docs/reference/synthetic-track-event.md
This page serves as an advanced reference for programmatically creating Perfetto trace files. It builds upon the foundational concepts and examples presented in "Converting arbitrary timestamped data to Perfetto".
We assume you are familiar with:
Trace message containing a stream
of TracePacket messages).TrackEvent payload within TracePacket to create custom tracks
with various types of slices (simple, nested, asynchronous), counters, and
flows.trace_converter_template.py) for generating
traces, and that the Python examples provided here are intended to be used
within its populate_packets(builder) function.This guide will currently focus on advanced TrackEvent features, such as:
While TrackEvent is a primary method for representing timeline data,
TracePacket is a versatile container. In the future, this guide may expand to
cover other TracePacket payloads useful for synthetic trace generation.
The examples will continue to use Python, but the principles apply to any language with Protocol Buffer support. For complete definitions of all available fields, always refer to the official Perfetto protobuf sources, particularly TracePacket and its various sub-messages, including TrackEvent.
While the "Converting arbitrary timestamped data to Perfetto" guide demonstrated creating generic custom tracks, you can provide more specific context to Perfetto by associating your tracks with operating system (OS) processes and threads. This allows Perfetto's UI and analysis tools to offer richer integration and better correlation with other system-wide data.
You can create a top-level track that represents an OS process. Any other custom tracks (which might contain slices or counters) can then be parented to this process track. This helps in:
To define a process track, you populate the process field within its
TrackDescriptor. At a minimum, you should provide a pid and ideally a
process_name.
It is also recommended to add a timestamp to the TracePacket containing the
process's TrackDescriptor. This is especially important when the trace
contains data from other sources (e.g. scheduling information from the kernel).
Unlike with "global" tracks, these track types may interact with other data
sources and as such having a timestamp makes sure that Trace Processor can
accurately sort the descriptor into the right place.
Let's say you want to emit a custom counter (e.g. "Active DB Connections") and have it appear under a specific process named "MyDatabaseService" with PID 1234.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 8008
# --- Define OS Process ---
PROCESS_ID = 1234
PROCESS_NAME = "MyDatabaseService"
# Define a UUID for the process track
process_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
# 1. Define the Process Track
# This packet establishes "MyDatabaseService (1234)" in the trace.
packet = builder.add_packet()
# It's good practice to timestamp the descriptor to be before the first
# event.
packet.timestamp = 9999
desc = packet.track_descriptor
desc.uuid = process_track_uuid
desc.process.pid = PROCESS_ID
desc.process.process_name = PROCESS_NAME
# This track itself usually doesn't have events, it serves as a parent.
# --- Define a Custom Counter Track parented to the Process ---
db_connections_counter_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = db_connections_counter_track_uuid
desc.parent_uuid = process_track_uuid # Link to the process track
desc.name = "Active DB Connections"
# Mark this track as a counter track
desc.counter.unit_name = "connections" # Optional: specify units
# Helper to add a counter event
def add_counter_event(ts, value, counter_track_uuid):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = TrackEvent.TYPE_COUNTER
packet.track_event.track_uuid = counter_track_uuid
packet.track_event.counter_value = value
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 3. Emit counter values on the custom counter track
add_counter_event(ts=10000, value=5, counter_track_uuid=db_connections_counter_track_uuid)
add_counter_event(ts=10100, value=7, counter_track_uuid=db_connections_counter_track_uuid)
add_counter_event(ts=10200, value=6, counter_track_uuid=db_connections_counter_track_uuid)
If you only have symbolized function names, call add_frame(...) with just the
interned function name ID: e.g. add_frame(packet.interned_data, FRAME_MAIN, FUNC_MAIN).
You can query process-associated counter data using SQL in the Perfetto UI's Query tab or with Trace Processor:
SELECT counter.ts, counter.value, process.name AS process_name
FROM counter
JOIN process_counter_track ON counter.track_id = process_counter_track.id
JOIN process USING(upid)
WHERE process.pid = 1234;
Once you have defined a process track, you can parent various other kinds of tracks to it. This includes tracks for specific threads within that process (see next section), as well as custom tracks for process-wide counters (as shown above) or groups of asynchronous operations related to this process (using the techniques for asynchronous slices described in the "Converting arbitrary timestamped data to Perfetto" guide).
