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447 lines
16 KiB
Plaintext
447 lines
16 KiB
Plaintext
[section:test_data Graphing, Profiling, and Generating Test Data for Special Functions]
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The class `test_data` and associated helper functions are designed so that in just
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a few lines of code you should be able to:
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* Profile a continued fraction, or infinite series for convergence and accuracy.
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* Generate csv data from a special function that can be imported into your favorite
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graphing program (or spreadsheet) for further analysis.
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* Generate high precision test data.
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[h4 Synopsis]
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#include <boost/math/tools/test_data.hpp>
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[important
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This is a non-core Boost.Math header that is predominantly used for internal
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maintenance of the library: as a result the library is located under
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`libs/math/include_private` and you will need to add that directory to
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your include path in order to use this feature.
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]
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namespace boost{ namespace math{ namespace tools{
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enum parameter_type
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{
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random_in_range = 0,
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periodic_in_range = 1,
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power_series = 2,
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dummy_param = 0x80,
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};
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template <class T>
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struct parameter_info;
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template <class T>
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parameter_info<T> make_random_param(T start_range, T end_range, int n_points);
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template <class T>
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parameter_info<T> make_periodic_param(T start_range, T end_range, int n_points);
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template <class T>
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parameter_info<T> make_power_param(T basis, int start_exponent, int end_exponent);
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template <class T>
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bool get_user_parameter_info(parameter_info<T>& info, const char* param_name);
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template <class T>
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class test_data
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{
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public:
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typedef std::vector<T> row_type;
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typedef row_type value_type;
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private:
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typedef std::set<row_type> container_type;
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public:
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typedef typename container_type::reference reference;
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typedef typename container_type::const_reference const_reference;
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typedef typename container_type::iterator iterator;
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typedef typename container_type::const_iterator const_iterator;
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typedef typename container_type::difference_type difference_type;
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typedef typename container_type::size_type size_type;
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// creation:
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test_data(){}
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template <class F>
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test_data(F func, const parameter_info<T>& arg1);
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// insertion:
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template <class F>
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test_data& insert(F func, const parameter_info<T>& arg1);
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template <class F>
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test_data& insert(F func, const parameter_info<T>& arg1,
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const parameter_info<T>& arg2);
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template <class F>
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test_data& insert(F func, const parameter_info<T>& arg1,
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const parameter_info<T>& arg2,
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const parameter_info<T>& arg3);
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void clear();
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// access:
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iterator begin();
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iterator end();
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const_iterator begin()const;
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const_iterator end()const;
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bool operator==(const test_data& d)const;
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bool operator!=(const test_data& d)const;
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void swap(test_data& other);
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size_type size()const;
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size_type max_size()const;
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bool empty()const;
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bool operator < (const test_data& dat)const;
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bool operator <= (const test_data& dat)const;
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bool operator > (const test_data& dat)const;
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bool operator >= (const test_data& dat)const;
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};
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template <class charT, class traits, class T>
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std::basic_ostream<charT, traits>& write_csv(
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std::basic_ostream<charT, traits>& os,
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const test_data<T>& data);
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template <class charT, class traits, class T>
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std::basic_ostream<charT, traits>& write_csv(
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std::basic_ostream<charT, traits>& os,
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const test_data<T>& data,
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const charT* separator);
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template <class T>
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std::ostream& write_code(std::ostream& os,
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const test_data<T>& data,
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const char* name);
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}}} // namespaces
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[h4 Description]
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This tool is best illustrated with the following series of examples.
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The functionality of test_data is split into the following parts:
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* A functor that implements the function for which data is being generated:
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this is the bit you have to write.
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* One of more parameters that are to be passed to the functor, these are
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described in fairly abstract terms: give me N points distributed like /this/ etc.
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* The class test_data, that takes the functor and descriptions of the parameters
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and computes how ever many output points have been requested, these are stored
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in a sorted container.
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* Routines to iterate over the test_data container and output the data in either
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csv format, or as C++ source code (as a table using Boost.Array).
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[h5 Example 1: Output Data for Graph Plotting]
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For example, lets say we want to graph the lgamma function between -3 and 100,
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one could do this like so:
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#include <boost/math/tools/test_data.hpp>
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#include <boost/math/special_functions/gamma.hpp>
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int main()
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{
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using namespace boost::math::tools;
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// create an object to hold the data:
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test_data<double> data;
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// insert 500 points at uniform intervals between just after -3 and 100:
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double (*pf)(double) = boost::math::lgamma;
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data.insert(pf, make_periodic_param(-3.0 + 0.00001, 100.0, 500));
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// print out in csv format:
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write_csv(std::cout, data, ", ");
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return 0;
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}
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Which, when plotted, results in:
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[graph lgamma]
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[h5 Example 2: Creating Test Data]
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As a second example, let's suppose we want to create highly accurate test
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data for a special function. Since many special functions have two or
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more independent parameters, it's very hard to effectively cover all of
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the possible parameter space without generating gigabytes of data at
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great computational expense. A second best approach is to provide the tools
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by which a user (or the library maintainer) can quickly generate more data
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on demand to probe the function over a particular domain of interest.
