Jens Maurer <Jens.Maurer@gmx.net>
2002-11-10
Document N1398=02-0056

$Id: proposal.html,v 1.44 2002/11/10 20:42:15 jmaurer Exp $

A Proposal to Add an Extensible Random Number Facility to the Standard Library (N1398)

Any one who considers arithmetical methods of producing random digits is, of course, in a state of sin.

John von Neumann, 1951

Revision history

I. Motivation

Why is this important? What kinds of problems does it address, and what kinds of programmers, is it intended to support? Is it based on existing practice?
Computers are deterministic machines by design: equal input data results in equal output, given the same internal state. Sometimes, applications require seemingly non-deterministic behaviour, usually provided by generating random numbers. Such applications include:

Programmers in all of the above areas have to find ways to generate random numbers. However, the difficulty to find generators that are both efficient and have good quality is often underestimated, and so ad-hoc implementations often fail to meet either or both of these goals.

The C++ standard library includes std::rand, inherited from the C standard library, as the only facility to generate pseudo-random numbers. It is underspecified, because the generation function is not defined, and indeed early C standard library implementations provided surprisingly bad generators. Furthermore, the interface relies on global state, making it difficult or inefficient to provide for correct operation for simultaneous invocations in multi-threaded applications.

There is a lot of existing practice in this area. A multitude of libraries, usually implemented in C or Fortran, is available from the scientific community. Some implement just one random number engine, others seek to provide a full framework. I know of no comprehensive C++ framework for generating random numbers that adheres to the design principles put forth in section III.

Random number generators are appropriate for this TR because they fall into one of the domains (numerics) identified in N1314 as a target for the TR.

Target Audience

There are several different kinds of programmers that are assumed to use the facilities provided in this proposal. This proposal specifies an infrastructure so that the needs of all four groups are met. The first two groups benefit from a modular design so that they can plug in their contributions. Providing add-on packages benefits from a design that suits to generic programming needs. Finally, users in need of random numbers benefit from an interface to the package that is easy to use.

II. Impact On the Standard

What does it depend on, and what depends on it? Is it a pure extension, or does it require changes to standard components? Does it require core language changes?
This proposal is a pure library extension. It does not require changes to any standard classes or functions. It does not require changes to any of the standard requirement tables. It does not require any changes in the core language, and it has been implemented in standard C++ as per ISO 14882:1998.

The ISO C99 extension that specify integral types having a given minimum or exact bitwidth (e.g. int32_t) aids in implementing this proposal, however these types (or the equivalent thereof under another name) can be defined with template metaprogramming in standard C++, so these are not strictly necessary.

In case the ISO C99 extensions become part of the TR, section IV should be reviewed whether some requirements could be reformulated with the ISO C99 extensions.

In case a standard reference-counted smart pointer becomes part of the TR, section IV should be reviewed and instances of the smart pointer be added to the acceptable template parameters for a variate_generator.

III. Design Decisions

Why did you choose the specific design that you did? What alternatives did you consider, and what are the tradeoffs? What are the consequences of your choice, for users and implementors? What decisions are left up to implementors? If there are any similar libraries in use, how do their design decisions compare to yours?
The design decisions are compared to those in the following libraries: The choice of engines and distributions is also contrasted against the following literature:

A. Overview on Requirements

Here is a short overview on the requirements for the random number framework. All of the requirements are revisited in detail in the following sections.

B. Pseudo-Random vs. Non-Deterministic Random Numbers

This section tries to avoid philosophical discussions about randomness as much as possible, a certain amount of intuition is assumed.

In this proposal, a pseudo-random number engine is defined as an initial internal state x(0), a function f that moves from one internal state to the next x(i+1) := f(x(i)), and an output function o that produces the output o(x(i)) of the generator. This is an entirely deterministic process, it is determined by the initial state x(0) and functions f and o only. The initial state x(0) is determined from a seed. Apparent randomness is achieved only because the user has limited perception.

A non-deterministic random-number engine provides a sequence of random numbers x(i) that cannot be foreseen. Examples are certain quantum-level physics experiments, measuring the time difference between radioactive decay of individual atoms or noise of a Zehner diode. Relatively unforeseeable random sources are also (the low bits of) timing between key touches, mouse movements, Ethernet packet arrivals, etc. An estimate for the amount of unforeseeability is the entropy, a concept from information theory. Completely foreseeable sequences (e.g., from pseudo-random number engines) have entropy 0, if all bits are unforeseeable, the entropy is equal to the number of bits in each number.

Pseudo-random number engines are usually much faster than non-deterministic random-number engines, because the latter require I/O to query some randomness device outside of the computer. However, there is a common interface feature subset of both pseudo-random and non-deterministic random-number engines. For example, a non-deterministic random-number engine could be employed to produce random numbers with normal distribution; I believe this to be an unlikely scenario in practice.

Other libraries, including those mentioned above, only provide either pseudo-random numbers, suitable for simulations and games, or non-deterministic random numbers, suitable for cryptographic applications.

C. Separation of Engines and Distributions

Random-number generation is usually conceptually separated into random-number engines that produce uniformly distributed random numbers between a given minimum and maximum and random-number distributions that retrieve uniformly distributed random numbers from some engine and produce numbers according to some distribution (e.g., Gaussian normal or Bernoulli distribution). Returning to the formalism from section A, the former can be identified with the function f and the latter with the output function o.

This proposal honours this conceptual separation, and provides a class template to merge an arbitrary engine with an arbitrary distribution on top. To this end, this proposal sets up requirements for engines so that each of them can be used to provide uniformly distributed random numbers for any of the distributions. The resulting freedom of combination allows for the utmost re-use.

Engines have usually been analyzed with all mathematical and empirical tools currently available. Nonetheless, those tools show the absence of a particular weakness only, and are not exhaustive. Albeit unlikely, a new kind of test (for example, a use of random numbers in a new kind of simulation or game) could show serious weaknesses in some engines that were not known before.

This proposal attempts to specify the engines precisely; two different implementations, with the same seed, should return the same output sequence. This forces implementations to use the well-researched engines specified hereinafter, and users can have confidence in their quality and the limits thereof.

On the other hand, the specifications for the distributions only define the statistical result, not the precise algorithm to use. This is different from engines, because for distribution algorithms, rigorous proofs of their correctness are available, usually under the precondition that the input random numbers are (truely) uniformly distributed. For example, there are at least a handful of algorithms known to produce normally distributed random numbers from uniformly distributed ones. Which one of these is most efficient depends on at least the relative execution speeds for various transcendental functions, cache and branch prediction behaviour of the CPU, and desired memory use. This proposal therefore leaves the choice of the algorithm to the implementation. It follows that output sequences for the distributions will not be identical across implementations. It is expected that implementations will carefully choose the algorithms for distributions up front, since it is certainly surprising to customers if some distribution produces different numbers from one implementation version to the next.

Other libraries usually provide the same differentiation between engines and distributions. Libraries rarely have a wrapper around both engine and distribution, but it turns out that this can hide some complexities from the authors of distributions, since some facitilies need to be provided only once. A previous version of this proposal had distributions directly exposed to the user, and the distribution type dependent on the engine type. In various discussions, this was considered as too much coupling.

Since other libraries do not aim to provide a portable specification framework, engines are sometimes only described qualitatively without giving the exact parameterization. Also, distributions are given as specific functions or classes, so the quality-of-implementation question which distribution algorithm to employ does not need to be addressed.

D. Templates vs. Virtual Functions

The layering sketched in the previous subsection can be implemented by either a template mechanism or by using virtual functions in a class hierarchy. This proposal uses templates. Template parameters are usually some base type and values denoting fixed parameters for the functions f and o, e.g. a word size or modulus.

For virtual functions in a class hierarchy, the core language requires a (nearly) exact type match for a function in a derived classes overriding a function in a base class. This seems to be unnecessarily restrictive, because engines can sometimes benefit from using different integral base types. Also, with current compiler technology, virtual functions prevent inlining when a pointer to the base class is used to call a virtual function that is overridden in some derived class. In particular with applications such as simulations that sometimes use millions of pseudo-random numbers per second, losing significant amounts of performance due to missed inlining opportunities appears to not be acceptable.

The CLHEP library bases all its engines on the abstract base class HepRandomEngine. Specific engines derive from this class and override its pure virtual functions. Similarly, all distributions are based on the base class HepRandom. Specific distributions derive from this class, override operator(), and provide a number of specific non-virtual functions.

The GNU Scientific Library, while coded in C, adheres to the principles of object-structuring; all engines can be used with any of the distributions. The technical implementation is by mechanisms similar to virtual functions.

E. Parameterization and Initialization for Engines

Engines usually have a "base" type which is used to store its internal state. Also, they usually have a choice of parameters. For example, a linear congruential engine is defined by x(i+1) = (a*x(i)+c) mod m, so f(x) = (a*x+c) mod m; the base type is "int" and parameters are a, c, and m. Finding parameters for a given function f that make for good randomness in the resulting engine's generated numbers x(i) requires extensive and specialized mathematical training and experience. In order to make good random numbers available to a large number of library users, this proposal not only defines generic random-number engines, but also provides a number of predefined well-known good parameterizations for those. Usually, there are only a few (less than five) well-known good parameterizations for each engine, so it appears feasible to provide these.

