and @f$\beta@f$.
2407	*/
2408	explicit
2409	gamma_distribution(_RealType __alpha_val = _RealType(`1`),
2410	_RealType __beta_val = _RealType(`1`))
2411	: _M_param(__alpha_val, __beta_val), _M_nd()
2412	{ }
2413
2414	explicit
2415	gamma_distribution(const param_type& __p)
2416	: _M_param(__p), _M_nd()
2417	{ }
2418
2419	/**
2420	* @brief Resets the distribution state.
2421	*/
2422	void
2423	reset()
2424	{ _M_nd.reset(); }
2425
2426	/**
2427	* @brief Returns the @f$\alpha@f$ of the distribution.
2428	*/
2429	_RealType
2430	alpha() const
2431	{ return _M_param.alpha(); }
2432
2433	/**
2434	* @brief Returns the @f$\beta@f$ of the distribution.
2435	*/
2436	_RealType
2437	beta() const
2438	{ return _M_param.beta(); }
2439
2440	/**
2441	* @brief Returns the parameter set of the distribution.
2442	*/
2443	param_type
2444	param() const
2445	{ return _M_param; }
2446
2447	/**
2448	* @brief Sets the parameter set of the distribution.
2449	* @param __param The new parameter set of the distribution.
2450	*/
2451	void
2452	param(const param_type& __param)
2453	{ _M_param = __param; }
2454
2455	/**
2456	* @brief Returns the greatest lower bound value of the distribution.
2457	*/
2458	result_type
2459	min() const
2460	{ return result_type(`0`); }
2461
2462	/**
2463	* @brief Returns the least upper bound value of the distribution.
2464	*/
2465	result_type
2466	max() const
2467	{ return std::numeric_limits<result_type>::max(); }
2468
2469	/**
2470	* @brief Generating functions.
2471	*/
2472	template<typename _UniformRandomNumberGenerator>
2473	result_type
2474	operator()(_UniformRandomNumberGenerator& __urng)
2475	{ return this->operator()(__urng, _M_param); }
2476
2477	template<typename _UniformRandomNumberGenerator>
2478	result_type
2479	operator()(_UniformRandomNumberGenerator& __urng,
2480	const param_type& __p);
2481
2482	template<typename _ForwardIterator,
2483	typename _UniformRandomNumberGenerator>
2484	void
2485	__generate(_ForwardIterator __f, _ForwardIterator __t,
2486	_UniformRandomNumberGenerator& __urng)
2487	{ this->__generate(__f, __t, __urng, _M_param); }
2488
2489	template<typename _ForwardIterator,
2490	typename _UniformRandomNumberGenerator>
2491	void
2492	__generate(_ForwardIterator __f, _ForwardIterator __t,
2493	_UniformRandomNumberGenerator& __urng,
2494	const param_type& __p)
2495	{ this->__generate_impl(__f, __t, __urng, __p); }
2496
2497	template<typename _UniformRandomNumberGenerator>
2498	void
2499	__generate(result_type* __f, result_type* __t,
2500	_UniformRandomNumberGenerator& __urng,
2501	const param_type& __p)
2502	{ this->__generate_impl(__f, __t, __urng, __p); }
2503
2504	/**
2505	* @brief Return true if two gamma distributions have the same
2506	* parameters and the sequences that would be generated
2507	* are equal.
2508	*/
2509	friend bool
2510	operator==(const gamma_distribution& __d1,
2511	const gamma_distribution& __d2)
2512	{ return (__d1._M_param == __d2._M_param
2513	&& __d1._M_nd == __d2._M_nd); }
2514
2515	/**
2516	* @brief Inserts a %gamma_distribution random number distribution
2517	* @p __x into the output stream @p __os.
2518	*
2519	* @param __os An output stream.
2520	* @param __x A %gamma_distribution random number distribution.
2521	*
2522	* @returns The output stream with the state of @p __x inserted or in
2523	* an error state.
2524	*/
2525	template<typename _RealType1, typename _CharT, typename _Traits>
2526	friend std::basic_ostream<_CharT, _Traits>&
2527	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
2528	const std::gamma_distribution<_RealType1>& __x);
2529
2530	/**
2531	* @brief Extracts a %gamma_distribution random number distribution
2532	* @p __x from the input stream @p __is.
2533	*
2534	* @param __is An input stream.
2535	* @param __x A %gamma_distribution random number generator engine.
2536	*
2537	* @returns The input stream with @p __x extracted or in an error state.
2538	*/
2539	template<typename _RealType1, typename _CharT, typename _Traits>
2540	friend std::basic_istream<_CharT, _Traits>&
2541	operator>>(std::basic_istream<_CharT, _Traits>& __is,
2542	std::gamma_distribution<_RealType1>& __x);
2543
2544	private:
2545	template<typename _ForwardIterator,
2546	typename _UniformRandomNumberGenerator>
2547	void
2548	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2549	_UniformRandomNumberGenerator& __urng,
2550	const param_type& __p);
2551
2552	param_type _M_param;
2553
2554	std::normal_distribution<result_type> _M_nd;
2555	};
2556
2557	/**
2558	* @brief Return true if two gamma distributions are different.
2559	*/
2560	template<typename _RealType>
2561	inline bool
2562	operator!=(const std::gamma_distribution<_RealType>& __d1,
2563	const std::gamma_distribution<_RealType>& __d2)
2564	{ return !(__d1 == __d2); }
2565
2566
2567	/**
2568	* @brief A chi_squared_distribution random number distribution.
2569	*
2570	* The formula for the normal probability mass function is
2571	* @f$p(x\|n) = \frac{x^{(n/2) - 1}e^{-x/2}}{\Gamma(n/2) 2^{n/2}}@f$
2572	*/
2573	template<typename _RealType = double>
2574	class chi_squared_distribution
2575	{
2576	static_assert(std::is_floating_point<_RealType>::value,
2577	"result_type must be a floating point type");
2578
2579	public:
2580	/* The type of the range of the distribution. /
2581	typedef _RealType result_type;
2582
2583	/* Parameter type. /
2584	struct param_type
2585	{
2586	typedef chi_squared_distribution<_RealType> distribution_type;
2587
2588	explicit
2589	param_type(_RealType __n = _RealType(`1`))
2590	: _M_n(__n)
2591	{ }
2592
2593	_RealType
2594	n() const
2595	{ return _M_n; }
2596
2597	friend bool
2598	operator==(const param_type& __p1, const param_type& __p2)
2599	{ return __p1._M_n == __p2._M_n; }
2600
2601	friend bool
2602	operator!=(const param_type& __p1, const param_type& __p2)
2603	{ return !(__p1 == __p2); }
2604
2605	private:
2606	_RealType _M_n;
2607	};
2608
2609	explicit
2610	chi_squared_distribution(_RealType __n = _RealType(`1`))
2611	: _M_param(__n), _M_gd(__n / `2`)
2612	{ }
2613
2614	explicit
2615	chi_squared_distribution(const param_type& __p)
2616	: _M_param(__p), _M_gd(__p.n() / `2`)
2617	{ }
2618
2619	/**
2620	* @brief Resets the distribution state.
2621	*/
2622	void
2623	reset()
2624	{ _M_gd.reset(); }
2625
2626	/**
2627	*
2628	*/
2629	_RealType
2630	n() const
2631	{ return _M_param.n(); }
2632
2633	/**
2634	* @brief Returns the parameter set of the distribution.
2635	*/
2636	param_type
2637	param() const
2638	{ return _M_param; }
2639
2640	/**
2641	* @brief Sets the parameter set of the distribution.
2642	* @param __param The new parameter set of the distribution.
2643	*/
2644	void
2645	param(const param_type& __param)
2646	{
2647	_M_param = __param;
2648	typedef typename std::gamma_distribution<result_type>::param_type
2649	param_type;
2650	_M_gd.param(param_type{__param.n() / `2`});
2651	}
2652
2653	/**
2654	* @brief Returns the greatest lower bound value of the distribution.
2655	*/
2656	result_type
2657	min() const
2658	{ return result_type(`0`); }
2659
2660	/**
2661	* @brief Returns the least upper bound value of the distribution.
2662	*/
2663	result_type
2664	max() const
2665	{ return std::numeric_limits<result_type>::max(); }
2666
2667	/**
2668	* @brief Generating functions.
2669	*/
2670	template<typename _UniformRandomNumberGenerator>
2671	result_type
2672	operator()(_UniformRandomNumberGenerator& __urng)
2673	{ return `2` * _M_gd(__urng); }
2674
2675	template<typename _UniformRandomNumberGenerator>
2676	result_type
2677	operator()(_UniformRandomNumberGenerator& __urng,
2678	const param_type& __p)
2679	{
2680	typedef typename std::gamma_distribution<result_type>::param_type
2681	param_type;
2682	return `2` * _M_gd(__urng, param_type(__p.n() / `2`));
2683	}
2684
2685	template<typename _ForwardIterator,
2686	typename _UniformRandomNumberGenerator>
2687	void
2688	__generate(_ForwardIterator __f, _ForwardIterator __t,
2689	_UniformRandomNumberGenerator& __urng)
2690	{ this->__generate_impl(__f, __t, __urng); }
2691
2692	template<typename _ForwardIterator,
2693	typename _UniformRandomNumberGenerator>
2694	void
2695	__generate(_ForwardIterator __f, _ForwardIterator __t,
2696	_UniformRandomNumberGenerator& __urng,
2697	const param_type& __p)
2698	{ typename std::gamma_distribution<result_type>::param_type
2699	__p2(__p.n() / `2`);
2700	this->__generate_impl(__f, __t, __urng, __p2); }
2701
2702	template<typename _UniformRandomNumberGenerator>
2703	void
2704	__generate(result_type* __f, result_type* __t,
2705	_UniformRandomNumberGenerator& __urng)
2706	{ this->__generate_impl(__f, __t, __urng); }
2707
2708	template<typename _UniformRandomNumberGenerator>
2709	void
2710	__generate(result_type* __f, result_type* __t,
2711	_UniformRandomNumberGenerator& __urng,
2712	const param_type& __p)
2713	{ typename std::gamma_distribution<result_type>::param_type
2714	__p2(__p.n() / `2`);
2715	this->__generate_impl(__f, __t, __urng, __p2); }
2716
2717	/**
2718	* @brief Return true if two Chi-squared distributions have
2719	* the same parameters and the sequences that would be
2720	* generated are equal.
2721	*/
2722	friend bool
2723	operator==(const chi_squared_distribution& __d1,
2724	const chi_squared_distribution& __d2)
2725	{ return __d1._M_param == __d2._M_param && __d1._M_gd == __d2._M_gd; }
2726
2727	/**
2728	* @brief Inserts a %chi_squared_distribution random number distribution
2729	* @p __x into the output stream @p __os.
2730	*
2731	* @param __os An output stream.
2732	* @param __x A %chi_squared_distribution random number distribution.
2733	*
2734	* @returns The output stream with the state of @p __x inserted or in
2735	* an error state.
2736	*/
2737	template<typename _RealType1, typename _CharT, typename _Traits>
2738	friend std::basic_ostream<_CharT, _Traits>&
2739	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
2740	const std::chi_squared_distribution<_RealType1>& __x);
2741
2742	/**
2743	* @brief Extracts a %chi_squared_distribution random number distribution
2744	* @p __x from the input stream @p __is.
2745	*
2746	* @param __is An input stream.
2747	* @param __x A %chi_squared_distribution random number
2748	* generator engine.
2749	*
2750	* @returns The input stream with @p __x extracted or in an error state.
2751	*/
2752	template<typename _RealType1, typename _CharT, typename _Traits>
2753	friend std::basic_istream<_CharT, _Traits>&
2754	operator>>(std::basic_istream<_CharT, _Traits>& __is,
2755	std::chi_squared_distribution<_RealType1>& __x);
2756
2757	private:
2758	template<typename _ForwardIterator,
2759	typename _UniformRandomNumberGenerator>
2760	void
2761	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2762	_UniformRandomNumberGenerator& __urng);
2763
2764	template<typename _ForwardIterator,
2765	typename _UniformRandomNumberGenerator>
2766	void
2767	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2768	_UniformRandomNumberGenerator& __urng,
2769	const typename
2770	std::gamma_distribution<result_type>::param_type& __p);
2771
2772	param_type _M_param;
2773
2774	std::gamma_distribution<result_type> _M_gd;
2775	};
2776
2777	/**
2778	* @brief Return true if two Chi-squared distributions are different.
2779	*/
2780	template<typename _RealType>
2781	inline bool
2782	operator!=(const std::chi_squared_distribution<_RealType>& __d1,
2783	const std::chi_squared_distribution<_RealType>& __d2)
2784	{ return !(__d1 == __d2); }
2785
2786
2787	/**
2788	* @brief A cauchy_distribution random number distribution.
2789	*
2790	* The formula for the normal probability mass function is
2791	* @f$p(x\|a,b) = (\pi b (1 + (\frac{x-a}{b})^2))^{-1}@f$
2792	*/
2793	template<typename _RealType = double>
2794	class cauchy_distribution
2795	{
2796	static_assert(std::is_floating_point<_RealType>::value,
2797	"result_type must be a floating point type");
2798
2799	public:
2800	/* The type of the range of the distribution. /
2801	typedef _RealType result_type;
2802
2803	/* Parameter type. /
2804	struct param_type
2805	{
2806	typedef cauchy_distribution<_RealType> distribution_type;
2807
2808	explicit
2809	param_type(_RealType __a = _RealType(`0`),
2810	_RealType __b = _RealType(`1`))
2811	: _M_a(__a), _M_b(__b)
2812	{ }
2813
2814	_RealType
2815	a() const
2816	{ return _M_a; }
2817
2818	_RealType
2819	b() const
2820	{ return _M_b; }
2821
2822	friend bool
2823	operator==(const param_type& __p1, const param_type& __p2)
2824	{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
2825
2826	friend bool
2827	operator!=(const param_type& __p1, const param_type& __p2)
2828	{ return !(__p1 == __p2); }
2829
2830	private:
2831	_RealType _M_a;
2832	_RealType _M_b;
2833	};
2834
2835	explicit
2836	cauchy_distribution(_RealType __a = _RealType(`0`),
2837	_RealType __b = _RealType(`1`))
2838	: _M_param(__a, __b)
2839	{ }
2840
2841	explicit
2842	cauchy_distribution(const param_type& __p)
2843	: _M_param(__p)
2844	{ }
2845
2846	/**
2847	* @brief Resets the distribution state.
2848	*/
2849	void
2850	reset()
2851	{ }
2852
2853	/**
2854	*
2855	*/
2856	_RealType
2857	a() const
2858	{ return _M_param.a(); }
2859
2860	_RealType
2861	b() const
2862	{ return _M_param.b(); }
2863
2864	/**
2865	* @brief Returns the parameter set of the distribution.
