base/metrics/histogram_functions.h - cobalt - Git at Google

 // Copyright 2016 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_METRICS_HISTOGRAM_FUNCTIONS_H_
 #define BASE_METRICS_HISTOGRAM_FUNCTIONS_H_

 #include "base/metrics/histogram.h"
 #include "base/metrics/histogram_base.h"
 #include "base/time/time.h"

 // Functions for recording metrics.
 //
 // For best practices on deciding when to emit to a histogram and what form
 // the histogram should take, see
 // https://chromium.googlesource.com/chromium/src.git/+/HEAD/tools/metrics/histograms/README.md

 // Functions for recording UMA histograms. These can be used for cases
 // when the histogram name is generated at runtime. The functionality is
 // equivalent to macros defined in histogram_macros.h but allowing non-constant
 // histogram names. These functions are slower compared to their macro
 // equivalent because the histogram objects are not cached between calls.
 // So, these shouldn't be used in performance critical code.
 namespace base {

 // For histograms with linear buckets.
 // Used for capturing integer data with a linear bucketing scheme. This can be
 // used when you want the exact value of some small numeric count, with a max of
 // 100 or less. If you need to capture a range of greater than 100, we recommend
 // the use of the COUNT histograms below.
 // Sample usage:
 //   base::UmaHistogramExactLinear("Histogram.Linear", some_value, 10);
 BASE_EXPORT void UmaHistogramExactLinear(const std::string& name,
                                          int sample,
                                          int value_max);

 // For adding a sample to an enumerated histogram.
 // Sample usage:
 //   // These values are persisted to logs. Entries should not be renumbered and
 //   // numeric values should never be reused.
 //   enum class MyEnum {
 //     FIRST_VALUE = 0,
 //     SECOND_VALUE = 1,
 //     ...
 //     FINAL_VALUE = N,
 //     COUNT
 //   };
 //   base::UmaHistogramEnumeration("My.Enumeration",
 //                                 MyEnum::SOME_VALUE, MyEnum::COUNT);
 //
 // Note: The value in |sample| must be strictly less than |enum_size|.
 template <typename T>
 void UmaHistogramEnumeration(const std::string& name, T sample, T enum_size) {
   static_assert(std::is_enum<T>::value,
                 "Non enum passed to UmaHistogramEnumeration");
   DCHECK_LE(static_cast<uintmax_t>(enum_size), static_cast<uintmax_t>(INT_MAX));
   DCHECK_LT(static_cast<uintmax_t>(sample), static_cast<uintmax_t>(enum_size));
   return UmaHistogramExactLinear(name, static_cast<int>(sample),
                                  static_cast<int>(enum_size));
 }

 // Same as above, but uses T::kMaxValue as the inclusive maximum value of the
 // enum.
 template <typename T>
 void UmaHistogramEnumeration(const std::string& name, T sample) {
   static_assert(std::is_enum<T>::value,
                 "Non enum passed to UmaHistogramEnumeration");
   DCHECK_LE(static_cast<uintmax_t>(T::kMaxValue),
             static_cast<uintmax_t>(INT_MAX) - 1);
   DCHECK_LE(static_cast<uintmax_t>(sample),
             static_cast<uintmax_t>(T::kMaxValue));
   return UmaHistogramExactLinear(name, static_cast<int>(sample),
                                  static_cast<int>(T::kMaxValue) + 1);
 }

 // For adding boolean sample to histogram.
 // Sample usage:
 //   base::UmaHistogramBoolean("My.Boolean", true)
 BASE_EXPORT void UmaHistogramBoolean(const std::string& name, bool sample);

 // For adding histogram with percent.
 // Percents are integer between 1 and 100.
 // Sample usage:
 //   base::UmaHistogramPercentage("My.Percent", 69)
 BASE_EXPORT void UmaHistogramPercentage(const std::string& name, int percent);

 // For adding counts histogram.
 // Sample usage:
 //   base::UmaHistogramCustomCounts("My.Counts", some_value, 1, 600, 30)
 BASE_EXPORT void UmaHistogramCustomCounts(const std::string& name,
                                           int sample,
                                           int min,
                                           int max,
                                           int buckets);

 // Counts specialization for maximum counts 100, 1000, 10k, 100k, 1M and 10M.
 BASE_EXPORT void UmaHistogramCounts100(const std::string& name, int sample);
 BASE_EXPORT void UmaHistogramCounts1000(const std::string& name, int sample);
 BASE_EXPORT void UmaHistogramCounts10000(const std::string& name, int sample);
 BASE_EXPORT void UmaHistogramCounts100000(const std::string& name, int sample);
 BASE_EXPORT void UmaHistogramCounts1M(const std::string& name, int sample);
 BASE_EXPORT void UmaHistogramCounts10M(const std::string& name, int sample);