Since random-number engines are mathematically designed with computer implementation in mind, parameters are usually integers representable in a machine word, which usually coincides nicely with a C++ built-in type. The parameters could either be given as (compile-time) template arguments or as (run-time) constructor arguments.

Providing parameters as template arguments allows for providing predefined parameterizations as simple "typedef"s. Furthermore, the parameters appear as integral constants, so the compiler can value-check the given constants against the engine's base type. Also, the library implementor can choose different implementations depending on the values of the parameters, without incurring any runtime overhead. For example, there is an efficient method to compute (a*x) mod m, provided that a certain magnitude of m relative to the underlying type is not exceeded. Additionally, the compiler's optimizer can benefit from the constants and potentially produce better code, for example by unrolling loops with fixed loop count.

As an alternative, providing parameters as constructor arguments allows for more flexibility for the library user, for example when experimenting with several parameterizations. Predefined parameterizations can be provided by defining wrapper types which default the constructor parameters.

Other libraries have hard-coded the parameters of their engines and do not allow the user any configuration of them at all. If the user wishes to change the parameters, he has to re-implement the engine's algorithm. In my opinion, this approach unnecessarily restricts re-use.

Regarding initialization, this proposal chooses to provide "deterministic seeding" with the default constructor and the seed function without parameters: Two engines constructed using the default constructor will output the same sequence. In contrast, the CLHEP library's default constructed engines will take a fresh seed from a seed table for each instance. While this approach may be convenient for a certain group of users, it relies on global state and can easily be emulated by appropriately wrapping engines with deterministic seeding.

In addition to the default constructor, all engines provide a constructor and seed function taking an iterator range [it1,it2) pointing to unsigned integral values. An engine initializes its state by successively consuming values from the iterator range, then returning the advanced iterator it1. This approach has the advantage that the user can completely exploit the large state of some engines for initialization. Also, it allows to initialize compound engines in a uniform manner. For example, a compound engine consisting of two simpler engines would initialize the first engine with its [it1,it2). The first engine returns a smaller iterator range that it has not consumed yet. This can be used to initialize the second engine.

The iterator range [it1,it2) is specified to point to unsigned long values. There is no way to determine from a generic user program how the initialization values will be treated and what range of bits must be provided, except by enumerating all engines, e.g. in template specializations. The problem is that a given generator might have differing requirements on the values of the seed range even within one seed call.

For example, imagine a

   xor_combine<lagged_fibonacci<...>, mersenne_twister<...> >
generator. For this, seed(first, last) will consume values as follows: First, seed the state of the lagged_fibonacci generator by consuming one item from [first, last) for each word of state. The values are reduced to (e.g.) 24 bits to fit the lagged_fibonacci state requirements. Then, seed the state of the mersenne_twister by consuming some number of items from the remaining [first, last). The values are reduced to 32 bits to fit the mersenne_twister state requirements.

How does a concise programming interface for those increasingly complex and varying requirements on [first, last) look like? I don't know, and I don't want to complicate the specification by inventing something complicated here.

Thus, the specification says for each generator how it uses the seed values, and how many are consumed. Additional features are left to the user.

In a way, this is similar to STL containers: It is intended that the user can exchange iterators to various containers in generic algorithms, but the container itself is not meant to be exchanged, i.e. having a Container template parameter is often not adequate. That is analogous to the random number case: The user can pass an engine around and use its operator() and min and max functions generically. However, the user can't generically query the engine attributes and parameters, simply because most are entirely different in semantics for each engine.

The seed(first, last) interface can serve two purposes:

  1. In a generic context, the user can pass several integer values >= 1 for seeding. It is unlikely that the user explores the full state space with the seeds she provides, but she can be reasonably sure that her seeds aren't entirely incorrect. (There is no formal guarantee for that, except that the ability to provide bad seeds usually means the parameterization of the engine is bad, e.g. a non-prime modulus for a linear congruential engine.) For example, if the user wants a seed(uint32_t) on top of seed(first, last), one option is to use a linear_congruential generator that produces the values required for seed(first, last). When the user defines the iterator type for first and last so that it encapsulates the linear_congruential engine in operator++, the user doesn't even need to know beforehand how many values seed(first, last) will need.
  2. If the user is in a non-generic context, he knows the specific template type of the engine (probably not the template value-based parameterization, though). The precise specification for seed(first, last) allows to know what values need to be passed in so that a specific initial state is attained, for example to compare one implementation of the engine with another one that uses different seeding.
  3. If the user requires both, he needs to inject knowledge into (1) so that he is in the position of (2). One way to inject the knowledge is to use (partial) template specialization to add the knowledge. The specific parameterization of some engine can then be obtained by querying the data members of the engines.

I haven't seen the iterator-based approach to engine initialization in other libraries; most initialization approaches rely on a either a single value or on per-engine specific approaches to initialization.

An alternative approach is to pass a zero-argument function object ("generator") for seeding. It is trivial to implement a generator from a given iterator range, but it is more complicated to implement an iterator range from a generator. Also, the exception object that is specified to be thrown when the iterator range is exhausted could be configured in a user-provided iterator to generator mapping. With this approach, some engines would have three one-argument constructors: One taking a single integer for seeding, one taking a (reference?) to a (templated) generator, and the copy constructor. It appears that the opportunities for ambiguities or choosing the wrong overload are too confusing to the unsuspecting user.

F. Parameterization and Initialization for Distributions

The distributions specified in this proposal have template parameters that indicate the output data type (e.g. float, double, long double) that the user desires.

The probability density functions of distributions usually have parameters. These are mapped to constructor parameters, to be set at runtime by the library user according to her requirements. The parameters for a distribution object cannot change after its construction. When constructing the distribution, this allows to pre-compute some data according to the parameters given without risk of inadvertently invalidating them later.

Distributions may implement operator()(T x), for arbitrary type T, to meet special needs, for example a "one-shot" mode where each invocation uses different distribution parameters.

G. Properties as Traits vs. In-Class Constants

Users might wish to query compile-time properties of the engines and distributions, e.g. their base types, constant parameters, etc. This is similar to querying the properties of the built-in types such as double using std::numeric_limits<>. However, engines and distributions cannot be simple types, so it does not appear to be necessary to separate the properties into separate traits classes. Instead, compile-time properties are given as members types and static member constants.

H. Which Engines to Include

There is a multitude of pseudo-random number engines available in both literature and code. Some engines, such as Mersenne Twister, have an independent algorithm ("base engine"). Others change the values or order of output of other engines to improve randomness, for example Knuth's "Algorithm B" ("compound engine"). The template mechanism allows easy combination of base and compound engines.

Engines may be categorized according to the following dimensions.

According to the criteria above, the engines given below were chosen. The quality and size indications were completed according to best known parameterizations. Other parameterizations usually yield poorer quality and/or less size.

engine int / float quality speed size of state subsequences comments
linear_congruential int medium medium 1 word yes cycle length is limited to the maximum value representable in one machine word, passes most statisticial tests with chosen parameters.
mersenne_twister int good fast 624 words no long cycles, passes all statistical tests, good equidistribution in high dimensions
subtract_with_carry both medium fast 25 words no very long cycles possible, fails some statistical tests. Can be improved with the discard_block compound engine.
discard_block both good slow base engine + 1 word no compound engine that removes correlation provably by throwing away significant chunks of the base engine's sequence, the resulting speed is reduced to 10% to 3% of the base engine's.
xor_combine int good fast base engines yes, if one of the base engines compound engine that XOR-combines the sequences of two base engines

Some engines were considered for inclusion, but left out for the following reasons:

engine int / float quality speed size of state subsequences comments
shuffle_output int good fast base engine + 100 words no compound engine that reorders the base engine's output, little overhead for generation (one multiplication)
lagged_fibonacci both medium fast up to 80,000 words no very long cycles possible, fails birthday spacings test. Same principle of generation as subtract_with_carry, i.e. x(i) = x(i-s) (*) x(i-r), where (*) is either of +, -, xor with or without carry.
inversive_congruential (Hellekalek 1995) int good slow 1 word no x(i+1) = a x(i)-1 + c. Good equidistribution in several dimensions. Provides no apparent advantage compared to ranlux; the latter can produce floating-point numbers directly.
additive_combine (L'Ecuyer 1988) int good medium 2 words yes Combines two linear congruential generators. Same principle of combination as xor_combine, i.e. z(i) = x(i) (*) y(i), where (*) is one of +, -, xor.
R250 (Kirkpatrick and Stoll) int bad fast ~ 20 words no General Feedback Shift Register with two taps: Easily exploitable correlation.
linear_feedback_shift int medium fast 1 word no cycle length is limited to the maximum value representable in one machine word, fails some statistical tests, can be improved with the xor_combine compound engine.

The GNU Scientific Library and Swarm have additional engine that are not mentioned in the table below.