2866	*/
2867	param_type
2868	param() const
2869	{ return _M_param; }
2870
2871	/**
2872	* @brief Sets the parameter set of the distribution.
2873	* @param __param The new parameter set of the distribution.
2874	*/
2875	void
2876	param(const param_type& __param)
2877	{ _M_param = __param; }
2878
2879	/**
2880	* @brief Returns the greatest lower bound value of the distribution.
2881	*/
2882	result_type
2883	min() const
2884	{ return std::numeric_limits<result_type>::lowest(); }
2885
2886	/**
2887	* @brief Returns the least upper bound value of the distribution.
2888	*/
2889	result_type
2890	max() const
2891	{ return std::numeric_limits<result_type>::max(); }
2892
2893	/**
2894	* @brief Generating functions.
2895	*/
2896	template<typename _UniformRandomNumberGenerator>
2897	result_type
2898	operator()(_UniformRandomNumberGenerator& __urng)
2899	{ return this->operator()(__urng, _M_param); }
2900
2901	template<typename _UniformRandomNumberGenerator>
2902	result_type
2903	operator()(_UniformRandomNumberGenerator& __urng,
2904	const param_type& __p);
2905
2906	template<typename _ForwardIterator,
2907	typename _UniformRandomNumberGenerator>
2908	void
2909	__generate(_ForwardIterator __f, _ForwardIterator __t,
2910	_UniformRandomNumberGenerator& __urng)
2911	{ this->__generate(__f, __t, __urng, _M_param); }
2912
2913	template<typename _ForwardIterator,
2914	typename _UniformRandomNumberGenerator>
2915	void
2916	__generate(_ForwardIterator __f, _ForwardIterator __t,
2917	_UniformRandomNumberGenerator& __urng,
2918	const param_type& __p)
2919	{ this->__generate_impl(__f, __t, __urng, __p); }
2920
2921	template<typename _UniformRandomNumberGenerator>
2922	void
2923	__generate(result_type* __f, result_type* __t,
2924	_UniformRandomNumberGenerator& __urng,
2925	const param_type& __p)
2926	{ this->__generate_impl(__f, __t, __urng, __p); }
2927
2928	/**
2929	* @brief Return true if two Cauchy distributions have
2930	* the same parameters.
2931	*/
2932	friend bool
2933	operator==(const cauchy_distribution& __d1,
2934	const cauchy_distribution& __d2)
2935	{ return __d1._M_param == __d2._M_param; }
2936
2937	private:
2938	template<typename _ForwardIterator,
2939	typename _UniformRandomNumberGenerator>
2940	void
2941	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
2942	_UniformRandomNumberGenerator& __urng,
2943	const param_type& __p);
2944
2945	param_type _M_param;
2946	};
2947
2948	/**
2949	* @brief Return true if two Cauchy distributions have
2950	* different parameters.
2951	*/
2952	template<typename _RealType>
2953	inline bool
2954	operator!=(const std::cauchy_distribution<_RealType>& __d1,
2955	const std::cauchy_distribution<_RealType>& __d2)
2956	{ return !(__d1 == __d2); }
2957
2958	/**
2959	* @brief Inserts a %cauchy_distribution random number distribution
2960	* @p __x into the output stream @p __os.
2961	*
2962	* @param __os An output stream.
2963	* @param __x A %cauchy_distribution random number distribution.
2964	*
2965	* @returns The output stream with the state of @p __x inserted or in
2966	* an error state.
2967	*/
2968	template<typename _RealType, typename _CharT, typename _Traits>
2969	std::basic_ostream<_CharT, _Traits>&
2970	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
2971	const std::cauchy_distribution<_RealType>& __x);
2972
2973	/**
2974	* @brief Extracts a %cauchy_distribution random number distribution
2975	* @p __x from the input stream @p __is.
2976	*
2977	* @param __is An input stream.
2978	* @param __x A %cauchy_distribution random number
2979	* generator engine.
2980	*
2981	* @returns The input stream with @p __x extracted or in an error state.
2982	*/
2983	template<typename _RealType, typename _CharT, typename _Traits>
2984	std::basic_istream<_CharT, _Traits>&
2985	operator>>(std::basic_istream<_CharT, _Traits>& __is,
2986	std::cauchy_distribution<_RealType>& __x);
2987
2988
2989	/**
2990	* @brief A fisher_f_distribution random number distribution.
2991	*
2992	* The formula for the normal probability mass function is
2993	* @f[
2994	* p(x\|m,n) = \frac{\Gamma((m+n)/2)}{\Gamma(m/2)\Gamma(n/2)}
2995	* (\frac{m}{n})^{m/2} x^{(m/2)-1}
2996	* (1 + \frac{mx}{n})^{-(m+n)/2}
2997	* @f]
2998	*/
2999	template<typename _RealType = double>
3000	class fisher_f_distribution
3001	{
3002	static_assert(std::is_floating_point<_RealType>::value,
3003	"result_type must be a floating point type");
3004
3005	public:
3006	/* The type of the range of the distribution. /
3007	typedef _RealType result_type;
3008
3009	/* Parameter type. /
3010	struct param_type
3011	{
3012	typedef fisher_f_distribution<_RealType> distribution_type;
3013
3014	explicit
3015	param_type(_RealType __m = _RealType(`1`),
3016	_RealType __n = _RealType(`1`))
3017	: _M_m(__m), _M_n(__n)
3018	{ }
3019
3020	_RealType
3021	m() const
3022	{ return _M_m; }
3023
3024	_RealType
3025	n() const
3026	{ return _M_n; }
3027
3028	friend bool
3029	operator==(const param_type& __p1, const param_type& __p2)
3030	{ return __p1._M_m == __p2._M_m && __p1._M_n == __p2._M_n; }
3031
3032	friend bool
3033	operator!=(const param_type& __p1, const param_type& __p2)
3034	{ return !(__p1 == __p2); }
3035
3036	private:
3037	_RealType _M_m;
3038	_RealType _M_n;
3039	};
3040
3041	explicit
3042	fisher_f_distribution(_RealType __m = _RealType(`1`),
3043	_RealType __n = _RealType(`1`))
3044	: _M_param(__m, __n), _M_gd_x(__m / `2`), _M_gd_y(__n / `2`)
3045	{ }
3046
3047	explicit
3048	fisher_f_distribution(const param_type& __p)
3049	: _M_param(__p), _M_gd_x(__p.m() / `2`), _M_gd_y(__p.n() / `2`)
3050	{ }
3051
3052	/**
3053	* @brief Resets the distribution state.
3054	*/
3055	void
3056	reset()
3057	{
3058	_M_gd_x.reset();
3059	_M_gd_y.reset();
3060	}
3061
3062	/**
3063	*
3064	*/
3065	_RealType
3066	m() const
3067	{ return _M_param.m(); }
3068
3069	_RealType
3070	n() const
3071	{ return _M_param.n(); }
3072
3073	/**
3074	* @brief Returns the parameter set of the distribution.
3075	*/
3076	param_type
3077	param() const
3078	{ return _M_param; }
3079
3080	/**
3081	* @brief Sets the parameter set of the distribution.
3082	* @param __param The new parameter set of the distribution.
3083	*/
3084	void
3085	param(const param_type& __param)
3086	{ _M_param = __param; }
3087
3088	/**
3089	* @brief Returns the greatest lower bound value of the distribution.
3090	*/
3091	result_type
3092	min() const
3093	{ return result_type(`0`); }
3094
3095	/**
3096	* @brief Returns the least upper bound value of the distribution.
3097	*/
3098	result_type
3099	max() const
3100	{ return std::numeric_limits<result_type>::max(); }
3101
3102	/**
3103	* @brief Generating functions.
3104	*/
3105	template<typename _UniformRandomNumberGenerator>
3106	result_type
3107	operator()(_UniformRandomNumberGenerator& __urng)
3108	{ return (_M_gd_x(__urng) * n()) / (_M_gd_y(__urng) * m()); }
3109
3110	template<typename _UniformRandomNumberGenerator>
3111	result_type
3112	operator()(_UniformRandomNumberGenerator& __urng,
3113	const param_type& __p)
3114	{
3115	typedef typename std::gamma_distribution<result_type>::param_type
3116	param_type;
3117	return ((_M_gd_x(__urng, param_type(__p.m() / `2`)) * n())
3118	/ (_M_gd_y(__urng, param_type(__p.n() / `2`)) * m()));
3119	}
3120
3121	template<typename _ForwardIterator,
3122	typename _UniformRandomNumberGenerator>
3123	void
3124	__generate(_ForwardIterator __f, _ForwardIterator __t,
3125	_UniformRandomNumberGenerator& __urng)
3126	{ this->__generate_impl(__f, __t, __urng); }
3127
3128	template<typename _ForwardIterator,
3129	typename _UniformRandomNumberGenerator>
3130	void
3131	__generate(_ForwardIterator __f, _ForwardIterator __t,
3132	_UniformRandomNumberGenerator& __urng,
3133	const param_type& __p)
3134	{ this->__generate_impl(__f, __t, __urng, __p); }
3135
3136	template<typename _UniformRandomNumberGenerator>
3137	void
3138	__generate(result_type* __f, result_type* __t,
3139	_UniformRandomNumberGenerator& __urng)
3140	{ this->__generate_impl(__f, __t, __urng); }
3141
3142	template<typename _UniformRandomNumberGenerator>
3143	void
3144	__generate(result_type* __f, result_type* __t,
3145	_UniformRandomNumberGenerator& __urng,
3146	const param_type& __p)
3147	{ this->__generate_impl(__f, __t, __urng, __p); }
3148
3149	/**
3150	* @brief Return true if two Fisher f distributions have
3151	* the same parameters and the sequences that would
3152	* be generated are equal.
3153	*/
3154	friend bool
3155	operator==(const fisher_f_distribution& __d1,
3156	const fisher_f_distribution& __d2)
3157	{ return (__d1._M_param == __d2._M_param
3158	&& __d1._M_gd_x == __d2._M_gd_x
3159	&& __d1._M_gd_y == __d2._M_gd_y); }
3160
3161	/**
3162	* @brief Inserts a %fisher_f_distribution random number distribution
3163	* @p __x into the output stream @p __os.
3164	*
3165	* @param __os An output stream.
3166	* @param __x A %fisher_f_distribution random number distribution.
3167	*
3168	* @returns The output stream with the state of @p __x inserted or in
3169	* an error state.
3170	*/
3171	template<typename _RealType1, typename _CharT, typename _Traits>
3172	friend std::basic_ostream<_CharT, _Traits>&
3173	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
3174	const std::fisher_f_distribution<_RealType1>& __x);
3175
3176	/**
3177	* @brief Extracts a %fisher_f_distribution random number distribution
3178	* @p __x from the input stream @p __is.
3179	*
3180	* @param __is An input stream.
3181	* @param __x A %fisher_f_distribution random number
3182	* generator engine.
3183	*
3184	* @returns The input stream with @p __x extracted or in an error state.
3185	*/
3186	template<typename _RealType1, typename _CharT, typename _Traits>
3187	friend std::basic_istream<_CharT, _Traits>&
3188	operator>>(std::basic_istream<_CharT, _Traits>& __is,
3189	std::fisher_f_distribution<_RealType1>& __x);
3190
3191	private:
3192	template<typename _ForwardIterator,
3193	typename _UniformRandomNumberGenerator>
3194	void
3195	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3196	_UniformRandomNumberGenerator& __urng);
3197
3198	template<typename _ForwardIterator,
3199	typename _UniformRandomNumberGenerator>
3200	void
3201	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3202	_UniformRandomNumberGenerator& __urng,
3203	const param_type& __p);
3204
3205	param_type _M_param;
3206
3207	std::gamma_distribution<result_type> _M_gd_x, _M_gd_y;
3208	};
3209
3210	/**
3211	* @brief Return true if two Fisher f distributions are different.
3212	*/
3213	template<typename _RealType>
3214	inline bool
3215	operator!=(const std::fisher_f_distribution<_RealType>& __d1,
3216	const std::fisher_f_distribution<_RealType>& __d2)
3217	{ return !(__d1 == __d2); }
3218
3219	/**
3220	* @brief A student_t_distribution random number distribution.
3221	*
3222	* The formula for the normal probability mass function is:
3223	* @f[
3224	* p(x\|n) = \frac{1}{\sqrt(n\pi)} \frac{\Gamma((n+1)/2)}{\Gamma(n/2)}
3225	* (1 + \frac{x^2}{n}) ^{-(n+1)/2}
3226	* @f]
3227	*/
3228	template<typename _RealType = double>
3229	class student_t_distribution
3230	{
3231	static_assert(std::is_floating_point<_RealType>::value,
3232	"result_type must be a floating point type");
3233
3234	public:
3235	/* The type of the range of the distribution. /
3236	typedef _RealType result_type;
3237
3238	/* Parameter type. /
3239	struct param_type
3240	{
3241	typedef student_t_distribution<_RealType> distribution_type;
3242
3243	explicit
3244	param_type(_RealType __n = _RealType(`1`))
3245	: _M_n(__n)
3246	{ }
3247
3248	_RealType
3249	n() const
3250	{ return _M_n; }
3251
3252	friend bool
3253	operator==(const param_type& __p1, const param_type& __p2)
3254	{ return __p1._M_n == __p2._M_n; }
3255
3256	friend bool
3257	operator!=(const param_type& __p1, const param_type& __p2)
3258	{ return !(__p1 == __p2); }
3259
3260	private:
3261	_RealType _M_n;
3262	};
3263
3264	explicit
3265	student_t_distribution(_RealType __n = _RealType(`1`))
3266	: _M_param(__n), _M_nd(), _M_gd(__n / `2`, `2`)
3267	{ }
3268
3269	explicit
3270	student_t_distribution(const param_type& __p)
3271	: _M_param(__p), _M_nd(), _M_gd(__p.n() / `2`, `2`)
3272	{ }
3273
3274	/**
3275	* @brief Resets the distribution state.
3276	*/
3277	void
3278	reset()
3279	{
3280	_M_nd.reset();
3281	_M_gd.reset();
3282	}
3283
3284	/**
3285	*
3286	*/
3287	_RealType
3288	n() const
3289	{ return _M_param.n(); }
3290
3291	/**
3292	* @brief Returns the parameter set of the distribution.
3293	*/
3294	param_type
3295	param() const
3296	{ return _M_param; }
3297
3298	/**
3299	* @brief Sets the parameter set of the distribution.
3300	* @param __param The new parameter set of the distribution.
