This page acts as a reference guide to synthetically generate TrackEvent, Perfetto‘s native protobuf based tracing format. This allows using Perfetto’s analysis and visualzation without using collecting traces using the Perfetto SDK.
TrackEvent protos can be manually written using the official protobuf library or any other protobuf-compatible library. To be language-agnostic, the rest of this page will show examples using the text format representation of protobufs.
The root container of the protobuf-based traces is the Trace message which itself is simply a repeated field of TracePacket messages.
NOTE: in the legacy JSON tracing format, this section correspond to B/E/I/X events with the associated M (metadata) events.
Thread scoped slices are used to trace execution of functions on a single thread. As only one function runs on a single thread over time, this requires that child slices nest perfectly inside parent slices and do not partially overlap.
This is corresponds to the following protos:
# Emit this packet once *before* you emit the first event for this process. packet { track_descriptor: { uuid: 894893984 # 64-bit random number. process: { pid: 1234 # PID for your process. process_name: "My process name" } } } # Emit this packet once *before* you emit the first event for this thread. packet { track_descriptor: { uuid: 49083589894 # 64-bit random number. parent_uuid: 894893984 # UUID from above. thread: { pid: 1234 # PID for your process. tid: 5678 # TID for your thread. thread_name: "My thread name" } } } # The events for this thread. packet { timestamp: 200 track_event: { type: TYPE_SLICE_BEGIN track_uuid: 49083589894 # Same random number from above. name: "My special parent" } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. } packet { timestamp: 250 track_event: { type: TYPE_SLICE_BEGIN track_uuid: 49083589894 name: "My special child" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 285 track_event { type: TYPE_INSTANT track_uuid: 49083589894 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 290 track_event: { type: TYPE_SLICE_END track_uuid: 49083589894 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 300 track_event: { type: TYPE_SLICE_END track_uuid: 49083589894 } trusted_packet_sequence_id: 3903809 }
NOTE: in the legacy JSON tracing format, this section corresponds to b/e/n events with the associated M (metadata) events.
Process-scoped slices are useful to trace execution of a “piece of work” across multiple threads of a process. A process-scoped slice can start on a thread A and end on a thread B. Examples include work submitted to thread pools and coroutines.
Process tracks can be named corresponding to the executor and can also have child slices in an identical way to thread-scoped slices. Importantly, this means slices on a single track must strictly nest inside each other without overlapping.
As separating each track in the UI can cause a lot of clutter, the UI visually merges process tracks with the same name in each process. Note that this does not change the data model (e.g. in trace processor tracks remain separated) as this is simply a visual grouping.
This is corresponds to the following protos:
# The first track associated with this process. packet { track_descriptor { uuid: 48948 # 64-bit random number. name: "My special track" process { pid: 1234 # PID for your process process_name: "My process name" } } } # The events for the first track. packet { timestamp: 200 track_event { type: TYPE_SLICE_BEGIN track_uuid: 48948 # Same random number from above. name: "My special parent A" } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. } packet { timestamp: 250 track_event { type: TYPE_SLICE_BEGIN track_uuid: 48948 name: "My special child" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 290 track_event { type: TYPE_SLICE_END track_uuid: 48948 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 300 track_event { type: TYPE_SLICE_END track_uuid: 48948 } trusted_packet_sequence_id: 3903809 } # The second track associated with this process. Note how we make the above # track the "parent" of this track: this means that this track also is # associated to the same process. Note further this shows as the same visual # track in the UI but remains separate in the trace and data model. Emitting # these events on a separate track is necessary because these events overlap # *without* nesting with the above events. packet { track_descriptor { uuid: 2390190934 # 64-bit random number. name: "My special track" parent_uuid: 48948 } } # The events for the second track. packet { timestamp: 230 track_event { type: TYPE_SLICE_BEGIN track_uuid: 2390190934 # Same random number from above. name: "My special parent A" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 260 track_event { type: TYPE_SLICE_BEGIN track_uuid: 2390190934 name: "My special child" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 270 track_event { type: TYPE_SLICE_END track_uuid: 2390190934 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 295 track_event { type: TYPE_SLICE_END track_uuid: 2390190934 } trusted_packet_sequence_id: 3903809 }
NOTE: there is no equivalent in the JSON tracing format.
As well as thread-scoped and process-scoped slices, Perfetto supports creating tracks which are not scoped to any OS-level concept. Moreover, these tracks can be recursively nested in a tree structure. This is useful to model the timeline of execution of GPUs, network traffic, IRQs etc.
Note: in the past, modelling such slices may have been done by abusing processes/threads slices, due to limitations with the data model and the Perfetto UI. This is no longer necessary and we strongly discourage continued use of this hack.