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In this example we'll generate test data for the beta function using
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[@http://shoup.net/ntl/doc/RR.txt NTL::RR] at 1000 bit precision.
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Rather than call our generic
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version of the beta function, we'll implement a deliberately naive version
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of the beta function using lgamma, and rely on the high precision of the
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data type used to get results accurate to at least 128-bit precision. In this
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way our test data is independent of whatever clever tricks we may wish to
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use inside the our beta function.
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To start with then, here's the function object that creates the test data:
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#include <boost/math/tools/ntl.hpp>
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#include <boost/math/special_functions/gamma.hpp>
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#include <boost/math/tools/test_data.hpp>
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#include <fstream>
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#include <boost/math/tools/test_data.hpp>
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using namespace boost::math::tools;
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struct beta_data_generator
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{
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NTL::RR operator()(NTL::RR a, NTL::RR b)
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{
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//
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// If we throw a domain error then test_data will
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// ignore this input point. We'll use this to filter
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// out all cases where a < b since the beta function
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// is symmetrical in a and b:
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//
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if(a < b)
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throw std::domain_error("");
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// very naively calculate spots with lgamma:
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NTL::RR g1, g2, g3;
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int s1, s2, s3;
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g1 = boost::math::lgamma(a, &s1);
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g2 = boost::math::lgamma(b, &s2);
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g3 = boost::math::lgamma(a+b, &s3);
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g1 += g2 - g3;
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g1 = exp(g1);
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g1 *= s1 * s2 * s3;
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return g1;
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}
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};
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To create the data, we'll need to input the domains for a and b
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for which the function will be tested: the function `get_user_parameter_info`
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is designed for just that purpose. The start of main will look something like:
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// Set the precision on RR:
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NTL::RR::SetPrecision(1000); // bits.
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NTL::RR::SetOutputPrecision(40); // decimal digits.
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parameter_info<NTL::RR> arg1, arg2;
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test_data<NTL::RR> data;
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std::cout << "Welcome.\n"
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"This program will generate spot tests for the beta function:\n"
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" beta(a, b)\n\n";
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bool cont;
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std::string line;
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do{
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// prompt the user for the domain of a and b to test:
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get_user_parameter_info(arg1, "a");
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get_user_parameter_info(arg2, "b");
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// create the data:
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data.insert(beta_data_generator(), arg1, arg2);
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// see if the user want's any more domains tested:
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std::cout << "Any more data [y/n]?";
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std::getline(std::cin, line);
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boost::algorithm::trim(line);
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cont = (line == "y");
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}while(cont);
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[caution At this point one potential stumbling block should be mentioned:
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test_data<>::insert will create a matrix of test data when there are two
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or more parameters, so if we have two parameters and we're asked for
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a thousand points on each, that's a ['million test points in total].
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Don't say you weren't warned!]
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There's just one final step now, and that's to write the test data to file:
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std::cout << "Enter name of test data file [default=beta_data.ipp]";
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std::getline(std::cin, line);
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boost::algorithm::trim(line);
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if(line == "")
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line = "beta_data.ipp";
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std::ofstream ofs(line.c_str());
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write_code(ofs, data, "beta_data");
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The format of the test data looks something like:
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#define SC_(x) static_cast<T>(BOOST_JOIN(x, L))
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static const boost::array<boost::array<T, 3>, 1830>
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beta_med_data = {
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SC_(0.4883005917072296142578125),
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SC_(0.4883005917072296142578125),
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SC_(3.245912809500479157065104747353807392371),
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SC_(3.5808107852935791015625),
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SC_(0.4883005917072296142578125),
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SC_(1.007653173802923954909901438393379243537),
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/* ... lots of rows skipped */
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};
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The first two values in each row are the input parameters that were passed
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to our functor and the last value is the return value from the functor.
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Had our functor returned a __tuple rather than a value, then we would have had
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one entry for each element in the tuple in addition to the input parameters.
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The first #define serves two purposes:
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* It reduces the file sizes considerably: all those `static_cast`'s add up to a lot
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of bytes otherwise (they are needed to suppress compiler warnings when `T` is
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narrower than a `long double`).
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* It provides a useful customisation point: for example if we were testing
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a user-defined type that has more precision than a `long double` we could change
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it to:
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[^#define SC_(x) lexical_cast<T>(BOOST_STRINGIZE(x))]
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in order to ensure that no truncation of the values occurs prior to conversion
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to `T`. Note that this isn't used by default as it's rather hard on the compiler
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when the table is large.