3301	*/
3302	void
3303	param(const param_type& __param)
3304	{ _M_param = __param; }
3305
3306	/**
3307	* @brief Returns the greatest lower bound value of the distribution.
3308	*/
3309	result_type
3310	min() const
3311	{ return std::numeric_limits<result_type>::lowest(); }
3312
3313	/**
3314	* @brief Returns the least upper bound value of the distribution.
3315	*/
3316	result_type
3317	max() const
3318	{ return std::numeric_limits<result_type>::max(); }
3319
3320	/**
3321	* @brief Generating functions.
3322	*/
3323	template<typename _UniformRandomNumberGenerator>
3324	result_type
3325	operator()(_UniformRandomNumberGenerator& __urng)
3326	{ return _M_nd(__urng) * std::sqrt(n() / _M_gd(__urng)); }
3327
3328	template<typename _UniformRandomNumberGenerator>
3329	result_type
3330	operator()(_UniformRandomNumberGenerator& __urng,
3331	const param_type& __p)
3332	{
3333	typedef typename std::gamma_distribution<result_type>::param_type
3334	param_type;
3335
3336	const result_type __g = _M_gd(__urng, param_type(__p.n() / `2`, `2`));
3337	return _M_nd(__urng) * std::sqrt(__p.n() / __g);
3338	}
3339
3340	template<typename _ForwardIterator,
3341	typename _UniformRandomNumberGenerator>
3342	void
3343	__generate(_ForwardIterator __f, _ForwardIterator __t,
3344	_UniformRandomNumberGenerator& __urng)
3345	{ this->__generate_impl(__f, __t, __urng); }
3346
3347	template<typename _ForwardIterator,
3348	typename _UniformRandomNumberGenerator>
3349	void
3350	__generate(_ForwardIterator __f, _ForwardIterator __t,
3351	_UniformRandomNumberGenerator& __urng,
3352	const param_type& __p)
3353	{ this->__generate_impl(__f, __t, __urng, __p); }
3354
3355	template<typename _UniformRandomNumberGenerator>
3356	void
3357	__generate(result_type* __f, result_type* __t,
3358	_UniformRandomNumberGenerator& __urng)
3359	{ this->__generate_impl(__f, __t, __urng); }
3360
3361	template<typename _UniformRandomNumberGenerator>
3362	void
3363	__generate(result_type* __f, result_type* __t,
3364	_UniformRandomNumberGenerator& __urng,
3365	const param_type& __p)
3366	{ this->__generate_impl(__f, __t, __urng, __p); }
3367
3368	/**
3369	* @brief Return true if two Student t distributions have
3370	* the same parameters and the sequences that would
3371	* be generated are equal.
3372	*/
3373	friend bool
3374	operator==(const student_t_distribution& __d1,
3375	const student_t_distribution& __d2)
3376	{ return (__d1._M_param == __d2._M_param
3377	&& __d1._M_nd == __d2._M_nd && __d1._M_gd == __d2._M_gd); }
3378
3379	/**
3380	* @brief Inserts a %student_t_distribution random number distribution
3381	* @p __x into the output stream @p __os.
3382	*
3383	* @param __os An output stream.
3384	* @param __x A %student_t_distribution random number distribution.
3385	*
3386	* @returns The output stream with the state of @p __x inserted or in
3387	* an error state.
3388	*/
3389	template<typename _RealType1, typename _CharT, typename _Traits>
3390	friend std::basic_ostream<_CharT, _Traits>&
3391	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
3392	const std::student_t_distribution<_RealType1>& __x);
3393
3394	/**
3395	* @brief Extracts a %student_t_distribution random number distribution
3396	* @p __x from the input stream @p __is.
3397	*
3398	* @param __is An input stream.
3399	* @param __x A %student_t_distribution random number
3400	* generator engine.
3401	*
3402	* @returns The input stream with @p __x extracted or in an error state.
3403	*/
3404	template<typename _RealType1, typename _CharT, typename _Traits>
3405	friend std::basic_istream<_CharT, _Traits>&
3406	operator>>(std::basic_istream<_CharT, _Traits>& __is,
3407	std::student_t_distribution<_RealType1>& __x);
3408
3409	private:
3410	template<typename _ForwardIterator,
3411	typename _UniformRandomNumberGenerator>
3412	void
3413	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3414	_UniformRandomNumberGenerator& __urng);
3415	template<typename _ForwardIterator,
3416	typename _UniformRandomNumberGenerator>
3417	void
3418	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3419	_UniformRandomNumberGenerator& __urng,
3420	const param_type& __p);
3421
3422	param_type _M_param;
3423
3424	std::normal_distribution<result_type> _M_nd;
3425	std::gamma_distribution<result_type> _M_gd;
3426	};
3427
3428	/**
3429	* @brief Return true if two Student t distributions are different.
3430	*/
3431	template<typename _RealType>
3432	inline bool
3433	operator!=(const std::student_t_distribution<_RealType>& __d1,
3434	const std::student_t_distribution<_RealType>& __d2)
3435	{ return !(__d1 == __d2); }
3436
3437
3438	/ @} / // group random_distributions_normal
3439
3440	/**
3441	* @addtogroup random_distributions_bernoulli Bernoulli Distributions
3442	* @ingroup random_distributions
3443	* @{
3444	*/
3445
3446	/**
3447	* @brief A Bernoulli random number distribution.
3448	*
3449	* Generates a sequence of true and false values with likelihood @f$p@f$
3450	* that true will come up and @f$(1 - p)@f$ that false will appear.
3451	*/
3452	class bernoulli_distribution
3453	{
3454	public:
3455	/* The type of the range of the distribution. /
3456	typedef bool result_type;
3457
3458	/* Parameter type. /
3459	struct param_type
3460	{
3461	typedef bernoulli_distribution distribution_type;
3462
3463	explicit
3464	param_type(double __p = `0.5`)
3465	: _M_p(__p)
3466	{
3467	__glibcxx_assert((_M_p >= `0.0`) && (_M_p <= `1.0`));
3468	}
3469
3470	double
3471	p() const
3472	{ return _M_p; }
3473
3474	friend bool
3475	operator==(const param_type& __p1, const param_type& __p2)
3476	{ return __p1._M_p == __p2._M_p; }
3477
3478	friend bool
3479	operator!=(const param_type& __p1, const param_type& __p2)
3480	{ return !(__p1 == __p2); }
3481
3482	private:
3483	double _M_p;
3484	};
3485
3486	public:
3487	/**
3488	* @brief Constructs a Bernoulli distribution with likelihood @p p.
3489	*
3490	* @param __p [IN] The likelihood of a true result being returned.
3491	* Must be in the interval @f$[0, 1]@f$.
3492	*/
3493	explicit
3494	bernoulli_distribution(double __p = `0.5`)
3495	: _M_param (__p)
3496	{ }
3497
3498	explicit
3499	bernoulli_distribution(const param_type& __p)
3500	: _M_param (__p)
3501	{ }
3502
3503	/**
3504	* @brief Resets the distribution state.
3505	*
3506	* Does nothing for a Bernoulli distribution.
3507	*/
3508	void
3509	reset() { }
3510
3511	/**
3512	* @brief Returns the @p p parameter of the distribution.
3513	*/
3514	double
3515	p() const
3516	{ return _M_param.p(); }
3517
3518	/**
3519	* @brief Returns the parameter set of the distribution.
3520	*/
3521	param_type
3522	param() const
3523	{ return _M_param; }
3524
3525	/**
3526	* @brief Sets the parameter set of the distribution.
3527	* @param __param The new parameter set of the distribution.
3528	*/
3529	void
3530	param(const param_type& __param)
3531	{ _M_param = __param; }
3532
3533	/**
3534	* @brief Returns the greatest lower bound value of the distribution.
3535	*/
3536	result_type
3537	min() const
3538	{ return std::numeric_limits<result_type>::min(); }
3539
3540	/**
3541	* @brief Returns the least upper bound value of the distribution.
3542	*/
3543	result_type
3544	max() const
3545	{ return std::numeric_limits<result_type>::max(); }
3546
3547	/**
3548	* @brief Generating functions.
3549	*/
3550	template<typename _UniformRandomNumberGenerator>
3551	result_type
3552	operator()(_UniformRandomNumberGenerator& __urng)
3553	{ return this->operator()(__urng, _M_param); }
3554
3555	template<typename _UniformRandomNumberGenerator>
3556	result_type
3557	operator()(_UniformRandomNumberGenerator& __urng,
3558	const param_type& __p)
3559	{
3560	__detail::_Adaptor<_UniformRandomNumberGenerator, double>
3561	__aurng(__urng);
3562	if ((__aurng() - __aurng.min())
3563	< __p.p() * (__aurng.max() - __aurng.min()))
3564	return true;
3565	return false;
3566	}
3567
3568	template<typename _ForwardIterator,
3569	typename _UniformRandomNumberGenerator>
3570	void
3571	__generate(_ForwardIterator __f, _ForwardIterator __t,
3572	_UniformRandomNumberGenerator& __urng)
3573	{ this->__generate(__f, __t, __urng, _M_param); }
3574
3575	template<typename _ForwardIterator,
3576	typename _UniformRandomNumberGenerator>
3577	void
3578	__generate(_ForwardIterator __f, _ForwardIterator __t,
3579	_UniformRandomNumberGenerator& __urng, const param_type& __p)
3580	{ this->__generate_impl(__f, __t, __urng, __p); }
3581
3582	template<typename _UniformRandomNumberGenerator>
3583	void
3584	__generate(result_type* __f, result_type* __t,
3585	_UniformRandomNumberGenerator& __urng,
3586	const param_type& __p)
3587	{ this->__generate_impl(__f, __t, __urng, __p); }
3588
3589	/**
3590	* @brief Return true if two Bernoulli distributions have
3591	* the same parameters.
3592	*/
3593	friend bool
3594	operator==(const bernoulli_distribution& __d1,
3595	const bernoulli_distribution& __d2)
3596	{ return __d1._M_param == __d2._M_param; }
3597
3598	private:
3599	template<typename _ForwardIterator,
3600	typename _UniformRandomNumberGenerator>
3601	void
3602	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3603	_UniformRandomNumberGenerator& __urng,
3604	const param_type& __p);
3605
3606	param_type _M_param;
3607	};
3608
3609	/**
3610	* @brief Return true if two Bernoulli distributions have
3611	* different parameters.
3612	*/
3613	inline bool
3614	operator!=(const std::bernoulli_distribution& __d1,
3615	const std::bernoulli_distribution& __d2)
3616	{ return !(__d1 == __d2); }
3617
3618	/**
3619	* @brief Inserts a %bernoulli_distribution random number distribution
3620	* @p __x into the output stream @p __os.
3621	*
3622	* @param __os An output stream.
3623	* @param __x A %bernoulli_distribution random number distribution.
3624	*
3625	* @returns The output stream with the state of @p __x inserted or in
3626	* an error state.
3627	*/
3628	template<typename _CharT, typename _Traits>
3629	std::basic_ostream<_CharT, _Traits>&
3630	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
3631	const std::bernoulli_distribution& __x);
3632
3633	/**
3634	* @brief Extracts a %bernoulli_distribution random number distribution
3635	* @p __x from the input stream @p __is.
3636	*
3637	* @param __is An input stream.
3638	* @param __x A %bernoulli_distribution random number generator engine.
3639	*
3640	* @returns The input stream with @p __x extracted or in an error state.
3641	*/
3642	template<typename _CharT, typename _Traits>
3643	std::basic_istream<_CharT, _Traits>&
3644	operator>>(std::basic_istream<_CharT, _Traits>& __is,
3645	std::bernoulli_distribution& __x)
3646	{
3647	double __p;
3648	__is >> __p;
3649	__x.param(bernoulli_distribution::param_type (__p));
3650	return __is;
3651	}
3652
3653
3654	/**
3655	* @brief A discrete binomial random number distribution.
3656	*
3657	* The formula for the binomial probability density function is
3658	* @f$p(i\|t,p) = \binom{t}{i} p^i (1 - p)^{t - i}@f$ where @f$t@f$
3659	* and @f$p@f$ are the parameters of the distribution.
3660	*/
3661	template<typename _IntType = int>
3662	class binomial_distribution
3663	{
3664	static_assert(std::is_integral<_IntType>::value,
3665	"result_type must be an integral type");
3666
3667	public:
3668	/* The type of the range of the distribution. /
3669	typedef _IntType result_type;
3670
3671	/* Parameter type. /
3672	struct param_type
3673	{
3674	typedef binomial_distribution<_IntType> distribution_type;
3675	friend class binomial_distribution<_IntType>;
3676
3677	explicit
3678	param_type(_IntType __t = _IntType(`1`), double __p = `0.5`)
3679	: _M_t(__t), _M_p(__p)
3680	{
3681	__glibcxx_assert((_M_t >= _IntType(`0`))
3682	&& (_M_p >= `0.0`)
3683	&& (_M_p <= `1.0`));
3684	_M_initialize();
3685	}
3686
3687	_IntType
3688	t() const
3689	{ return _M_t; }
3690
3691	double
3692	p() const
3693	{ return _M_p; }
3694
3695	friend bool
3696	operator==(const param_type& __p1, const param_type& __p2)
3697	{ return __p1._M_t == __p2._M_t && __p1._M_p == __p2._M_p; }
3698
3699	friend bool
3700	operator!=(const param_type& __p1, const param_type& __p2)
3701	{ return !(__p1 == __p2); }
3702
3703	private:
3704	void
3705	_M_initialize();
3706
3707	_IntType _M_t;
3708	double _M_p;
3709
3710	double _M_q;
3711	#if _GLIBCXX_USE_C99_MATH_TR1
3712	double _M_d1, _M_d2, _M_s1, _M_s2, _M_c,
3713	_M_a1, _M_a123, _M_s, _M_lf, _M_lp1p;
3714	#endif
3715	bool _M_easy;
3716	};
3717
3718	// constructors and member function
3719	explicit
3720	binomial_distribution(_IntType __t = _IntType(`1`),
3721	double __p = `0.5`)
3722	: _M_param(__t, __p), _M_nd ()
3723	{ }
3724
3725	explicit
3726	binomial_distribution(const param_type& __p)
3727	: _M_param(__p), _M_nd ()
3728	{ }
3729
3730	/**
3731	* @brief Resets the distribution state.
3732	*/
3733	void
3734	reset()
3735	{ _M_nd.reset(); }
3736
3737	/**
3738	* @brief Returns the distribution @p t parameter.
3739	*/
3740	_IntType
3741	t() const
3742	{ return _M_param.t(); }
3743
3744	/**
3745	* @brief Returns the distribution @p p parameter.
