boost/histogram/axis/regular.hpp
// Copyright 2015-2018 Hans Dembinski // // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt // or copy at http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_HISTOGRAM_AXIS_REGULAR_HPP #define BOOST_HISTOGRAM_AXIS_REGULAR_HPP #include <boost/core/nvp.hpp> #include <boost/histogram/axis/interval_view.hpp> #include <boost/histogram/axis/iterator.hpp> #include <boost/histogram/axis/metadata_base.hpp> #include <boost/histogram/axis/option.hpp> #include <boost/histogram/detail/convert_integer.hpp> #include <boost/histogram/detail/relaxed_equal.hpp> #include <boost/histogram/detail/replace_type.hpp> #include <boost/histogram/fwd.hpp> #include <boost/mp11/utility.hpp> #include <boost/throw_exception.hpp> #include <cassert> #include <cmath> #include <limits> #include <stdexcept> #include <string> #include <type_traits> #include <utility> namespace boost { namespace histogram { namespace detail { template <class T> using get_scale_type_helper = typename T::value_type; template <class T> using get_scale_type = mp11::mp_eval_or<T, detail::get_scale_type_helper, T>; struct one_unit {}; template <class T> T operator*(T&& t, const one_unit&) { return std::forward<T>(t); } template <class T> T operator/(T&& t, const one_unit&) { return std::forward<T>(t); } template <class T> using get_unit_type_helper = typename T::unit_type; template <class T> using get_unit_type = mp11::mp_eval_or<one_unit, detail::get_unit_type_helper, T>; template <class T, class R = get_scale_type<T>> R get_scale(const T& t) { return t / get_unit_type<T>(); } } // namespace detail namespace axis { namespace transform { /// Identity transform for equidistant bins. struct id { /// Pass-through. template <class T> static T forward(T&& x) noexcept { return std::forward<T>(x); } /// Pass-through. template <class T> static T inverse(T&& x) noexcept { return std::forward<T>(x); } template <class Archive> void serialize(Archive&, unsigned /* version */) {} }; /// Log transform for equidistant bins in log-space. struct log { /// Returns log(x) of external value x. template <class T> static T forward(T x) { return std::log(x); } /// Returns exp(x) for internal value x. template <class T> static T inverse(T x) { return std::exp(x); } template <class Archive> void serialize(Archive&, unsigned /* version */) {} }; /// Sqrt transform for equidistant bins in sqrt-space. struct sqrt { /// Returns sqrt(x) of external value x. template <class T> static T forward(T x) { return std::sqrt(x); } /// Returns x^2 of internal value x. template <class T> static T inverse(T x) { return x * x; } template <class Archive> void serialize(Archive&, unsigned /* version */) {} }; /// Pow transform for equidistant bins in pow-space. struct pow { double power = 1; /**< power index */ /// Make transform with index p. explicit pow(double p) : power(p) {} pow() = default; /// Returns pow(x, power) of external value x. template <class T> auto forward(T x) const { return std::pow(x, power); } /// Returns pow(x, 1/power) of external value x. template <class T> auto inverse(T x) const { return std::pow(x, 1.0 / power); } bool operator==(const pow& o) const noexcept { return power == o.power; } template <class Archive> void serialize(Archive& ar, unsigned /* version */) { ar& make_nvp("power", power); } }; } // namespace transform #ifndef BOOST_HISTOGRAM_DOXYGEN_INVOKED // Type envelope to mark value as step size template <class T> struct step_type { T value; }; #endif /** Helper function to mark argument as step size. */ template <class T> step_type<T> step(T t) { return step_type<T>{t}; } /** Axis for equidistant intervals on the real line. The most common binning strategy. Very fast. Binning is a O(1) operation. @tparam Value input value type, must be floating point. @tparam Transform builtin or user-defined transform type. @tparam MetaData type to store meta data. @tparam Options see boost::histogram::axis::option (all values allowed). */ template <class Value, class Transform, class MetaData, class Options> class regular : public iterator_mixin<regular<Value, Transform, MetaData, Options>>, protected detail::replace_default<Transform, transform::id>, public metadata_base_t<MetaData> { // these must be