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[h5 Example 3: Profiling a Continued Fraction for Convergence and Accuracy]
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Alternatively, lets say we want to profile a continued fraction for
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convergence and error. As an example, we'll use the continued fraction
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for the upper incomplete gamma function, the following function object
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returns the next a[sub N ] and b[sub N ] of the continued fraction
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each time it's invoked:
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template <class T>
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struct upper_incomplete_gamma_fract
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{
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private:
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T z, a;
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int k;
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public:
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typedef std::pair<T,T> result_type;
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upper_incomplete_gamma_fract(T a1, T z1)
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: z(z1-a1+1), a(a1), k(0)
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{
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}
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result_type operator()()
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{
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++k;
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z += 2;
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return result_type(k * (a - k), z);
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}
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};
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We want to measure both the relative error, and the rate of convergence
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of this fraction, so we'll write a functor that returns both as a __tuple:
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class test_data will unpack the tuple for us, and create one column of data
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for each element in the tuple (in addition to the input parameters):
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#include <boost/math/tools/test_data.hpp>
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#include <boost/math/tools/test.hpp>
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#include <boost/math/special_functions/gamma.hpp>
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#include <boost/math/tools/ntl.hpp>
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#include <boost/math/tools/tuple.hpp>
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template <class T>
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struct profile_gamma_fraction
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{
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typedef ``__tuple``<T, T> result_type;
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result_type operator()(T val)
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{
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using namespace boost::math::tools;
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// estimate the true value, using arbitary precision
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// arithmetic and NTL::RR:
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NTL::RR rval(val);
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upper_incomplete_gamma_fract<NTL::RR> f1(rval, rval);
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NTL::RR true_val = continued_fraction_a(f1, 1000);
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//
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// Now get the aproximation at double precision, along with the number of
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// iterations required:
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boost::uintmax_t iters = std::numeric_limits<boost::uintmax_t>::max();
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upper_incomplete_gamma_fract<T> f2(val, val);
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T found_val = continued_fraction_a(f2, std::numeric_limits<T>::digits, iters);
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//
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// Work out the relative error, as measured in units of epsilon:
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T err = real_cast<T>(relative_error(true_val, NTL::RR(found_val)) / std::numeric_limits<T>::epsilon());
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//
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// now just return the results as a tuple:
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return boost::math::make_tuple(err, iters);
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}
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};
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Feeding that functor into test_data allows rapid output of csv data,
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for whatever type `T` we may be interested in:
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int main()
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{
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using namespace boost::math::tools;
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// create an object to hold the data:
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test_data<double> data;
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// insert 500 points at uniform intervals between just after 0 and 100:
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data.insert(profile_gamma_fraction<double>(), make_periodic_param(0.01, 100.0, 100));
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// print out in csv format:
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write_csv(std::cout, data, ", ");
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return 0;
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}
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This time there's no need to plot a graph, the first few rows are:
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a and z, Error/epsilon, Iterations required
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0.01, 9723.14, 4726
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1.0099, 9.54818, 87
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2.0098, 3.84777, 40
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3.0097, 0.728358, 25
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4.0096, 2.39712, 21
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5.0095, 0.233263, 16
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So it's pretty clear that this fraction shouldn't be used for small values
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of a and z.
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[h4 reference]
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Most of this tool has been described already in the examples above, we'll
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just add the following notes on the non-member functions:
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template <class T>
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parameter_info<T> make_random_param(T start_range, T end_range, int n_points);
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Tells class test_data to test /n_points/ random values in the range
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[start_range,end_range].
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template <class T>
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parameter_info<T> make_periodic_param(T start_range, T end_range, int n_points);
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Tells class test_data to test /n_points/ evenly spaced values in the range
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[start_range,end_range].
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template <class T>
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parameter_info<T> make_power_param(T basis, int start_exponent, int end_exponent);
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Tells class test_data to test points of the form ['basis + R * 2[super expon]] for each
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/expon/ in the range [start_exponent, end_exponent], and /R/ a random number in \[0.5, 1\].
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template <class T>
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bool get_user_parameter_info(parameter_info<T>& info, const char* param_name);
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Prompts the user for the parameter range and form to use.
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Finally, if we don't want the parameter to be included in the output, we can tell
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test_data by setting it a "dummy parameter":
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parameter_info<double> p = make_random_param(2.0, 5.0, 10);
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p.type |= dummy_param;
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This is useful when the functor used transforms the parameter in some way
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before passing it to the function under test, usually the functor will then
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return both the transformed input and the result in a tuple, so there's no
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need for the original pseudo-parameter to be included in program output.
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[endsect][/section:test_data Graphing, Profiling, and Generating Test Data for Special Functions]
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[/
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Copyright 2006 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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