3746	*/
3747	double
3748	p() const
3749	{ return _M_param.p(); }
3750
3751	/**
3752	* @brief Returns the parameter set of the distribution.
3753	*/
3754	param_type
3755	param() const
3756	{ return _M_param; }
3757
3758	/**
3759	* @brief Sets the parameter set of the distribution.
3760	* @param __param The new parameter set of the distribution.
3761	*/
3762	void
3763	param(const param_type& __param)
3764	{ _M_param = __param; }
3765
3766	/**
3767	* @brief Returns the greatest lower bound value of the distribution.
3768	*/
3769	result_type
3770	min() const
3771	{ return `0`; }
3772
3773	/**
3774	* @brief Returns the least upper bound value of the distribution.
3775	*/
3776	result_type
3777	max() const
3778	{ return _M_param.t(); }
3779
3780	/**
3781	* @brief Generating functions.
3782	*/
3783	template<typename _UniformRandomNumberGenerator>
3784	result_type
3785	operator()(_UniformRandomNumberGenerator& __urng)
3786	{ return this->operator()(__urng, _M_param); }
3787
3788	template<typename _UniformRandomNumberGenerator>
3789	result_type
3790	operator()(_UniformRandomNumberGenerator& __urng,
3791	const param_type& __p);
3792
3793	template<typename _ForwardIterator,
3794	typename _UniformRandomNumberGenerator>
3795	void
3796	__generate(_ForwardIterator __f, _ForwardIterator __t,
3797	_UniformRandomNumberGenerator& __urng)
3798	{ this->__generate(__f, __t, __urng, _M_param); }
3799
3800	template<typename _ForwardIterator,
3801	typename _UniformRandomNumberGenerator>
3802	void
3803	__generate(_ForwardIterator __f, _ForwardIterator __t,
3804	_UniformRandomNumberGenerator& __urng,
3805	const param_type& __p)
3806	{ this->__generate_impl(__f, __t, __urng, __p); }
3807
3808	template<typename _UniformRandomNumberGenerator>
3809	void
3810	__generate(result_type* __f, result_type* __t,
3811	_UniformRandomNumberGenerator& __urng,
3812	const param_type& __p)
3813	{ this->__generate_impl(__f, __t, __urng, __p); }
3814
3815	/**
3816	* @brief Return true if two binomial distributions have
3817	* the same parameters and the sequences that would
3818	* be generated are equal.
3819	*/
3820	friend bool
3821	operator==(const binomial_distribution& __d1,
3822	const binomial_distribution& __d2)
3823	#ifdef _GLIBCXX_USE_C99_MATH_TR1
3824	{ return __d1._M_param == __d2._M_param && __d1._M_nd == __d2._M_nd; }
3825	#else
3826	{ return __d1._M_param == __d2._M_param; }
3827	#endif
3828
3829	/**
3830	* @brief Inserts a %binomial_distribution random number distribution
3831	* @p __x into the output stream @p __os.
3832	*
3833	* @param __os An output stream.
3834	* @param __x A %binomial_distribution random number distribution.
3835	*
3836	* @returns The output stream with the state of @p __x inserted or in
3837	* an error state.
3838	*/
3839	template<typename _IntType1,
3840	typename _CharT, typename _Traits>
3841	friend std::basic_ostream<_CharT, _Traits>&
3842	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
3843	const std::binomial_distribution<_IntType1>& __x);
3844
3845	/**
3846	* @brief Extracts a %binomial_distribution random number distribution
3847	* @p __x from the input stream @p __is.
3848	*
3849	* @param __is An input stream.
3850	* @param __x A %binomial_distribution random number generator engine.
3851	*
3852	* @returns The input stream with @p __x extracted or in an error
3853	* state.
3854	*/
3855	template<typename _IntType1,
3856	typename _CharT, typename _Traits>
3857	friend std::basic_istream<_CharT, _Traits>&
3858	operator>>(std::basic_istream<_CharT, _Traits>& __is,
3859	std::binomial_distribution<_IntType1>& __x);
3860
3861	private:
3862	template<typename _ForwardIterator,
3863	typename _UniformRandomNumberGenerator>
3864	void
3865	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
3866	_UniformRandomNumberGenerator& __urng,
3867	const param_type& __p);
3868
3869	template<typename _UniformRandomNumberGenerator>
3870	result_type
3871	_M_waiting(_UniformRandomNumberGenerator& __urng,
3872	_IntType __t, double __q);
3873
3874	param_type _M_param;
3875
3876	// NB: Unused when _GLIBCXX_USE_C99_MATH_TR1 is undefined.
3877	std::normal_distribution<double> _M_nd;
3878	};
3879
3880	/**
3881	* @brief Return true if two binomial distributions are different.
3882	*/
3883	template<typename _IntType>
3884	inline bool
3885	operator!=(const std::binomial_distribution<_IntType>& __d1,
3886	const std::binomial_distribution<_IntType>& __d2)
3887	{ return !(__d1 == __d2); }
3888
3889
3890	/**
3891	* @brief A discrete geometric random number distribution.
3892	*
3893	* The formula for the geometric probability density function is
3894	* @f$p(i\|p) = p(1 - p)^{i}@f$ where @f$p@f$ is the parameter of the
3895	* distribution.
3896	*/
3897	template<typename _IntType = int>
3898	class geometric_distribution
3899	{
3900	static_assert(std::is_integral<_IntType>::value,
3901	"result_type must be an integral type");
3902
3903	public:
3904	/* The type of the range of the distribution. /
3905	typedef _IntType result_type;
3906
3907	/* Parameter type. /
3908	struct param_type
3909	{
3910	typedef geometric_distribution<_IntType> distribution_type;
3911	friend class geometric_distribution<_IntType>;
3912
3913	explicit
3914	param_type(double __p = `0.5`)
3915	: _M_p(__p)
3916	{
3917	__glibcxx_assert((_M_p > `0.0`) && (_M_p < `1.0`));
3918	_M_initialize();
3919	}
3920
3921	double
3922	p() const
3923	{ return _M_p; }
3924
3925	friend bool
3926	operator==(const param_type& __p1, const param_type& __p2)
3927	{ return __p1._M_p == __p2._M_p; }
3928
3929	friend bool
3930	operator!=(const param_type& __p1, const param_type& __p2)
3931	{ return !(__p1 == __p2); }
3932
3933	private:
3934	void
3935	_M_initialize()
3936	{ _M_log_1_p = std::log(`1.0` - _M_p); }
3937
3938	double _M_p;
3939
3940	double _M_log_1_p;
3941	};
3942
3943	// constructors and member function
3944	explicit
3945	geometric_distribution(double __p = `0.5`)
3946	: _M_param(__p)
3947	{ }
3948
3949	explicit
3950	geometric_distribution(const param_type& __p)
3951	: _M_param(__p)
3952	{ }
3953
3954	/**
3955	* @brief Resets the distribution state.
3956	*
3957	* Does nothing for the geometric distribution.
3958	*/
3959	void
3960	reset() { }
3961
3962	/**
3963	* @brief Returns the distribution parameter @p p.
3964	*/
3965	double
3966	p() const
3967	{ return _M_param.p(); }
3968
3969	/**
3970	* @brief Returns the parameter set of the distribution.
3971	*/
3972	param_type
3973	param() const
3974	{ return _M_param; }
3975
3976	/**
3977	* @brief Sets the parameter set of the distribution.
3978	* @param __param The new parameter set of the distribution.
3979	*/
3980	void
3981	param(const param_type& __param)
3982	{ _M_param = __param; }
3983
3984	/**
3985	* @brief Returns the greatest lower bound value of the distribution.
3986	*/
3987	result_type
3988	min() const
3989	{ return `0`; }
3990
3991	/**
3992	* @brief Returns the least upper bound value of the distribution.
3993	*/
3994	result_type
3995	max() const
3996	{ return std::numeric_limits<result_type>::max(); }
3997
3998	/**
3999	* @brief Generating functions.
4000	*/
4001	template<typename _UniformRandomNumberGenerator>
4002	result_type
4003	operator()(_UniformRandomNumberGenerator& __urng)
4004	{ return this->operator()(__urng, _M_param); }
4005
4006	template<typename _UniformRandomNumberGenerator>
4007	result_type
4008	operator()(_UniformRandomNumberGenerator& __urng,
4009	const param_type& __p);
4010
4011	template<typename _ForwardIterator,
4012	typename _UniformRandomNumberGenerator>
4013	void
4014	__generate(_ForwardIterator __f, _ForwardIterator __t,
4015	_UniformRandomNumberGenerator& __urng)
4016	{ this->__generate(__f, __t, __urng, _M_param); }
4017
4018	template<typename _ForwardIterator,
4019	typename _UniformRandomNumberGenerator>
4020	void
4021	__generate(_ForwardIterator __f, _ForwardIterator __t,
4022	_UniformRandomNumberGenerator& __urng,
4023	const param_type& __p)
4024	{ this->__generate_impl(__f, __t, __urng, __p); }
4025
4026	template<typename _UniformRandomNumberGenerator>
4027	void
4028	__generate(result_type* __f, result_type* __t,
4029	_UniformRandomNumberGenerator& __urng,
4030	const param_type& __p)
4031	{ this->__generate_impl(__f, __t, __urng, __p); }
4032
4033	/**
4034	* @brief Return true if two geometric distributions have
4035	* the same parameters.
4036	*/
4037	friend bool
4038	operator==(const geometric_distribution& __d1,
4039	const geometric_distribution& __d2)
4040	{ return __d1._M_param == __d2._M_param; }
4041
4042	private:
4043	template<typename _ForwardIterator,
4044	typename _UniformRandomNumberGenerator>
4045	void
4046	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4047	_UniformRandomNumberGenerator& __urng,
4048	const param_type& __p);
4049
4050	param_type _M_param;
4051	};
4052
4053	/**
4054	* @brief Return true if two geometric distributions have
4055	* different parameters.
4056	*/
4057	template<typename _IntType>
4058	inline bool
4059	operator!=(const std::geometric_distribution<_IntType>& __d1,
4060	const std::geometric_distribution<_IntType>& __d2)
4061	{ return !(__d1 == __d2); }
4062
4063	/**
4064	* @brief Inserts a %geometric_distribution random number distribution
4065	* @p __x into the output stream @p __os.
4066	*
4067	* @param __os An output stream.
4068	* @param __x A %geometric_distribution random number distribution.
4069	*
4070	* @returns The output stream with the state of @p __x inserted or in
4071	* an error state.
4072	*/
4073	template<typename _IntType,
4074	typename _CharT, typename _Traits>
4075	std::basic_ostream<_CharT, _Traits>&
4076	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
4077	const std::geometric_distribution<_IntType>& __x);
4078
4079	/**
4080	* @brief Extracts a %geometric_distribution random number distribution
4081	* @p __x from the input stream @p __is.
4082	*
4083	* @param __is An input stream.
4084	* @param __x A %geometric_distribution random number generator engine.
4085	*
4086	* @returns The input stream with @p __x extracted or in an error state.
4087	*/
4088	template<typename _IntType,
4089	typename _CharT, typename _Traits>
4090	std::basic_istream<_CharT, _Traits>&
4091	operator>>(std::basic_istream<_CharT, _Traits>& __is,
4092	std::geometric_distribution<_IntType>& __x);
4093
4094
4095	/**
4096	* @brief A negative_binomial_distribution random number distribution.
4097	*
4098	* The formula for the negative binomial probability mass function is
4099	* @f$p(i) = \binom{n}{i} p^i (1 - p)^{t - i}@f$ where @f$t@f$
4100	* and @f$p@f$ are the parameters of the distribution.
4101	*/
4102	template<typename _IntType = int>
4103	class negative_binomial_distribution
4104	{
4105	static_assert(std::is_integral<_IntType>::value,
4106	"result_type must be an integral type");
4107
4108	public:
4109	/* The type of the range of the distribution. /
4110	typedef _IntType result_type;
4111
4112	/* Parameter type. /
4113	struct param_type
4114	{
4115	typedef negative_binomial_distribution<_IntType> distribution_type;
4116
4117	explicit
4118	param_type(_IntType __k = `1`, double __p = `0.5`)
4119	: _M_k(__k), _M_p(__p)
4120	{
4121	__glibcxx_assert((_M_k > `0`) && (_M_p > `0.0`) && (_M_p <= `1.0`));
4122	}
4123
4124	_IntType
4125	k() const
4126	{ return _M_k; }
4127
4128	double
4129	p() const
4130	{ return _M_p; }
4131
4132	friend bool
4133	operator==(const param_type& __p1, const param_type& __p2)
4134	{ return __p1._M_k == __p2._M_k && __p1._M_p == __p2._M_p; }
4135
4136	friend bool
4137	operator!=(const param_type& __p1, const param_type& __p2)
4138	{ return !(__p1 == __p2); }
4139
4140	private:
4141	_IntType _M_k;
4142	double _M_p;
4143	};
4144
4145	explicit
4146	negative_binomial_distribution(_IntType __k = `1`, double __p = `0.5`)
4147	: _M_param(__k, __p), _M_gd(__k, (`1.0` - __p) / __p)
4148	{ }
4149
4150	explicit
4151	negative_binomial_distribution(const param_type& __p)
4152	: _M_param(__p), _M_gd(__p.k(), (`1.0` - __p.p()) / __p.p())
4153	{ }
4154
4155	/**
4156	* @brief Resets the distribution state.
4157	*/
4158	void
4159	reset()
4160	{ _M_gd.reset(); }
4161
4162	/**
4163	* @brief Return the @f$k@f$ parameter of the distribution.
4164	*/
4165	_IntType
4166	k() const
4167	{ return _M_param.k(); }
4168
4169	/**
4170	* @brief Return the @f$p@f$ parameter of the distribution.
4171	*/
4172	double
4173	p() const
4174	{ return _M_param.p(); }
4175
4176	/**
4177	* @brief Returns the parameter set of the distribution.
4178	*/
4179	param_type
4180	param() const
4181	{ return _M_param; }
4182
4183	/**
4184	* @brief Sets the parameter set of the distribution.
4185	* @param __param The new parameter set of the distribution.
4186	*/
4187	void
4188	param(const param_type& __param)
4189	{ _M_param = __param; }
4190
4191	/**
4192	* @brief Returns the greatest lower bound value of the distribution.
4193	*/
4194	result_type
4195	min() const
4196	{ return result_type(`0`); }
4197
4198	/**
4199	* @brief Returns the least upper bound value of the distribution.
4200	*/
4201	result_type
4202	max() const
4203	{ return std::numeric_limits<result_type>::max(); }
4204
4205	/**
4206	* @brief Generating functions.