This is corresponds to the following protos:
packet { track_descriptor { uuid: 48948 # 64-bit random number. name: "Root" } } packet { track_descriptor { uuid: 50001 # 64-bit random number. parent_uuid: 48948 # UUID of root track. name: "Parent B" } } packet { track_descriptor { uuid: 50000 # 64-bit random number. parent_uuid: 48948 # UUID of root track. name: "Parent A" } } packet { track_descriptor { uuid: 60000 # 64-bit random number. parent_uuid: 50000 # UUID of Parent A track. name: "Child A1" } } packet { track_descriptor { uuid: 60001 # 64-bit random number. parent_uuid: 50000 # UUID of Parent A track. name: "Child A2" } } packet { track_descriptor { uuid: 70000 # 64-bit random number. parent_uuid: 50001 # UUID of Parent B track. name: "Child B1" } } # The events for the Child A1 track. packet { timestamp: 200 track_event { type: TYPE_SLICE_BEGIN track_uuid: 60000 # Same random number from above. name: "A1" } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. } packet { timestamp: 250 track_event { type: TYPE_SLICE_END track_uuid: 60000 } trusted_packet_sequence_id: 3903809 } # The events for the Child A2 track. packet { timestamp: 220 track_event { type: TYPE_SLICE_BEGIN track_uuid: 60001 # Same random number from above. name: "A2" } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. } packet { timestamp: 240 track_event { type: TYPE_SLICE_END track_uuid: 60001 } trusted_packet_sequence_id: 3903809 } # The events for the Child B1 track. packet { timestamp: 210 track_event { type: TYPE_SLICE_BEGIN track_uuid: 70000 # Same random number from above. name: "B1" } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. } packet { timestamp: 230 track_event { type: TYPE_SLICE_END track_uuid: 70000 } trusted_packet_sequence_id: 3903809 }
NOTE: the closest equivalent to this in the JSON format is process_sort_index
but the Perfetto approach is significantly more flexible.
Perfetto also supports specifying of how the tracks should be visualized in the UI by default. This is done via the use of the child_ordering
field which can be set on TrackDescriptor
.
For example, to sort the tracks lexicographically (i.e. in alphabetical order):
packet { track_descriptor { uuid: 10 name: "Root" # Any children of the `Root` track will appear in alphabetical order. This # does *not* propogate to any indirect descendants, just the direct # children. child_ordering: LEXICOGRAPHIC } } # B will appear nested under `Root` but *after* `A` in the UI, even though it # appears first in the trace and has a smaller UUID. packet { track_descriptor { uuid: 11 parent_uuid: 10 name: "B" } } packet { track_descriptor { uuid: 12 parent_uuid: 10 name: "A" } }
Chronological order is also supported, this sorts the tracks with the earliest event first:
packet { track_descriptor { uuid: 10 name: "Root" # Any children of the `Root` track will appear in the order based on the # timestamp of the first event on the trace: earlier timestamps will appear # higher in the trace. This does *not* propogate to any indirect # descendants, just the direct children. child_ordering: CHRONOLOGICAL } } # B will appear before A because B's first slice starts earlier than A's first # slice. packet { track_descriptor { uuid: 11 parent_uuid: 10 name: "A" } } packet { timestamp: 220 track_event { type: TYPE_SLICE_BEGIN track_uuid: 11 name: "A1" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 230 track_event { type: TYPE_SLICE_END track_uuid: 60000 } trusted_packet_sequence_id: 3903809 } packet { track_descriptor { uuid: 12 parent_uuid: 10 name: "B" } } packet { timestamp: 210 track_event { type: TYPE_SLICE_BEGIN track_uuid: 12 name: "B1" } trusted_packet_sequence_id: 3903809 } packet { timestamp: 240 track_event { type: TYPE_SLICE_END track_uuid: 12 } trusted_packet_sequence_id: 3903809 }
Finally, for exact control, you can use the EXPLICIT
ordering and specify sibling_order_rank
on each child track:
packet { track_descriptor { uuid: 10 name: "Root" # Any children of the `Root` track will appear in order specified by # `sibling_order_rank` exactly: any unspecified rank is treated as 0 # implicitly. child_ordering: EXPLICIT } } # C will appear first, then B then A following the order specified by # `sibling_order_rank`. packet { track_descriptor { uuid: 11 parent_uuid: 10 name: "B" sibling_order_rank: 1 } } packet { track_descriptor { uuid: 12 parent_uuid: 10 name: "A" sibling_order_rank: 100 } } packet { track_descriptor { uuid: 13 parent_uuid: 10 name: "C" sibling_order_rank: -100 } }
NOTE: using EXPLICIT
is strongly discouraged where there is another option. Other orders are significantly more efficient and also allows for trace processor and the UI to better understand what you want to do with those tracks. Moreover, it gives the flexibility for having custom visualization (e.g. Gannt charts for CHRONOLOGICAL view) based on the type specified.
Further documentation about the sorting order is available on the protos for TrackDescriptor and ChildTracksOrdering.
NOTE: the order specified in the trace is a treated as a hint in the UI not a gurantee. The UI reserves the right to change the ordering as it sees fit.
NOTE: in the legacy JSON tracing format, this section correspond to s/t/f events.
