base/metrics/histogram_base.h - gn - Git at Google

 // Copyright (c) 2012 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_BASE_H_
 #define BASE_METRICS_HISTOGRAM_BASE_H_

 #include <limits.h>
 #include <stddef.h>
 #include <stdint.h>

 #include <memory>
 #include <string>
 #include <vector>

 #include "base/atomicops.h"
 #include "base/base_export.h"
 #include "base/macros.h"
 #include "base/strings/string_piece.h"
 #include "base/time/time.h"

 namespace base {

 class DictionaryValue;
 class HistogramBase;
 class HistogramSamples;
 class ListValue;
 class Pickle;
 class PickleIterator;

 ////////////////////////////////////////////////////////////////////////////////
 // This enum is used to facilitate deserialization of histograms from other
 // processes into the browser. If you create another class that inherits from
 // HistogramBase, add new histogram types and names below.

 enum HistogramType {
   HISTOGRAM,
   LINEAR_HISTOGRAM,
   BOOLEAN_HISTOGRAM,
   CUSTOM_HISTOGRAM,
   SPARSE_HISTOGRAM,
   DUMMY_HISTOGRAM,
 };

 // Controls the verbosity of the information when the histogram is serialized to
 // a JSON.
 // GENERATED_JAVA_ENUM_PACKAGE: org.chromium.base.metrics
 enum JSONVerbosityLevel {
   // The histogram is completely serialized.
   JSON_VERBOSITY_LEVEL_FULL,
   // The bucket information is not serialized.
   JSON_VERBOSITY_LEVEL_OMIT_BUCKETS,
 };

 std::string HistogramTypeToString(HistogramType type);

 // This enum is used for reporting how many histograms and of what types and
 // variations are being created. It has to be in the main .h file so it is
 // visible to files that define the various histogram types.
 enum HistogramReport {
   // Count the number of reports created. The other counts divided by this
   // number will give the average per run of the program.
   HISTOGRAM_REPORT_CREATED = 0,

   // Count the total number of histograms created. It is the limit against
   // which all others are compared.
   HISTOGRAM_REPORT_HISTOGRAM_CREATED = 1,

   // Count the total number of histograms looked-up. It's better to cache
   // the result of a single lookup rather than do it repeatedly.
   HISTOGRAM_REPORT_HISTOGRAM_LOOKUP = 2,

   // These count the individual histogram types. This must follow the order
   // of HistogramType above.
   HISTOGRAM_REPORT_TYPE_LOGARITHMIC = 3,
   HISTOGRAM_REPORT_TYPE_LINEAR = 4,
   HISTOGRAM_REPORT_TYPE_BOOLEAN = 5,
   HISTOGRAM_REPORT_TYPE_CUSTOM = 6,
   HISTOGRAM_REPORT_TYPE_SPARSE = 7,

   // These indicate the individual flags that were set.
   HISTOGRAM_REPORT_FLAG_UMA_TARGETED = 8,
   HISTOGRAM_REPORT_FLAG_UMA_STABILITY = 9,
   HISTOGRAM_REPORT_FLAG_PERSISTENT = 10,

   // This must be last.
   HISTOGRAM_REPORT_MAX = 11
 };

 // Create or find existing histogram that matches the pickled info.
 // Returns NULL if the pickled data has problems.
 BASE_EXPORT HistogramBase* DeserializeHistogramInfo(base::PickleIterator* iter);

 ////////////////////////////////////////////////////////////////////////////////

 class BASE_EXPORT HistogramBase {
  public:
   typedef int32_t Sample;                // Used for samples.
   typedef subtle::Atomic32 AtomicCount;  // Used to count samples.
   typedef int32_t Count;  // Used to manipulate counts in temporaries.

   static const Sample kSampleType_MAX;  // INT_MAX

   enum Flags {
     kNoFlags = 0x0,

     // Histogram should be UMA uploaded.
     kUmaTargetedHistogramFlag = 0x1,

     // Indicates that this is a stability histogram. This flag exists to specify
     // which histograms should be included in the initial stability log. Please
     // refer to |MetricsService::PrepareInitialStabilityLog|.
     kUmaStabilityHistogramFlag = kUmaTargetedHistogramFlag | 0x2,