You can create tracks that are explicitly associated with specific threads within an OS process. This is the most common way to represent thread-specific activity, such as function call stacks or thread-local counters.
Benefits:
pid and tid are specified
in its TrackDescriptor, the Perfetto UI typically groups it under the
corresponding process (identified by that pid). This helps organize the
trace.To define a thread track:
TrackDescriptor for the thread.thread field, providing the pid of the process this thread
belongs to and the unique tid of the thread. You should also set
thread_name.TrackDescriptor
for the parent process itself (using its process field and pid), though
it's not strictly required for the thread track to be recognized as a
thread of that PID. The UI often infers process groupings from PIDs present
in thread tracks.Similarly to process tracks, it is also recommended to add a timestamp to the
TracePacket containing the thread's TrackDescriptor. This is especially
important when the trace contains data from other sources (e.g. scheduling
information from the kernel). Unlike with "global" tracks, these track types may
interact with other data sources and as such having a timestamp makes sure that
Trace Processor can accurately sort the descriptor into the right place.
Python Example: Thread-Specific Slices
This example defines a thread "MainWorkLoop" (TID 5678) belonging to process
"MyApplication" (PID 1234). It then emits a couple of slices directly onto this
thread's track. We also define a track for the process itself for clarity,
though the thread track's association is primarily through its pid and tid
fields.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 8009
# --- Define OS Process and Thread IDs and Names ---
APP_PROCESS_ID = 1234
APP_PROCESS_NAME = "MyApplication"
MAIN_THREAD_ID = 5678
MAIN_THREAD_NAME = "MainWorkLoop"
# --- Define UUIDs for the tracks ---
# While not strictly necessary to parent a thread track to a process track
# for the UI to group them by PID, defining a process track can be good practice
# if you want to name the process explicitly or attach process-scoped tracks later.
app_process_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
main_thread_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
# 1. Define the Process Track (Optional, but good for naming the process)
packet = builder.add_packet()
packet.timestamp = 14998
desc = packet.track_descriptor
desc.uuid = app_process_track_uuid
desc.process.pid = APP_PROCESS_ID
desc.process.process_name = APP_PROCESS_NAME
# 2. Define the Thread Track
# The .thread.pid field associates it with the process.
# No parent_uuid is set here; UI will group by PID.
packet = builder.add_packet()
packet.timestamp = 14999
desc = packet.track_descriptor
desc.uuid = main_thread_track_uuid
# desc.parent_uuid = app_process_track_uuid # This line is NOT used
desc.thread.pid = APP_PROCESS_ID
desc.thread.tid = MAIN_THREAD_ID
desc.thread.thread_name = MAIN_THREAD_NAME
# Helper to add a slice event to a specific track
def add_slice_event(ts, event_type, event_track_uuid, name=None):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = event_type
packet.track_event.track_uuid = event_track_uuid
if name:
packet.track_event.name = name
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 3. Emit slices on the main_thread_track_uuid
add_slice_event(ts=15000, event_type=TrackEvent.TYPE_SLICE_BEGIN,
event_track_uuid=main_thread_track_uuid, name="ProcessInputEvent")
# Nested slice
add_slice_event(ts=15050, event_type=TrackEvent.TYPE_SLICE_BEGIN,
event_track_uuid=main_thread_track_uuid, name="UpdateState")
add_slice_event(ts=15150, event_type=TrackEvent.TYPE_SLICE_END, # Ends UpdateState
event_track_uuid=main_thread_track_uuid)
add_slice_event(ts=15200, event_type=TrackEvent.TYPE_SLICE_END, # Ends ProcessInputEvent
event_track_uuid=main_thread_track_uuid)
add_slice_event(ts=16000, event_type=TrackEvent.TYPE_SLICE_BEGIN,
event_track_uuid=main_thread_track_uuid, name="RenderFrame")
add_slice_event(ts=16500, event_type=TrackEvent.TYPE_SLICE_END,
event_track_uuid=main_thread_track_uuid)
You can query thread-specific slices using SQL in the Perfetto UI's Query tab or with Trace Processor:
INCLUDE PERFETTO MODULE slices.with_context;
SELECT ts, dur, name, thread_name
FROM thread_slice
WHERE tid = 5678;
Beyond associating tracks with OS concepts, Perfetto offers ways to fine-tune how your tracks are presented and how data is encoded.
