Nagram/TMessagesProj/jni/webrtc/base/trace_event/trace_arguments.h
2020-08-14 19:58:22 +03:00

673 lines
25 KiB
C++

// Copyright 2018 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef BASE_TRACE_EVENT_TRACE_ARGUMENTS_H_
#define BASE_TRACE_EVENT_TRACE_ARGUMENTS_H_
#include <stdlib.h>
#include <string.h>
#include <algorithm>
#include <memory>
#include <string>
#include "base/base_export.h"
#include "base/macros.h"
#include "base/trace_event/common/trace_event_common.h"
// Trace macro can have one or two optional arguments, each one of them
// identified by a name (a C string literal) and a value, which can be an
// integer, enum, floating point, boolean, string pointer or reference, or
// std::unique_ptr<ConvertableToTraceFormat> compatible values. Additionally,
// custom data types need to be supported, like time values or WTF::CString.
//
// TraceArguments is a helper class used to store 0 to 2 named arguments
// corresponding to an individual trace macro call. As efficiently as possible,
// and with the minimal amount of generated machine code (since this affects
// any TRACE macro call). Each argument has:
//
// - A name (C string literal, e.g "dumps")
// - An 8-bit type value, corresponding to the TRACE_VALUE_TYPE_XXX macros.
// - A value, stored in a TraceValue union
//
// IMPORTANT: For a TRACE_VALUE_TYPE_CONVERTABLE types, the TraceArguments
// instance owns the pointed ConvertableToTraceFormat object, i.e. it will
// delete it automatically on destruction.
//
// TraceArguments instances should be built using one of specialized
// constructors declared below. One cannot modify an instance once it has
// been built, except for move operations, Reset() and destruction. Examples:
//
// TraceArguments args; // No arguments.
// // args.size() == 0
//
// TraceArguments("foo", 100);
// // args.size() == 1
// // args.types()[0] == TRACE_VALUE_TYPE_INT
// // args.names()[0] == "foo"
// // args.values()[0].as_int == 100
//
// TraceArguments("bar", 1ULL);
// // args.size() == 1
// // args.types()[0] == TRACE_VALUE_TYPE_UINT
// // args.names()[0] == "bar"
// // args.values()[0].as_uint == 100
//
// TraceArguments("foo", "Hello", "bar", "World");
// // args.size() == 2
// // args.types()[0] == TRACE_VALUE_TYPE_STRING
// // args.types()[1] == TRACE_VALUE_TYPE_STRING
// // args.names()[0] == "foo"
// // args.names()[1] == "bar"
// // args.values()[0].as_string == "Hello"
// // args.values()[1].as_string == "World"
//
// std::string some_string = ...;
// TraceArguments("str1", some_string);
// // args.size() == 1
// // args.types()[0] == TRACE_VALUE_TYPE_COPY_STRING
// // args.names()[0] == "str1"
// // args.values()[0].as_string == some_string.c_str()
//
// Note that TRACE_VALUE_TYPE_COPY_STRING corresponds to string pointers
// that point to temporary values that may disappear soon. The
// TraceArguments::CopyStringTo() method can be used to copy their content
// into a StringStorage memory block, and update the |as_string| value pointers
// to it to avoid keeping any dangling pointers. This is used by TraceEvent
// to keep copies of such strings in the log after their initialization values
// have disappeared.
//
// The TraceStringWithCopy helper class can be used to initialize a value
// from a regular string pointer with TRACE_VALUE_TYPE_COPY_STRING too, as in:
//
// const char str[] = "....";
// TraceArguments("foo", str, "bar", TraceStringWithCopy(str));
// // args.size() == 2
// // args.types()[0] == TRACE_VALUE_TYPE_STRING
// // args.types()[1] == TRACE_VALUE_TYPE_COPY_STRING
// // args.names()[0] == "foo"
// // args.names()[1] == "bar"
// // args.values()[0].as_string == str
// // args.values()[1].as_string == str
//
// StringStorage storage;
// args.CopyStringTo(&storage, false, nullptr, nullptr);
// // args.size() == 2
// // args.types()[0] == TRACE_VALUE_TYPE_STRING
// // args.types()[1] == TRACE_VALUE_TYPE_COPY_STRING
// // args.names()[0] == "foo"
// // args.names()[1] == "bar"
// // args.values()[0].as_string == str
// // args.values()[1].as_string == Address inside |storage|.
