third_party/metrics_proto/perf_data.proto - cobalt - Git at Google

 // Copyright 2014 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.

 syntax = "proto2";

 option optimize_for = LITE_RUNTIME;
 option java_outer_classname = "PerfDataProtos";
 option java_package = "org.chromium.components.metrics";

 package metrics;

 // Stores information from a perf session generated via running:
 // "perf record"
 //
 // See $kernel/tools/perf/design.txt for more details.

 // Please do not modify this protobuf directly, except to mirror the upstream
 // version found here:
 // https://chromium.googlesource.com/chromiumos/platform/chromiumos-wide-profiling/+/master/perf_data.proto
 // with some fields omitted for privacy reasons. Because it is a read-only copy
 // of the upstream protobuf, "Next tag:" comments are also absent.

 message PerfDataProto {
   // Perf event attribute. Stores the event description.
   // This data structure is defined in the linux kernel:
   // $kernel/tools/perf/util/event.h.
   message PerfEventAttr {
     // Type of the event. Type is an enumeration and can be:
     // IP: an instruction-pointer was stored in the event.
     // MMAP: a DLL was loaded.
     // FORK: a process was forked.
     // etc.
     optional uint32 type = 1;

     // Size of the event data in bytes.
     optional uint32 size = 2;

     // The config stores the CPU-specific counter information.
     optional uint64 config = 3;

     // Sample period of the event. Indicates how often the event is
     // triggered in terms of # of events. After |sample_period| events, an event
     // will be recorded and stored.
     optional uint64 sample_period = 4;

     // Sample frequency of the event. Indicates how often the event is
     // triggered in terms of # per second. The kernel will try to record
     // |sample_freq| events per second.
     optional uint64 sample_freq = 5;

     // Sample type is a bitfield that records attributes of the sample. Example,
     // whether an entire callchain was recorded, etc.
     optional uint64 sample_type = 6;

     // Bitfield that indicates whether reads on the counter will return the
     // total time enabled and total time running.
     optional uint64 read_format = 7;

     // Indicates whether the counter starts off disabled.
     optional bool disabled = 8;

     // Indicates whether child processes inherit the counter.
     optional bool inherit = 9;

     // Indicates whether the counter is pinned to a particular CPU.
     optional bool pinned = 10;

     // Indicates whether this counter's group has exclusive access to the CPU's
     // counters.
     optional bool exclusive = 11;

     // The following bits restrict events to be counted when the CPU is in user,
     // kernel, hypervisor or idle modes.
     optional bool exclude_user = 12;
     optional bool exclude_kernel = 13;
     optional bool exclude_hv = 14;
     optional bool exclude_idle = 15;

     // Indicates whether mmap events should be recorded.
     optional bool mmap = 16;

     // Indicates whether process comm information should be recorded upon
     // process creation.
     optional bool comm = 17;

     // Indicates that we are in frequency mode, not period mode.
     optional bool freq = 18;

     // Indicates whether we have per-task counts.
     optional bool inherit_stat = 19;

     // Indicates whether we enable perf events after an exec() function call.
     optional bool enable_on_exec = 20;

     // Indicates whether we trace fork/exit.
     optional bool task = 21;

     // Indicates whether we are using a watermark to wake up.
     optional bool watermark = 22;

     // CPUs often "skid" when recording events. That means the instruction
     // pointer may not be the same as the one that caused the counter overflow.
     // Indicates the capabilities of the CPU in terms of recording precise
     // instruction pointer.
     optional uint32 precise_ip = 23;

     // Indicates whether we have non-exec mmap data.
     optional bool mmap_data = 24;

     // If set, all the event types will have the same sample_type.
     optional bool sample_id_all = 25;

     // Indicates whether we are counting events from the host (when running a
     // VM).
     optional bool exclude_host = 26;

     // Exclude events that happen on a guest OS.
     optional bool exclude_guest = 27;

     // Contains the number of events after which we wake up.
     optional uint32 wakeup_events = 28;

     // Contains the number of bytes after which we wake up.
     optional uint32 wakeup_watermark = 29;

     // Information about the type of the breakpoint.
     optional uint32 bp_type = 30;

     // Contains the breakpoint address.
     optional uint64 bp_addr = 31;