private, so that they are not automatically inherited using value_type = Value; using transform_type = detail::replace_default<Transform, transform::id>; using metadata_base = metadata_base_t<MetaData>; using metadata_type = typename metadata_base::metadata_type; using options_type = detail::replace_default<Options, decltype(option::underflow | option::overflow)>; static_assert(std::is_nothrow_move_constructible<transform_type>::value, "transform must be no-throw move constructible"); static_assert(std::is_nothrow_move_assignable<transform_type>::value, "transform must be no-throw move assignable"); using unit_type = detail::get_unit_type<value_type>; using internal_value_type = detail::get_scale_type<value_type>; static_assert(std::is_floating_point<internal_value_type>::value, "regular axis requires floating point type"); static_assert( (!options_type::test(option::circular) && !options_type::test(option::growth)) || (options_type::test(option::circular) ^ options_type::test(option::growth)), "circular and growth options are mutually exclusive"); public: constexpr regular() = default; /** Construct n bins over real transformed range [start, stop). * * @param trans transform instance to use. * @param n number of bins. * @param start low edge of first bin. * @param stop high edge of last bin. * @param meta description of the axis (optional). */ regular(transform_type trans, unsigned n, value_type start, value_type stop, metadata_type meta = {}) : transform_type(std::move(trans)) , metadata_base(std::move(meta)) , size_(static_cast<index_type>(n)) , min_(this->forward(detail::get_scale(start))) , delta_(this->forward(detail::get_scale(stop)) - min_) { if (size() == 0) BOOST_THROW_EXCEPTION(std::invalid_argument("bins > 0 required")); if (!std::isfinite(min_) || !std::isfinite(delta_)) BOOST_THROW_EXCEPTION( std::invalid_argument("forward transform of start or stop invalid")); if (delta_ == 0) BOOST_THROW_EXCEPTION(std::invalid_argument("range of axis is zero")); } /** Construct n bins over real range [start, stop). * * @param n number of bins. * @param start low edge of first bin. * @param stop high edge of last bin. * @param meta description of the axis (optional). */ regular(unsigned n, value_type start, value_type stop, metadata_type meta = {}) : regular({}, n, start, stop, std::move(meta)) {} /** Construct bins with the given step size over real transformed range * [start, stop). * * @param trans transform instance to use. * @param step width of a single bin. * @param start low edge of first bin. * @param stop upper limit of high edge of last bin (see below). * @param meta description of the axis (optional). * * The axis computes the number of bins as n = abs(stop - start) / step, * rounded down. This means that stop is an upper limit to the actual value * (start + n * step). */ template <class T> regular(transform_type trans, step_type<T> step, value_type start, value_type stop, metadata_type meta = {}) : regular(trans, static_cast<index_type>(std::abs(stop - start) / step.value), start, start + static_cast<index_type>(std::abs(stop - start) / step.value) * step.value, std::move(meta)) {} /** Construct bins with the given step size over real range [start, stop). * * @param step width of a single bin. * @param start low edge of first bin. * @param stop upper limit of high edge of last bin (see below). * @param meta description of the axis (optional). * * The axis computes the number of bins as n = abs(stop - start) / step, * rounded down. This means that stop is an upper limit to the actual value * (start + n * step). */ template <class T> regular(step_type<T> step, value_type start, value_type stop, metadata_type meta = {}) : regular({}, step, start, stop, std::move(meta)) {} /// Constructor used by algorithm::reduce to shrink and rebin (not for users). regular(const regular& src, index_type begin, index_type end, unsigned merge) : regular(src.transform(), (end - begin) / merge, src.value(begin), src.value(end), src.metadata()) { assert((end - begin) % merge == 0); if (options_type::test(option::circular) && !