By default, the Perfetto UI applies its own heuristics to sort tracks (e.g.,
alphabetically by name, or by track UUID). However, for complex custom traces,
you might want to explicitly define the order in which sibling tracks appear
under a parent. This is achieved using the child_ordering field on the parent
TrackDescriptor and, for EXPLICIT ordering, the sibling_order_rank on the
child TrackDescriptors.
This child_ordering setting on a parent track only affects its direct
children.
Available child_ordering modes (defined in
TrackDescriptor.ChildTracksOrdering):
ORDERING_UNSPECIFIED: The default. The UI will use its own heuristics.LEXICOGRAPHIC: Child tracks are sorted alphabetically by their name.CHRONOLOGICAL: Child tracks are sorted based on the timestamp of the
earliest TrackEvent that occurs on each of them. Tracks with earlier events
appear first.EXPLICIT: Child tracks are sorted based on the sibling_order_rank field
set in their respective TrackDescriptors. Lower ranks appear first. If ranks
are equal, or if sibling_order_rank is not set, the tie-breaking order is
undefined.Note: The UI treats these as strong hints. While it generally respects these orderings, there are contexts in which the UI reserves the right not to show them in this order; generally this would be if the user explicitly requested this or if the UI has some special handling for these tracks.
Python Example: Demonstrating All Sorting Types
This example defines three parent tracks, each demonstrating a different
child_ordering mode.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 9000
# Helper to define a TrackDescriptor
def define_custom_track(track_uuid, name, parent_track_uuid=None, child_ordering_mode=None, order_rank=None):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
if parent_track_uuid:
desc.parent_uuid = parent_track_uuid
if child_ordering_mode:
desc.child_ordering = child_ordering_mode
if order_rank is not None:
desc.sibling_order_rank = order_rank
# Helper to add a simple instant event
def add_instant_event(ts, track_uuid, event_name):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = TrackEvent.TYPE_INSTANT
packet.track_event.track_uuid = track_uuid
packet.track_event.name = event_name
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# --- 1. Lexicographical Sorting Example ---
parent_lex_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(parent_lex_uuid, "Lexicographic Parent",
child_ordering_mode=TrackDescriptor.LEXICOGRAPHIC)
child_c_lex_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_a_lex_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_b_lex_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(child_c_lex_uuid, "C-Item (Lex)", parent_track_uuid=parent_lex_uuid)
define_custom_track(child_a_lex_uuid, "A-Item (Lex)", parent_track_uuid=parent_lex_uuid)
define_custom_track(child_b_lex_uuid, "B-Item (Lex)", parent_track_uuid=parent_lex_uuid)
add_instant_event(ts=100, track_uuid=child_c_lex_uuid, event_name="Event C")
add_instant_event(ts=100, track_uuid=child_a_lex_uuid, event_name="Event A")
add_instant_event(ts=100, track_uuid=child_b_lex_uuid, event_name="Event B")
# Expected UI order under "Lexicographic Parent": A-Item, B-Item, C-Item
# --- 2. Chronological Sorting Example ---
parent_chrono_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(parent_chrono_uuid, "Chronological Parent",
child_ordering_mode=TrackDescriptor.CHRONOLOGICAL)
child_late_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_early_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_middle_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(child_late_uuid, "Late Event Track", parent_track_uuid=parent_chrono_uuid)
define_custom_track(child_early_uuid, "Early Event Track", parent_track_uuid=parent_chrono_uuid)
define_custom_track(child_middle_uuid, "Middle Event Track", parent_track_uuid=parent_chrono_uuid)
add_instant_event(ts=2000, track_uuid=child_late_uuid, event_name="Late Event")
add_instant_event(ts=1000, track_uuid=child_early_uuid, event_name="Early Event")
add_instant_event(ts=1500, track_uuid=child_middle_uuid, event_name="Middle Event")
# Expected UI order under "Chronological Parent": Early, Middle, Late Event Track
# --- 3. Explicit Sorting Example ---
parent_explicit_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(parent_explicit_uuid, "Explicit Parent",
child_ordering_mode=TrackDescriptor.EXPLICIT)
child_rank10_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_rank_neg5_uuid = uuid.uuid4().int & ((1 << 63) - 1)
child_rank0_uuid = uuid.uuid4().int & ((1 << 63) - 1)
define_custom_track(child_rank10_uuid, "Explicit Rank 10",
parent_track_uuid=parent_explicit_uuid, order_rank=10)
define_custom_track(child_rank_neg5_uuid, "Explicit Rank -5",
parent_track_uuid=parent_explicit_uuid, order_rank=-5)
define_custom_track(child_rank0_uuid, "Explicit Rank 0",
parent_track_uuid=parent_explicit_uuid, order_rank=0)
add_instant_event(ts=3000, track_uuid=child_rank10_uuid, event_name="Event Rank 10")
add_instant_event(ts=3000, track_uuid=child_rank_neg5_uuid, event_name="Event Rank -5")
add_instant_event(ts=3000, track_uuid=child_rank0_uuid, event_name="Event Rank 0")
# Expected UI order under "Explicit Parent": Rank -5, Rank 0, Rank 10
When visualizing multiple counter tracks, it is often useful to have them share
the same Y-axis range. This allows for easy comparison of their values. Perfetto
supports this feature through the y_axis_share_key field in the
CounterDescriptor.