     // This is an extension of config (see above).
     optional uint64 config1 = 32;

     // The length of the breakpoint data in bytes.
     optional uint64 bp_len = 33;

     // This is an extension of config (see above).
     optional uint64 config2 = 34;

     // Contains the type of branch, example: user, kernel, call, return, etc.
     optional uint64 branch_sample_type = 35;
   }

   // Describes a perf.data file attribute.
   message PerfFileAttr {
     optional PerfEventAttr attr = 1;

     // List of perf file attribute ids. Each id describes an event.
     repeated uint64 ids = 2;
   }

   // This message contains information about a perf sample itself, as opposed to
   // a perf event captured by a sample.
   message SampleInfo {
     // Process ID / thread ID from which this sample was taken.
     optional uint32 pid = 1;
     optional uint32 tid = 2;

     // Time this sample was taken (NOT the same as an event time).
     // It is the number of nanoseconds since bootup.
     optional uint64 sample_time_ns = 3;

     // The ID of the sample's event type (cycles, instructions, etc).
     // The event type IDs are defined in PerfFileAttr.
     optional uint64 id = 4;

     // The CPU on which this sample was taken.
     optional uint32 cpu = 5;
   }

   message CommEvent {
     // Process id.
     optional uint32 pid = 1;

     // Thread id.
     optional uint32 tid = 2;

     // Comm string's md5 prefix.
     // The comm string was field 3 and has been intentionally left out.
     optional uint64 comm_md5_prefix = 4;

     // Time the sample was taken.
     // Deprecated, use |sample_info| instead.
     optional uint64 sample_time = 5 [deprecated = true];

     // Info about the perf sample containing this event.
     optional SampleInfo sample_info = 6;
   }

   message MMapEvent {
     // Process id.
     optional uint32 pid = 1;

     // Thread id.
     optional uint32 tid = 2;

     // Start address.
     optional uint64 start = 3;

     // Length.
     optional uint64 len = 4;

     // PG Offset.
     optional uint64 pgoff = 5;

     // Filename's md5 prefix.
     // The filename was field 6 and has been intentionally left out.
     optional uint64 filename_md5_prefix = 7;

     // Info about the perf sample containing this event.
     optional SampleInfo sample_info = 8;
   }

   message BranchStackEntry {
     // Branch source address.
     optional uint64 from_ip = 1;

     // Branch destination address.
     optional uint64 to_ip = 2;

     // Indicates a mispredicted branch.
     optional bool mispredicted = 3;
   }

   message SampleEvent {
     // Instruction pointer.
     optional uint64 ip = 1;

     // Process id.
     optional uint32 pid = 2;

     // Thread id.
     optional uint32 tid = 3;

     // The time after boot when the sample was recorded, in nanoseconds.
     optional uint64 sample_time_ns = 4;

     // The address of the sample.
     optional uint64 addr = 5;

     // The id of the sample.
     optional uint64 id = 6;

     // The stream id of the sample.
     optional uint64 stream_id = 7;

     // The period of the sample.
     optional uint64 period = 8;

     // The CPU where the event was recorded.
     optional uint32 cpu = 9;

     // The raw size of the event in bytes.
     optional uint32 raw_size = 10;

     // Sample callchain info.
     repeated uint64 callchain = 11;

     // Branch stack info.
     repeated BranchStackEntry branch_stack = 12;

     // Not added from original: fields 13 and 14.

     // Sample weight for special events.
     optional uint64 weight = 15;

     // Sample data source flags.
     // Possible flag values:
     // http://lxr.free-electrons.com/source/include/uapi/linux/perf_event.h#L849
     optional uint64 data_src = 16;

     // Sample transaction flags for special events.
     // Flag fields:
     // http://lxr.free-electrons.com/source/include/uapi/linux/perf_event.h#L209
     optional uint64 transaction = 17;
   }

   // ForkEvent is used for both FORK and EXIT events, which have the same data
   // format.  We don't want to call this "ForkOrExitEvent", in case a separate
   // exit event is introduced in the future.
   message ForkEvent {
     // Forked process ID.
     optional uint32 pid = 1;

     // Parent process ID.
     optional uint32 ppid = 2;