Flows allow connecting any number of slices with arrows. The semantic meaning of the arrow varies across different applications but most commonly it is used to track work passing between threads or processes: e.g. the UI thread asks a background thread to do some work and notify when the result is available.
NOTE: a single flow cannot fork ands imply represents a single stream of arrows from one slice to the next. See this comment for information.
# The main thread of the process. packet { track_descriptor { uuid: 93094 thread { pid: 100 tid: 100 thread_name: "Main thread" } } } packet { timestamp: 200 track_event { type: TYPE_SLICE_BEGIN track_uuid: 93094 name: "Request generation" flow_ids: 1055895987 # Random number used to track work # across threads/processes. } trusted_packet_sequence_id: 3903809 } packet { timestamp: 300 track_event { type: TYPE_SLICE_END track_uuid: 93094 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 400 track_event { type: TYPE_SLICE_BEGIN track_uuid: 93094 name: "Process background result" flow_ids: 1055895987 # Same as above. } trusted_packet_sequence_id: 3903809 } packet { timestamp: 500 track_event { type: TYPE_SLICE_END track_uuid: 93094 } trusted_packet_sequence_id: 3903809 } # The background thread of the process. packet { track_descriptor { uuid: 40489498 thread { pid: 100 tid: 101 thread_name: "Background thread" } } } packet { timestamp: 310 track_event { type: TYPE_SLICE_BEGIN track_uuid: 40489498 name: "Background work" flow_ids: 1055895987 # Same as above. } trusted_packet_sequence_id: 3903809 } packet { timestamp: 385 track_event { type: TYPE_SLICE_END track_uuid: 40489498 } trusted_packet_sequence_id: 3903809 }
NOTE: in the legacy JSON tracing format, this section correspond to C events.
Counters are useful to represent continuous values which change with time. Common examples include CPU frequency, memory usage, battery charge etc.
This corresponds to the following protos:
# Counter track scoped to a process. packet { track_descriptor { uuid: 1388 process { pid: 1024 process_name: "MySpecialProcess" } } } packet { track_descriptor { uuid: 4489498 parent_uuid: 1388 name: "My special counter" counter {} } } packet { timestamp: 200 track_event { type: TYPE_COUNTER track_uuid: 4489498 counter_value: 34567 # Value at start } trusted_packet_sequence_id: 3903809 } packet { timestamp: 250 track_event { type: TYPE_COUNTER track_uuid: 4489498 counter_value: 67890 # Value goes up } trusted_packet_sequence_id: 3903809 } packet { timestamp: 300 track_event { type: TYPE_COUNTER track_uuid: 4489498 counter_value: 12345 # Value goes down } trusted_packet_sequence_id: 3903809 } packet { timestamp: 400 track_event { type: TYPE_COUNTER track_uuid: 4489498 counter_value: 12345 # Final value } trusted_packet_sequence_id: 3903809 }
NOTE: there is no equivalent to interning in the JSON tracing format.
Interning is an advanced but powerful feature of the protobuf tracing format which allows allows for reducing the number of times long strings are emitted in the trace.
Specifically, certain fields in the protobuf format allow associating an “iid” (interned id) to a string and using the iid to reference the string in all future packets. The most commonly used cases are slice names and category names
Here is an example of a trace which makes use of interning to reduce the number of times a very long slice name is emitted:
This corresponds to the following protos:
packet { track_descriptor { uuid: 48948 # 64-bit random number. name: "My special track" process { pid: 1234 # PID for your process process_name: "My process name" } } } packet { timestamp: 200 track_event { type: TYPE_SLICE_BEGIN track_uuid: 48948 # Same random number from above. name_iid: 1 # References the string in interned_data # (see below) } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. interned_data { # Creates a mapping from the iid "1" to the string name: any |name_iid| field # in this packet onwards will transparently be remapped to this string by trace # processor. # Note: iid 0 is *not* a valid IID and should not be used. event_names { iid: 1 name: "A very very very long slice name which we don't want to repeat" } } first_packet_on_sequence: true # Indicates to trace processor that # this is the first packet on the # sequence. previous_packet_dropped: true # Same as |first_packet_on_sequence|. # Indicates to trace processor that this sequence resets the incremental state but # also depends on incrtemental state state. # 3 = SEQ_INCREMENTAL_STATE_CLEARED | SEQ_NEEDS_INCREMENTAL_STATE sequence_flags: 3 } packet { timestamp: 201 track_event { type: TYPE_SLICE_END track_uuid: 48948 } trusted_packet_sequence_id: 3903809 } packet { timestamp: 202 track_event { type: TYPE_SLICE_BEGIN track_uuid: 48948 # Same random number from above. name_iid: 1 # References the string in interned_data # above. } trusted_packet_sequence_id: 3903809 # Generate *once*, use throughout. # 2 = SEQ_NEEDS_INCREMENTAL_STATE sequence_flags: 2 } packet { timestamp: 203 track_event { type: TYPE_SLICE_END track_uuid: 48948 } trusted_packet_sequence_id: 3903809 }