All counter tracks that have the same y_axis_share_key and the same parent
track will share their Y-axis range in the UI.
Python Example: Sharing Y-Axis
In this example, we create two counter tracks with the same y_axis_share_key.
This will cause them to be rendered with the same Y-axis range in the Perfetto
UI.
TRUSTED_PACKET_SEQUENCE_ID = 9005
# --- Define Track UUIDs ---
counter1_uuid = 1
counter2_uuid = 2
# Helper to define a Counter TrackDescriptor
def define_counter_track(track_uuid, name, share_key=None):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
if share_key:
desc.counter.y_axis_share_key = share_key
# 1. Define the counter tracks with the same share key
define_counter_track(counter1_uuid, "Counter 1", "group1")
define_counter_track(counter2_uuid, "Counter 2", "group1")
# Helper to add a counter event
def add_counter_event(ts, value, counter_track_uuid):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = TrackEvent.TYPE_COUNTER
packet.track_event.track_uuid = counter_track_uuid
packet.track_event.counter_value = value
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 2. Add events to the tracks
add_counter_event(ts=1000, value=100, counter_track_uuid=counter1_uuid)
add_counter_event(ts=2000, value=200, counter_track_uuid=counter1_uuid)
add_counter_event(ts=1000, value=300, counter_track_uuid=counter2_uuid)
add_counter_event(ts=2000, value=400, counter_track_uuid=counter2_uuid)
You can add a human-readable description to any track to provide more context about the data it contains. In the Perfetto UI, this description appears in a popup when the user clicks the help icon next to the track's name. This is useful for explaining what a track represents, the meaning of its events, or how it should be interpreted, especially in complex custom traces.
To add a description, you simply set the optional description field in the
track's TrackDescriptor.
This example defines two tracks: one with a description field set and one
without, to illustrate the difference in the UI.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 9005
# --- Define Track UUID ---
described_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
undescribed_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
# --- 1. Define two tracks, one with a description and one without ---
# Track WITH description
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = described_track_uuid
desc.name = "Track With Description"
desc.description = "This track shows the processing stages for incoming user requests. Click the (?) icon to see this text."
# Track WITHOUT description
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = undescribed_track_uuid
desc.name = "Track Without Description"
# The 'description' field is simply not set.
# Helper to add a slice event to the track
def add_slice_event(ts, event_type, event_track_uuid, name=None):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = event_type
packet.track_event.track_uuid = event_track_uuid
if name:
packet.track_event.name = name
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# --- 2. Emit some events on both tracks ---
# Events for the described track
add_slice_event(ts=1000, event_type=TrackEvent.TYPE_SLICE_BEGIN,
event_track_uuid=described_track_uuid, name="Request #123")
add_slice_event(ts=1200, event_type=TrackEvent.TYPE_SLICE_END,
event_track_uuid=described_track_uuid)
# Events for the undescribed track
add_slice_event(ts=1300, event_type=TrackEvent.TYPE_SLICE_BEGIN,
event_track_uuid=undescribed_track_uuid, name="Some Other Task")
add_slice_event(ts=1500, event_type=TrackEvent.TYPE_SLICE_END,
event_track_uuid=undescribed_track_uuid)
This section covers advanced TrackEvent features for specialized use cases, including data optimization techniques and event linking mechanisms.