     // Forked process thread ID.
     optional uint32 tid = 3;

     // Parent process thread ID.
     optional uint32 ptid = 4;

     // Time of fork event in nanoseconds since bootup.
     optional uint64 fork_time_ns = 5;

     // Info about the perf sample containing this event.
     optional SampleInfo sample_info = 11;
   }

   message EventHeader {
     // Type of event.
     optional uint32 type = 1;
     optional uint32 misc = 2;
     // Size of event.
     optional uint32 size = 3;
   }

   message PerfEvent {
     optional EventHeader header = 1;

     optional MMapEvent mmap_event = 2;
     optional SampleEvent sample_event = 3;
     optional CommEvent comm_event = 4;
     // FORK and EXIT events are structurally identical. They only differ by the
     // event type. But using two distinct fields makes things easier.
     optional ForkEvent fork_event = 5;
     optional ForkEvent exit_event = 9;

     // Not added from original: optional LostEvent lost_event = 6;
     // Not added from original: optional ThrottleEvent throttle_event = 7;
     // Not added from original: optional ReadEvent read_event = 8;
   }

   message PerfEventStats {
     // Total number of events read from perf data.
     optional uint32 num_events_read = 1;

     // Total number of various types of events.
     optional uint32 num_sample_events = 2;
     optional uint32 num_mmap_events = 3;
     optional uint32 num_fork_events = 4;
     optional uint32 num_exit_events = 5;

     // Number of sample events that were successfully mapped by the address
     // mapper, a quipper module that is used to obscure addresses and convert
     // them to DSO name + offset.  Sometimes it fails to process sample events.
     // This field allows us to track the success rate of the address mapper.
     optional uint32 num_sample_events_mapped = 6;

     // Whether address remapping was enabled.
     optional bool did_remap = 7;
   }

   message PerfBuildID {
     // Misc field in perf_event_header.
     // Indicates whether the file is mapped in kernel mode or user mode.
     optional uint32 misc = 1;

     // Process ID.
     optional uint32 pid = 2;

     // Build id.  Should always contain kBuildIDArraySize bytes of data.
     // perf_reader.h in Chrome OS defines kBuildIDArraySize = 20.
     optional bytes build_hash = 3;

     // Filename Md5sum prefix.
     // The filename was field 4 and has been intentionally left out.
     optional uint64 filename_md5_prefix = 5;
   }

   repeated PerfFileAttr file_attrs = 1;
   repeated PerfEvent events = 2;

   // Time when quipper generated this perf data / protobuf, given as seconds
   // since the epoch.
   optional uint64 timestamp_sec = 3;

   // Records some stats about the serialized perf events.
   optional PerfEventStats stats = 4;

   // Not added from original: repeated uint64 metadata_mask = 5;

   // Build ID metadata.
   repeated PerfBuildID build_ids = 7;

   // Not added from original: repeated PerfUint32Metadata uint32_metadata = 8;
   // Not added from original: repeated PerfUint64Metadata uint64_metadata = 9;
   // Not added from original:
   //     optional PerfCPUTopologyMetadata cpu_topology = 11;
   // Not added from original:
   //     repeated PerfNodeTopologyMetadata numa_topology = 12;

   message StringMetadata {
     message StringAndMd5sumPrefix {
       // The string value was field 1 and has been intentionally left out.

       // The string value's md5sum prefix.
       optional uint64 value_md5_prefix = 2;
     }

     // Not added from original: optional StringAndMd5sumPrefix hostname = 1;
     // Not added from original:
     //     optional StringAndMd5sumPrefix kernel_version =2;
     // Not added from original: optional StringAndMd5sumPrefix perf_version = 3;
     // Not added from original: optional StringAndMd5sumPrefix architecture = 4;
     // Not added from original:
     //     optional StringAndMd5sumPrefix cpu_description = 5;
     // Not added from original: optional StringAndMd5sumPrefix cpu_id = 6;
     // Not added from original:
     //     repeated StringAndMd5sumPrefix perf_command_line_token = 7;

     // The command line stored as a single string.
     optional StringAndMd5sumPrefix perf_command_line_whole = 8;
   }

   // All the string metadata from the perf data file.
   optional StringMetadata string_metadata = 13;
 }
	// Copyright 2014 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.

	syntax = "proto2";

	option optimize_for = LITE_RUNTIME;
	option java_outer_classname = "PerfDataProtos";
	option java_package = "org.chromium.components.metrics";

	package metrics;

	// Stores information from a perf session generated via running:
	// "perf record"
	//
	// See $kernel/tools/perf/design.txt for more details.