Engine this proposal CLHEP crng GNU Scientific Library Swarm Numerical Recipes Knuth
LCG(231-1, 16807) minstd_rand0 - ParkMiller ran0, minstd - ran0 p106, table 1, line 19
LCG(232, a=1664525, c=1013904223) linear_congruential< ..., 1664525, 1013904223, (1 << 32) > - - - LCG1gen - p106, table 1, line 16
LCG1 + LCG2 + LCG3 - - WichmannHill - - - -
(LCG1 - LCG2 + LCG3 - LCG4) mod m0 - - - - C4LCGXgen - -
LCG(231-1, 16807) with Bays/Durham shuffle shuffle_output<minstd_rand0, 32> (shuffle_output not in this proposal) - - ran1 PMMLCG1gen ran1 Algorithm "B"
(LCG(231-85, 40014) + LCG(231-249, 40692)) mod 231-85 ecuyer1988 (additive_combine not in this proposal) Ranecu LEcuyer - C2LCGXgen - -
(LCG(231-85, 40014) with Bays/Durham shuffle + LCG(231-249, 40692)) mod 231-85 additive_combine< shuffle_output<
linear_congruential<int, 40014, 0, 2147483563>, 32>,
linear_congruential<int, 40692, 0, 2147483399> > (additive_combine and shuffle_output not in this proposal)
- - ran2 - ran2 -
X(i) = (X(i-55) - X(i-33)) mod 109 - - - ran3 ~SCGgen ran3 -
X(i) = (X(i-100) - X(i-37)) mod 230 - - - - - - ran_array
X(i) = (X(i-55) + X(i-24)) mod 232 lagged_fibonacci< ..., 32, 55, 24, ...> (lagged_fibonacci not in this proposal) - - - ACGgen - -
DEShash(i,j) - - - - - ran4 -
MT mt19937 MTwistEngine MT19937 mt19937 MT19937gen - -
X(i) = (X(i-37) - X(i-24) - carry) mod 232 subtract_with_carry< ..., (1<<32), 37, 24, ...> - - - SWB1gen - -
X(i) = (X(i-43) - X(i-22) - carry) mod 232-5 subtract_with_carry< ..., (1<<32)-5, 43, 22, ...> - - - PSWBgen - -
RCARRY with block discard by Lüscher discard_block< subtract_with_carry<...>, ...> RanluxEngine, Ranlux64Engine Ranlux ranlx* - - -
Hurd - Hurd160, Hurd288 - - - - -
physical model by Ranshi - Ranshi - - - - -
return predefined data - NonRandom - - - - -
RANMAR: z(i) = (z(i-97) - z(i-33)) mod 224; y(i+1) = (y(i)-c) mod 224-3; X(i) = (z(i) - y(i)) mod 224 additive_combine< lagged_fibonacci< (1<<24), 97, 33, ... >, linear_congruential< (1<<24)-3, 1, c, ...> (additive_combine and lagged_fibonacci not in this proposal) JamesRandom - ranmar - - -
Taus88 taus88 = xor_combine ... - Taus88 taus, taus2 - - -
Taus60 xor_combine< linear_feedback_shift< 31, 13, 12 >, 0, linear_feedback_shift< 29, 2, 4 >, 2, 0> (linear_feedback_shift not in this proposal) - - - C2TAUSgen - -
GFSR, 4-tap - - - gfsr4 - - -
MRG32k3a - - MRG32k3a - - - -

I. Which Distributions to Include

The following distributions were chosen due to their relatively widespread use: The GNU Scientific Library has a multitude of additional distributions that are not mentioned in the table below.

Distribution this proposal CLHEP crng GNU Scientific Library Swarm Numerical Recipes Knuth
uniform (int) uniform_int - - - UniformIntegerDist - -
uniform (float) uniform_real RandFlat UniformDeviate flat UniformDoubleDist - uniform
exponential exponential_distribution RandExponential ExponentialDeviate exponential ExponentialDist exponential exponential
normal normal_distribution RandGauss* NormalDeviate gaussian NormalDist normal (gaussian) normal
lognormal - - - lognormal LogNormalDist - -
gamma gamma_distribution RandGamma GammaDeviate gamma GammaDist gamma gamma
beta - - BetaDeviate beta - - beta
poisson poisson_distribution Poisson PoissonDeviate poisson PoissonDist poisson poisson
binomial binomial_distribution RandBinomial BinomialDeviate binomial - binomial binomial
geometric geometric_distribution - GeometricDeviate geometric - - geometric
bernoulli bernoulli_distribution - BernoulliDeviate bernoulli BernoulliDist - -
random bit - RandBit - - RandomBitDist - -
breit-wigner - RandBreitWigner - - - - -
chi-square - RandChiSquare - chisq - - chi-square
landau - Landau - landau - - -
F - - - F - - F (variance-ratio)
t - - - t - - t

J. Taxonomy of Concepts

All of the engines support the number generator requirements, i.e. they are zero-argument function objects which return numbers. All of the distributions are one-argument function objects, taking a reference to an engine and returning numbers. All of the engines and some of the distributions return uniformly distributed random numbers. This is reflected in the concept of the uniform random number generator, which refines number generator. Engines for pseudo-random numbers model the requirements for pseudo-random number engine, which refines uniform random number generator.
NumberGenerator ---- UniformRandomNumberGenerator ---- PseudoRandomNumberGenerator
                \--- RandomDistribution

K. Validation

How can a user have confidence that the implementation of a random-number engine is exactly as specified, correctly taking into account any platform pecularities (e.g., odd-sized ints)? After all, minor typos in the implementation might not be apparent; the numbers produced may look "random". This proposal therefore specifies for each engine the 10000th number in the random number sequence that a default-constructed engine object produces.

This is considered an important feature for library implementors and serious users to check whether the provided library on the given platform returns the correct numbers. It could be argued that a library implementor should provide a correct implementation of some standard feature in any case.

No other library I have encountered provides explicit validation values in either their specification or their implementation, although some of them claim to be widely portable.

Another design option for validation that was part of early drafts of this proposal is moving the reference number (10000th value in the sequence) from specification space to implementation space, thus providing a validation(x) static member function for each engine that compares the hard-coded 10000th value of the sequence with some user-provided value x presumeably obtained by actually invoking the random-number engine object 10000 times. Due to the template-based design, this amounted to a "val" template value parameter for each engine, and the validation(x) function reduced to the trivial comparison "val == x". Handling validation for floating-point engines required more machinery, because template value parameters cannot be of floating-point type. Also, from a conceptual perspective, it seemed odd to demand a validation decision from the very entitiy which one wanted to validate.

L. Non-Volatile Storage of Engine and Distribution State

Pseudo-random number engines and distributions may store their state on a std::ostream in textual form and recover it from an appropriate std::istream. Each engine specifies how its internal state is represented. The specific algorithm of a distribution is left implementation-defined, thus no specifics about the representation of its internal state are given. A store operation must not affect the number sequence produced. It is expected that such external storage happens rarely as opposed to producing random numbers, thus no particular attention to performance is paid.

Engines and distributions use the usual idioms of operator<< and operator>>. If the user needs additional processing before or after storage on non-volatile media, there is always the option to use a temporary std::stringstream.

Distributions sometimes store values from their associated source of random numbers across calls to their operator(). For example, a common method for generating normally distributed random numbers is to retrieve two uniformly distributed random numbers and compute two normally distributed random numbers out of them. In order to reset the distribution's random number cache to a defined state, each distribution has a reset member function. It should be called on a distribution whenever its associated engine is exchanged or restored.

M. Values vs. References

Compounded engines such as shuffle_output and discard_block contain a base engine by value, because compounding is not intended to be used by reference to an existing (re-used) engine object.

The wrapper variate_generator can store engines either by value or by reference, explicitly chosen by the template parameters. This allows to use references to a single engine in several variate_generator, but makes it explicit to the user that he is responsible for the management of the lifetime of the engine.

N. Providing the Probability Density Function in Distributions

Some libraries provide the probability density function of a given distribution as part of that distribution's interface. While this may be useful occasionally, this proposal does not provide for such a feature. One reason is separation of concerns: The distribution class templates might benefit from precomputing large tables of values depending on the distribution parameters, while the computation of the probability density function does not. Also, the function representation is often straightforward, so the user can easily code it himself.

O. Implementation-defined behaviour

This proposal specifies implementation-defined behaviour in a number of places. I believe this is unavoidable; this section provides detailed reasoning, including why the implementation is required to document the choice.

The precise state-holding base data types for the various engines are left implementation-defined, because engines are usually optimized for binary integers with 32 bits of word size. The specification in this proposal cannot foresee whether a 32 bit quantity on the machine is available in C++ as short, int, long, or not at all. It is up to the implementation to decide which data type fits best. The implementation is required to document the choice of data type, so that users can (non-portably) rely on the precise type, for example for further computation. Should the ISO C99 extensions become part of ISO C++, the implementation-defined types could be replaced by e.g. int_least32_t.

The method how to produce non-deterministic random numbers is considered implementation-defined, because it inherently depends on the implementation and possibly even on the runtime environment: Imagine a platform that has operating system support for randomness collection, e.g. from user keystrokes and Ethernet inter-packet arrival timing (Linux /dev/random does this). If, in some installation, access to the operating system functions providing these services has been restricted, the C++ non-deterministic random number engine has been deprived of its randomness. An implementation is required to document how it obtains the non-deterministic random numbers, because only then can users' confidence in them grow. Confidence is of particular concern in the area of cryptography.