     // Indicates that the histogram was pickled to be sent across an IPC
     // Channel. If we observe this flag on a histogram being aggregated into
     // after IPC, then we are running in a single process mode, and the
     // aggregation should not take place (as we would be aggregating back into
     // the source histogram!).
     kIPCSerializationSourceFlag = 0x10,

     // Indicates that a callback exists for when a new sample is recorded on
     // this histogram. We store this as a flag with the histogram since
     // histograms can be in performance critical code, and this allows us
     // to shortcut looking up the callback if it doesn't exist.
     kCallbackExists = 0x20,

     // Indicates that the histogram is held in "persistent" memory and may
     // be accessible between processes. This is only possible if such a
     // memory segment has been created/attached, used to create a Persistent-
     // MemoryAllocator, and that loaded into the Histogram module before this
     // histogram is created.
     kIsPersistent = 0x40,
   };

   // Histogram data inconsistency types.
   enum Inconsistency : uint32_t {
     NO_INCONSISTENCIES = 0x0,
     RANGE_CHECKSUM_ERROR = 0x1,
     BUCKET_ORDER_ERROR = 0x2,
     COUNT_HIGH_ERROR = 0x4,
     COUNT_LOW_ERROR = 0x8,

     NEVER_EXCEEDED_VALUE = 0x10,
   };

   // Construct the base histogram. The name is not copied; it's up to the
   // caller to ensure that it lives at least as long as this object.
   explicit HistogramBase(const char* name);
   virtual ~HistogramBase();

   const char* histogram_name() const { return histogram_name_; }

   // Compares |name| to the histogram name and triggers a DCHECK if they do not
   // match. This is a helper function used by histogram macros, which results in
   // in more compact machine code being generated by the macros.
   virtual void CheckName(const StringPiece& name) const;

   // Get a unique ID for this histogram's samples.
   virtual uint64_t name_hash() const = 0;

   // Operations with Flags enum.
   int32_t flags() const { return subtle::NoBarrier_Load(&flags_); }
   void SetFlags(int32_t flags);
   void ClearFlags(int32_t flags);

   virtual HistogramType GetHistogramType() const = 0;

   // Whether the histogram has construction arguments as parameters specified.
   // For histograms that don't have the concept of minimum, maximum or
   // bucket_count, this function always returns false.
   virtual bool HasConstructionArguments(
       Sample expected_minimum,
       Sample expected_maximum,
       uint32_t expected_bucket_count) const = 0;

   virtual void Add(Sample value) = 0;

   // In Add function the |value| bucket is increased by one, but in some use
   // cases we need to increase this value by an arbitrary integer. AddCount
   // function increases the |value| bucket by |count|. |count| should be greater
   // than or equal to 1.
   virtual void AddCount(Sample value, int count) = 0;

   // Similar to above but divides |count| by the |scale| amount. Probabilistic
   // rounding is used to yield a reasonably accurate total when many samples
   // are added. Methods for common cases of scales 1000 and 1024 are included.
   void AddScaled(Sample value, int count, int scale);
   void AddKilo(Sample value, int count);  // scale=1000
   void AddKiB(Sample value, int count);   // scale=1024

   // Convenient functions that call Add(Sample).
   void AddTime(const TimeDelta& time) { AddTimeMillisecondsGranularity(time); }
   void AddTimeMillisecondsGranularity(const TimeDelta& time);
   // Note: AddTimeMicrosecondsGranularity() drops the report if this client
   // doesn't have a high-resolution clock.
   void AddTimeMicrosecondsGranularity(const TimeDelta& time);
   void AddBoolean(bool value);

   virtual void AddSamples(const HistogramSamples& samples) = 0;
   virtual bool AddSamplesFromPickle(base::PickleIterator* iter) = 0;

   // Serialize the histogram info into |pickle|.
   // Note: This only serializes the construction arguments of the histogram, but
   // does not serialize the samples.
   void SerializeInfo(base::Pickle* pickle) const;