	// Please do not modify this protobuf directly, except to mirror the upstream
	// version found here:
	// https://chromium.googlesource.com/chromiumos/platform/chromiumos-wide-profiling/+/master/perf_data.proto
	// with some fields omitted for privacy reasons. Because it is a read-only copy
	// of the upstream protobuf, "Next tag:" comments are also absent.

	message PerfDataProto {
	// Perf event attribute. Stores the event description.
	// This data structure is defined in the linux kernel:
	// $kernel/tools/perf/util/event.h.
	message PerfEventAttr {
	// Type of the event. Type is an enumeration and can be:
	// IP: an instruction-pointer was stored in the event.
	// MMAP: a DLL was loaded.
	// FORK: a process was forked.
	// etc.
	optional uint32 type = 1;

	// Size of the event data in bytes.
	optional uint32 size = 2;

	// The config stores the CPU-specific counter information.
	optional uint64 config = 3;

	// Sample period of the event. Indicates how often the event is
	// triggered in terms of # of events. After \|sample_period\| events, an event
	// will be recorded and stored.
	optional uint64 sample_period = 4;

	// Sample frequency of the event. Indicates how often the event is
	// triggered in terms of # per second. The kernel will try to record
	// \|sample_freq\| events per second.
	optional uint64 sample_freq = 5;

	// Sample type is a bitfield that records attributes of the sample. Example,
	// whether an entire callchain was recorded, etc.
	optional uint64 sample_type = 6;

	// Bitfield that indicates whether reads on the counter will return the
	// total time enabled and total time running.
	optional uint64 read_format = 7;

	// Indicates whether the counter starts off disabled.
	optional bool disabled = 8;

	// Indicates whether child processes inherit the counter.
	optional bool inherit = 9;

	// Indicates whether the counter is pinned to a particular CPU.
	optional bool pinned = 10;

	// Indicates whether this counter's group has exclusive access to the CPU's
	// counters.
	optional bool exclusive = 11;

	// The following bits restrict events to be counted when the CPU is in user,
	// kernel, hypervisor or idle modes.
	optional bool exclude_user = 12;
	optional bool exclude_kernel = 13;
	optional bool exclude_hv = 14;
	optional bool exclude_idle = 15;

	// Indicates whether mmap events should be recorded.
	optional bool mmap = 16;

	// Indicates whether process comm information should be recorded upon
	// process creation.
	optional bool comm = 17;

	// Indicates that we are in frequency mode, not period mode.
	optional bool freq = 18;

	// Indicates whether we have per-task counts.
	optional bool inherit_stat = 19;

	// Indicates whether we enable perf events after an exec() function call.
	optional bool enable_on_exec = 20;

	// Indicates whether we trace fork/exit.
	optional bool task = 21;

	// Indicates whether we are using a watermark to wake up.
	optional bool watermark = 22;

	// CPUs often "skid" when recording events. That means the instruction
	// pointer may not be the same as the one that caused the counter overflow.
	// Indicates the capabilities of the CPU in terms of recording precise
	// instruction pointer.
	optional uint32 precise_ip = 23;

	// Indicates whether we have non-exec mmap data.
	optional bool mmap_data = 24;

	// If set, all the event types will have the same sample_type.
	optional bool sample_id_all = 25;

	// Indicates whether we are counting events from the host (when running a
	// VM).
	optional bool exclude_host = 26;

	// Exclude events that happen on a guest OS.
	optional bool exclude_guest = 27;

	// Contains the number of events after which we wake up.
	optional uint32 wakeup_events = 28;

	// Contains the number of bytes after which we wake up.
	optional uint32 wakeup_watermark = 29;

	// Information about the type of the breakpoint.
	optional uint32 bp_type = 30;

	// Contains the breakpoint address.
	optional uint64 bp_addr = 31;