Interning is a technique used to reduce the size of trace files by emitting
frequently repeated strings (like event names or categories) only once in the
trace. Subsequent references to these strings use a compact integer identifier
(an "interning ID" or iid). This is particularly useful when you have many
events that share the same name or other string-based attributes.
How it works:
Define Interned Data: In a TracePacket, you include an interned_data
message. Inside this, you map your strings to iids. For example, you can
define event_names where each entry has an iid (a non-zero integer you
choose) and a name string. This packet establishes the mapping.
Reference by IID: In subsequent TrackEvents (within the same
trusted_packet_sequence_id and before the interned state is cleared),
instead of setting the name field directly, you set the corresponding
name_iid field to the integer iid you defined.
Sequence Flags: The TracePacket.sequence_flags field is crucial:
SEQ_INCREMENTAL_STATE_CLEARED (value 1): Set this on a packet if the
interning dictionary (and other incremental state) for this sequence
should be considered reset before processing this packet's
interned_data. This is often used on the first packet of a sequence that
defines interned entries.SEQ_NEEDS_INCREMENTAL_STATE (value 2): Set this on any packet that
either defines new interned data entries OR uses iids that were defined
in previous packets (within the current valid state of the sequence).A typical packet that initializes the interning dictionary for a sequence
will set both flags:
TracePacket.SEQ_INCREMENTAL_STATE_CLEARED | TracePacket.SEQ_NEEDS_INCREMENTAL_STATE.
Packets that use these established interned entries (or add more entries
to the existing valid dictionary) will set
TracePacket.SEQ_NEEDS_INCREMENTAL_STATE.
Python Example: Interning Event Names
This example shows how to define an interned string for an event name and then use it multiple times.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 9002
# --- Define Track UUID ---
interning_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
# Helper to define a TrackDescriptor
def define_custom_track(track_uuid, name):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
# 1. Define the track
define_custom_track(interning_track_uuid, "Interning Demo Track")
# --- Define Interned Event Name ---
INTERNED_EVENT_NAME_IID = 1 # Choose a unique iid (non-zero)
VERY_LONG_EVENT_NAME = "MyFrequentlyRepeatedLongEventNameThatTakesUpSpace"
# Helper to add a TrackEvent packet, managing interning and sequence flags
def add_slice_with_interning(ts, event_type, name_iid=None, name_literal=None, define_new_internment=False, new_intern_iid=None, new_intern_name=None):
packet = builder.add_packet()
packet.timestamp = ts
tev = packet.track_event
tev.type = event_type
tev.track_uuid = interning_track_uuid
if name_iid:
tev.name_iid = name_iid
elif name_literal and event_type != TrackEvent.TYPE_SLICE_END:
tev.name = name_literal
if define_new_internment:
# This packet defines new interned data.
# We'll also clear any prior state for this sequence.
if new_intern_iid and new_intern_name:
entry = packet.interned_data.event_names.add()
entry.iid = new_intern_iid
entry.name = new_intern_name
packet.sequence_flags = TracePacket.SEQ_INCREMENTAL_STATE_CLEARED | TracePacket.SEQ_NEEDS_INCREMENTAL_STATE
else:
# This packet uses existing interned data (or has no interned fields)
# but is part of a sequence that relies on incremental state.
packet.sequence_flags = TracePacket.SEQ_NEEDS_INCREMENTAL_STATE
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
return packet
# --- Packet 1: Define the interned name and start a slice using it ---
add_slice_with_interning(
ts=1000,
event_type=TrackEvent.TYPE_SLICE_BEGIN,
name_iid=INTERNED_EVENT_NAME_IID,
define_new_internment=True, # This packet defines/resets internment
new_intern_iid=INTERNED_EVENT_NAME_IID,
new_intern_name=VERY_LONG_EVENT_NAME
)
# End the first slice
add_slice_with_interning(
ts=1100,
event_type=TrackEvent.TYPE_SLICE_END
# No name_iid needed for END, uses existing interned state context
)
# --- Packet 2: Use the Interned Event Name Again ---
add_slice_with_interning(
ts=1200,
event_type=TrackEvent.TYPE_SLICE_BEGIN,
name_iid=INTERNED_EVENT_NAME_IID # Re-use the iid
# define_new_internment is False by default, so this uses existing state
)
# End the second slice
add_slice_with_interning(
ts=1300,
event_type=TrackEvent.TYPE_SLICE_END
)
The Getting Started guide covers inline callstacks for simple use cases. This section covers interned callstacks for efficiency when callstacks repeat or when you need binary mapping information for symbolization.