(begin == 0 && end == src.size())) BOOST_THROW_EXCEPTION(std::invalid_argument("cannot shrink circular axis")); } /// Return instance of the transform type. const transform_type& transform() const noexcept { return *this; } /// Return index for value argument. index_type index(value_type x) const noexcept { // Runs in hot loop, please measure impact of changes auto z = (this->forward(x / unit_type{}) - min_) / delta_; if (options_type::test(option::circular)) { if (std::isfinite(z)) { z -= std::floor(z); return static_cast<index_type>(z * size()); } } else { if (z < 1) { if (z >= 0) return static_cast<index_type>(z * size()); else return -1; } } return size(); // also returned if x is NaN } /// Returns index and shift (if axis has grown) for the passed argument. std::pair<index_type, index_type> update(value_type x) noexcept { assert(options_type::test(option::growth)); const auto z = (this->forward(x / unit_type{}) - min_) / delta_; if (z < 1) { // don't use i here! if (z >= 0) { const auto i = static_cast<axis::index_type>(z * size()); return {i, 0}; } if (z != -std::numeric_limits<internal_value_type>::infinity()) { const auto stop = min_ + delta_; const auto i = static_cast<axis::index_type>(std::floor(z * size())); min_ += i * (delta_ / size()); delta_ = stop - min_; size_ -= i; return {0, -i}; } // z is -infinity return {-1, 0}; } // z either beyond range, infinite, or NaN if (z < std::numeric_limits<internal_value_type>::infinity()) { const auto i = static_cast<axis::index_type>(z * size()); const auto n = i - size() + 1; delta_ /= size(); delta_ *= size() + n; size_ += n; return {i, -n}; } // z either infinite or NaN return {size(), 0}; } /// Return value for fractional index argument. value_type value(real_index_type i) const noexcept { auto z = i / size(); if (!options_type::test(option::circular) && z < 0.0) z = -std::numeric_limits<internal_value_type>::infinity() * delta_; else if (options_type::test(option::circular) || z <= 1.0) z = (1.0 - z) * min_ + z * (min_ + delta_); else { z = std::numeric_limits<internal_value_type>::infinity() * delta_; } return static_cast<value_type>(this->inverse(z) * unit_type()); } /// Return bin for index argument. decltype(auto) bin(index_type idx) const noexcept { return interval_view<regular>(*this, idx); } /// Returns the number of bins, without over- or underflow. index_type size() const noexcept { return size_; } /// Returns the options. static constexpr unsigned options() noexcept { return options_type::value; } template <class V, class T, class M, class O> bool operator==(const regular<V, T, M, O>& o) const noexcept { return detail::relaxed_equal{}(transform(), o.transform()) && size() == o.size() && min_ == o.min_ && delta_ == o.delta_ && detail::relaxed_equal{}(this->metadata(), o.metadata()); } template <class V, class T, class M, class O> bool operator!=(const regular<V, T, M, O>& o) const noexcept { return !operator==(o); } template <class Archive> void serialize(Archive& ar, unsigned /* version */) { ar& make_nvp("transform", static_cast<transform_type&>(*this)); ar& make_nvp("size", size_); ar& make_nvp("meta", this->metadata()); ar& make_nvp("min", min_); ar& make_nvp("delta", delta_); } private: index_type size_{0}; internal_value_type min_{0}, delta_{1}; template <class V, class T, class M, class O> friend class regular; }; #if __cpp_deduction_guides >= 201606 template <class T> regular(unsigned, T, T) ->regular<detail::convert_integer<T, double>, transform::id, null_type>; template <class T, class M> regular(unsigned, T, T, M) ->regular<detail::convert_integer<T, double>, transform::id, detail::replace_cstring<std::decay_t<M>>>; template <class Tr, class T, class = detail::requires_transform<Tr, T>> regular(Tr, unsigned, T, T)->regular<detail::convert_integer<T, double>, Tr, null_type>; template <class Tr, class T, class M> regular(Tr, unsigned, T, T, M) ->regular<detail::convert_integer<T, double>, Tr, detail::replace_cstring<std::decay_t<M>>>; #endif /// Regular axis with circular option already set. template <class Value = double, class MetaData = use_default, class Options = use_default> #ifndef BOOST_HISTOGRAM_DOXYGEN_INVOKED using circular = regular<Value, transform::id, MetaData, decltype(detail::replace_default<Options, option::overflow_t>{} | option::circular)>; #else class circular; #endif } // namespace axis } // namespace histogram } // namespace boost #endif