The algorithms how to produce the various distributions are specified as implementation-defined, because there is a vast variety of algorithms known for each distribution. Each has a different trade-off in terms of speed, adaptation to recent computer architectures, and memory use. The implementation is required to document its choice so that the user can judge whether it is acceptable quality-wise.

P. Lower and upper bounds on UniformRandomNumberGenerator

The member functions min() and max() return the lower and upper bounds of a UniformRandomNumberGenerator. This could be a random-number engine or one of the uniform_int and uniform_real distributions.

Those bounds are not specified to be tight, because for some engines, the bounds depend on the seeds. The seed can be changed during the lifetime of the engine object, while the values returned by min() and max() are invariant. Therefore, min() and max() must return conservative bounds that are independent of the seed.

Q. With or without manager class

This proposal presents a design with a manager class template, variate_generator, after extensive discussion with some members of the computing division of Fermi National Accelerator Laboratory. User-written and library-provided engines and distributions plug in to the manager class. The approach is remotely similar to the locale design in the standard library, where (user-written) facets plug in to the (library-provided) locale class.

Earlier versions of this propsoal made (potentially user-written) distributions directly visible to (some other) user that wants to get random numbers distributed accordingly ("client"), there was no additional management layer between the distribution and the client.

The following additional features could be provided by the management layer:

It is envisioned that user-written distributions will often be based on some arbitrary algorithmic distribution, instead of trying to implement a given mathematical probability density function. Here is an example: Both in this case and when implementing complex distributions based on a probability density function (e.g. the gamma distribution), it is important to be able to arbitrarily nest distributions. Either design allows for this with utmost ease: Compounding distributions are contained in the compound by value, and each one produces a single value on invocation. With the alternative design of giving distributions the freedom to produce more than one output number in each invocation, compound distributions such as the one shown above need to handle the situation that each of the compounding members could provide several output values, the number of which is unknown at the time the distribution is written. (Remember that it is unfeasible to prescribe a precise algorithm for each library-provided distribution in the standard, see subsection O.) That approach shifts implementation effort from the place where it came up, i.e. the distribution that chose to use an algorithm that produces several values in one invocation, to the places where that distribution is used. This, considered by itself, does not seem to be a good approach. Also, only very few distributions lead to a natural implementation that produces several values in one invocation; so far, the normal distribution is the only one known to me. However, it is expected that there will be plenty of distributions that use a normal distribution as its base, so far those known to me are lognormal and uniform_on_sphere (both not part of this proposal). As a conclusion, independent of whether the design provides for a management layer or not, distributions should always return a single value on each invocation, and management of buffers for additional values that might be produced should be internal to the distribution. Should it become necessary for the user to employ buffer management more often, a user-written base class for the distributions could be of help.

The ability to share engines is important. This proposal makes lifetime management issues explicit by requiring pointer or reference types in the template instantiation of variate_generator if reference semantics are desired. Without a management class, providing this features is much more cumbersome and imposes additional burden on the programmers that produce distributions. Alternatively, reference semantics could always be used, but this is an error-prone approach due to the lack of a standard reference-counted smart pointer. I believe it is impossible to add a reference-counted sharing mechanism in a manager-class-free design without giving its precise type. And that would certainly conflict in semantic scope with a smart pointer that will get into the standard eventually.

The management layer allows for a few common features to be factored out, in particular access to the engine and some member typedefs.

Comparison of other differing features between manager and non-manager designs:

R. Add-on packages

This proposal specifies a framework for random number generation. Users might have additional requirements not met by this framework. The following extensions have been identified, and they are expressly not addressed in this proposal. It is perceived that these items can be seamlessly implemented in an add-on package which sits on top of an implementation according to this proposal.

S. Adaptors

Sometimes, users may want to have better control how the bits from the engine are used to fill the mantissa of the floating-point value that serves as input to some distribution. This is possible by writing an engine wrapper and passing that in to the variate_generator as the engine. The variate_generator will only apply automatic adaptations if the output type of the engine is integers and the input type for the distribution is floating-point or vice versa.

Z. Open issues

IV. Proposed Text

(Insert the following as a new section in clause 26 "Numerics". Adjust the overview at the beginning of clause 26 accordingly.)

This subclause defines a facility for generating random numbers.

Random number requirements

A number generator is a function object (std:20.3 [lib.function.objects]).

In the following table, X denotes a number generator class returning objects of type T, and u is a (possibly const) value of X.

Number generator requirements (in addition to function object)
expression return type pre/post-condition complexity
X::result_type T std::numeric_limits<T>::is_specialized is true compile-time

In the following table, X denotes a uniform random number generator class returning objects of type T, u is a value of X and v is a (possibly const) value of X.

Uniform random number generator requirements (in addition to number generator)
expression return type pre/post-condition complexity
u() T - amortized constant
v.min() T Returns some l where l is less than or equal to all values potentially returned by operator(). The return value of this function shall not change during the lifetime of v. constant
v.max() T If std::numeric_limits<T>::is_integer, returns l where l is less than or equal to all values potentially returned by operator(), otherwise, returns l where l is strictly less than all values potentially returned by operator(). In any case, the return value of this function shall not change during the lifetime of v. constant

In the following table, X denotes a pseudo-random number engine class returning objects of type T, t is a value of T, u is a value of X, v is an lvalue of X, it1 is an lvalue and it2 is a (possibly const) value of an input iterator type It having an unsigned integral value type, x, y are (possibly const) values of X, os is convertible to an lvalue of type std::ostream, and is is convertible to an lvalue of type std::istream.

A pseudo-random number engine x has a state x(i) at any given time. The specification of each pseudo-random number engines defines the size of its state in multiples of the size of its result_type, given as an integral constant expression.

Pseudo-random number engine requirements (in addition to uniform random number generator, CopyConstructible, and Assignable)
expressionreturn type pre/post-condition complexity
X() - creates an engine with the same initial state as all other default-constructed engines of type X in the program. O(size of state)
X(it1, it2) - creates an engine with the initial state given by the range [it1,it2). it1 is advanced by the size of state. If the size of the range [it1,it2) is insufficient, leaves it1 == it2 and throws invalid_argument. O(size of state)
u.seed() void post: u == X() O(size of state)
u.seed(it1, it2) void post: If there are sufficiently many values in [it1, it2) to initialize the state of u, then u == X(it1,it2). Otherwise, it1 == it2, throws invalid_argument, and further use of u (except destruction) is undefined until a seed member function has been executed without throwing an exception. O(size of state)
u() T given the state u(i) of the engine, computes u(i+1), sets the state to u(i+1), and returns some output dependent on u(i+1) amortized constant
x == y bool == is an equivalence relation. The current state x(i) of x is equal to the current state y(j) of y. O(size of state)
x != y bool !(x == y) O(size of state)
os << x std::ostream& writes the textual representation of the state x(i) of x to os, with os.fmtflags set to ios_base::dec|ios_base::fixed|ios_base::left and the fill character set to the space character. In the output, adjacent numbers are separated by one or more space characters.
post: The os.fmtflags and fill character are unchanged.
O(size of state)
is >> v std::istream& sets the state v(i) of v as determined by reading its textual representation from is.
post: The is.fmtflags are unchanged.
O(size of state)

In the following table, X denotes a random distribution class returning objects of type T, u is a value of X, x is a (possibly const) value of X, and e is an lvalue of an arbitrary type that meets the requirements of a uniform random number generator, returning values of type U.

Random distribution requirements (in addition to number generator, CopyConstructible, and Assignable)
expressionreturn type pre/post-condition complexity
X::input_type U - compile-time
u.reset() void subsequent uses of u do not depend on values produced by e prior to invoking reset. constant
u(e) T the sequence of numbers returned by successive invocations with the same object e is randomly distributed with some probability density function p(x) amortized constant number of invocations of e
os << x std::ostream& writes a textual representation for the parameters and additional internal data of the distribution x to os.
post: The os.fmtflags and fill character are unchanged.
O(size of state)
is >> u std::istream& restores the parameters and additional internal data of the distribution u.
pre: is provides a textual representation that was previously written by operator<<
post: The is.fmtflags are unchanged.
O(size of state)

Additional requirements: The sequence of numbers produced by repeated invocations of x(e) does not change whether or not os << x is invoked between any of the invocations x(e). If a textual representation is written using os << x and that representation is restored into the same or a different object y of the same type using is >> y, repeated invocations of y(e) produce the same sequence of random numbers as would repeated invocations of x(e).

In the following subclauses, a template parameter named UniformRandomNumberGenerator shall denote a class that satisfies all the requirements of a uniform random number generator. Moreover, a template parameter named Distribution shall denote a type that satisfies all the requirements of a random distribution. Furthermore, a template parameter named RealType shall denote a type that holds an approximation to a real number. This type shall meet the requirements for a numeric type (26.1 [lib.numeric.requirements]), the binary operators +, -, *, / shall be applicable to it, a conversion from double shall exist, and function signatures corresponding to those for type double in subclause 26.5 [lib.c.math] shall be available by argument-dependent lookup (3.4.2 [basic.lookup.koenig]). [Note: The built-in floating-point types float and double meet these requirements.]