	// This is an extension of config (see above).
	optional uint64 config1 = 32;

	// The length of the breakpoint data in bytes.
	optional uint64 bp_len = 33;

	// This is an extension of config (see above).
	optional uint64 config2 = 34;

	// Contains the type of branch, example: user, kernel, call, return, etc.
	optional uint64 branch_sample_type = 35;
	}

	// Describes a perf.data file attribute.
	message PerfFileAttr {
	optional PerfEventAttr attr = 1;

	// List of perf file attribute ids. Each id describes an event.
	repeated uint64 ids = 2;
	}

	// This message contains information about a perf sample itself, as opposed to
	// a perf event captured by a sample.
	message SampleInfo {
	// Process ID / thread ID from which this sample was taken.
	optional uint32 pid = 1;
	optional uint32 tid = 2;

	// Time this sample was taken (NOT the same as an event time).
	// It is the number of nanoseconds since bootup.
	optional uint64 sample_time_ns = 3;

	// The ID of the sample's event type (cycles, instructions, etc).
	// The event type IDs are defined in PerfFileAttr.
	optional uint64 id = 4;

	// The CPU on which this sample was taken.
	optional uint32 cpu = 5;
	}

	message CommEvent {
	// Process id.
	optional uint32 pid = 1;

	// Thread id.
	optional uint32 tid = 2;

	// Comm string's md5 prefix.
	// The comm string was field 3 and has been intentionally left out.
	optional uint64 comm_md5_prefix = 4;

	// Time the sample was taken.
	// Deprecated, use \|sample_info\| instead.
	optional uint64 sample_time = 5 [deprecated = true];

	// Info about the perf sample containing this event.
	optional SampleInfo sample_info = 6;
	}

	message MMapEvent {
	// Process id.
	optional uint32 pid = 1;

	// Thread id.
	optional uint32 tid = 2;

	// Start address.
	optional uint64 start = 3;

	// Length.
	optional uint64 len = 4;

	// PG Offset.
	optional uint64 pgoff = 5;

	// Filename's md5 prefix.
	// The filename was field 6 and has been intentionally left out.
	optional uint64 filename_md5_prefix = 7;

	// Info about the perf sample containing this event.
	optional SampleInfo sample_info = 8;
	}

	message BranchStackEntry {
	// Branch source address.
	optional uint64 from_ip = 1;

	// Branch destination address.
	optional uint64 to_ip = 2;

	// Indicates a mispredicted branch.
	optional bool mispredicted = 3;
	}

	message SampleEvent {
	// Instruction pointer.
	optional uint64 ip = 1;

	// Process id.
	optional uint32 pid = 2;

	// Thread id.
	optional uint32 tid = 3;

	// The time after boot when the sample was recorded, in nanoseconds.
	optional uint64 sample_time_ns = 4;

	// The address of the sample.
	optional uint64 addr = 5;

	// The id of the sample.
	optional uint64 id = 6;

	// The stream id of the sample.
	optional uint64 stream_id = 7;

	// The period of the sample.
	optional uint64 period = 8;

	// The CPU where the event was recorded.
	optional uint32 cpu = 9;

	// The raw size of the event in bytes.
	optional uint32 raw_size = 10;

	// Sample callchain info.
	repeated uint64 callchain = 11;

	// Branch stack info.
	repeated BranchStackEntry branch_stack = 12;

	// Not added from original: fields 13 and 14.

	// Sample weight for special events.
	optional uint64 weight = 15;

	// Sample data source flags.
	// Possible flag values:
	// http://lxr.free-electrons.com/source/include/uapi/linux/perf_event.h#L849
	optional uint64 data_src = 16;

	// Sample transaction flags for special events.
	// Flag fields:
	// http://lxr.free-electrons.com/source/include/uapi/linux/perf_event.h#L209
	optional uint64 transaction = 17;
	}

	// ForkEvent is used for both FORK and EXIT events, which have the same data
	// format. We don't want to call this "ForkOrExitEvent", in case a separate
	// exit event is introduced in the future.
	message ForkEvent {
	// Forked process ID.
	optional uint32 pid = 1;

	// Parent process ID.
	optional uint32 ppid = 2;