4207	*/
4208	template<typename _UniformRandomNumberGenerator>
4209	result_type
4210	operator()(_UniformRandomNumberGenerator& __urng);
4211
4212	template<typename _UniformRandomNumberGenerator>
4213	result_type
4214	operator()(_UniformRandomNumberGenerator& __urng,
4215	const param_type& __p);
4216
4217	template<typename _ForwardIterator,
4218	typename _UniformRandomNumberGenerator>
4219	void
4220	__generate(_ForwardIterator __f, _ForwardIterator __t,
4221	_UniformRandomNumberGenerator& __urng)
4222	{ this->__generate_impl(__f, __t, __urng); }
4223
4224	template<typename _ForwardIterator,
4225	typename _UniformRandomNumberGenerator>
4226	void
4227	__generate(_ForwardIterator __f, _ForwardIterator __t,
4228	_UniformRandomNumberGenerator& __urng,
4229	const param_type& __p)
4230	{ this->__generate_impl(__f, __t, __urng, __p); }
4231
4232	template<typename _UniformRandomNumberGenerator>
4233	void
4234	__generate(result_type* __f, result_type* __t,
4235	_UniformRandomNumberGenerator& __urng)
4236	{ this->__generate_impl(__f, __t, __urng); }
4237
4238	template<typename _UniformRandomNumberGenerator>
4239	void
4240	__generate(result_type* __f, result_type* __t,
4241	_UniformRandomNumberGenerator& __urng,
4242	const param_type& __p)
4243	{ this->__generate_impl(__f, __t, __urng, __p); }
4244
4245	/**
4246	* @brief Return true if two negative binomial distributions have
4247	* the same parameters and the sequences that would be
4248	* generated are equal.
4249	*/
4250	friend bool
4251	operator==(const negative_binomial_distribution& __d1,
4252	const negative_binomial_distribution& __d2)
4253	{ return __d1._M_param == __d2._M_param && __d1._M_gd == __d2._M_gd; }
4254
4255	/**
4256	* @brief Inserts a %negative_binomial_distribution random
4257	* number distribution @p __x into the output stream @p __os.
4258	*
4259	* @param __os An output stream.
4260	* @param __x A %negative_binomial_distribution random number
4261	* distribution.
4262	*
4263	* @returns The output stream with the state of @p __x inserted or in
4264	* an error state.
4265	*/
4266	template<typename _IntType1, typename _CharT, typename _Traits>
4267	friend std::basic_ostream<_CharT, _Traits>&
4268	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
4269	const std::negative_binomial_distribution<_IntType1>& __x);
4270
4271	/**
4272	* @brief Extracts a %negative_binomial_distribution random number
4273	* distribution @p __x from the input stream @p __is.
4274	*
4275	* @param __is An input stream.
4276	* @param __x A %negative_binomial_distribution random number
4277	* generator engine.
4278	*
4279	* @returns The input stream with @p __x extracted or in an error state.
4280	*/
4281	template<typename _IntType1, typename _CharT, typename _Traits>
4282	friend std::basic_istream<_CharT, _Traits>&
4283	operator>>(std::basic_istream<_CharT, _Traits>& __is,
4284	std::negative_binomial_distribution<_IntType1>& __x);
4285
4286	private:
4287	template<typename _ForwardIterator,
4288	typename _UniformRandomNumberGenerator>
4289	void
4290	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4291	_UniformRandomNumberGenerator& __urng);
4292	template<typename _ForwardIterator,
4293	typename _UniformRandomNumberGenerator>
4294	void
4295	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4296	_UniformRandomNumberGenerator& __urng,
4297	const param_type& __p);
4298
4299	param_type _M_param;
4300
4301	std::gamma_distribution<double> _M_gd;
4302	};
4303
4304	/**
4305	* @brief Return true if two negative binomial distributions are different.
4306	*/
4307	template<typename _IntType>
4308	inline bool
4309	operator!=(const std::negative_binomial_distribution<_IntType>& __d1,
4310	const std::negative_binomial_distribution<_IntType>& __d2)
4311	{ return !(__d1 == __d2); }
4312
4313
4314	/ @} / // group random_distributions_bernoulli
4315
4316	/**
4317	* @addtogroup random_distributions_poisson Poisson Distributions
4318	* @ingroup random_distributions
4319	* @{
4320	*/
4321
4322	/**
4323	* @brief A discrete Poisson random number distribution.
4324	*
4325	* The formula for the Poisson probability density function is
4326	* @f$p(i\|\mu) = \frac{\mu^i}{i!} e^{-\mu}@f$ where @f$\mu@f$ is the
4327	* parameter of the distribution.
4328	*/
4329	template<typename _IntType = int>
4330	class poisson_distribution
4331	{
4332	static_assert(std::is_integral<_IntType>::value,
4333	"result_type must be an integral type");
4334
4335	public:
4336	/* The type of the range of the distribution. /
4337	typedef _IntType result_type;
4338
4339	/* Parameter type. /
4340	struct param_type
4341	{
4342	typedef poisson_distribution<_IntType> distribution_type;
4343	friend class poisson_distribution<_IntType>;
4344
4345	explicit
4346	param_type(double __mean = `1.0`)
4347	: _M_mean(__mean)
4348	{
4349	__glibcxx_assert(_M_mean > `0.0`);
4350	_M_initialize();
4351	}
4352
4353	double
4354	mean() const
4355	{ return _M_mean; }
4356
4357	friend bool
4358	operator==(const param_type& __p1, const param_type& __p2)
4359	{ return __p1._M_mean == __p2._M_mean; }
4360
4361	friend bool
4362	operator!=(const param_type& __p1, const param_type& __p2)
4363	{ return !(__p1 == __p2); }
4364
4365	private:
4366	// Hosts either log(mean) or the threshold of the simple method.
4367	void
4368	_M_initialize();
4369
4370	double _M_mean;
4371
4372	double _M_lm_thr;
4373	#if _GLIBCXX_USE_C99_MATH_TR1
4374	double _M_lfm, _M_sm, _M_d, _M_scx, _M_1cx, _M_c2b, _M_cb;
4375	#endif
4376	};
4377
4378	// constructors and member function
4379	explicit
4380	poisson_distribution(double __mean = `1.0`)
4381	: _M_param(__mean), _M_nd ()
4382	{ }
4383
4384	explicit
4385	poisson_distribution(const param_type& __p)
4386	: _M_param(__p), _M_nd ()
4387	{ }
4388
4389	/**
4390	* @brief Resets the distribution state.
4391	*/
4392	void
4393	reset()
4394	{ _M_nd.reset(); }
4395
4396	/**
4397	* @brief Returns the distribution parameter @p mean.
4398	*/
4399	double
4400	mean() const
4401	{ return _M_param.mean(); }
4402
4403	/**
4404	* @brief Returns the parameter set of the distribution.
4405	*/
4406	param_type
4407	param() const
4408	{ return _M_param; }
4409
4410	/**
4411	* @brief Sets the parameter set of the distribution.
4412	* @param __param The new parameter set of the distribution.
4413	*/
4414	void
4415	param(const param_type& __param)
4416	{ _M_param = __param; }
4417
4418	/**
4419	* @brief Returns the greatest lower bound value of the distribution.
4420	*/
4421	result_type
4422	min() const
4423	{ return `0`; }
4424
4425	/**
4426	* @brief Returns the least upper bound value of the distribution.
4427	*/
4428	result_type
4429	max() const
4430	{ return std::numeric_limits<result_type>::max(); }
4431
4432	/**
4433	* @brief Generating functions.
4434	*/
4435	template<typename _UniformRandomNumberGenerator>
4436	result_type
4437	operator()(_UniformRandomNumberGenerator& __urng)
4438	{ return this->operator()(__urng, _M_param); }
4439
4440	template<typename _UniformRandomNumberGenerator>
4441	result_type
4442	operator()(_UniformRandomNumberGenerator& __urng,
4443	const param_type& __p);
4444
4445	template<typename _ForwardIterator,
4446	typename _UniformRandomNumberGenerator>
4447	void
4448	__generate(_ForwardIterator __f, _ForwardIterator __t,
4449	_UniformRandomNumberGenerator& __urng)
4450	{ this->__generate(__f, __t, __urng, _M_param); }
4451
4452	template<typename _ForwardIterator,
4453	typename _UniformRandomNumberGenerator>
4454	void
4455	__generate(_ForwardIterator __f, _ForwardIterator __t,
4456	_UniformRandomNumberGenerator& __urng,
4457	const param_type& __p)
4458	{ this->__generate_impl(__f, __t, __urng, __p); }
4459
4460	template<typename _UniformRandomNumberGenerator>
4461	void
4462	__generate(result_type* __f, result_type* __t,
4463	_UniformRandomNumberGenerator& __urng,
4464	const param_type& __p)
4465	{ this->__generate_impl(__f, __t, __urng, __p); }
4466
4467	/**
4468	* @brief Return true if two Poisson distributions have the same
4469	* parameters and the sequences that would be generated
4470	* are equal.
4471	*/
4472	friend bool
4473	operator==(const poisson_distribution& __d1,
4474	const poisson_distribution& __d2)
4475	#ifdef _GLIBCXX_USE_C99_MATH_TR1
4476	{ return __d1._M_param == __d2._M_param && __d1._M_nd == __d2._M_nd; }
4477	#else
4478	{ return __d1._M_param == __d2._M_param; }
4479	#endif
4480
4481	/**
4482	* @brief Inserts a %poisson_distribution random number distribution
4483	* @p __x into the output stream @p __os.
4484	*
4485	* @param __os An output stream.
4486	* @param __x A %poisson_distribution random number distribution.
4487	*
4488	* @returns The output stream with the state of @p __x inserted or in
4489	* an error state.
4490	*/
4491	template<typename _IntType1, typename _CharT, typename _Traits>
4492	friend std::basic_ostream<_CharT, _Traits>&
4493	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
4494	const std::poisson_distribution<_IntType1>& __x);
4495
4496	/**
4497	* @brief Extracts a %poisson_distribution random number distribution
4498	* @p __x from the input stream @p __is.
4499	*
4500	* @param __is An input stream.
4501	* @param __x A %poisson_distribution random number generator engine.
4502	*
4503	* @returns The input stream with @p __x extracted or in an error
4504	* state.
4505	*/
4506	template<typename _IntType1, typename _CharT, typename _Traits>
4507	friend std::basic_istream<_CharT, _Traits>&
4508	operator>>(std::basic_istream<_CharT, _Traits>& __is,
4509	std::poisson_distribution<_IntType1>& __x);
4510
4511	private:
4512	template<typename _ForwardIterator,
4513	typename _UniformRandomNumberGenerator>
4514	void
4515	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4516	_UniformRandomNumberGenerator& __urng,
4517	const param_type& __p);
4518
4519	param_type _M_param;
4520
4521	// NB: Unused when _GLIBCXX_USE_C99_MATH_TR1 is undefined.
4522	std::normal_distribution<double> _M_nd;
4523	};
4524
4525	/**
4526	* @brief Return true if two Poisson distributions are different.
4527	*/
4528	template<typename _IntType>
4529	inline bool
4530	operator!=(const std::poisson_distribution<_IntType>& __d1,
4531	const std::poisson_distribution<_IntType>& __d2)
4532	{ return !(__d1 == __d2); }
4533
4534
4535	/**
4536	* @brief An exponential continuous distribution for random numbers.
4537	*
4538	* The formula for the exponential probability density function is
4539	* @f$p(x\|\lambda) = \lambda e^{-\lambda x}@f$.
4540	*
4541	* <table border=1 cellpadding=10 cellspacing=0>
4542	* <caption align=top>Distribution Statistics</caption>
4543	* <tr><td>Mean</td><td>@f$\frac{1}{\lambda}@f$</td></tr>
4544	* <tr><td>Median</td><td>@f$\frac{\ln 2}{\lambda}@f$</td></tr>
4545	* <tr><td>Mode</td><td>@f$zero@f$</td></tr>
4546	* <tr><td>Range</td><td>@f$[0, \infty]@f$</td></tr>
4547	* <tr><td>Standard Deviation</td><td>@f$\frac{1}{\lambda}@f$</td></tr>
4548	* </table>
4549	*/
4550	template<typename _RealType = double>
4551	class exponential_distribution
4552	{
4553	static_assert(std::is_floating_point<_RealType>::value,
4554	"result_type must be a floating point type");
4555
4556	public:
4557	/* The type of the range of the distribution. /
4558	typedef _RealType result_type;
4559
4560	/* Parameter type. /
4561	struct param_type
4562	{
4563	typedef exponential_distribution<_RealType> distribution_type;
4564
4565	explicit
4566	param_type(_RealType __lambda = _RealType(`1`))
4567	: _M_lambda(__lambda)
4568	{
4569	__glibcxx_assert(_M_lambda > _RealType(`0`));
4570	}
4571
4572	_RealType
4573	lambda() const
4574	{ return _M_lambda; }
4575
4576	friend bool
4577	operator==(const param_type& __p1, const param_type& __p2)
4578	{ return __p1._M_lambda == __p2._M_lambda; }
4579
4580	friend bool
4581	operator!=(const param_type& __p1, const param_type& __p2)
4582	{ return !(__p1 == __p2); }
4583
4584	private:
4585	_RealType _M_lambda;
4586	};
4587
4588	public:
4589	/**
4590	* @brief Constructs an exponential distribution with inverse scale
4591	* parameter @f$\lambda@f$.
4592	*/
4593	explicit
4594	exponential_distribution(const result_type& __lambda = result_type(`1`))
4595	: _M_param(__lambda)
4596	{ }
4597
4598	explicit
4599	exponential_distribution(const param_type& __p)
4600	: _M_param(__p)
4601	{ }
4602
4603	/**
4604	* @brief Resets the distribution state.
4605	*
4606	* Has no effect on exponential distributions.
4607	*/
4608	void
4609	reset() { }
4610
4611	/**
4612	* @brief Returns the inverse scale parameter of the distribution.
4613	*/
4614	_RealType
4615	lambda() const
4616	{ return _M_param.lambda(); }
4617
4618	/**
4619	* @brief Returns the parameter set of the distribution.
4620	*/
4621	param_type
4622	param() const
4623	{ return _M_param; }
4624
4625	/**
4626	* @brief Sets the parameter set of the distribution.
4627	* @param __param The new parameter set of the distribution.
4628	*/
4629	void
4630	param(const param_type& __param)
4631	{ _M_param = __param; }
4632
4633	/**
4634	* @brief Returns the greatest lower bound value of the distribution.
4635	*/
4636	result_type
4637	min() const
4638	{ return result_type(`0`); }
4639
4640	/**
4641	* @brief Returns the least upper bound value of the distribution.