Header <random> synopsis

namespace std {
  template<class UniformRandomNumberGenerator, class Distribution>
  class variate_generator;

  template<class IntType, IntType a, IntType c, IntType m>
  class linear_congruential;

  template<class UIntType, int w, int n, int m, int r, UIntType a, int u,
  int s, UIntType b, int t, UIntType c, int l>
  class mersenne_twister;

  template<class IntType, IntType m, int s, int r>
  class subtract_with_carry;

  template<class RealType, int w, int s, int r>
  class subtract_with_carry_01;

  template<class UniformRandomNumberGenerator, int p, int r>
  class discard_block;

  template<class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  class xor_combine;

  class random_device;

  template<class IntType = int>
  class uniform_int;

  template<class RealType = double>
  class bernoulli_distribution;

  template<class IntType = int, class RealType = double>
  class geometric_distribution;

  template<class IntType = int, class RealType = double>
  class poisson_distribution;

  template<class IntType = int, class RealType = double>
  class binomial_distribution;

  template<class RealType = double>
  class uniform_real;

  template<class RealType = double>
  class exponential_distribution;

  template<class RealType = double>
  class normal_distribution;

  template<class RealType = double>
  class gamma_distribution;

} // namespace std

Class template variate_generator

A variate_generator produces random numbers, drawing randomness from an underlying uniform random number generator and shaping the distribution of the numbers corresponding to a distribution function.
template<class Engine, class Distribution>
class variate_generator
{
public:
  typedef Engine engine_type;
  typedef /* implementation defined */ engine_value_type;
  typedef Distribution distribution_type;
  typedef typename Distribution::result_type result_type;

  variate_generator(engine_type eng, distribution_type d);

  result_type operator()();
  template<class T>  result_type operator()(T value);

  engine_value_type& engine();
  const engine_value_type& engine() const;

  distribution_type& distribution();
  const distribution_type& distribution() const;

  result_type min() const;
  result_type max() const;
};
The template argument for the parameter Engine shall be of the form U, U&, or U*, where U denotes a class that satisfies all the requirements of a uniform random number generator. The member engine_value_type shall name U.

Specializations of variate_generator satisfy the requirements of CopyConstructible. They also satisfy the requirements of Assignable unless the template parameter Engine is of the form U&.

The complexity of all functions specified in this section is constant. No function described in this section except the constructor throws an exception.

    variate_generator(engine_type eng, distribution_type d)
Effects: Constructs a variate_generator object with the associated uniform random number generator eng and the associated random distribution d.
Throws: If and what the copy constructor of Engine or Distribution throws.
    result_type operator()()
Returns: distribution()(e)
Notes: The sequence of numbers produced by the uniform random number generator e, se, is obtained from the sequence of numbers produced by the associated uniform random number generator eng, seng, as follows: Consider the values of numeric_limits<T>::is_integer for T both Distribution::input_type and engine_value_type::result_type. If the values for both types are true, then se is identical to seng. Otherwise, if the values for both types are false, then the numbers in seng are divided by engine().max()-engine().min() to obtain the numbers in se. Otherwise, if the value for engine_value_type::result_type is true and the value for Distribution::input_type is false, then the numbers in seng are divided by engine().max()-engine().min()+1 to obtain the numbers in se. Otherwise, the mapping from seng to se is implementation-defined. In all cases, an implicit conversion from engine_value_type::result_type to Distribution::input_type is performed. If such a conversion does not exist, the program is ill-formed.
    template<class T> result_type operator()(T value)
Returns: distribution()(e, value). For the semantics of e, see the description of operator()().
    engine_value_type& engine()
Returns: A reference to the associated uniform random number generator.
    const engine_value_type& engine() const
Returns: A reference to the associated uniform random number generator.
    distribution_type& distribution()
Returns: A reference to the associated random distribution.
    const distribution_type& distribution() const
Returns: A reference to the associated random distribution.
    result_type min() const
Precondition: distribution().min() is well-formed
Returns: distribution().min()
    result_type max() const
Precondition: distribution().max() is well-formed
Returns: distribution().max()

Random number engine class templates

Except where specified otherwise, the complexity of all functions specified in the following sections is constant. No function described in this section except the constructor and seed functions taking an iterator range [it1,it2) throws an exception.

The class templates specified in this section satisfy all the requirements of a pseudo-random number engine (given in tables in section x.x), except where specified otherwise. Descriptions are provided here only for operations on the engines that are not described in one of these tables or for operations where there is additional semantic information.

All members declared static const in any of the following class templates shall be defined in such a way that they are usable as integral constant expressions.

Class template linear_congruential

A linear_congruential engine produces random numbers using a linear function x(i+1) := (a * x(i) + c) mod m.
namespace std {
  template<class IntType, IntType a, IntType c, IntType m>
  class linear_congruential
  {
  public:
    // types
    typedef IntType result_type;

    // parameter values
    static const IntType multiplier = a;
    static const IntType increment = c;
    static const IntType modulus = m;

    //  constructors and member function
    explicit linear_congruential(IntType x0 = 1);
    template<class In> linear_congruential(In& first, In last);
    void seed(IntType x0 = 1);
    template<class In> void seed(In& first, In last);
    result_type min() const;
    result_type max() const;
    result_type operator()();
  };

  template<class IntType, IntType a, IntType c, IntType m>
  bool operator==(const linear_congruential<IntType, a, c, m>& x,
                  const linear_congruential<IntType, a, c, m>& y);
  template<class IntType, IntType a, IntType c, IntType m>
  bool operator!=(const linear_congruential<IntType, a, c, m>& x,
                  const linear_congruential<IntType, a, c, m>& y);

  template<class CharT, class traits,
           class IntType, IntType a, IntType c, IntType m>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const linear_congruential<IntType, a, c, m>& x);  
  template<class CharT, class traits,
           class IntType, IntType a, IntType c, IntType m>
  basic_istream<CharT, traits>& operator>>(basic_istream<CharT, traits>& is, 
                                           linear_congruential<IntType, a, c, m>& x);
}
The template parameter IntType shall denote an integral type large enough to store values up to (m-1). If the template parameter m is 0, the behaviour is implementation-defined. Otherwise, the template parameters a and c shall be less than m.

The size of the state x(i) is 1.

    explicit linear_congruential(IntType x0 = 1)
Requires: c > 0 || (x0 % m) > 0
Effects: Constructs a linear_congruential engine with state x(0) := x0 mod m.
    void seed(IntType x0 = 1)
Requires: c > 0 || (x0 % m) > 0
Effects: Sets the state x(i) of the engine to x0 mod m.
    template<class In> linear_congruential(In& first, In last)
Requires: c > 0 || *first > 0
Effects: Sets the state x(i) of the engine to *first mod m.
Complexity: Exactly one dereference of *first.
  template<class CharT, class traits,
           class IntType, IntType a, IntType c, IntType m>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const linear_congruential<IntType, a, c, m>& x);  
Effects: Writes x(i) to os.

Class template mersenne_twister

A mersenne_twister engine produces random numbers o(x(i)) using the following computation, performed modulo 2w. um is a value with only the upper w-r bits set in its binary representation. lm is a value with only its lower r bits set in its binary representation. rshift is a bitwise right shift with zero-valued bits appearing in the high bits of the result. lshift is a bitwise left shift with zero-valued bits appearing in the low bits of the result.
namespace std {
  template<class UIntType, int w, int n, int m, int r, UIntType a, int u,
  int s, UIntType b, int t, UIntType c, int l>
  class mersenne_twister
  {
  public:
    // types
    typedef UIntType result_type;

    // parameter values
    static const int word_size = w;
    static const int state_size = n;
    static const int shift_size = m;
    static const int mask_bits = r;
    static const UIntType parameter_a = a;
    static const int output_u = u;
    static const int output_s = s;
    static const UIntType output_b = b;
    static const int output_t = t;
    static const UIntType output_c = c;
    static const int output_l = l;

    //  constructors and member function
    mersenne_twister();
    explicit mersenne_twister(UIntType value);
    template<class In> mersenne_twister(In& first, In last);
    void seed();
    void seed(UIntType value);
    template<class In> void seed(In& first, In last);
    result_type min() const;
    result_type max() const;
    result_type operator()();
  };

  template<class UIntType, int w, int n, int m, int r, UIntType a, int u,
           int s, UIntType b, int t, UIntType c, int l>
  bool operator==(const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& y,
                  const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x);
  template<class UIntType, int w, int n, int m, int r, UIntType a, int u,
           int s, UIntType b, int t, UIntType c, int l>
  bool operator!=(const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& y,
                  const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x);

  template<class CharT, class traits,
           class UIntType, int w, int n, int m, int r, UIntType a, int u,
           int s, UIntType b, int t, UIntType c, int l>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x);
  template<class CharT, class traits,
           class UIntType, int w, int n, int m, int r, UIntType a, int u,
           int s, UIntType b, int t, UIntType c, int l>
  basic_istream<CharT, traits>& operator>>(basic_istream<CharT, traits>& is, 
                                           mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x);
}
The template parameter UIntType shall denote an unsigned integral type large enough to store values up to 2w-1. Also, the following relations shall hold: 1<=m<=n. 0<=r,u,s,t,l<=w. 0<=a,b,c<=2w-1.