Interned callstacks define the callstack structure once in InternedData and
reference it by ID from multiple events. At a minimum you only need to define
frames, callstacks, and reference those callstacks from your events. The
other pieces are optional and can be supplied when you have that information:
mapping_id, rel_pc,
source_file_id, line_number, etc. are all optional—set only what makes
sense for your data.callstack_iid)This example demonstrates the complete workflow for interning callstacks, including mappings, frames, and callstacks. For minimal traces you can skip the mapping entries and populate frames with just function names (and whatever location details you have).
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
from perfetto.protos.perfetto.trace.perfetto_trace_pb2 import TracePacket
TRUSTED_PACKET_SEQUENCE_ID = 9001
# --- Define Track UUID ---
interned_callstack_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
def add_function_name(entry, iid, name):
item = entry.function_names.add()
item.iid = iid
item.str = name.encode()
def add_mapping(entry, iid, build_id, start, end, path_id):
mapping_entry = entry.mappings.add()
mapping_entry.iid = iid
mapping_entry.build_id = build_id
mapping_entry.exact_offset = 0
mapping_entry.start = start
mapping_entry.end = end
mapping_entry.load_bias = 0
mapping_entry.path_string_ids.append(path_id)
def add_frame(entry, iid, function_name_id, mapping_id=None, rel_pc=None):
frame_entry = entry.frames.add()
frame_entry.iid = iid
frame_entry.function_name_id = function_name_id
if mapping_id is not None:
frame_entry.mapping_id = mapping_id
if rel_pc is not None:
frame_entry.rel_pc = rel_pc
def add_callstack(entry, iid, frame_ids):
callstack_entry = entry.callstacks.add()
callstack_entry.iid = iid
callstack_entry.frame_ids.extend(frame_ids)
def emit_track_event(
ts,
event_type,
name,
callstack_iid,
):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = event_type
packet.track_event.track_uuid = interned_callstack_track_uuid
if name is not None:
packet.track_event.name = name
if callstack_iid is not None:
packet.track_event.callstack_iid = callstack_iid
packet.sequence_flags = TracePacket.SEQ_NEEDS_INCREMENTAL_STATE
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 1. Define the track
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = interned_callstack_track_uuid
desc.name = "Interned Callstack Demo"
# 2. Define interned data (mappings, frames, callstacks)
# We'll create this in a single packet that initializes the interning state
packet = builder.add_packet()
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
packet.sequence_flags = (TracePacket.SEQ_INCREMENTAL_STATE_CLEARED |
TracePacket.SEQ_NEEDS_INCREMENTAL_STATE)
# Define Build IDs
BUILD_ID_APP = 1
BUILD_ID_LIBC = 2
build_id_entry = packet.interned_data.build_ids.add()
build_id_entry.iid = BUILD_ID_APP
build_id_entry.str = b"a1b2c3d4e5f67890" # Hex-encoded build ID
build_id_entry = packet.interned_data.build_ids.add()
build_id_entry.iid = BUILD_ID_LIBC
build_id_entry.str = b"1234567890abcdef"
# Define Mapping Paths
PATH_APP = 1
PATH_LIBC = 2
path_entry = packet.interned_data.mapping_paths.add()
path_entry.iid = PATH_APP
path_entry.str = b"/usr/bin/myapp"
path_entry = packet.interned_data.mapping_paths.add()
path_entry.iid = PATH_LIBC
path_entry.str = b"/lib/x86_64-linux-gnu/libc.so.6"
# Define Mappings
MAPPING_APP = 1
MAPPING_LIBC = 2
add_mapping(packet.interned_data, MAPPING_APP, BUILD_ID_APP, 0x400000, 0x500000, PATH_APP)
add_mapping(packet.interned_data, MAPPING_LIBC, BUILD_ID_LIBC, 0x7F0000000000, 0x7F0000200000, PATH_LIBC)
# Define Frames
FUNC_MAIN = 1
FUNC_PROCESS_REQUESTS = 2
FUNC_HANDLE_REQUEST = 3