4642	*/
4643	result_type
4644	max() const
4645	{ return std::numeric_limits<result_type>::max(); }
4646
4647	/**
4648	* @brief Generating functions.
4649	*/
4650	template<typename _UniformRandomNumberGenerator>
4651	result_type
4652	operator()(_UniformRandomNumberGenerator& __urng)
4653	{ return this->operator()(__urng, _M_param); }
4654
4655	template<typename _UniformRandomNumberGenerator>
4656	result_type
4657	operator()(_UniformRandomNumberGenerator& __urng,
4658	const param_type& __p)
4659	{
4660	__detail::_Adaptor<_UniformRandomNumberGenerator, result_type>
4661	__aurng(__urng);
4662	return -std::log(result_type(`1`) - __aurng()) / __p.lambda();
4663	}
4664
4665	template<typename _ForwardIterator,
4666	typename _UniformRandomNumberGenerator>
4667	void
4668	__generate(_ForwardIterator __f, _ForwardIterator __t,
4669	_UniformRandomNumberGenerator& __urng)
4670	{ this->__generate(__f, __t, __urng, _M_param); }
4671
4672	template<typename _ForwardIterator,
4673	typename _UniformRandomNumberGenerator>
4674	void
4675	__generate(_ForwardIterator __f, _ForwardIterator __t,
4676	_UniformRandomNumberGenerator& __urng,
4677	const param_type& __p)
4678	{ this->__generate_impl(__f, __t, __urng, __p); }
4679
4680	template<typename _UniformRandomNumberGenerator>
4681	void
4682	__generate(result_type* __f, result_type* __t,
4683	_UniformRandomNumberGenerator& __urng,
4684	const param_type& __p)
4685	{ this->__generate_impl(__f, __t, __urng, __p); }
4686
4687	/**
4688	* @brief Return true if two exponential distributions have the same
4689	* parameters.
4690	*/
4691	friend bool
4692	operator==(const exponential_distribution& __d1,
4693	const exponential_distribution& __d2)
4694	{ return __d1._M_param == __d2._M_param; }
4695
4696	private:
4697	template<typename _ForwardIterator,
4698	typename _UniformRandomNumberGenerator>
4699	void
4700	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4701	_UniformRandomNumberGenerator& __urng,
4702	const param_type& __p);
4703
4704	param_type _M_param;
4705	};
4706
4707	/**
4708	* @brief Return true if two exponential distributions have different
4709	* parameters.
4710	*/
4711	template<typename _RealType>
4712	inline bool
4713	operator!=(const std::exponential_distribution<_RealType>& __d1,
4714	const std::exponential_distribution<_RealType>& __d2)
4715	{ return !(__d1 == __d2); }
4716
4717	/**
4718	* @brief Inserts a %exponential_distribution random number distribution
4719	* @p __x into the output stream @p __os.
4720	*
4721	* @param __os An output stream.
4722	* @param __x A %exponential_distribution random number distribution.
4723	*
4724	* @returns The output stream with the state of @p __x inserted or in
4725	* an error state.
4726	*/
4727	template<typename _RealType, typename _CharT, typename _Traits>
4728	std::basic_ostream<_CharT, _Traits>&
4729	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
4730	const std::exponential_distribution<_RealType>& __x);
4731
4732	/**
4733	* @brief Extracts a %exponential_distribution random number distribution
4734	* @p __x from the input stream @p __is.
4735	*
4736	* @param __is An input stream.
4737	* @param __x A %exponential_distribution random number
4738	* generator engine.
4739	*
4740	* @returns The input stream with @p __x extracted or in an error state.
4741	*/
4742	template<typename _RealType, typename _CharT, typename _Traits>
4743	std::basic_istream<_CharT, _Traits>&
4744	operator>>(std::basic_istream<_CharT, _Traits>& __is,
4745	std::exponential_distribution<_RealType>& __x);
4746
4747
4748	/**
4749	* @brief A weibull_distribution random number distribution.
4750	*
4751	* The formula for the normal probability density function is:
4752	* @f[
4753	* p(x\|\alpha,\beta) = \frac{\alpha}{\beta} (\frac{x}{\beta})^{\alpha-1}
4754	* \exp{(-(\frac{x}{\beta})^\alpha)}
4755	* @f]
4756	*/
4757	template<typename _RealType = double>
4758	class weibull_distribution
4759	{
4760	static_assert(std::is_floating_point<_RealType>::value,
4761	"result_type must be a floating point type");
4762
4763	public:
4764	/* The type of the range of the distribution. /
4765	typedef _RealType result_type;
4766
4767	/* Parameter type. /
4768	struct param_type
4769	{
4770	typedef weibull_distribution<_RealType> distribution_type;
4771
4772	explicit
4773	param_type(_RealType __a = _RealType(`1`),
4774	_RealType __b = _RealType(`1`))
4775	: _M_a(__a), _M_b(__b)
4776	{ }
4777
4778	_RealType
4779	a() const
4780	{ return _M_a; }
4781
4782	_RealType
4783	b() const
4784	{ return _M_b; }
4785
4786	friend bool
4787	operator==(const param_type& __p1, const param_type& __p2)
4788	{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
4789
4790	friend bool
4791	operator!=(const param_type& __p1, const param_type& __p2)
4792	{ return !(__p1 == __p2); }
4793
4794	private:
4795	_RealType _M_a;
4796	_RealType _M_b;
4797	};
4798
4799	explicit
4800	weibull_distribution(_RealType __a = _RealType(`1`),
4801	_RealType __b = _RealType(`1`))
4802	: _M_param(__a, __b)
4803	{ }
4804
4805	explicit
4806	weibull_distribution(const param_type& __p)
4807	: _M_param(__p)
4808	{ }
4809
4810	/**
4811	* @brief Resets the distribution state.
4812	*/
4813	void
4814	reset()
4815	{ }
4816
4817	/**
4818	* @brief Return the @f$a@f$ parameter of the distribution.
4819	*/
4820	_RealType
4821	a() const
4822	{ return _M_param.a(); }
4823
4824	/**
4825	* @brief Return the @f$b@f$ parameter of the distribution.
4826	*/
4827	_RealType
4828	b() const
4829	{ return _M_param.b(); }
4830
4831	/**
4832	* @brief Returns the parameter set of the distribution.
4833	*/
4834	param_type
4835	param() const
4836	{ return _M_param; }
4837
4838	/**
4839	* @brief Sets the parameter set of the distribution.
4840	* @param __param The new parameter set of the distribution.
4841	*/
4842	void
4843	param(const param_type& __param)
4844	{ _M_param = __param; }
4845
4846	/**
4847	* @brief Returns the greatest lower bound value of the distribution.
4848	*/
4849	result_type
4850	min() const
4851	{ return result_type(`0`); }
4852
4853	/**
4854	* @brief Returns the least upper bound value of the distribution.
4855	*/
4856	result_type
4857	max() const
4858	{ return std::numeric_limits<result_type>::max(); }
4859
4860	/**
4861	* @brief Generating functions.
4862	*/
4863	template<typename _UniformRandomNumberGenerator>
4864	result_type
4865	operator()(_UniformRandomNumberGenerator& __urng)
4866	{ return this->operator()(__urng, _M_param); }
4867
4868	template<typename _UniformRandomNumberGenerator>
4869	result_type
4870	operator()(_UniformRandomNumberGenerator& __urng,
4871	const param_type& __p);
4872
4873	template<typename _ForwardIterator,
4874	typename _UniformRandomNumberGenerator>
4875	void
4876	__generate(_ForwardIterator __f, _ForwardIterator __t,
4877	_UniformRandomNumberGenerator& __urng)
4878	{ this->__generate(__f, __t, __urng, _M_param); }
4879
4880	template<typename _ForwardIterator,
4881	typename _UniformRandomNumberGenerator>
4882	void
4883	__generate(_ForwardIterator __f, _ForwardIterator __t,
4884	_UniformRandomNumberGenerator& __urng,
4885	const param_type& __p)
4886	{ this->__generate_impl(__f, __t, __urng, __p); }
4887
4888	template<typename _UniformRandomNumberGenerator>
4889	void
4890	__generate(result_type* __f, result_type* __t,
4891	_UniformRandomNumberGenerator& __urng,
4892	const param_type& __p)
4893	{ this->__generate_impl(__f, __t, __urng, __p); }
4894
4895	/**
4896	* @brief Return true if two Weibull distributions have the same
4897	* parameters.
4898	*/
4899	friend bool
4900	operator==(const weibull_distribution& __d1,
4901	const weibull_distribution& __d2)
4902	{ return __d1._M_param == __d2._M_param; }
4903
4904	private:
4905	template<typename _ForwardIterator,
4906	typename _UniformRandomNumberGenerator>
4907	void
4908	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
4909	_UniformRandomNumberGenerator& __urng,
4910	const param_type& __p);
4911
4912	param_type _M_param;
4913	};
4914
4915	/**
4916	* @brief Return true if two Weibull distributions have different
4917	* parameters.
4918	*/
4919	template<typename _RealType>
4920	inline bool
4921	operator!=(const std::weibull_distribution<_RealType>& __d1,
4922	const std::weibull_distribution<_RealType>& __d2)
4923	{ return !(__d1 == __d2); }
4924
4925	/**
4926	* @brief Inserts a %weibull_distribution random number distribution
4927	* @p __x into the output stream @p __os.
4928	*
4929	* @param __os An output stream.
4930	* @param __x A %weibull_distribution random number distribution.
4931	*
4932	* @returns The output stream with the state of @p __x inserted or in
4933	* an error state.
4934	*/
4935	template<typename _RealType, typename _CharT, typename _Traits>
4936	std::basic_ostream<_CharT, _Traits>&
4937	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
4938	const std::weibull_distribution<_RealType>& __x);
4939
4940	/**
4941	* @brief Extracts a %weibull_distribution random number distribution
4942	* @p __x from the input stream @p __is.
4943	*
4944	* @param __is An input stream.
4945	* @param __x A %weibull_distribution random number
4946	* generator engine.
4947	*
4948	* @returns The input stream with @p __x extracted or in an error state.
4949	*/
4950	template<typename _RealType, typename _CharT, typename _Traits>
4951	std::basic_istream<_CharT, _Traits>&
4952	operator>>(std::basic_istream<_CharT, _Traits>& __is,
4953	std::weibull_distribution<_RealType>& __x);
4954
4955
4956	/**
4957	* @brief A extreme_value_distribution random number distribution.
4958	*
4959	* The formula for the normal probability mass function is
4960	* @f[
4961	* p(x\|a,b) = \frac{1}{b}
4962	* \exp( \frac{a-x}{b} - \exp(\frac{a-x}{b}))
4963	* @f]
4964	*/
4965	template<typename _RealType = double>
4966	class extreme_value_distribution
4967	{
4968	static_assert(std::is_floating_point<_RealType>::value,
4969	"result_type must be a floating point type");
4970
4971	public:
4972	/* The type of the range of the distribution. /
4973	typedef _RealType result_type;
4974
4975	/* Parameter type. /
4976	struct param_type
4977	{
4978	typedef extreme_value_distribution<_RealType> distribution_type;
4979
4980	explicit
4981	param_type(_RealType __a = _RealType(`0`),
4982	_RealType __b = _RealType(`1`))
4983	: _M_a(__a), _M_b(__b)
4984	{ }
4985
4986	_RealType
4987	a() const
4988	{ return _M_a; }
4989
4990	_RealType
4991	b() const
4992	{ return _M_b; }
4993
4994	friend bool
4995	operator==(const param_type& __p1, const param_type& __p2)
4996	{ return __p1._M_a == __p2._M_a && __p1._M_b == __p2._M_b; }
4997
4998	friend bool
4999	operator!=(const param_type& __p1, const param_type& __p2)
5000	{ return !(__p1 == __p2); }
5001
5002	private:
5003	_RealType _M_a;
5004	_RealType _M_b;
5005	};
5006
5007	explicit
5008	extreme_value_distribution(_RealType __a = _RealType(`0`),
5009	_RealType __b = _RealType(`1`))
5010	: _M_param(__a, __b)
5011	{ }
5012
5013	explicit
5014	extreme_value_distribution(const param_type& __p)
5015	: _M_param(__p)
5016	{ }
5017
5018	/**
5019	* @brief Resets the distribution state.
5020	*/
5021	void
5022	reset()
5023	{ }
5024
5025	/**
5026	* @brief Return the @f$a@f$ parameter of the distribution.
5027	*/
5028	_RealType
5029	a() const
5030	{ return _M_param.a(); }
5031
5032	/**
5033	* @brief Return the @f$b@f$ parameter of the distribution.
5034	*/
5035	_RealType
5036	b() const
5037	{ return _M_param.b(); }
5038
5039	/**
5040	* @brief Returns the parameter set of the distribution.
5041	*/
5042	param_type
5043	param() const
5044	{ return _M_param; }
5045
5046	/**
5047	* @brief Sets the parameter set of the distribution.
5048	* @param __param The new parameter set of the distribution.
5049	*/
5050	void
5051	param(const param_type& __param)
5052	{ _M_param = __param; }
5053
5054	/**
5055	* @brief Returns the greatest lower bound value of the distribution.
5056	*/
5057	result_type
5058	min() const
5059	{ return std::numeric_limits<result_type>::lowest(); }
5060
5061	/**
5062	* @brief Returns the least upper bound value of the distribution.
5063	*/
5064	result_type
5065	max() const
5066	{ return std::numeric_limits<result_type>::max(); }
5067
5068	/**
5069	* @brief Generating functions.
5070	*/
5071	template<typename _UniformRandomNumberGenerator>
5072	result_type
5073	operator()(_UniformRandomNumberGenerator& __urng)
5074	{ return this->operator()(__urng, _M_param); }
5075
5076	template<typename _UniformRandomNumberGenerator>
5077	result_type
5078	operator()(_UniformRandomNumberGenerator& __urng,
5079	const param_type& __p);
5080
5081	template<typename _ForwardIterator,
5082	typename _UniformRandomNumberGenerator>
5083	void
5084	__generate(_ForwardIterator __f, _ForwardIterator __t,
5085	_UniformRandomNumberGenerator& __urng)
5086	{ this->__generate(__f, __t, __urng, _M_param); }
5087
5088	template<typename _ForwardIterator,
5089	typename _UniformRandomNumberGenerator>
5090	void
5091	__generate(_ForwardIterator __f, _ForwardIterator __t,
5092	_UniformRandomNumberGenerator& __urng,
5093	const param_type& __p)
5094	{ this->__generate_impl(__f, __t, __urng, __p); }
5095
5096	template<typename _UniformRandomNumberGenerator>
5097	void
5098	__generate(result_type* __f, result_type* __t,
5099	_UniformRandomNumberGenerator& __urng,
5100	const param_type& __p)
5101	{ this->__generate_impl(__f, __t, __urng, __p); }
5102
5103	/**
5104	* @brief Return true if two extreme value distributions have the same
5105	* parameters.