The size of the state x(i) is n.

    mersenne_twister()
Effects: Constructs a mersenne_twister engine and invokes seed().
    explicit mersenne_twister(result_type value)
Effects: Constructs a mersenne_twister engine and invokes seed(value).
    template<class In> mersenne_twister(In& first, In last)
Effects: Constructs a mersenne_twister engine and invokes seed(first, last).
    void seed()
Effects: Invokes seed(4357).
    void seed(result_type value)
Requires: value > 0
Effects: With a linear congruential generator l(i) having parameters ml = 232, al = 69069, cl = 0, and l(0) = value, sets x(-n) ... x(-1) to l(1) ... l(n), respectively.
Complexity: O(n)
    template<class In> void seed(In& first, In last)
Effects: Given the values z0 ... zn-1 obtained by dereferencing [first, first+n), sets x(-n) ... x(-1) to z0 mod 2w ... zn-1 mod 2w.
Complexity: Exactly n dereferences of first.
    template<class UIntType, int w, int n, int m, int r, UIntType a, int u,
             int s, UIntType b, int t, UIntType c, int l>
    bool operator==(const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& y,
                    const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x)
Returns: x(i-n) == y(j-n) and ... and x(i-1) == y(j-1)
Notes: Assumes the next output of x is o(x(i)) and the next output of y is o(y(j)).
Complexity: O(n)
    template<class CharT, class traits,
             class UIntType, int w, int n, int m, int r, UIntType a, int u,
             int s, UIntType b, int t, UIntType c, int l>
    basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                             const mersenne_twister<UIntType, w, n, m, r, a, u, s, b, t, c, l>& x)
Effects: Writes x(i-n), ... x(i-1) to os, in that order.
Complexity: O(n)

Class template subtract_with_carry

A subtract_with_carry engine produces integer random numbers using x(i) = (x(i-s) - x(i-r) - carry(i-1)) mod m; carry(i) = 1 if x(i-s) - x(i-r) - carry(i-1) < 0, else carry(i) = 0.

namespace std {
  template<class IntType, IntType m, int s, int r>
  class subtract_with_carry
  {
  public:
    // types
    typedef IntType result_type;

    // parameter values
    static const IntType modulus = m;
    static const int long_lag = r;
    static const int short_lag = s;

    //  constructors and member function
    subtract_with_carry();
    explicit subtract_with_carry(IntType value);
    template<class In> subtract_with_carry(In& first, In last);
    void seed(IntType value = 19780503);
    template<class In> void seed(In& first, In last);
    result_type min() const;
    result_type max() const;
    result_type operator()();
  };
  template<class IntType, IntType m, int s, int r>
  bool operator==(const subtract_with_carry<IntType, m, s, r> & x,
                  const subtract_with_carry<IntType, m, s, r> & y);

  template<class IntType, IntType m, int s, int r>
  bool operator!=(const subtract_with_carry<IntType, m, s, r> & x,
                  const subtract_with_carry<IntType, m, s, r> & y);

  template<class CharT, class Traits,
           class IntType, IntType m, int s, int r>
  std::basic_ostream<CharT,Traits>& operator<<(std::basic_ostream<CharT,Traits>& os,
                                               const subtract_with_carry<IntType, m, s, r>& f);

  template<class CharT, class Traits,
          class IntType, IntType m, int s, int r>
  std::basic_istream<CharT,Traits>& operator>>(std::basic_istream<CharT,Traits>& is, 
                                               subtract_with_carry<IntType, m, s, r>& f);
}
The template parameter IntType shall denote a signed integral type large enough to store values up to m-1. The following relation shall hold: 0<s<r. Let w the number of bits in the binary representation of m.

The size of the state is r.

    subtract_with_carry()
Effects: Constructs a subtract_with_carry engine and invokes seed().
    explicit subtract_with_carry(IntType value)
Effects: Constructs a subtract_with_carry engine and invokes seed(value).
    template<class In> subtract_with_carry(In& first, In last)
Effects: Constructs a subtract_with_carry engine and invokes seed(first, last).
    void seed(IntType value = 19780503)
Requires: value > 0
Effects: With a linear congruential generator l(i) having parameters ml = 2147483563, al = 40014, cl = 0, and l(0) = value, sets x(-r) ... x(-1) to l(1) mod m ... l(r) mod m, respectively. If x(-1) == 0, sets carry(-1) = 1, else sets carry(-1) = 0.
Complexity: O(r)
    template<class In> void seed(In& first, In last)
Effects: With n=w/32+1 (rounded downward) and given the values z0 ... zn*r-1 obtained by dereferencing [first, first+n*r), sets x(-r) ... x(-1) to (z0 * 232 + ... + zn-1 * 232*(n-1)) mod m ... (z(r-1)*n * 232 + ... + zr-1 * 232*(n-1)) mod m. If x(-1) == 0, sets carry(-1) = 1, else sets carry(-1) = 0.
Complexity: Exactly r*n dereferences of first.
    template<class IntType, IntType m, int s, int r>
    bool operator==(const subtract_with_carry<IntType, m, s, r> & x,
                    const subtract_with_carry<IntType, m, s, r> & y)
Returns: x(i-r) == y(j-r) and ... and x(i-1) == y(j-1).
Notes: Assumes the next output of x is x(i) and the next output of y is y(j).
Complexity: O(r)
    template<class CharT, class Traits,
          class IntType, IntType m, int s, int r>
    std::basic_ostream<CharT,Traits>& operator<<(std::basic_ostream<CharT,Traits>& os,
                                                 const subtract_with_carry<IntType, m, s, r>& f)
Effects: Writes x(i-r) ... x(i-1), carry(i-1) to os, in that order.
Complexity: O(r)

Class template subtract_with_carry_01

A subtract_with_carry_01 engine produces floating-point random numbers using x(i) = (x(i-s) - x(i-r) - carry(i-1)) mod 1; carry(i) = 2-w if x(i-s) - x(i-r) - carry(i-1) < 0, else carry(i) = 0.

namespace std {
  template<class RealType, int w, int s, int r>
  class subtract_with_carry_01
  {
  public:
    // types
    typedef RealType result_type;

    // parameter values
    static const int word_size = w;
    static const int long_lag = r;
    static const int short_lag = s;

    //  constructors and member function
    subtract_with_carry_01();
    explicit subtract_with_carry_01(unsigned int value);
    template<class In> subtract_with_carry_01(In& first, In last);
    void seed(unsigned int value = 19780503);
    template<class In> void seed(In& first, In last);
    result_type min() const;
    result_type max() const;
    result_type operator()();
  };
  template<class RealType, int w, int s, int r>
  bool operator==(const subtract_with_carry_01<RealType, w, s, r> x,
                  const subtract_with_carry_01<RealType, w, s, r> y);

  template<class RealType, int w, int s, int r>
  bool operator!=(const subtract_with_carry_01<RealType, w, s, r> x,
                  const subtract_with_carry_01<RealType, w, s, r> y);

  template<class CharT, class Traits,
           class RealType, int w, int s, int r>
  std::basic_ostream<CharT,Traits>& operator<<(std::basic_ostream<CharT,Traits>& os,
                                               const subtract_with_carry_01<RealType, w, s, r>& f);

  template<class CharT, class Traits,
           class RealType, int w, int s, int r>
  std::basic_istream<CharT,Traits>& operator>>(std::basic_istream<CharT,Traits>& is, 
                                               subtract_with_carry_01<RealType, w, s, r>& f);
}
The following relation shall hold: 0<s<r.

The size of the state is r.

    subtract_with_carry_01()
Effects: Constructs a subtract_with_carry_01 engine and invokes seed().
    explicit subtract_with_carry_01(unsigned int value)
Effects: Constructs a subtract_with_carry_01 engine and invokes seed(value).
    template<class In> subtract_with_carry_01(In& first, In last)
Effects: Constructs a subtract_with_carry_01 engine and invokes seed(first, last).
    void seed(unsigned int value = 19780503)
Effects: With a linear congruential generator l(i) having parameters m = 2147483563, a = 40014, c = 0, and l(0) = value, sets x(-r) ... x(-1) to (l(1)*2-w) mod 1 ... (l(r)*2-w) mod 1, respectively. If x(-1) == 0, sets carry(-1) = 2-w, else sets carry(-1) = 0.
Complexity: O(r)
    template<class In> void seed(In& first, In last)
Effects: With n=w/32+1 (rounded downward) and given the values z0 ... zn*r-1 obtained by dereferencing [first, first+n*r), sets x(-r) ... x(-1) to (z0 * 232 + ... + zn-1 * 232*(n-1)) * 2-w mod 1 ... (z(r-1)*n * 232 + ... + zr-1 * 232*(n-1)) * 2-w mod 1. If x(-1) == 0, sets carry(-1) = 2-w, else sets carry(-1) = 0.
Complexity: O(r*n)
    template<class RealType, int w, int s, int r>
    bool operator==(const subtract_with_carry<RealType, w, s, r> x,
                    const subtract_with_carry<RealType, w, s, r> y);
Returns: true, if and only if x(i-r) == y(j-r) and ... and x(i-1) == y(j-1).
Complexity: O(r)
    template<class CharT, class Traits,
             class RealType, int w, int s, int r>
    std::basic_ostream<CharT,Traits>& operator<<(std::basic_ostream<CharT,Traits>& os,
                                                 const subtract_with_carry<RealType, w, s, r>& f);
Effects: Write x(i-r)*2w ... x(i-1)*2w, carry(i-1)*2w to os, in that order.
Complexity: O(r)