   // Try to find out data corruption from histogram and the samples.
   // The returned value is a combination of Inconsistency enum.
   virtual uint32_t FindCorruption(const HistogramSamples& samples) const;

   // Snapshot the current complete set of sample data.
   // Override with atomic/locked snapshot if needed.
   // NOTE: this data can overflow for long-running sessions. It should be
   // handled with care and this method is recommended to be used only
   // in about:histograms and test code.
   virtual std::unique_ptr<HistogramSamples> SnapshotSamples() const = 0;

   // Calculate the change (delta) in histogram counts since the previous call
   // to this method. Each successive call will return only those counts
   // changed since the last call.
   virtual std::unique_ptr<HistogramSamples> SnapshotDelta() = 0;

   // Calculate the change (delta) in histogram counts since the previous call
   // to SnapshotDelta() but do so without modifying any internal data as to
   // what was previous logged. After such a call, no further calls to this
   // method or to SnapshotDelta() should be done as the result would include
   // data previously returned. Because no internal data is changed, this call
   // can be made on "const" histograms such as those with data held in
   // read-only memory.
   virtual std::unique_ptr<HistogramSamples> SnapshotFinalDelta() const = 0;

   // The following methods provide graphical histogram displays.
   virtual void WriteHTMLGraph(std::string* output) const = 0;
   virtual void WriteAscii(std::string* output) const = 0;

   // TODO(bcwhite): Remove this after https://crbug/836875.
   virtual void ValidateHistogramContents() const;

   // Produce a JSON representation of the histogram with |verbosity_level| as
   // the serialization verbosity. This is implemented with the help of
   // GetParameters and GetCountAndBucketData; overwrite them to customize the
   // output.
   void WriteJSON(std::string* output, JSONVerbosityLevel verbosity_level) const;

  protected:
   enum ReportActivity { HISTOGRAM_CREATED, HISTOGRAM_LOOKUP };

   // Subclasses should implement this function to make SerializeInfo work.
   virtual void SerializeInfoImpl(base::Pickle* pickle) const = 0;

   // Writes information about the construction parameters in |params|.
   virtual void GetParameters(DictionaryValue* params) const = 0;

   // Writes information about the current (non-empty) buckets and their sample
   // counts to |buckets|, the total sample count to |count| and the total sum
   // to |sum|.
   virtual void GetCountAndBucketData(Count* count,
                                      int64_t* sum,
                                      ListValue* buckets) const = 0;

   //// Produce actual graph (set of blank vs non blank char's) for a bucket.
   void WriteAsciiBucketGraph(double current_size,
                              double max_size,
                              std::string* output) const;

   // Return a string description of what goes in a given bucket.
   const std::string GetSimpleAsciiBucketRange(Sample sample) const;

   // Write textual description of the bucket contents (relative to histogram).
   // Output is the count in the buckets, as well as the percentage.
   void WriteAsciiBucketValue(Count current,
                              double scaled_sum,
                              std::string* output) const;

   // Retrieves the callback for this histogram, if one exists, and runs it
   // passing |sample| as the parameter.
   void FindAndRunCallback(Sample sample) const;

   // Gets a permanent string that can be used for histogram objects when the
   // original is not a code constant or held in persistent memory.
   static const char* GetPermanentName(const std::string& name);

  private:
   friend class HistogramBaseTest;

   // A pointer to permanent storage where the histogram name is held. This can
   // be code space or the output of GetPermanentName() or any other storage
   // that is known to never change. This is not StringPiece because (a) char*
   // is 1/2 the size and (b) StringPiece transparently casts from std::string
   // which can easily lead to a pointer to non-permanent space.
   // For persistent histograms, this will simply point into the persistent
   // memory segment, thus avoiding duplication. For heap histograms, the
   // GetPermanentName method will create the necessary copy.
   const char* const histogram_name_;

   // Additional information about the histogram.
   AtomicCount flags_;

   DISALLOW_COPY_AND_ASSIGN(HistogramBase);
 };

