/* * Copyright 2016 The WebRTC Project Authors. All rights reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #ifndef API_STATS_RTCSTATS_H_ #define API_STATS_RTCSTATS_H_ #include #include #include #include #include #include "rtc_base/checks.h" namespace webrtc { class RTCStatsMemberInterface; // Abstract base class for RTCStats-derived dictionaries, see // https://w3c.github.io/webrtc-stats/. // // All derived classes must have the following static variable defined: // static const char kType[]; // It is used as a unique class identifier and a string representation of the // class type, see https://w3c.github.io/webrtc-stats/#rtcstatstype-str*. // Use the |WEBRTC_RTCSTATS_IMPL| macro when implementing subclasses, see macro // for details. // // Derived classes list their dictionary members, RTCStatsMember, as public // fields, allowing the following: // // RTCFooStats foo("fooId", GetCurrentTime()); // foo.bar = 42; // foo.baz = std::vector(); // foo.baz->push_back("hello world"); // uint32_t x = *foo.bar; // // Pointers to all the members are available with |Members|, allowing iteration: // // for (const RTCStatsMemberInterface* member : foo.Members()) { // printf("%s = %s\n", member->name(), member->ValueToString().c_str()); // } class RTCStats { public: RTCStats(const std::string& id, int64_t timestamp_us) : id_(id), timestamp_us_(timestamp_us) {} RTCStats(std::string&& id, int64_t timestamp_us) : id_(std::move(id)), timestamp_us_(timestamp_us) {} virtual ~RTCStats() {} virtual std::unique_ptr copy() const = 0; const std::string& id() const { return id_; } // Time relative to the UNIX epoch (Jan 1, 1970, UTC), in microseconds. int64_t timestamp_us() const { return timestamp_us_; } // Returns the static member variable |kType| of the implementing class. virtual const char* type() const = 0; // Returns a vector of pointers to all the |RTCStatsMemberInterface| members // of this class. This allows for iteration of members. For a given class, // |Members| always returns the same members in the same order. std::vector Members() const; // Checks if the two stats objects are of the same type and have the same // member values. Timestamps are not compared. These operators are exposed for // testing. bool operator==(const RTCStats& other) const; bool operator!=(const RTCStats& other) const; // Creates a JSON readable string representation of the stats // object, listing all of its members (names and values). std::string ToJson() const; // Downcasts the stats object to an |RTCStats| subclass |T|. DCHECKs that the // object is of type |T|. template const T& cast_to() const { RTC_DCHECK_EQ(type(), T::kType); return static_cast(*this); } protected: // Gets a vector of all members of this |RTCStats| object, including members // derived from parent classes. |additional_capacity| is how many more members // shall be reserved in the vector (so that subclasses can allocate a vector // with room for both parent and child members without it having to resize). virtual std::vector MembersOfThisObjectAndAncestors(size_t additional_capacity) const; std::string const id_; int64_t timestamp_us_; }; // All |RTCStats| classes should use these macros. // |WEBRTC_RTCSTATS_DECL| is placed in a public section of the class definition. // |WEBRTC_RTCSTATS_IMPL| is placed outside the class definition (in a .cc). // // These macros declare (in _DECL) and define (in _IMPL) the static |kType| and // overrides methods as required by subclasses of |RTCStats|: |copy|, |type| and // |MembersOfThisObjectAndAncestors|. The |...| argument is a list of addresses // to each member defined in the implementing class. The list must have at least // one member. // // (Since class names need to be known to implement these methods this cannot be // part of the base |RTCStats|. While these methods could be implemented using // templates, that would only work for immediate subclasses. Subclasses of // subclasses also have to override these methods, resulting in boilerplate // code. Using a macro avoids this and works for any |RTCStats| class, including // grandchildren.) // // Sample usage: // // rtcfoostats.h: // class RTCFooStats : public RTCStats { // public: // WEBRTC_RTCSTATS_DECL(); // // RTCFooStats(const std::string& id, int64_t timestamp_us); // // RTCStatsMember foo; // RTCStatsMember bar; // }; // // rtcfoostats.cc: // WEBRTC_RTCSTATS_IMPL(RTCFooStats, RTCStats, "foo-stats" // &foo, // &bar); // // RTCFooStats::RTCFooStats(const std::string& id, int64_t timestamp_us) // : RTCStats(id, timestamp_us), // foo("foo"), // bar("bar") { // } // #define WEBRTC_RTCSTATS_DECL() \ public: \ static const char kType[]; \ \ std::unique_ptr copy() const override; \ const char* type() const override; \ \ protected: \ std::vector \ MembersOfThisObjectAndAncestors(size_t local_var_additional_capacity) \ const override; \ \ public: #define WEBRTC_RTCSTATS_IMPL(this_class, parent_class, type_str, ...) \ const char this_class::kType[] = type_str; \ \ std::unique_ptr this_class::copy() const { \ return std::unique_ptr(new this_class(*this)); \ } \ \ const char* this_class::type() const { return this_class::kType; } \ \ std::vector \ this_class::MembersOfThisObjectAndAncestors( \ size_t local_var_additional_capacity) const { \ const webrtc::RTCStatsMemberInterface* local_var_members[] = { \ __VA_ARGS__}; \ size_t local_var_members_count = \ sizeof(local_var_members) / sizeof(local_var_members[0]); \ std::vector \ local_var_members_vec = parent_class::MembersOfThisObjectAndAncestors( \ local_var_members_count + local_var_additional_capacity); \ RTC_DCHECK_GE( \ local_var_members_vec.capacity() - local_var_members_vec.size(), \ local_var_members_count + local_var_additional_capacity); \ local_var_members_vec.insert(local_var_members_vec.end(), \ &local_var_members[0], \ &local_var_members[local_var_members_count]); \ return local_var_members_vec; \ } // Interface for |RTCStats| members, which have a name and a value of a type // defined in a subclass. Only the types listed in |Type| are supported, these // are implemented by |RTCStatsMember|. The value of a member may be // undefined, the value can only be read if |is_defined|. class RTCStatsMemberInterface { public: // Member value types. enum Type { kBool, // bool kInt32, // int32_t kUint32, // uint32_t kInt64, // int64_t kUint64, // uint64_t kDouble, // double kString, // std::string kSequenceBool, // std::vector kSequenceInt32, // std::vector kSequenceUint32, // std::vector kSequenceInt64, // std::vector kSequenceUint64, // std::vector kSequenceDouble, // std::vector kSequenceString, // std::vector }; virtual ~RTCStatsMemberInterface() {} const char* name() const { return name_; } virtual Type type() const = 0; virtual bool is_sequence() const = 0; virtual bool is_string() const = 0; bool is_defined() const { return is_defined_; } // Is this part of the stats spec? Used so that chromium can easily filter // out anything unstandardized. virtual bool is_standardized() const = 0; // Type and value comparator. The names are not compared. These operators are // exposed for testing. virtual bool operator==(const RTCStatsMemberInterface& other) const = 0; bool operator!=(const RTCStatsMemberInterface& other) const { return !(*this == other); } virtual std::string ValueToString() const = 0; // This is the same as ValueToString except for kInt64 and kUint64 types, // where the value is represented as a double instead of as an integer. // Since JSON stores numbers as floating point numbers, very large integers // cannot be accurately represented, so we prefer to display them as doubles // instead. virtual std::string ValueToJson() const = 0; template const T& cast_to() const { RTC_DCHECK_EQ(type(), T::kType); return static_cast(*this); } protected: RTCStatsMemberInterface(const char* name, bool is_defined) : name_(name), is_defined_(is_defined) {} const char* const name_; bool is_defined_; }; // Template implementation of |RTCStatsMemberInterface|. Every possible |T| is // specialized in rtcstats.cc, using a different |T| results in a linker error // (undefined reference to |kType|). The supported types are the ones described // by |RTCStatsMemberInterface::Type|. template class RTCStatsMember : public RTCStatsMemberInterface { public: static const Type kType; explicit RTCStatsMember(const char* name) : RTCStatsMemberInterface(name, /*is_defined=*/false), value_() {} RTCStatsMember(const char* name, const T& value) : RTCStatsMemberInterface(name, /*is_defined=*/true), value_(value) {} RTCStatsMember(const char* name, T&& value) : RTCStatsMemberInterface(name, /*is_defined=*/true), value_(std::move(value)) {} explicit RTCStatsMember(const RTCStatsMember& other) : RTCStatsMemberInterface(other.name_, other.is_defined_), value_(other.value_) {} explicit RTCStatsMember(RTCStatsMember&& other) : RTCStatsMemberInterface(other.name_, other.is_defined_), value_(std::move(other.value_)) {} Type type() const override { return kType; } bool is_sequence() const override; bool is_string() const override; bool is_standardized() const override { return true; } bool operator==(const RTCStatsMemberInterface& other) const override { if (type() != other.type() || is_standardized() != other.is_standardized()) return false; const RTCStatsMember& other_t = static_cast&>(other); if (!is_defined_) return !other_t.is_defined(); if (!other.is_defined()) return false; return value_ == other_t.value_; } std::string ValueToString() const override; std::string ValueToJson() const override; // Assignment operators. T& operator=(const T& value) { value_ = value; is_defined_ = true; return value_; } T& operator=(const T&& value) { value_ = std::move(value); is_defined_ = true; return value_; } T& operator=(const RTCStatsMember& other) { RTC_DCHECK(other.is_defined_); // Shouldn't be attempting to assign an RTCNonStandardStatsMember to an // RTCStatsMember or vice versa. RTC_DCHECK(is_standardized() == other.is_standardized()); value_ = other.value_; is_defined_ = true; return value_; } // Value getters. T& operator*() { RTC_DCHECK(is_defined_); return value_; } const T& operator*() const { RTC_DCHECK(is_defined_); return value_; } // Value getters, arrow operator. T* operator->() { RTC_DCHECK(is_defined_); return &value_; } const T* operator->() const { RTC_DCHECK(is_defined_); return &value_; } private: T value_; }; // Same as above, but "is_standardized" returns false. // // Using inheritance just so that it's obvious from the member's declaration // whether it's standardized or not. template class RTCNonStandardStatsMember : public RTCStatsMember { public: explicit RTCNonStandardStatsMember(const char* name) : RTCStatsMember(name) {} RTCNonStandardStatsMember(const char* name, const T& value) : RTCStatsMember(name, value) {} RTCNonStandardStatsMember(const char* name, T&& value) : RTCStatsMember(name, std::move(value)) {} explicit RTCNonStandardStatsMember(const RTCNonStandardStatsMember& other) : RTCStatsMember(other) {} explicit RTCNonStandardStatsMember(RTCNonStandardStatsMember&& other) : RTCStatsMember(std::move(other)) {} bool is_standardized() const override { return false; } }; } // namespace webrtc #endif // API_STATS_RTCSTATS_H_