Class template discard_block

A discard_block engine produces random numbers from some base engine by discarding blocks of data.

namespace std {
  template<class UniformRandomNumberGenerator, int p, int r>
  class discard_block
  {
  public:
    // types
    typedef UniformRandomNumberGenerator base_type;
    typedef typename base_type::result_type result_type;
  
    // parameter values
    static const int block_size = p;
    static const int used_block = r;
  
    //  constructors and member function
    discard_block();
    explicit discard_block(const base_type & rng);
    template<class In> discard_block(In& first, In last);
    void seed();
    template<class In> void seed(In& first, In last);
    const base_type& base() const;
    result_type min() const;
    result_type max() const;
    result_type operator()();  
  private:
    // base_type b;                 exposition only
    // int n;                       exposition only
  };
  template<class UniformRandomNumberGenerator, int p, int r>
  bool operator==(const discard_block<UniformRandomNumberGenerator,p,r> & x,
                 (const discard_block<UniformRandomNumberGenerator,p,r> & y);
  template<class UniformRandomNumberGenerator, int p, int r,
    typename UniformRandomNumberGenerator::result_type val>
  bool operator!=(const discard_block<UniformRandomNumberGenerator,p,r> & x,
                 (const discard_block<UniformRandomNumberGenerator,p,r> & y);

  template<class CharT, class traits,
           class UniformRandomNumberGenerator, int p, int r>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const discard_block<UniformRandomNumberGenerator,p,r> & x);
  template<class CharT, class traits,
           class UniformRandomNumberGenerator, int p, int r>
  basic_istream<CharT, traits>& operator>>(basic_istream<CharT, traits>& is, 
                                           discard_block<UniformRandomNumberGenerator,p,r> & x);

}
The template parameter UniformRandomNumberGenerator shall denote a class that satisfies all the requirements of a uniform random number generator, given in tables in section x.x. r <= p. The size of the state is the size of b plus 1.
    discard_block()
Effects: Constructs a discard_block engine. To construct the subobject b, invokes its default constructor. Sets n = 0.
    explicit discard_block(const base_type & rng)
Effects: Constructs a discard_block engine. Initializes b with a copy of rng. Sets n = 0.
    template<class In> discard_block(In& first, In last)
Effects: Constructs a discard_block engine. To construct the subobject b, invokes the b(first, last) constructor. Sets n = 0.
    void seed()
Effects: Invokes b.seed() and sets n = 0.
    template<class In> void seed(In& first, In last)
Effects: Invokes b.seed(first, last) and sets n = 0.
    const base_type& base() const
Returns: b
    result_type operator()()
Effects: If n >= r, invokes b (p-r) times, discards the values returned, and sets n = 0. In any case, then increments n and returns b().
  template<class CharT, class traits,
           class UniformRandomNumberGenerator, int p, int r>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const discard_block<UniformRandomNumberGenerator,p,r> & x);
Effects: Writes b, then n to os.

Class template xor_combine

A xor_combine engine produces random numbers from two integer base engines by merging their random values with bitwise exclusive-or.

namespace std {
  template<class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  class xor_combine
  {
  public:
    // types
    typedef UniformRandomNumberGenerator1 base1_type;
    typedef UniformRandomNumberGenerator2 base2_type;
    typedef typename base_type::result_type result_type;
  
    // parameter values
    static const int shift1 = s1;
    static const int shift2 = s2;
  
    //  constructors and member function
    xor_combine();
    xor_combine(const base1_type & rng1, const base2_type & rng2);
    template<class In> xor_combine(In& first, In last);
    void seed();
    template<class In> void seed(In& first, In last);
    const base1_type& base1() const;
    const base2_type& base2() const;
    result_type min() const;
    result_type max() const;
    result_type operator()();  
  private:
    // base1_type b1;               exposition only
    // base2_type b2;               exposition only
  };
  template<class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  bool operator==(const xor_combine<UniformRandomNumberGenerator1, s1, 
                                    UniformRandomNumberGenerator2, s2> & x,
                 (const xor_combine<UniformRandomNumberGenerator1, s1,
                                    UniformRandomNumberGenerator2, s2> & y);
  template<class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  bool operator!=(const xor_combine<UniformRandomNumberGenerator1, s1,
                                    UniformRandomNumberGenerator2, s2> & x,
                 (const xor_combine<UniformRandomNumberGenerator1, s1,
                                    UniformRandomNumberGenerator2, s2> & y);

  template<class CharT, class traits,
           class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const xor_combine<UniformRandomNumberGenerator1, s1,
                                                             UniformRandomNumberGenerator2, s2> & x);
  template<class CharT, class traits,
           class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  basic_istream<CharT, traits>& operator>>(basic_istream<CharT, traits>& is, 
                                           xor_combine<UniformRandomNumberGenerator1, s1,
                                                       UniformRandomNumberGenerator2, s2> & x);

}
The template parameters UniformRandomNumberGenerator1 and UniformRandomNumberGenerator1 shall denote classes that satisfy all the requirements of a uniform random number generator, given in tables in section x.x . The size of the state is the size of b1 plus the size of b2.
    xor_combine()
Effects: Constructs a xor_combine engine. To construct each of the subobjects b1 and b2, invokes their respective default constructors.
    xor_combine(const base1_type & rng1, const base2_type & rng2)
Effects: Constructs a xor_combine engine. Initializes b1 with a copy of rng1 and b2 with a copy of rng2.
    template<class In> xor_combine(In& first, In last)
Effects: Constructs a xor_combine engine. To construct the subobject b1, invokes the b1(first, last) constructor. Then, to construct the subobject b2, invokes the b2(first, last) constructor.
    void seed()
Effects: Invokes b1.seed() and b2.seed().
    template<class In> void seed(In& first, In last)
Effects: Invokes b1.seed(first, last), then invokes b2.seed(first, last).
    const base1_type& base1() const
Returns: b1
    const base2_type& base2() const
Returns: b2
    result_type operator()()
Returns: (b1() << s1) ^ (b2() << s2).
  template<class CharT, class traits,
           class UniformRandomNumberGenerator1, int s1,
           class UniformRandomNumberGenerator2, int s2>
  basic_ostream<CharT, traits>& operator<<(basic_ostream<CharT, traits>& os,
                                           const xor_combine<UniformRandomNumberGenerator1, s1,
                                                             UniformRandomNumberGenerator2, s2> & x);
Effects: Writes b1, then b2 to os.

Engines with predefined parameters

namespace std {
  typedef linear_congruential</* implementation defined */, 16807, 0, 2147483647> minstd_rand0;
  typedef linear_congruential</* implementation defined */, 48271, 0, 2147483647> minstd_rand;

  typedef mersenne_twister</* implementation defined */,32,624,397,31,0x9908b0df,11,7,0x9d2c5680,15,0xefc60000,18> mt19937;

  typedef subtract_with_carry_01 ranlux_base_01;
  typedef subtract_with_carry_01 ranlux64_base_01;

  typedef discard_block<subtract_with_carry</* implementation defined */, (1<<24), 10, 24>, 223, 24> ranlux3;
  typedef discard_block<subtract_with_carry</* implementation defined */, (1<<24), 10, 24>, 389, 24> ranlux4;

  typedef discard_block<subtract_with_carry_01<float, 24, 10, 24>, 223, 24> ranlux3_01;
  typedef discard_block<subtract_with_carry_01<float, 24, 10, 24>, 389, 24> ranlux4_01;
}
For a default-constructed minstd_rand0 object, x(10000) = 1043618065. For a default-constructed minstd_rand object, x(10000) = 399268537.

For a default-constructed mt19937 object, x(10000) = 3346425566.

For a default-constructed ranlux3 object, x(10000) = 5957620. For a default-constructed ranlux4 object, x(10000) = 8587295. For a default-constructed ranlux3_01 object, x(10000) = 5957620 * 2-24. For a default-constructed ranlux4_01 object, x(10000) = 8587295 * 2-24.

Class random_device

A random_device produces non-deterministic random numbers. It satisfies all the requirements of a uniform random number generator (given in tables in section x.x). Descriptions are provided here only for operations on the engines that are not described in one of these tables or for operations where there is additional semantic information.