//
// Initialization from a std::unique_ptr<ConvertableToTraceFormat>
// is supported but will move ownership of the pointer objects to the
// TraceArguments instance:
//
// class MyConvertableType :
// public base::trace_event::AsConvertableToTraceFormat {
// ...
// };
//
// {
// TraceArguments args("foo" , std::make_unique<MyConvertableType>(...));
// // args.size() == 1
// // args.values()[0].as_convertable == address of MyConvertable object.
// } // Calls |args| destructor, which will delete the object too.
//
// Finally, it is possible to support initialization from custom values by
// specializing the TraceValue::Helper<> template struct as described below.
//
// This is how values of custom types like WTF::CString can be passed directly
// to trace macros.
namespace base {
class Time;
class TimeTicks;
class ThreadTicks;
namespace trace_event {
class TraceEventMemoryOverhead;
// For any argument of type TRACE_VALUE_TYPE_CONVERTABLE the provided
// class must implement this interface. Note that unlike other values,
// these objects will be owned by the TraceArguments instance that points
// to them.
class BASE_EXPORT ConvertableToTraceFormat {
public:
ConvertableToTraceFormat() = default;
virtual ~ConvertableToTraceFormat() = default;
// Append the class info to the provided |out| string. The appended
// data must be a valid JSON object. Strings must be properly quoted, and
// escaped. There is no processing applied to the content after it is
// appended.
virtual void AppendAsTraceFormat(std::string* out) const = 0;
// Append the class info directly into the Perfetto-defined proto
// format; this is attempted first and if this returns true,
// AppendAsTraceFormat is not called. The ProtoAppender interface
// acts as a bridge to avoid proto/Perfetto dependencies in base.
class BASE_EXPORT ProtoAppender {
public:
virtual ~ProtoAppender() = default;
virtual void AddBuffer(uint8_t* begin, uint8_t* end) = 0;
// Copy all of the previous buffers registered with AddBuffer
// into the proto, with the given |field_id|.
virtual size_t Finalize(uint32_t field_id) = 0;
};
virtual bool AppendToProto(ProtoAppender* appender);
virtual void EstimateTraceMemoryOverhead(TraceEventMemoryOverhead* overhead);
private:
DISALLOW_COPY_AND_ASSIGN(ConvertableToTraceFormat);
};
const int kTraceMaxNumArgs = 2;
// A union used to hold the values of individual trace arguments.
//
// This is a POD union for performance reason. Initialization from an
// explicit C++ trace argument should be performed with the Init()
// templated method described below.
//
// Initialization from custom types is possible by implementing a custom
// TraceValue::Helper<> instantiation as described below.
//
// IMPORTANT: Pointer storage inside a TraceUnion follows specific rules:
//
// - |as_pointer| is for raw pointers that should be treated as a simple
// address and will never be dereferenced. Associated with the
// TRACE_VALUE_TYPE_POINTER type.
//
// - |as_string| is for C-string pointers, associated with both
// TRACE_VALUE_TYPE_STRING and TRACE_VALUE_TYPE_COPY_STRING. The former
// indicates that the string pointer is persistent (e.g. a C string
// literal), while the second indicates that the pointer belongs to a
// temporary variable that may disappear soon. The TraceArguments class
// provides a CopyStringTo() method to copy these strings into a
// StringStorage instance, which is useful if the instance needs to
// survive longer than the temporaries.
//
// - |as_convertable| is equivalent to
// std::unique_ptr<ConvertableToTraceFormat>, except that it is a pointer
// to keep this union POD and avoid un-necessary declarations and potential
// code generation. This means that its ownership is passed to the
// TraceValue instance when Init(std::unique_ptr<ConvertableToTraceFormat>)
// is called, and that it will be deleted by the containing TraceArguments
// destructor, or Reset() method.