 // For histograms storing times.
 BASE_EXPORT void UmaHistogramCustomTimes(const std::string& name,
                                          TimeDelta sample,
                                          TimeDelta min,
                                          TimeDelta max,
                                          int buckets);
 // For short timings from 1 ms up to 10 seconds (50 buckets).
 BASE_EXPORT void UmaHistogramTimes(const std::string& name, TimeDelta sample);
 // For medium timings up to 3 minutes (50 buckets).
 BASE_EXPORT void UmaHistogramMediumTimes(const std::string& name,
                                          TimeDelta sample);
 // For time intervals up to 1 hr (50 buckets).
 BASE_EXPORT void UmaHistogramLongTimes(const std::string& name,
                                        TimeDelta sample);

 // For recording memory related histograms.
 // Used to measure common KB-granularity memory stats. Range is up to 500M.
 BASE_EXPORT void UmaHistogramMemoryKB(const std::string& name, int sample);
 // Used to measure common MB-granularity memory stats. Range is up to ~1G.
 BASE_EXPORT void UmaHistogramMemoryMB(const std::string& name, int sample);
 // Used to measure common MB-granularity memory stats. Range is up to ~64G.
 BASE_EXPORT void UmaHistogramMemoryLargeMB(const std::string& name, int sample);

 // For recording sparse histograms.
 // The |sample| can be a negative or non-negative number.
 //
 // Sparse histograms are well suited for recording counts of exact sample values
 // that are sparsely distributed over a relatively large range, in cases where
 // ultra-fast performance is not critical. For instance, Sqlite.Version.* are
 // sparse because for any given database, there's going to be exactly one
 // version logged.
 //
 // Performance:
 // ------------
 // Sparse histograms are typically more memory-efficient but less time-efficient
 // than other histograms. Essentially, they sparse histograms use a map rather
 // than a vector for their backing storage; they also require lock acquisition
 // to increment a sample, whereas other histogram do not. Hence, each increment
 // operation is a bit slower than for other histograms. But, if the data is
 // sparse, then they use less memory client-side, because they allocate buckets
 // on demand rather than preallocating.
 //
 // Data size:
 // ----------
 // Note that server-side, we still need to load all buckets, across all users,
 // at once. Thus, please avoid exploding such histograms, i.e. uploading many
 // many distinct values to the server (across all users). Concretely, keep the
 // number of distinct values <= 100 ideally, definitely <= 1000. If you have no
 // guarantees on the range of your data, use clamping, e.g.:
 //   UmaHistogramSparse("MyHistogram", ClampToRange(value, 0, 200));
 BASE_EXPORT void UmaHistogramSparse(const std::string& name, int sample);

 }  // namespace base

 #endif  // BASE_METRICS_HISTOGRAM_FUNCTIONS_H_
	// Copyright 2016 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_METRICS_HISTOGRAM_FUNCTIONS_H_
	#define BASE_METRICS_HISTOGRAM_FUNCTIONS_H_

	#include "base/metrics/histogram.h"
	#include "base/metrics/histogram_base.h"
	#include "base/time/time.h"

	// Functions for recording metrics.
	//
	// For best practices on deciding when to emit to a histogram and what form
	// the histogram should take, see
	// https://chromium.googlesource.com/chromium/src.git/+/HEAD/tools/metrics/histograms/README.md

	// Functions for recording UMA histograms. These can be used for cases
	// when the histogram name is generated at runtime. The functionality is
	// equivalent to macros defined in histogram_macros.h but allowing non-constant
	// histogram names. These functions are slower compared to their macro
	// equivalent because the histogram objects are not cached between calls.
	// So, these shouldn't be used in performance critical code.
	namespace base {

	// For histograms with linear buckets.
	// Used for capturing integer data with a linear bucketing scheme. This can be
	// used when you want the exact value of some small numeric count, with a max of
	// 100 or less. If you need to capture a range of greater than 100, we recommend
	// the use of the COUNT histograms below.
	// Sample usage:
	// base::UmaHistogramExactLinear("Histogram.Linear", some_value, 10);
	BASE_EXPORT void UmaHistogramExactLinear(const std::string& name,
	int sample,
	int value_max);

	// For adding a sample to an enumerated histogram.
	// Sample usage:
	// // These values are persisted to logs. Entries should not be renumbered and
	// // numeric values should never be reused.
	// enum class MyEnum {
	// FIRST_VALUE = 0,
	// SECOND_VALUE = 1,
	// ...
	// FINAL_VALUE = N,
	// COUNT
	// };
	// base::UmaHistogramEnumeration("My.Enumeration",
	// MyEnum::SOME_VALUE, MyEnum::COUNT);
	//
	// Note: The value in \|sample\| must be strictly less than \|enum_size\|.
	template <typename T>
	void UmaHistogramEnumeration(const std::string& name, T sample, T enum_size) {
	static_assert(std::is_enum<T>::value,
	"Non enum passed to UmaHistogramEnumeration");
	DCHECK_LE(static_cast<uintmax_t>(enum_size), static_cast<uintmax_t>(INT_MAX));
	DCHECK_LT(static_cast<uintmax_t>(sample), static_cast<uintmax_t>(enum_size));
	return UmaHistogramExactLinear(name, static_cast<int>(sample),
	static_cast<int>(enum_size));
	}