If implementation limitations prevent generating non-deterministic random numbers, the implementation can employ a pseudo-random number engine.

namespace std {
  class random_device
  {
  public:
    // types
    typedef unsigned int result_type;

    // constructors, destructors and member functions
    explicit random_device(const std::string& token = /* implementation-defined */);
    result_type min() const;
    result_type max() const;
    double entropy() const;
    result_type operator()();
  
  private:
    random_device(const random_device& );
    void operator=(const random_device& );
  };
}
    explicit random_device(const std::string& token = /* implementation-defined */)
Effects: Constructs a random_device non-deterministic random number engine. The semantics and default value of the token parameter are implementation-defined. [Footnote: The parameter is intended to allow an implementation to differentiate between different sources of randomness.]
Throws: A value of some type derived from exception if the random_device could not be initialized.
    result_type min() const
Returns: numeric_limits<result_type>::min()
    result_type max() const
Returns: numeric_limits<result_type>::max()
    double entropy() const
Returns: An entropy estimate for the random numbers returned by operator(), in the range min() to log2( max()+1). A deterministic random number generator (e.g. a pseudo-random number engine) has entropy 0.
Throws: Nothing.
    result_type operator()()
Returns: A non-deterministic random value, uniformly distributed between min() and max(), inclusive. It is implementation-defined how these values are generated.
Throws: A value of some type derived from exception if a random number could not be obtained.

Random distribution class templates

The class templates specified in this section satisfy all the requirements of a random distribution (given in tables in section x.x). Descriptions are provided here only for operations on the distributions that are not described in one of these tables or for operations where there is additional semantic information.

A template parameter named IntType shall denote a type that represents an integer number. This type shall meet the requirements for a numeric type (26.1 [lib.numeric.requirements]), the binary operators +, -, *, /, % shall be applicable to it, and a conversion from int shall exist. [Footnote: The built-in types int and long meet these requirements.]

Given an object whose type is specified in this subclause, if the lifetime of the uniform random number generator referred to in the constructor invocation for that object has ended, any use of that object is undefined.

No function described in this section throws an exception, unless an operation on values of IntType or RealType throws an exception. [Note: Then, the effects are undefined, see [lib.numeric.requirements]. ]

The algorithms for producing each of the specified distributions are implementation-defined.

Class template uniform_int

A uniform_int random distribution produces integer random numbers x in the range min <= x <= max, with equal probability. min and max are the parameters of the distribution.

A uniform_int random distribution satisfies all the requirements of a uniform random number generator (given in tables in section x.x).

namespace std {
  template<class IntType = int>
  class uniform_int
  {
  public:
    // types
    typedef IntType input_type;
    typedef IntType result_type;

    //  constructors and member function
    explicit uniform_int(IntType min = 0, IntType max = 9);
    result_type min() const;
    result_type max() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng, result_type n);
  };
}
    uniform_int(IntType min = 0, IntType max = 9)
Requires: min <= max
Effects: Constructs a uniform_int object. min and max are the parameters of the distribution.
    result_type min() const
Returns: The "min" parameter of the distribution.
    result_type max() const
Returns: The "max" parameter of the distribution.
    result_type operator()(UniformRandomNumberGenerator& urng, result_type n)
Returns: A uniform random number x in the range 0 <= x < n. [Note: This allows a variate_generator object with a uniform_int distribution to be used with std::random_shuffe, see [lib.alg.random.shuffle]. ]

Class template bernoulli_distribution

A bernoulli_distribution random distribution produces bool values distributed with probabilities p(true) = p and p(false) = 1-p. p is the parameter of the distribution.
namespace std {
  template<class RealType = double>
  class bernoulli_distribution
  {
  public:
    // types
    typedef int input_type;
    typedef bool result_type;

    //  constructors and member function
    explicit bernoulli_distribution(const RealType& p = RealType(0.5));
    RealType p() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    bernoulli_distribution(const RealType& p = RealType(0.5))
Requires: 0 <= p <= 1
Effects: Constructs a bernoulli_distribution object. p is the parameter of the distribution.
    RealType p() const
Returns: The "p" parameter of the distribution.

Class template geometric_distribution

A geometric_distribution random distribution produces integer values i >= 1 with p(i) = (1-p) * pi-1. p is the parameter of the distribution.
namespace std {
  template<class IntType = int, class RealType = double>
  class geometric_distribution
  {
  public:
    // types
    typedef RealType input_type;
    typedef IntType result_type;

    //  constructors and member function
    explicit geometric_distribution(const RealType& p = RealType(0.5));
    RealType p() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    geometric_distribution(const RealType& p = RealType(0.5))
Requires: 0 < p < 1
Effects: Constructs a geometric_distribution object; p is the parameter of the distribution.
   RealType p() const
Returns: The "p" parameter of the distribution.

Class template poisson_distribution

A poisson_distribution random distribution produces integer values i >= 0 with p(i) = exp(-mean) * meani / i!. mean is the parameter of the distribution.
namespace std {
  template<class IntType = int, class RealType = double>
  class poisson_distribution
  {
  public:
    // types
    typedef RealType input_type;
    typedef IntType result_type;

    //  constructors and member function
    explicit poisson_distribution(const RealType& mean = RealType(1));
    RealType mean() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    poisson_distribution(const RealType& mean = RealType(1))
Requires: mean > 0
Effects: Constructs a poisson_distribution object; mean is the parameter of the distribution.
   RealType mean() const
Returns: The "mean" parameter of the distribution.

Class template binomial_distribution

A binomial_distribution random distribution produces integer values i >= 0 with p(i) = (n over i) * pi * (1-p)t-i. t and p are the parameters of the distribution.
namespace std {
  template<class IntType = int, class RealType = double>
  class binomial_distribution
  {
  public:
    // types
    typedef /* implementation-defined */ input_type;
    typedef IntType result_type;

    //  constructors and member function
    explicit binomial_distribution(IntType t = 1, const RealType& p = RealType(0.5));
    IntType t() const;
    RealType p() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    binomial_distribution(IntType t = 1, const RealType& p = RealType(0.5))
Requires: 0 <= p <= 1 and t >= 0
Effects: Constructs a binomial_distribution object; t and p are the parameters of the distribution.
   IntType t() const
Returns: The "t" parameter of the distribution.
   RealType p() const
Returns: The "p" parameter of the distribution.

Class template uniform_real

A uniform_real random distribution produces floating-point random numbers x in the range min <= x <= max, with equal probability. min and max are the parameters of the distribution.

A uniform_real random distribution satisfies all the requirements of a uniform random number generator (given in tables in section x.x).

namespace std {
  template<class RealType = double>
  class uniform_real
  {
  public:
    // types
    typedef RealType input_type;
    typedef RealType result_type;

    //  constructors and member function
    explicit uniform_real(RealType min = RealType(0), RealType max = RealType(1));
    result_type min() const;
    result_type max() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    uniform_real(RealType min = RealType(0), RealType max = RealType(1))
Requires: min <= max
Effects: Constructs a uniform_real object; min and max are the parameters of the distribution.
    result_type min() const
Returns: The "min" parameter of the distribution.
    result_type max() const
Returns: The "max" parameter of the distribution.

Class template exponential_distribution

An exponential_distribution random distribution produces random numbers x > 0 distributed with probability density function p(x) = lambda * exp(-lambda * x), where lambda is the parameter of the distribution.
namespace std {
  template<class RealType = double>
  class exponential_distribution
  {
  public:
    // types
    typedef RealType input_type;
    typedef RealType result_type;

    //  constructors and member function
    explicit exponential_distribution(const result_type& lambda = result_type(1));
    RealType lambda() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    exponential_distribution(const result_type& lambda = result_type(1))
Requires: lambda > 0
Effects: Constructs an exponential_distribution object with rng as the reference to the underlying source of random numbers. lambda is the parameter for the distribution.
    RealType lambda() const
Returns: The "lambda" parameter of the distribution.

Class template normal_distribution

A normal_distribution random distribution produces random numbers x distributed with probability density function p(x) = 1/sqrt(2*pi*sigma) * exp(- (x-mean)2 / (2*sigma2) ), where mean and sigma are the parameters of the distribution.
namespace std {
  template<class RealType = double>
  class normal_distribution
  {
  public:
    // types
    typedef RealType input_type;
    typedef RealType result_type;

    //  constructors and member function
    explicit normal_distribution(base_type & rng, const result_type& mean = 0,
                                 const result_type& sigma = 1);
    RealType mean() const;
    RealType sigma() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    explicit normal_distribution( const result_type& mean = 0,
                                 const result_type& sigma = 1);
Requires: sigma > 0
Effects: Constructs a normal_distribution object; mean and sigma are the parameters for the distribution.
    RealType mean() const
Returns: The "mean" parameter of the distribution.
    RealType sigma() const
Returns: The "sigma" parameter of the distribution.

Class template gamma_distribution

A gamma_distribution random distribution produces random numbers x distributed with probability density function p(x) = 1/Gamma(alpha) * xalpha-1 * exp(-x), where alpha is the parameter of the distribution.
namespace std {
  template<class RealType = double>
  class gamma_distribution
  {
  public:
    // types
    typedef RealType input_type;
    typedef RealType result_type;

    //  constructors and member function
    explicit gamma_distribution(const result_type& alpha = result_type(1));
    RealType alpha() const;
    void reset();
    template<class UniformRandomNumberGenerator>
    result_type operator()(UniformRandomNumberGenerator& urng);
  };
}
    explicit gamma_distribution(const result_type& alpha = result_type(1));
Requires: alpha > 0
Effects: Constructs a gamma_distribution object; alpha is the parameter for the distribution.
    RealType alpha() const
Returns: The "alpha" parameter of the distribution.

V. Acknowledgements

VI. References