//
union BASE_EXPORT TraceValue {
bool as_bool;
unsigned long long as_uint;
long long as_int;
double as_double;
const void* as_pointer;
const char* as_string;
ConvertableToTraceFormat* as_convertable;
// There is no constructor to keep this structure POD intentionally.
// This avoids un-needed initialization when only 0 or 1 arguments are
// used to construct a TraceArguments instance. Use Init() instead to
// perform explicit initialization from a given C++ value.
// Initialize TraceValue instance from a C++ trace value.
// This relies on the proper specialization of TraceValue::Helper<>
// described below. Usage is simply:
//
// TraceValue v;
// v.Init(<value>);
//
// NOTE: For ConvertableToTraceFormat values, see the note above and
// the one for TraceValue::Helper for CONVERTABLE_TYPE below.
template <typename T>
void Init(T&& value) {
using ValueType = typename InnerType<T>::type;
Helper<ValueType>::SetValue(this, std::forward<T>(value));
}
// Static method to create a new TraceValue instance from a given
// initialization value. Note that this deduces the TRACE_VALUE_TYPE_XXX
// type but doesn't return it, use ForType<T>::value for this.
//
// Usage example:
// auto v = TraceValue::Make(100);
// auto v2 = TraceValue::Make("Some text string");
//
// IMPORTANT: Experience shows that the compiler generates worse code when
// using this method rather than calling Init() directly on an existing
// TraceValue union :-(
//
template <typename T>
static TraceValue Make(T&& value) {
TraceValue ret;
ret.Init(std::forward<T>(value));
return ret;
}
// Output current value as a JSON string. |type| must be a valid
// TRACE_VALUE_TYPE_XXX value.
void AppendAsJSON(unsigned char type, std::string* out) const;
// Output current value as a string. If the output string is to be used
// in a JSON format use AppendAsJSON instead. |type| must be valid
// TRACE_VALUE_TYPE_XXX value.
void AppendAsString(unsigned char type, std::string* out) const;
private:
void Append(unsigned char type, bool as_json, std::string* out) const;
// InnerType<T>::type removes reference, cv-qualifications and decays
// function and arrays into pointers. Only used internally.
template <typename T>
struct InnerType {
using type = typename std::remove_cv<typename std::remove_reference<
typename std::decay<T>::type>::type>::type;
};
public:
// TraceValue::Helper is used to provide information about initialization
// value types and an initialization function. It is a struct that should
// provide the following for supported initialization value types:
//
// - kType: is a static TRACE_VALUE_TYPE_XXX constant.
//
// - SetValue(TraceValue*, T): is a static inline method that sets
// TraceValue value from a given T value. Second parameter type
// can also be const T& or T&& to restrict uses.
//
// IMPORTANT: The type T must be InnerType<Q>, where Q is the real C++
// argument type. I.e. you should not have to deal with reference types
// in your specialization.
//
// Specializations are defined for integers, enums, floating point, pointers,
// constant C string literals and pointers, std::string, time values below.
//
// Specializations for custom types are possible provided that there exists
// a corresponding Helper specialization, for example:
//
// template <>
// struct base::trace_event::TraceValue::Helper<Foo> {
// static constexpr unsigned char kTypes = TRACE_VALUE_TYPE_COPY_STRING;
// static inline void SetValue(TraceValue* v, const Foo& value) {
// v->as_string = value.c_str();
// }
// };
//
// Will allow code like:
//
// Foo foo = ...;
// auto v = TraceValue::Make(foo);
//
// Or even:
// Foo foo = ...;
// TraceArguments args("foo_arg1", foo);
//
template <typename T, class = void>
struct Helper {};
// TraceValue::TypeFor<T>::value returns the TRACE_VALUE_TYPE_XXX
// corresponding to initialization values of type T.
