/** * Copyright 2013-2022 Software Radio Systems Limited * * This file is part of srsRAN. * * srsRAN is free software: you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as * published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * srsRAN is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * A copy of the GNU Affero General Public License can be found in * the LICENSE file in the top-level directory of this distribution * and at http://www.gnu.org/licenses/. * */ #ifndef SRSLOG_CONTEXT_H #define SRSLOG_CONTEXT_H #include "srsran/srslog/detail/support/tmp_utils.h" #include #include namespace srslog { /// Metric formatting kinds for textual conversion. enum class metric_kind { numeric, /// Metric represents a numeric value. string /// Metric represents a string. }; namespace detail { /// This metrics container class is a wrapper to simplify access to the elements /// of the underlying tuple that stores metrics and metric sets. template struct metrics_container { /// Writes the arg value to metric T. template void write(Arg&& arg) { constexpr std::size_t index = detail::get_type_index_in_tuple(); std::get(metrics).value = std::forward(arg); } /// Returns the value of metric T. template auto read() const -> const decltype(T::value) & { constexpr std::size_t index = detail::get_type_index_in_tuple(); return std::get(metrics).value; } /// Returns the element of type T. template T& get() { constexpr std::size_t index = detail::get_type_index_in_tuple(); return std::get(metrics); } /// Returns the element of type T. template const T& get() const { constexpr std::size_t index = detail::get_type_index_in_tuple(); return std::get(metrics); } /// Returns the element in the specified index of list T. /// NOTE: T must have implemented the T operator. template auto at(std::size_t i) -> typename T::value_type& { constexpr std::size_t index = detail::get_type_index_in_tuple(); auto& elem = std::get(metrics); assert(i < elem.size() && "Invalid index"); return elem[i]; } /// Returns the element in the specified index of list T. /// NOTE: T must have implemented the T operator. template auto at(std::size_t i) const -> const typename T::value_type& { constexpr std::size_t index = detail::get_type_index_in_tuple(); const auto& elem = std::get(metrics); assert(i < elem.size() && "Invalid index"); return elem[i]; } /// Returns the raw contents of the metric set as a tuple. const std::tuple& contents() const { return metrics; } private: std::tuple metrics; }; } // namespace detail /// A generic list to store metric sets of the same type. template struct metric_list : public T { /// Returns the name of the list. static const char* name() { return Name::name(); } }; /// Template specializations of this struct allow configuring what formatting /// kind should be used for a concrete metric. /// By default treat all metrics as strings. template struct metric_kind_selector { static const metric_kind kind = metric_kind::string; }; /// A metric is the most basic object that composes a context. It is generally /// used to represent any kind of state of a program. /// It stores a value of type T associated with a name and the units. template struct metric { /// Value of the metric. Ty value{}; /// Returns the name of the metric. static const char* name() { return Name::name(); } /// Returns the units of the metric. static const char* units() { return Units::units(); } /// Returns the formatting kind of the metric. static metric_kind kind() { return metric_kind_selector >::kind; } }; /// Template specialization that tags metrics with arithmetic values (integers /// and floating point) as numeric. template struct metric_kind_selector, typename std::enable_if::value>::type> { static const metric_kind kind = metric_kind::numeric; }; /// A metric set is a group of metrics that share a logical relation. Allows /// storing and mixing other metric sets and metrics for building complex /// structures. template struct metric_set : public detail::metrics_container { /// Name of the metric set. static const char* name() { return Name::name(); } }; /// A context captures the state of different parts of a program grouping metric /// sets. It is the root element of the metrics structure and allows mixing and /// storing other metric sets and metrics. template struct context : public detail::metrics_container { explicit context(std::string n) : name_str(std::move(n)) {} /// Name of the context. const std::string& name() const { return name_str; } private: const std::string name_str; }; namespace detail { /// Builds a metric set type using a list of metric, metric sets or list types. /// eg: using my_metric_t = srslog::build_metric_set_type; /// NOTE: Adding duplicated types into the list is not allowed. template using build_metric_set_type = metric_set::type...>; } // namespace detail /// Builds a context type using a list of metric set types. /// eg: using my_context_t = srslog::build_context_type; /// NOTE: Adding duplicated types into the list is not allowed. template using build_context_type = context::type...>; /// This macro defines a new metric type using the following attributes: /// a) name: encoded as a string. /// b) Metric type: type identifier to create objects for this metric. /// c) Value type: type of the underlying metric value. /// d) Units: encoded as a string, leave as empty string for no units. /// /// The following example declares a metric with the following attributes: /// a) metric type: my_metric_t /// b) metric value type: float /// c) units: MB/s /// d) name: Throughput /// DECLARE_METRIC("Throughput", my_metric_t, float, "MB/s"); #define DECLARE_METRIC(_name_rep, _type, _value_type, _units) \ namespace metric_info { \ struct _type##__units { \ static const char* units() { return _units; } \ }; \ struct _type##__name_rep { \ static const char* name() { return _name_rep; } \ }; \ } \ using _type = srslog:: \ metric::type, metric_info::_type##__name_rep, metric_info::_type##__units> /// This macro defines a new metric set type using the following attributes: /// a) name: encoded as a string. /// b) Metric set type: type identifier to create objects for this metric set. /// c) Type list: list of types this set will hold (other sets, metrics, /// lists). /// /// The following example declares a metric set of three elements (two metrics /// and one set) with the following attributes: /// a) metric type: my_set_t /// b) name: my_set /// b) type list: metric1_t, metric2_t, set2_t /// DECLARE_METRIC_SET("my_set", my_set_t, metric1_t, metric2_t, set2_t); #define DECLARE_METRIC_SET(_name_rep, _type, ...) \ namespace metric_set_info { \ struct _type##__name_rep { \ static const char* name() { return _name_rep; } \ }; \ } \ using _type = srslog::detail::build_metric_set_type /// This macro defines a list of metric sets of the same type: /// a) name: encoded as a string. /// b) List type: type identifier to create objects for this list. /// c) Underlying type: type of the underlying list (vector, array, ...). /// /// The following example declares a list of metrics sets of type set1_t with /// the following attributes: /// a) list type: my_list_t /// b) name: my_list /// b) underlying type: std::vector /// DECLARE_METRIC_LIST("my_list", my_list_t, std::vector); #define DECLARE_METRIC_LIST(_name_rep, _type, _list_type) \ namespace list_info { \ struct _type##__name_rep { \ static const char* name() { return _name_rep; } \ }; \ } \ using _type = srslog::metric_list::type> } // namespace srslog #endif // SRSLOG_CONTEXT_H