5106	*/
5107	friend bool
5108	operator==(const extreme_value_distribution& __d1,
5109	const extreme_value_distribution& __d2)
5110	{ return __d1._M_param == __d2._M_param; }
5111
5112	private:
5113	template<typename _ForwardIterator,
5114	typename _UniformRandomNumberGenerator>
5115	void
5116	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
5117	_UniformRandomNumberGenerator& __urng,
5118	const param_type& __p);
5119
5120	param_type _M_param;
5121	};
5122
5123	/**
5124	* @brief Return true if two extreme value distributions have different
5125	* parameters.
5126	*/
5127	template<typename _RealType>
5128	inline bool
5129	operator!=(const std::extreme_value_distribution<_RealType>& __d1,
5130	const std::extreme_value_distribution<_RealType>& __d2)
5131	{ return !(__d1 == __d2); }
5132
5133	/**
5134	* @brief Inserts a %extreme_value_distribution random number distribution
5135	* @p __x into the output stream @p __os.
5136	*
5137	* @param __os An output stream.
5138	* @param __x A %extreme_value_distribution random number distribution.
5139	*
5140	* @returns The output stream with the state of @p __x inserted or in
5141	* an error state.
5142	*/
5143	template<typename _RealType, typename _CharT, typename _Traits>
5144	std::basic_ostream<_CharT, _Traits>&
5145	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
5146	const std::extreme_value_distribution<_RealType>& __x);
5147
5148	/**
5149	* @brief Extracts a %extreme_value_distribution random number
5150	* distribution @p __x from the input stream @p __is.
5151	*
5152	* @param __is An input stream.
5153	* @param __x A %extreme_value_distribution random number
5154	* generator engine.
5155	*
5156	* @returns The input stream with @p __x extracted or in an error state.
5157	*/
5158	template<typename _RealType, typename _CharT, typename _Traits>
5159	std::basic_istream<_CharT, _Traits>&
5160	operator>>(std::basic_istream<_CharT, _Traits>& __is,
5161	std::extreme_value_distribution<_RealType>& __x);
5162
5163
5164	/**
5165	* @brief A discrete_distribution random number distribution.
5166	*
5167	* The formula for the discrete probability mass function is
5168	*
5169	*/
5170	template<typename _IntType = int>
5171	class discrete_distribution
5172	{
5173	static_assert(std::is_integral<_IntType>::value,
5174	"result_type must be an integral type");
5175
5176	public:
5177	/* The type of the range of the distribution. /
5178	typedef _IntType result_type;
5179
5180	/* Parameter type. /
5181	struct param_type
5182	{
5183	typedef discrete_distribution<_IntType> distribution_type;
5184	friend class discrete_distribution<_IntType>;
5185
5186	param_type()
5187	: _M_prob (), _M_cp ()
5188	{ }
5189
5190	template<typename _InputIterator>
5191	param_type(_InputIterator __wbegin,
5192	_InputIterator __wend)
5193	: _M_prob(__wbegin, __wend), _M_cp ()
5194	{ _M_initialize(); }
5195
5196	param_type(initializer_list<double> __wil)
5197	: _M_prob (__wil.begin(), __wil.end()), _M_cp ()
5198	{ _M_initialize(); }
5199
5200	template<typename _Func>
5201	param_type(size_t __nw, double __xmin, double __xmax,
5202	_Func __fw);
5203
5204	// See: http://cpp-next.com/archive/2010/10/implicit-move-must-go/
5205	param_type(const param_type&) = default;
5206	param_type& operator=(const param_type&) = default;
5207
5208	std::vector<double>
5209	probabilities() const
5210	{ return _M_prob.empty() ? std::vector<double>(`1`, `1.0`) : _M_prob; }
5211
5212	friend bool
5213	operator==(const param_type& __p1, const param_type& __p2)
5214	{ return __p1._M_prob == __p2._M_prob; }
5215
5216	friend bool
5217	operator!=(const param_type& __p1, const param_type& __p2)
5218	{ return !(__p1 == __p2); }
5219
5220	private:
5221	void
5222	_M_initialize();
5223
5224	std::vector<double> _M_prob;
5225	std::vector<double> _M_cp;
5226	};
5227
5228	discrete_distribution()
5229	: _M_param()
5230	{ }
5231
5232	template<typename _InputIterator>
5233	discrete_distribution(_InputIterator __wbegin,
5234	_InputIterator __wend)
5235	: _M_param(__wbegin, __wend)
5236	{ }
5237
5238	discrete_distribution(initializer_list<double> __wl)
5239	: _M_param(__wl)
5240	{ }
5241
5242	template<typename _Func>
5243	discrete_distribution(size_t __nw, double __xmin, double __xmax,
5244	_Func __fw)
5245	: _M_param(__nw, __xmin, __xmax, __fw)
5246	{ }
5247
5248	explicit
5249	discrete_distribution(const param_type& __p)
5250	: _M_param(__p)
5251	{ }
5252
5253	/**
5254	* @brief Resets the distribution state.
5255	*/
5256	void
5257	reset()
5258	{ }
5259
5260	/**
5261	* @brief Returns the probabilities of the distribution.
5262	*/
5263	std::vector<double>
5264	probabilities() const
5265	{
5266	return _M_param._M_prob.empty()
5267	? std::vector<double>(`1`, `1.0`) : _M_param._M_prob;
5268	}
5269
5270	/**
5271	* @brief Returns the parameter set of the distribution.
5272	*/
5273	param_type
5274	param() const
5275	{ return _M_param; }
5276
5277	/**
5278	* @brief Sets the parameter set of the distribution.
5279	* @param __param The new parameter set of the distribution.
5280	*/
5281	void
5282	param(const param_type& __param)
5283	{ _M_param = __param; }
5284
5285	/**
5286	* @brief Returns the greatest lower bound value of the distribution.
5287	*/
5288	result_type
5289	min() const
5290	{ return result_type(`0`); }
5291
5292	/**
5293	* @brief Returns the least upper bound value of the distribution.
5294	*/
5295	result_type
5296	max() const
5297	{
5298	return _M_param._M_prob.empty()
5299	? result_type(`0`) : result_type(_M_param._M_prob.size() - `1`);
5300	}
5301
5302	/**
5303	* @brief Generating functions.
5304	*/
5305	template<typename _UniformRandomNumberGenerator>
5306	result_type
5307	operator()(_UniformRandomNumberGenerator& __urng)
5308	{ return this->operator()(__urng, _M_param); }
5309
5310	template<typename _UniformRandomNumberGenerator>
5311	result_type
5312	operator()(_UniformRandomNumberGenerator& __urng,
5313	const param_type& __p);
5314
5315	template<typename _ForwardIterator,
5316	typename _UniformRandomNumberGenerator>
5317	void
5318	__generate(_ForwardIterator __f, _ForwardIterator __t,
5319	_UniformRandomNumberGenerator& __urng)
5320	{ this->__generate(__f, __t, __urng, _M_param); }
5321
5322	template<typename _ForwardIterator,
5323	typename _UniformRandomNumberGenerator>
5324	void
5325	__generate(_ForwardIterator __f, _ForwardIterator __t,
5326	_UniformRandomNumberGenerator& __urng,
5327	const param_type& __p)
5328	{ this->__generate_impl(__f, __t, __urng, __p); }
5329
5330	template<typename _UniformRandomNumberGenerator>
5331	void
5332	__generate(result_type* __f, result_type* __t,
5333	_UniformRandomNumberGenerator& __urng,
5334	const param_type& __p)
5335	{ this->__generate_impl(__f, __t, __urng, __p); }
5336
5337	/**
5338	* @brief Return true if two discrete distributions have the same
5339	* parameters.
5340	*/
5341	friend bool
5342	operator==(const discrete_distribution& __d1,
5343	const discrete_distribution& __d2)
5344	{ return __d1._M_param == __d2._M_param; }
5345
5346	/**
5347	* @brief Inserts a %discrete_distribution random number distribution
5348	* @p __x into the output stream @p __os.
5349	*
5350	* @param __os An output stream.
5351	* @param __x A %discrete_distribution random number distribution.
5352	*
5353	* @returns The output stream with the state of @p __x inserted or in
5354	* an error state.
5355	*/
5356	template<typename _IntType1, typename _CharT, typename _Traits>
5357	friend std::basic_ostream<_CharT, _Traits>&
5358	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
5359	const std::discrete_distribution<_IntType1>& __x);
5360
5361	/**
5362	* @brief Extracts a %discrete_distribution random number distribution
5363	* @p __x from the input stream @p __is.
5364	*
5365	* @param __is An input stream.
5366	* @param __x A %discrete_distribution random number
5367	* generator engine.
5368	*
5369	* @returns The input stream with @p __x extracted or in an error
5370	* state.
5371	*/
5372	template<typename _IntType1, typename _CharT, typename _Traits>
5373	friend std::basic_istream<_CharT, _Traits>&
5374	operator>>(std::basic_istream<_CharT, _Traits>& __is,
5375	std::discrete_distribution<_IntType1>& __x);
5376
5377	private:
5378	template<typename _ForwardIterator,
5379	typename _UniformRandomNumberGenerator>
5380	void
5381	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
5382	_UniformRandomNumberGenerator& __urng,
5383	const param_type& __p);
5384
5385	param_type _M_param;
5386	};
5387
5388	/**
5389	* @brief Return true if two discrete distributions have different
5390	* parameters.
5391	*/
5392	template<typename _IntType>
5393	inline bool
5394	operator!=(const std::discrete_distribution<_IntType>& __d1,
5395	const std::discrete_distribution<_IntType>& __d2)
5396	{ return !(__d1 == __d2); }
5397
5398
5399	/**
5400	* @brief A piecewise_constant_distribution random number distribution.
5401	*
5402	* The formula for the piecewise constant probability mass function is
5403	*
5404	*/
5405	template<typename _RealType = double>
5406	class piecewise_constant_distribution
5407	{
5408	static_assert(std::is_floating_point<_RealType>::value,
5409	"result_type must be a floating point type");
5410
5411	public:
5412	/* The type of the range of the distribution. /
5413	typedef _RealType result_type;
5414
5415	/* Parameter type. /
5416	struct param_type
5417	{
5418	typedef piecewise_constant_distribution<_RealType> distribution_type;
5419	friend class piecewise_constant_distribution<_RealType>;
5420
5421	param_type()
5422	: _M_int(), _M_den (), _M_cp ()
5423	{ }
5424
5425	template<typename _InputIteratorB, typename _InputIteratorW>
5426	param_type(_InputIteratorB __bfirst,
5427	_InputIteratorB __bend,
5428	_InputIteratorW __wbegin);
5429
5430	template<typename _Func>
5431	param_type(initializer_list<_RealType> __bi, _Func __fw);
5432
5433	template<typename _Func>
5434	param_type(size_t __nw, _RealType __xmin, _RealType __xmax,
5435	_Func __fw);
5436
5437	// See: http://cpp-next.com/archive/2010/10/implicit-move-must-go/
5438	param_type(const param_type&) = default;
5439	param_type& operator=(const param_type&) = default;
5440
5441	std::vector<_RealType>
5442	intervals() const
5443	{
5444	if (_M_int.empty())
5445	{
5446	std::vector<_RealType> __tmp(`2`);
5447	__tmp[`1`] = _RealType(`1`);
5448	return __tmp;
5449	}
5450	else
5451	return _M_int;
5452	}
5453
5454	std::vector<double>
5455	densities() const
5456	{ return _M_den.empty() ? std::vector<double>(`1`, `1.0`) : _M_den; }
5457
5458	friend bool
5459	operator==(const param_type& __p1, const param_type& __p2)
5460	{ return __p1._M_int == __p2._M_int && __p1._M_den == __p2._M_den; }
5461
5462	friend bool
5463	operator!=(const param_type& __p1, const param_type& __p2)
5464	{ return !(__p1 == __p2); }
5465
5466	private:
5467	void
5468	_M_initialize();
5469
5470	std::vector<_RealType> _M_int;
5471	std::vector<double> _M_den;
5472	std::vector<double> _M_cp;
5473	};
5474
5475	explicit
5476	piecewise_constant_distribution()
5477	: _M_param()
5478	{ }
5479
5480	template<typename _InputIteratorB, typename _InputIteratorW>
5481	piecewise_constant_distribution(_InputIteratorB __bfirst,
5482	_InputIteratorB __bend,
5483	_InputIteratorW __wbegin)
5484	: _M_param(__bfirst, __bend, __wbegin)
5485	{ }
5486
5487	template<typename _Func>
5488	piecewise_constant_distribution(initializer_list<_RealType> __bl,
5489	_Func __fw)
5490	: _M_param(__bl, __fw)
5491	{ }
5492
5493	template<typename _Func>
5494	piecewise_constant_distribution(size_t __nw,
5495	_RealType __xmin, _RealType __xmax,
5496	_Func __fw)
5497	: _M_param(__nw, __xmin, __xmax, __fw)
5498	{ }
5499
5500	explicit
5501	piecewise_constant_distribution(const param_type& __p)
5502	: _M_param(__p)
5503	{ }
5504
5505	/**
5506	* @brief Resets the distribution state.
5507	*/
5508	void
5509	reset()
5510	{ }
5511
5512	/**
5513	* @brief Returns a vector of the intervals.
5514	*/
5515	std::vector<_RealType>
5516	intervals() const
5517	{
5518	if (_M_param._M_int.empty())
5519	{
5520	std::vector<_RealType> __tmp(`2`);
5521	__tmp[`1`] = _RealType(`1`);
5522	return __tmp;
5523	}
5524	else
5525	return _M_param._M_int;
5526	}
5527
5528	/**
5529	* @brief Returns a vector of the probability densities.
5530	*/
5531	std::vector<double>
5532	densities() const
5533	{
5534	return _M_param._M_den.empty()
5535	? std::vector<double>(`1`, `1.0`) : _M_param._M_den;
5536	}
5537
5538	/**
5539	* @brief Returns the parameter set of the distribution.
5540	*/
5541	param_type
5542	param() const
5543	{ return _M_param; }
5544
5545	/**
5546	* @brief Sets the parameter set of the distribution.
5547	* @param __param The new parameter set of the distribution.
5548	*/
5549	void
5550	param(const param_type& __param)
5551	{ _M_param = __param; }
5552
5553	/**
5554	* @brief Returns the greatest lower bound value of the distribution.