template <typename T>
struct TypeFor {
using ValueType = typename InnerType<T>::type;
static const unsigned char value = Helper<ValueType>::kType;
};
// TraceValue::TypeCheck<T>::value is only defined iff T can be used to
// initialize a TraceValue instance. This is useful to restrict template
// instantiation to only the appropriate type (see TraceArguments
// constructors below).
template <typename T,
class = decltype(TraceValue::Helper<
typename TraceValue::InnerType<T>::type>::kType)>
struct TypeCheck {
static const bool value = true;
};
};
// TraceValue::Helper for integers and enums.
template <typename T>
struct TraceValue::Helper<
T,
typename std::enable_if<std::is_integral<T>::value ||
std::is_enum<T>::value>::type> {
static constexpr unsigned char kType =
std::is_signed<T>::value ? TRACE_VALUE_TYPE_INT : TRACE_VALUE_TYPE_UINT;
static inline void SetValue(TraceValue* v, T value) {
v->as_uint = static_cast<unsigned long long>(value);
}
};
// TraceValue::Helper for floating-point types
template <typename T>
struct TraceValue::
Helper<T, typename std::enable_if<std::is_floating_point<T>::value>::type> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_DOUBLE;
static inline void SetValue(TraceValue* v, T value) { v->as_double = value; }
};
// TraceValue::Helper for bool.
template <>
struct TraceValue::Helper<bool> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_BOOL;
static inline void SetValue(TraceValue* v, bool value) { v->as_bool = value; }
};
// TraceValue::Helper for generic pointer types.
template <typename T>
struct TraceValue::Helper<T*> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_POINTER;
static inline void SetValue(TraceValue* v,
const typename std::decay<T>::type* value) {
v->as_pointer = value;
}
};
// TraceValue::Helper for raw persistent C strings.
template <>
struct TraceValue::Helper<const char*> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_STRING;
static inline void SetValue(TraceValue* v, const char* value) {
v->as_string = value;
}
};
// TraceValue::Helper for std::string values.
template <>
struct TraceValue::Helper<std::string> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_COPY_STRING;
static inline void SetValue(TraceValue* v, const std::string& value) {
v->as_string = value.c_str();
}
};
// Special case for scoped pointers to convertables to trace format.
// |CONVERTABLE_TYPE| must be a type whose pointers can be converted to a
// ConvertableToTraceFormat* pointer as well (e.g. a derived class).
// IMPORTANT: This takes an std::unique_ptr<CONVERTABLE_TYPE> value, and takes
// ownership of the pointed object!
template <typename CONVERTABLE_TYPE>
struct TraceValue::Helper<std::unique_ptr<CONVERTABLE_TYPE>,
typename std::enable_if<std::is_convertible<
CONVERTABLE_TYPE*,
ConvertableToTraceFormat*>::value>::type> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_CONVERTABLE;
static inline void SetValue(TraceValue* v,
std::unique_ptr<CONVERTABLE_TYPE> value) {
v->as_convertable = value.release();
}
};
// Specialization for time-based values like base::Time, which provide a
// a ToInternalValue() method.
template <typename T>
struct TraceValue::Helper<
T,
typename std::enable_if<std::is_same<T, base::Time>::value ||
std::is_same<T, base::TimeTicks>::value ||
std::is_same<T, base::ThreadTicks>::value>::type> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_INT;
static inline void SetValue(TraceValue* v, const T& value) {
v->as_int = value.ToInternalValue();
}
};
// Simple container for const char* that should be copied instead of retained.
// The goal is to indicate that the C string is copyable, unlike the default
// Init(const char*) implementation. Usage is:
//
// const char* str = ...;
// v.Init(TraceStringWithCopy(str));
//
// Which will mark the string as TRACE_VALUE_TYPE_COPY_STRING, instead of
// TRACE_VALUE_TYPE_STRING.