	// Forked process thread ID.
	optional uint32 tid = 3;

	// Parent process thread ID.
	optional uint32 ptid = 4;

	// Time of fork event in nanoseconds since bootup.
	optional uint64 fork_time_ns = 5;

	// Info about the perf sample containing this event.
	optional SampleInfo sample_info = 11;
	}

	message EventHeader {
	// Type of event.
	optional uint32 type = 1;
	optional uint32 misc = 2;
	// Size of event.
	optional uint32 size = 3;
	}

	message PerfEvent {
	optional EventHeader header = 1;

	optional MMapEvent mmap_event = 2;
	optional SampleEvent sample_event = 3;
	optional CommEvent comm_event = 4;
	// FORK and EXIT events are structurally identical. They only differ by the
	// event type. But using two distinct fields makes things easier.
	optional ForkEvent fork_event = 5;
	optional ForkEvent exit_event = 9;

	// Not added from original: optional LostEvent lost_event = 6;
	// Not added from original: optional ThrottleEvent throttle_event = 7;
	// Not added from original: optional ReadEvent read_event = 8;
	}

	message PerfEventStats {
	// Total number of events read from perf data.
	optional uint32 num_events_read = 1;

	// Total number of various types of events.
	optional uint32 num_sample_events = 2;
	optional uint32 num_mmap_events = 3;
	optional uint32 num_fork_events = 4;
	optional uint32 num_exit_events = 5;

	// Number of sample events that were successfully mapped by the address
	// mapper, a quipper module that is used to obscure addresses and convert
	// them to DSO name + offset. Sometimes it fails to process sample events.
	// This field allows us to track the success rate of the address mapper.
	optional uint32 num_sample_events_mapped = 6;

	// Whether address remapping was enabled.
	optional bool did_remap = 7;
	}

	message PerfBuildID {
	// Misc field in perf_event_header.
	// Indicates whether the file is mapped in kernel mode or user mode.
	optional uint32 misc = 1;

	// Process ID.
	optional uint32 pid = 2;

	// Build id. Should always contain kBuildIDArraySize bytes of data.
	// perf_reader.h in Chrome OS defines kBuildIDArraySize = 20.
	optional bytes build_hash = 3;

	// Filename Md5sum prefix.
	// The filename was field 4 and has been intentionally left out.
	optional uint64 filename_md5_prefix = 5;
	}

	repeated PerfFileAttr file_attrs = 1;
	repeated PerfEvent events = 2;

	// Time when quipper generated this perf data / protobuf, given as seconds
	// since the epoch.
	optional uint64 timestamp_sec = 3;

	// Records some stats about the serialized perf events.
	optional PerfEventStats stats = 4;

	// Not added from original: repeated uint64 metadata_mask = 5;

	// Build ID metadata.
	repeated PerfBuildID build_ids = 7;

	// Not added from original: repeated PerfUint32Metadata uint32_metadata = 8;
	// Not added from original: repeated PerfUint64Metadata uint64_metadata = 9;
	// Not added from original:
	// optional PerfCPUTopologyMetadata cpu_topology = 11;
	// Not added from original:
	// repeated PerfNodeTopologyMetadata numa_topology = 12;

	message StringMetadata {
	message StringAndMd5sumPrefix {
	// The string value was field 1 and has been intentionally left out.

	// The string value's md5sum prefix.
	optional uint64 value_md5_prefix = 2;
	}

	// Not added from original: optional StringAndMd5sumPrefix hostname = 1;
	// Not added from original:
	// optional StringAndMd5sumPrefix kernel_version =2;
	// Not added from original: optional StringAndMd5sumPrefix perf_version = 3;
	// Not added from original: optional StringAndMd5sumPrefix architecture = 4;
	// Not added from original:
	// optional StringAndMd5sumPrefix cpu_description = 5;
	// Not added from original: optional StringAndMd5sumPrefix cpu_id = 6;
	// Not added from original:
	// repeated StringAndMd5sumPrefix perf_command_line_token = 7;

	// The command line stored as a single string.
	optional StringAndMd5sumPrefix perf_command_line_whole = 8;
	}

	// All the string metadata from the perf data file.
	optional StringMetadata string_metadata = 13;
	}