5555	*/
5556	result_type
5557	min() const
5558	{
5559	return _M_param._M_int.empty()
5560	? result_type(`0`) : _M_param._M_int.front();
5561	}
5562
5563	/**
5564	* @brief Returns the least upper bound value of the distribution.
5565	*/
5566	result_type
5567	max() const
5568	{
5569	return _M_param._M_int.empty()
5570	? result_type(`1`) : _M_param._M_int.back();
5571	}
5572
5573	/**
5574	* @brief Generating functions.
5575	*/
5576	template<typename _UniformRandomNumberGenerator>
5577	result_type
5578	operator()(_UniformRandomNumberGenerator& __urng)
5579	{ return this->operator()(__urng, _M_param); }
5580
5581	template<typename _UniformRandomNumberGenerator>
5582	result_type
5583	operator()(_UniformRandomNumberGenerator& __urng,
5584	const param_type& __p);
5585
5586	template<typename _ForwardIterator,
5587	typename _UniformRandomNumberGenerator>
5588	void
5589	__generate(_ForwardIterator __f, _ForwardIterator __t,
5590	_UniformRandomNumberGenerator& __urng)
5591	{ this->__generate(__f, __t, __urng, _M_param); }
5592
5593	template<typename _ForwardIterator,
5594	typename _UniformRandomNumberGenerator>
5595	void
5596	__generate(_ForwardIterator __f, _ForwardIterator __t,
5597	_UniformRandomNumberGenerator& __urng,
5598	const param_type& __p)
5599	{ this->__generate_impl(__f, __t, __urng, __p); }
5600
5601	template<typename _UniformRandomNumberGenerator>
5602	void
5603	__generate(result_type* __f, result_type* __t,
5604	_UniformRandomNumberGenerator& __urng,
5605	const param_type& __p)
5606	{ this->__generate_impl(__f, __t, __urng, __p); }
5607
5608	/**
5609	* @brief Return true if two piecewise constant distributions have the
5610	* same parameters.
5611	*/
5612	friend bool
5613	operator==(const piecewise_constant_distribution& __d1,
5614	const piecewise_constant_distribution& __d2)
5615	{ return __d1._M_param == __d2._M_param; }
5616
5617	/**
5618	* @brief Inserts a %piecewise_constant_distribution random
5619	* number distribution @p __x into the output stream @p __os.
5620	*
5621	* @param __os An output stream.
5622	* @param __x A %piecewise_constant_distribution random number
5623	* distribution.
5624	*
5625	* @returns The output stream with the state of @p __x inserted or in
5626	* an error state.
5627	*/
5628	template<typename _RealType1, typename _CharT, typename _Traits>
5629	friend std::basic_ostream<_CharT, _Traits>&
5630	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
5631	const std::piecewise_constant_distribution<_RealType1>& __x);
5632
5633	/**
5634	* @brief Extracts a %piecewise_constant_distribution random
5635	* number distribution @p __x from the input stream @p __is.
5636	*
5637	* @param __is An input stream.
5638	* @param __x A %piecewise_constant_distribution random number
5639	* generator engine.
5640	*
5641	* @returns The input stream with @p __x extracted or in an error
5642	* state.
5643	*/
5644	template<typename _RealType1, typename _CharT, typename _Traits>
5645	friend std::basic_istream<_CharT, _Traits>&
5646	operator>>(std::basic_istream<_CharT, _Traits>& __is,
5647	std::piecewise_constant_distribution<_RealType1>& __x);
5648
5649	private:
5650	template<typename _ForwardIterator,
5651	typename _UniformRandomNumberGenerator>
5652	void
5653	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
5654	_UniformRandomNumberGenerator& __urng,
5655	const param_type& __p);
5656
5657	param_type _M_param;
5658	};
5659
5660	/**
5661	* @brief Return true if two piecewise constant distributions have
5662	* different parameters.
5663	*/
5664	template<typename _RealType>
5665	inline bool
5666	operator!=(const std::piecewise_constant_distribution<_RealType>& __d1,
5667	const std::piecewise_constant_distribution<_RealType>& __d2)
5668	{ return !(__d1 == __d2); }
5669
5670
5671	/**
5672	* @brief A piecewise_linear_distribution random number distribution.
5673	*
5674	* The formula for the piecewise linear probability mass function is
5675	*
5676	*/
5677	template<typename _RealType = double>
5678	class piecewise_linear_distribution
5679	{
5680	static_assert(std::is_floating_point<_RealType>::value,
5681	"result_type must be a floating point type");
5682
5683	public:
5684	/* The type of the range of the distribution. /
5685	typedef _RealType result_type;
5686
5687	/* Parameter type. /
5688	struct param_type
5689	{
5690	typedef piecewise_linear_distribution<_RealType> distribution_type;
5691	friend class piecewise_linear_distribution<_RealType>;
5692
5693	param_type()
5694	: _M_int(), _M_den (), _M_cp (), _M_m ()
5695	{ }
5696
5697	template<typename _InputIteratorB, typename _InputIteratorW>
5698	param_type(_InputIteratorB __bfirst,
5699	_InputIteratorB __bend,
5700	_InputIteratorW __wbegin);
5701
5702	template<typename _Func>
5703	param_type(initializer_list<_RealType> __bl, _Func __fw);
5704
5705	template<typename _Func>
5706	param_type(size_t __nw, _RealType __xmin, _RealType __xmax,
5707	_Func __fw);
5708
5709	// See: http://cpp-next.com/archive/2010/10/implicit-move-must-go/
5710	param_type(const param_type&) = default;
5711	param_type& operator=(const param_type&) = default;
5712
5713	std::vector<_RealType>
5714	intervals() const
5715	{
5716	if (_M_int.empty())
5717	{
5718	std::vector<_RealType> __tmp(`2`);
5719	__tmp[`1`] = _RealType(`1`);
5720	return __tmp;
5721	}
5722	else
5723	return _M_int;
5724	}
5725
5726	std::vector<double>
5727	densities() const
5728	{ return _M_den.empty() ? std::vector<double>(`2`, `1.0`) : _M_den; }
5729
5730	friend bool
5731	operator==(const param_type& __p1, const param_type& __p2)
5732	{ return __p1._M_int == __p2._M_int && __p1._M_den == __p2._M_den; }
5733
5734	friend bool
5735	operator!=(const param_type& __p1, const param_type& __p2)
5736	{ return !(__p1 == __p2); }
5737
5738	private:
5739	void
5740	_M_initialize();
5741
5742	std::vector<_RealType> _M_int;
5743	std::vector<double> _M_den;
5744	std::vector<double> _M_cp;
5745	std::vector<double> _M_m;
5746	};
5747
5748	explicit
5749	piecewise_linear_distribution()
5750	: _M_param()
5751	{ }
5752
5753	template<typename _InputIteratorB, typename _InputIteratorW>
5754	piecewise_linear_distribution(_InputIteratorB __bfirst,
5755	_InputIteratorB __bend,
5756	_InputIteratorW __wbegin)
5757	: _M_param(__bfirst, __bend, __wbegin)
5758	{ }
5759
5760	template<typename _Func>
5761	piecewise_linear_distribution(initializer_list<_RealType> __bl,
5762	_Func __fw)
5763	: _M_param(__bl, __fw)
5764	{ }
5765
5766	template<typename _Func>
5767	piecewise_linear_distribution(size_t __nw,
5768	_RealType __xmin, _RealType __xmax,
5769	_Func __fw)
5770	: _M_param(__nw, __xmin, __xmax, __fw)
5771	{ }
5772
5773	explicit
5774	piecewise_linear_distribution(const param_type& __p)
5775	: _M_param(__p)
5776	{ }
5777
5778	/**
5779	* Resets the distribution state.
5780	*/
5781	void
5782	reset()
5783	{ }
5784
5785	/**
5786	* @brief Return the intervals of the distribution.
5787	*/
5788	std::vector<_RealType>
5789	intervals() const
5790	{
5791	if (_M_param._M_int.empty())
5792	{
5793	std::vector<_RealType> __tmp(`2`);
5794	__tmp[`1`] = _RealType(`1`);
5795	return __tmp;
5796	}
5797	else
5798	return _M_param._M_int;
5799	}
5800
5801	/**
5802	* @brief Return a vector of the probability densities of the
5803	* distribution.
5804	*/
5805	std::vector<double>
5806	densities() const
5807	{
5808	return _M_param._M_den.empty()
5809	? std::vector<double>(`2`, `1.0`) : _M_param._M_den;
5810	}
5811
5812	/**
5813	* @brief Returns the parameter set of the distribution.
5814	*/
5815	param_type
5816	param() const
5817	{ return _M_param; }
5818
5819	/**
5820	* @brief Sets the parameter set of the distribution.
5821	* @param __param The new parameter set of the distribution.
5822	*/
5823	void
5824	param(const param_type& __param)
5825	{ _M_param = __param; }
5826
5827	/**
5828	* @brief Returns the greatest lower bound value of the distribution.
5829	*/
5830	result_type
5831	min() const
5832	{
5833	return _M_param._M_int.empty()
5834	? result_type(`0`) : _M_param._M_int.front();
5835	}
5836
5837	/**
5838	* @brief Returns the least upper bound value of the distribution.
5839	*/
5840	result_type
5841	max() const
5842	{
5843	return _M_param._M_int.empty()
5844	? result_type(`1`) : _M_param._M_int.back();
5845	}
5846
5847	/**
5848	* @brief Generating functions.
5849	*/
5850	template<typename _UniformRandomNumberGenerator>
5851	result_type
5852	operator()(_UniformRandomNumberGenerator& __urng)
5853	{ return this->operator()(__urng, _M_param); }
5854
5855	template<typename _UniformRandomNumberGenerator>
5856	result_type
5857	operator()(_UniformRandomNumberGenerator& __urng,
5858	const param_type& __p);
5859
5860	template<typename _ForwardIterator,
5861	typename _UniformRandomNumberGenerator>
5862	void
5863	__generate(_ForwardIterator __f, _ForwardIterator __t,
5864	_UniformRandomNumberGenerator& __urng)
5865	{ this->__generate(__f, __t, __urng, _M_param); }
5866
5867	template<typename _ForwardIterator,
5868	typename _UniformRandomNumberGenerator>
5869	void
5870	__generate(_ForwardIterator __f, _ForwardIterator __t,
5871	_UniformRandomNumberGenerator& __urng,
5872	const param_type& __p)
5873	{ this->__generate_impl(__f, __t, __urng, __p); }
5874
5875	template<typename _UniformRandomNumberGenerator>
5876	void
5877	__generate(result_type* __f, result_type* __t,
5878	_UniformRandomNumberGenerator& __urng,
5879	const param_type& __p)
5880	{ this->__generate_impl(__f, __t, __urng, __p); }
5881
5882	/**
5883	* @brief Return true if two piecewise linear distributions have the
5884	* same parameters.
5885	*/
5886	friend bool
5887	operator==(const piecewise_linear_distribution& __d1,
5888	const piecewise_linear_distribution& __d2)
5889	{ return __d1._M_param == __d2._M_param; }
5890
5891	/**
5892	* @brief Inserts a %piecewise_linear_distribution random number
5893	* distribution @p __x into the output stream @p __os.
5894	*
5895	* @param __os An output stream.
5896	* @param __x A %piecewise_linear_distribution random number
5897	* distribution.
5898	*
5899	* @returns The output stream with the state of @p __x inserted or in
5900	* an error state.
5901	*/
5902	template<typename _RealType1, typename _CharT, typename _Traits>
5903	friend std::basic_ostream<_CharT, _Traits>&
5904	operator<<(std::basic_ostream<_CharT, _Traits>& __os,
5905	const std::piecewise_linear_distribution<_RealType1>& __x);
5906
5907	/**
5908	* @brief Extracts a %piecewise_linear_distribution random number
5909	* distribution @p __x from the input stream @p __is.
5910	*
5911	* @param __is An input stream.
5912	* @param __x A %piecewise_linear_distribution random number
5913	* generator engine.
5914	*
5915	* @returns The input stream with @p __x extracted or in an error
5916	* state.
5917	*/
5918	template<typename _RealType1, typename _CharT, typename _Traits>
5919	friend std::basic_istream<_CharT, _Traits>&
5920	operator>>(std::basic_istream<_CharT, _Traits>& __is,
5921	std::piecewise_linear_distribution<_RealType1>& __x);
5922
5923	private:
5924	template<typename _ForwardIterator,
5925	typename _UniformRandomNumberGenerator>
5926	void
5927	__generate_impl(_ForwardIterator __f, _ForwardIterator __t,
5928	_UniformRandomNumberGenerator& __urng,
5929	const param_type& __p);
5930
5931	param_type _M_param;
5932	};
5933
5934	/**
5935	* @brief Return true if two piecewise linear distributions have
5936	* different parameters.
5937	*/
5938	template<typename _RealType>
5939	inline bool
5940	operator!=(const std::piecewise_linear_distribution<_RealType>& __d1,
5941	const std::piecewise_linear_distribution<_RealType>& __d2)
5942	{ return !(__d1 == __d2); }
5943
5944
5945	/ @} / // group random_distributions_poisson
5946
5947	/ @} / // group random_distributions
5948
5949	/**
5950	* @addtogroup random_utilities Random Number Utilities
5951	* @ingroup random
5952	* @{
5953	*/
5954
5955	/**
5956	* @brief The seed_seq class generates sequences of seeds for random
5957	* number generators.
5958	*/
5959	class seed_seq
5960	{
5961	public:
5962	/* The type of the seed vales. /
5963	typedef uint_least32_t result_type;
5964
5965	/* Default constructor. /
5966	seed_seq() noexcept
5967	: _M_v ()
5968	{ }
5969
5970	template<typename _IntType>
5971	seed_seq(std::initializer_list<_IntType> il);
5972
5973	template<typename _InputIterator>
5974	seed_seq(_InputIterator __begin, _InputIterator __end);
5975
5976	// generating functions
5977	template<typename _RandomAccessIterator>
5978	void
5979	generate(_RandomAccessIterator __begin, _RandomAccessIterator __end);
5980
5981	// property functions
5982	size_t size() const noexcept
5983	{ return _M_v.size(); }
5984
5985	template<typename OutputIterator>
5986	void
5987	param(OutputIterator __dest) const
5988	{ std::copy(_M_v.begin(), _M_v.end(), __dest); }
5989
5990	// no copy functions
5991	seed_seq(const seed_seq&) = delete;
5992	seed_seq& operator=(const seed_seq&) = delete;
5993
5994	private:
5995	std::vector<result_type> _M_v;
5996	};
5997
5998	/ @} / // group random_utilities
5999
6000	/ @} / // group random
6001
6002	_GLIBCXX_END_NAMESPACE_VERSION
6003	} // namespace std
6004
6005	#endif
6006

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