//
class TraceStringWithCopy {
public:
explicit TraceStringWithCopy(const char* str) : str_(str) {}
const char* str() const { return str_; }
private:
const char* str_;
};
template <>
struct TraceValue::Helper<TraceStringWithCopy> {
static constexpr unsigned char kType = TRACE_VALUE_TYPE_COPY_STRING;
static inline void SetValue(TraceValue* v, const TraceStringWithCopy& value) {
v->as_string = value.str();
}
};
class TraceArguments;
// A small class used to store a copy of all strings from a given
// TraceArguments instance (see below). When empty, this should only
// take the size of a pointer. Otherwise, this will point to a heap
// allocated block containing a size_t value followed by all characters
// in the storage area. For most cases, this is more efficient
// than using a std::unique_ptr<std::string> or an std::vector<char>.
class BASE_EXPORT StringStorage {
public:
constexpr StringStorage() = default;
explicit StringStorage(size_t alloc_size) { Reset(alloc_size); }
~StringStorage() {
if (data_)
::free(data_);
}
StringStorage(StringStorage&& other) noexcept : data_(other.data_) {
other.data_ = nullptr;
}
StringStorage& operator=(StringStorage&& other) noexcept {
if (this != &other) {
if (data_)
::free(data_);
data_ = other.data_;
other.data_ = nullptr;
}
return *this;
}
// Reset storage area to new allocation size. Existing content might not
// be preserved. If |alloc_size| is 0, this will free the storage area
// as well.
void Reset(size_t alloc_size = 0);
// Accessors.
constexpr size_t size() const { return data_ ? data_->size : 0u; }
constexpr const char* data() const { return data_ ? data_->chars : nullptr; }
constexpr char* data() { return data_ ? data_->chars : nullptr; }
constexpr const char* begin() const { return data(); }
constexpr const char* end() const { return data() + size(); }
inline char* begin() { return data(); }
inline char* end() { return data() + size(); }
// True iff storage is empty.
constexpr bool empty() const { return size() == 0; }
// Returns true if |ptr| is inside the storage area, false otherwise.
// Used during unit-testing.
constexpr bool Contains(const void* ptr) const {
const char* char_ptr = static_cast<const char*>(ptr);
return (char_ptr >= begin() && char_ptr < end());
}
// Returns true if all string pointers in |args| are contained in this
// storage area.
bool Contains(const TraceArguments& args) const;
// Return an estimate of the memory overhead of this instance. This doesn't
// count the size of |data_| itself.
constexpr size_t EstimateTraceMemoryOverhead() const {
return data_ ? sizeof(size_t) + data_->size : 0u;
}
private:
// Heap allocated data block (variable size), made of:
//
// - size: a size_t field, giving the size of the following |chars| array.
// - chars: an array of |size| characters, holding all zero-terminated
// strings referenced from a TraceArguments instance.
struct Data {
size_t size = 0;
char chars[1]; // really |size| character items in storage.
};
// This is an owning pointer. Normally, using a std::unique_ptr<> would be
// enough, but the compiler will then complaing about inlined constructors
// and destructors being too complex (!), resulting in larger code for no
// good reason.
Data* data_ = nullptr;
};
// TraceArguments models an array of kMaxSize trace-related items,
// each one of them having:
// - a name, which is a constant char array literal.
// - a type, as described by TRACE_VALUE_TYPE_XXX macros.
// - a value, stored in a TraceValue union.
//
// IMPORTANT: For TRACE_VALUE_TYPE_CONVERTABLE, the value holds an owning
// pointer to an AsConvertableToTraceFormat instance, which will
// be destroyed with the array (or moved out of it when passed
// to a TraceEvent instance).
//
// For TRACE_VALUE_TYPE_COPY_STRING, the value holds a const char* pointer
// whose content will be copied when creating a TraceEvent instance.
//
// IMPORTANT: Most constructors and the destructor are all inlined
// intentionally, in order to let the compiler remove un-necessary operations
// and reduce machine code.
//
class BASE_EXPORT TraceArguments {
public:
// Maximum number of arguments held by this structure.
static constexpr size_t kMaxSize = 2;
// Default constructor, no arguments.