 }  // namespace base

 #endif  // BASE_METRICS_HISTOGRAM_BASE_H_
	// Copyright (c) 2012 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_BASE_H_
	#define BASE_METRICS_HISTOGRAM_BASE_H_

	#include <limits.h>
	#include <stddef.h>
	#include <stdint.h>

	#include <memory>
	#include <string>
	#include <vector>

	#include "base/atomicops.h"
	#include "base/base_export.h"
	#include "base/macros.h"
	#include "base/strings/string_piece.h"
	#include "base/time/time.h"

	namespace base {

	class DictionaryValue;
	class HistogramBase;
	class HistogramSamples;
	class ListValue;
	class Pickle;
	class PickleIterator;

	////////////////////////////////////////////////////////////////////////////////
	// This enum is used to facilitate deserialization of histograms from other
	// processes into the browser. If you create another class that inherits from
	// HistogramBase, add new histogram types and names below.

	enum HistogramType {
	HISTOGRAM,
	LINEAR_HISTOGRAM,
	BOOLEAN_HISTOGRAM,
	CUSTOM_HISTOGRAM,
	SPARSE_HISTOGRAM,
	DUMMY_HISTOGRAM,
	};

	// Controls the verbosity of the information when the histogram is serialized to
	// a JSON.
	// GENERATED_JAVA_ENUM_PACKAGE: org.chromium.base.metrics
	enum JSONVerbosityLevel {
	// The histogram is completely serialized.
	JSON_VERBOSITY_LEVEL_FULL,
	// The bucket information is not serialized.
	JSON_VERBOSITY_LEVEL_OMIT_BUCKETS,
	};

	std::string HistogramTypeToString(HistogramType type);

	// This enum is used for reporting how many histograms and of what types and
	// variations are being created. It has to be in the main .h file so it is
	// visible to files that define the various histogram types.
	enum HistogramReport {
	// Count the number of reports created. The other counts divided by this
	// number will give the average per run of the program.
	HISTOGRAM_REPORT_CREATED = 0,

	// Count the total number of histograms created. It is the limit against
	// which all others are compared.
	HISTOGRAM_REPORT_HISTOGRAM_CREATED = 1,

	// Count the total number of histograms looked-up. It's better to cache
	// the result of a single lookup rather than do it repeatedly.
	HISTOGRAM_REPORT_HISTOGRAM_LOOKUP = 2,

	// These count the individual histogram types. This must follow the order
	// of HistogramType above.
	HISTOGRAM_REPORT_TYPE_LOGARITHMIC = 3,
	HISTOGRAM_REPORT_TYPE_LINEAR = 4,
	HISTOGRAM_REPORT_TYPE_BOOLEAN = 5,
	HISTOGRAM_REPORT_TYPE_CUSTOM = 6,
	HISTOGRAM_REPORT_TYPE_SPARSE = 7,

	// These indicate the individual flags that were set.
	HISTOGRAM_REPORT_FLAG_UMA_TARGETED = 8,
	HISTOGRAM_REPORT_FLAG_UMA_STABILITY = 9,
	HISTOGRAM_REPORT_FLAG_PERSISTENT = 10,

	// This must be last.
	HISTOGRAM_REPORT_MAX = 11
	};

	// Create or find existing histogram that matches the pickled info.
	// Returns NULL if the pickled data has problems.
	BASE_EXPORT HistogramBase* DeserializeHistogramInfo(base::PickleIterator* iter);

	////////////////////////////////////////////////////////////////////////////////

	class BASE_EXPORT HistogramBase {
	public:
	typedef int32_t Sample; // Used for samples.
	typedef subtle::Atomic32 AtomicCount; // Used to count samples.
	typedef int32_t Count; // Used to manipulate counts in temporaries.

	static const Sample kSampleType_MAX; // INT_MAX

	enum Flags {
	kNoFlags = 0x0,

	// Histogram should be UMA uploaded.
	kUmaTargetedHistogramFlag = 0x1,

	// Indicates that this is a stability histogram. This flag exists to specify
	// which histograms should be included in the initial stability log. Please
	// refer to \|MetricsService::PrepareInitialStabilityLog\|.
	kUmaStabilityHistogramFlag = kUmaTargetedHistogramFlag \| 0x2,