	// Same as above, but uses T::kMaxValue as the inclusive maximum value of the
	// enum.
	template <typename T>
	void UmaHistogramEnumeration(const std::string& name, T sample) {
	static_assert(std::is_enum<T>::value,
	"Non enum passed to UmaHistogramEnumeration");
	DCHECK_LE(static_cast<uintmax_t>(T::kMaxValue),
	static_cast<uintmax_t>(INT_MAX) - 1);
	DCHECK_LE(static_cast<uintmax_t>(sample),
	static_cast<uintmax_t>(T::kMaxValue));
	return UmaHistogramExactLinear(name, static_cast<int>(sample),
	static_cast<int>(T::kMaxValue) + 1);
	}

	// For adding boolean sample to histogram.
	// Sample usage:
	// base::UmaHistogramBoolean("My.Boolean", true)
	BASE_EXPORT void UmaHistogramBoolean(const std::string& name, bool sample);

	// For adding histogram with percent.
	// Percents are integer between 1 and 100.
	// Sample usage:
	// base::UmaHistogramPercentage("My.Percent", 69)
	BASE_EXPORT void UmaHistogramPercentage(const std::string& name, int percent);

	// For adding counts histogram.
	// Sample usage:
	// base::UmaHistogramCustomCounts("My.Counts", some_value, 1, 600, 30)
	BASE_EXPORT void UmaHistogramCustomCounts(const std::string& name,
	int sample,
	int min,
	int max,
	int buckets);

	// Counts specialization for maximum counts 100, 1000, 10k, 100k, 1M and 10M.
	BASE_EXPORT void UmaHistogramCounts100(const std::string& name, int sample);
	BASE_EXPORT void UmaHistogramCounts1000(const std::string& name, int sample);
	BASE_EXPORT void UmaHistogramCounts10000(const std::string& name, int sample);
	BASE_EXPORT void UmaHistogramCounts100000(const std::string& name, int sample);
	BASE_EXPORT void UmaHistogramCounts1M(const std::string& name, int sample);
	BASE_EXPORT void UmaHistogramCounts10M(const std::string& name, int sample);

	// For histograms storing times.
	BASE_EXPORT void UmaHistogramCustomTimes(const std::string& name,
	TimeDelta sample,
	TimeDelta min,
	TimeDelta max,
	int buckets);
	// For short timings from 1 ms up to 10 seconds (50 buckets).
	BASE_EXPORT void UmaHistogramTimes(const std::string& name, TimeDelta sample);
	// For medium timings up to 3 minutes (50 buckets).
	BASE_EXPORT void UmaHistogramMediumTimes(const std::string& name,
	TimeDelta sample);
	// For time intervals up to 1 hr (50 buckets).
	BASE_EXPORT void UmaHistogramLongTimes(const std::string& name,
	TimeDelta sample);

	// For recording memory related histograms.
	// Used to measure common KB-granularity memory stats. Range is up to 500M.
	BASE_EXPORT void UmaHistogramMemoryKB(const std::string& name, int sample);
	// Used to measure common MB-granularity memory stats. Range is up to ~1G.
	BASE_EXPORT void UmaHistogramMemoryMB(const std::string& name, int sample);
	// Used to measure common MB-granularity memory stats. Range is up to ~64G.
	BASE_EXPORT void UmaHistogramMemoryLargeMB(const std::string& name, int sample);

	// For recording sparse histograms.
	// The \|sample\| can be a negative or non-negative number.
	//
	// Sparse histograms are well suited for recording counts of exact sample values
	// that are sparsely distributed over a relatively large range, in cases where
	// ultra-fast performance is not critical. For instance, Sqlite.Version.* are
	// sparse because for any given database, there's going to be exactly one
	// version logged.
	//
	// Performance:
	// ------------
	// Sparse histograms are typically more memory-efficient but less time-efficient
	// than other histograms. Essentially, they sparse histograms use a map rather
	// than a vector for their backing storage; they also require lock acquisition
	// to increment a sample, whereas other histogram do not. Hence, each increment
	// operation is a bit slower than for other histograms. But, if the data is
	// sparse, then they use less memory client-side, because they allocate buckets
	// on demand rather than preallocating.
	//
	// Data size:
	// ----------
	// Note that server-side, we still need to load all buckets, across all users,
	// at once. Thus, please avoid exploding such histograms, i.e. uploading many
	// many distinct values to the server (across all users). Concretely, keep the
	// number of distinct values <= 100 ideally, definitely <= 1000. If you have no
	// guarantees on the range of your data, use clamping, e.g.:
	// UmaHistogramSparse("MyHistogram", ClampToRange(value, 0, 200));
	BASE_EXPORT void UmaHistogramSparse(const std::string& name, int sample);

	} // namespace base

	#endif // BASE_METRICS_HISTOGRAM_FUNCTIONS_H_