TraceArguments() : size_(0) {}
// Constructor for a single argument.
template <typename T, class = decltype(TraceValue::TypeCheck<T>::value)>
TraceArguments(const char* arg1_name, T&& arg1_value) : size_(1) {
types_[0] = TraceValue::TypeFor<T>::value;
names_[0] = arg1_name;
values_[0].Init(std::forward<T>(arg1_value));
}
// Constructor for two arguments.
template <typename T1,
typename T2,
class = decltype(TraceValue::TypeCheck<T1>::value &&
TraceValue::TypeCheck<T2>::value)>
TraceArguments(const char* arg1_name,
T1&& arg1_value,
const char* arg2_name,
T2&& arg2_value)
: size_(2) {
types_[0] = TraceValue::TypeFor<T1>::value;
types_[1] = TraceValue::TypeFor<T2>::value;
names_[0] = arg1_name;
names_[1] = arg2_name;
values_[0].Init(std::forward<T1>(arg1_value));
values_[1].Init(std::forward<T2>(arg2_value));
}
// Constructor used to convert a legacy set of arguments when there
// are no convertable values at all.
TraceArguments(int num_args,
const char* const* arg_names,
const unsigned char* arg_types,
const unsigned long long* arg_values);
// Constructor used to convert legacy set of arguments, where the
// convertable values are also provided by an array of CONVERTABLE_TYPE.
template <typename CONVERTABLE_TYPE>
TraceArguments(int num_args,
const char* const* arg_names,
const unsigned char* arg_types,
const unsigned long long* arg_values,
CONVERTABLE_TYPE* arg_convertables) {
static int max_args = static_cast<int>(kMaxSize);
if (num_args > max_args)
num_args = max_args;
size_ = static_cast<unsigned char>(num_args);
for (size_t n = 0; n < size_; ++n) {
types_[n] = arg_types[n];
names_[n] = arg_names[n];
if (arg_types[n] == TRACE_VALUE_TYPE_CONVERTABLE) {
values_[n].Init(
std::forward<CONVERTABLE_TYPE>(std::move(arg_convertables[n])));
} else {
values_[n].as_uint = arg_values[n];
}
}
}
// Destructor. NOTE: Intentionally inlined (see note above).
~TraceArguments() {
for (size_t n = 0; n < size_; ++n) {
if (types_[n] == TRACE_VALUE_TYPE_CONVERTABLE)
delete values_[n].as_convertable;
}
}
// Disallow copy operations.
TraceArguments(const TraceArguments&) = delete;
TraceArguments& operator=(const TraceArguments&) = delete;
// Allow move operations.
TraceArguments(TraceArguments&& other) noexcept {
::memcpy(this, &other, sizeof(*this));
// All owning pointers were copied to |this|. Setting |other.size_| will
// mask the pointer values still in |other|.
other.size_ = 0;
}
TraceArguments& operator=(TraceArguments&&) noexcept;
// Accessors
size_t size() const { return size_; }
const unsigned char* types() const { return types_; }
const char* const* names() const { return names_; }
const TraceValue* values() const { return values_; }
// Reset to empty arguments list.
void Reset();
// Use |storage| to copy all copyable strings.
// If |copy_all_strings| is false, then only the TRACE_VALUE_TYPE_COPY_STRING
// values will be copied into storage. If it is true, then argument names are
// also copied to storage, as well as the strings pointed to by
// |*extra_string1| and |*extra_string2|.
// NOTE: If there are no strings to copy, |*storage| is left untouched.
void CopyStringsTo(StringStorage* storage,
bool copy_all_strings,
const char** extra_string1,
const char** extra_string2);
// Append debug string representation to |*out|.
void AppendDebugString(std::string* out);
private:
unsigned char size_;
unsigned char types_[kMaxSize];
const char* names_[kMaxSize];
TraceValue values_[kMaxSize];
};
} // namespace trace_event
} // namespace base
#endif // BASE_TRACE_EVENT_TRACE_ARGUMENTS_H_