	// Indicates that the histogram was pickled to be sent across an IPC
	// Channel. If we observe this flag on a histogram being aggregated into
	// after IPC, then we are running in a single process mode, and the
	// aggregation should not take place (as we would be aggregating back into
	// the source histogram!).
	kIPCSerializationSourceFlag = 0x10,

	// Indicates that a callback exists for when a new sample is recorded on
	// this histogram. We store this as a flag with the histogram since
	// histograms can be in performance critical code, and this allows us
	// to shortcut looking up the callback if it doesn't exist.
	kCallbackExists = 0x20,

	// Indicates that the histogram is held in "persistent" memory and may
	// be accessible between processes. This is only possible if such a
	// memory segment has been created/attached, used to create a Persistent-
	// MemoryAllocator, and that loaded into the Histogram module before this
	// histogram is created.
	kIsPersistent = 0x40,
	};

	// Histogram data inconsistency types.
	enum Inconsistency : uint32_t {
	NO_INCONSISTENCIES = 0x0,
	RANGE_CHECKSUM_ERROR = 0x1,
	BUCKET_ORDER_ERROR = 0x2,
	COUNT_HIGH_ERROR = 0x4,
	COUNT_LOW_ERROR = 0x8,

	NEVER_EXCEEDED_VALUE = 0x10,
	};

	// Construct the base histogram. The name is not copied; it's up to the
	// caller to ensure that it lives at least as long as this object.
	explicit HistogramBase(const char* name);
	virtual ~HistogramBase();

	const char* histogram_name() const { return histogram_name_; }

	// Compares \|name\| to the histogram name and triggers a DCHECK if they do not
	// match. This is a helper function used by histogram macros, which results in
	// in more compact machine code being generated by the macros.
	virtual void CheckName(const StringPiece& name) const;

	// Get a unique ID for this histogram's samples.
	virtual uint64_t name_hash() const = 0;

	// Operations with Flags enum.
	int32_t flags() const { return subtle::NoBarrier_Load(&flags_); }
	void SetFlags(int32_t flags);
	void ClearFlags(int32_t flags);

	virtual HistogramType GetHistogramType() const = 0;

	// Whether the histogram has construction arguments as parameters specified.
	// For histograms that don't have the concept of minimum, maximum or
	// bucket_count, this function always returns false.
	virtual bool HasConstructionArguments(
	Sample expected_minimum,
	Sample expected_maximum,
	uint32_t expected_bucket_count) const = 0;

	virtual void Add(Sample value) = 0;

	// In Add function the \|value\| bucket is increased by one, but in some use
	// cases we need to increase this value by an arbitrary integer. AddCount
	// function increases the \|value\| bucket by \|count\|. \|count\| should be greater
	// than or equal to 1.
	virtual void AddCount(Sample value, int count) = 0;

	// Similar to above but divides \|count\| by the \|scale\| amount. Probabilistic
	// rounding is used to yield a reasonably accurate total when many samples
	// are added. Methods for common cases of scales 1000 and 1024 are included.
	void AddScaled(Sample value, int count, int scale);
	void AddKilo(Sample value, int count); // scale=1000
	void AddKiB(Sample value, int count); // scale=1024

	// Convenient functions that call Add(Sample).
	void AddTime(const TimeDelta& time) { AddTimeMillisecondsGranularity(time); }
	void AddTimeMillisecondsGranularity(const TimeDelta& time);
	// Note: AddTimeMicrosecondsGranularity() drops the report if this client
	// doesn't have a high-resolution clock.
	void AddTimeMicrosecondsGranularity(const TimeDelta& time);
	void AddBoolean(bool value);

	virtual void AddSamples(const HistogramSamples& samples) = 0;
	virtual bool AddSamplesFromPickle(base::PickleIterator* iter) = 0;

	// Serialize the histogram info into \|pickle\|.
	// Note: This only serializes the construction arguments of the histogram, but
	// does not serialize the samples.
	void SerializeInfo(base::Pickle* pickle) const;

	// Try to find out data corruption from histogram and the samples.
	// The returned value is a combination of Inconsistency enum.
	virtual uint32_t FindCorruption(const HistogramSamples& samples) const;

	// Snapshot the current complete set of sample data.
	// Override with atomic/locked snapshot if needed.
	// NOTE: this data can overflow for long-running sessions. It should be
	// handled with care and this method is recommended to be used only
	// in about:histograms and test code.
	virtual std::unique_ptr<HistogramSamples> SnapshotSamples() const = 0;

	// Calculate the change (delta) in histogram counts since the previous call
	// to this method. Each successive call will return only those counts
	// changed since the last call.
	virtual std::unique_ptr<HistogramSamples> SnapshotDelta() = 0;

	// Calculate the change (delta) in histogram counts since the previous call
	// to SnapshotDelta() but do so without modifying any internal data as to
	// what was previous logged. After such a call, no further calls to this
	// method or to SnapshotDelta() should be done as the result would include
	// data previously returned. Because no internal data is changed, this call
	// can be made on "const" histograms such as those with data held in
	// read-only memory.
	virtual std::unique_ptr<HistogramSamples> SnapshotFinalDelta() const = 0;

	// The following methods provide graphical histogram displays.
	virtual void WriteHTMLGraph(std::string* output) const = 0;
	virtual void WriteAscii(std::string* output) const = 0;

	// TODO(bcwhite): Remove this after https://crbug/836875.
	virtual void ValidateHistogramContents() const;

	// Produce a JSON representation of the histogram with \|verbosity_level\| as
	// the serialization verbosity. This is implemented with the help of
	// GetParameters and GetCountAndBucketData; overwrite them to customize the
	// output.
	void WriteJSON(std::string* output, JSONVerbosityLevel verbosity_level) const;

	protected:
	enum ReportActivity { HISTOGRAM_CREATED, HISTOGRAM_LOOKUP };

	// Subclasses should implement this function to make SerializeInfo work.
	virtual void SerializeInfoImpl(base::Pickle* pickle) const = 0;

	// Writes information about the construction parameters in \|params\|.
	virtual void GetParameters(DictionaryValue* params) const = 0;

	// Writes information about the current (non-empty) buckets and their sample
	// counts to \|buckets\|, the total sample count to \|count\| and the total sum
	// to \|sum\|.
	virtual void GetCountAndBucketData(Count* count,
	int64_t* sum,
	ListValue* buckets) const = 0;

	//// Produce actual graph (set of blank vs non blank char's) for a bucket.
	void WriteAsciiBucketGraph(double current_size,
	double max_size,
	std::string* output) const;

	// Return a string description of what goes in a given bucket.
	const std::string GetSimpleAsciiBucketRange(Sample sample) const;

	// Write textual description of the bucket contents (relative to histogram).
	// Output is the count in the buckets, as well as the percentage.
	void WriteAsciiBucketValue(Count current,
	double scaled_sum,
	std::string* output) const;

	// Retrieves the callback for this histogram, if one exists, and runs it
	// passing \|sample\| as the parameter.
	void FindAndRunCallback(Sample sample) const;

	// Gets a permanent string that can be used for histogram objects when the
	// original is not a code constant or held in persistent memory.
	static const char* GetPermanentName(const std::string& name);

	private:
	friend class HistogramBaseTest;

	// A pointer to permanent storage where the histogram name is held. This can
	// be code space or the output of GetPermanentName() or any other storage
	// that is known to never change. This is not StringPiece because (a) char*
	// is 1/2 the size and (b) StringPiece transparently casts from std::string
	// which can easily lead to a pointer to non-permanent space.
	// For persistent histograms, this will simply point into the persistent
	// memory segment, thus avoiding duplication. For heap histograms, the
	// GetPermanentName method will create the necessary copy.
	const char* const histogram_name_;

	// Additional information about the histogram.
	AtomicCount flags_;

	DISALLOW_COPY_AND_ASSIGN(HistogramBase);
	};

	} // namespace base

	#endif // BASE_METRICS_HISTOGRAM_BASE_H_