FUNC_MALLOC = 4
add_function_name(packet.interned_data, FUNC_MAIN, "main")
add_function_name(packet.interned_data, FUNC_PROCESS_REQUESTS, "ProcessRequests")
add_function_name(packet.interned_data, FUNC_HANDLE_REQUEST, "HandleRequest")
add_function_name(packet.interned_data, FUNC_MALLOC, "malloc")
FRAME_MAIN = 1
FRAME_PROCESS_REQUESTS = 2
FRAME_HANDLE_REQUEST = 3
FRAME_MALLOC = 4
add_frame(packet.interned_data, FRAME_MAIN, FUNC_MAIN, MAPPING_APP, 0x1234)
add_frame(packet.interned_data, FRAME_PROCESS_REQUESTS, FUNC_PROCESS_REQUESTS, MAPPING_APP, 0x2345)
add_frame(packet.interned_data, FRAME_HANDLE_REQUEST, FUNC_HANDLE_REQUEST, MAPPING_APP, 0x3456)
add_frame(packet.interned_data, FRAME_MALLOC, FUNC_MALLOC, MAPPING_LIBC, 0x8765)
# Define Callstacks
# Callstack 1: main -> ProcessRequests -> HandleRequest
CALLSTACK_1 = 1
add_callstack(packet.interned_data, CALLSTACK_1, [FRAME_MAIN, FRAME_PROCESS_REQUESTS, FRAME_HANDLE_REQUEST])
# Callstack 2: main -> ProcessRequests -> HandleRequest -> malloc
CALLSTACK_2 = 2
add_callstack(
packet.interned_data,
CALLSTACK_2,
[FRAME_MAIN, FRAME_PROCESS_REQUESTS, FRAME_HANDLE_REQUEST, FRAME_MALLOC],
)
# 3. Create events that reference the interned callstacks
# Event 1: References CALLSTACK_1
emit_track_event(
ts=5000,
event_type=TrackEvent.TYPE_SLICE_BEGIN,
name="HandleRequest",
callstack_iid=CALLSTACK_1,
)
emit_track_event(
ts=5300,
event_type=TrackEvent.TYPE_SLICE_END,
name=None,
callstack_iid=None,
)
# Event 2: References CALLSTACK_2
emit_track_event(
ts=5100,
event_type=TrackEvent.TYPE_SLICE_BEGIN,
name="AllocateMemory",
callstack_iid=CALLSTACK_2,
)
emit_track_event(
ts=5200,
event_type=TrackEvent.TYPE_SLICE_END,
name=None,
callstack_iid=None,
)
# Event 3: Another event with CALLSTACK_1 (reusing the interned data)
emit_track_event(
ts=6000,
event_type=TrackEvent.TYPE_SLICE_BEGIN,
name="HandleRequest",
callstack_iid=CALLSTACK_1,
)
emit_track_event(
ts=6400,
event_type=TrackEvent.TYPE_SLICE_END,
name=None,
callstack_iid=None,
)
Notes:
SEQ_INCREMENTAL_STATE_CLEARED | SEQ_NEEDS_INCREMENTAL_STATE when defining interned data (for the first time); use only
SEQ_NEEDS_INCREMENTAL_STATE when referencing it or defining more incremental data.frame_ids are ordered outermost to innermost (same as inline
callstacks).CALLSTACK_1, demonstrating the efficiency gain.After running the script, opening the generated trace in the Perfetto UI and doing an area selection will display the following output:
Correlation IDs provide a way to visually link slices that are part of the same logical operation, even when they are not causally connected. Unlike flows, which represent direct cause-and-effect relationships, correlation IDs group events that share a common context or belong to the same high-level operation.
Common use cases:
Visual benefits: The Perfetto UI can use correlation IDs to assign consistent colors to related slices or highlight the entire correlated set when one slice is hovered, making it easier to track related operations across different tracks.
Relationship to flows:
Perfetto supports three types of correlation identifiers:
correlation_id: A 64-bit unsigned integer (most efficient, recommended for
most cases)correlation_id_str: A string value (most flexible, human-readable)correlation_id_str_iid: An interned string ID (see
Interning Data for Trace Size Optimization
above for details on interning)This example demonstrates correlation IDs using integer identifiers by simulating different stages of processing for two separate requests across multiple service tracks.
Copy the following Python code into the populate_packets(builder) function in
your trace_converter_template.py script.
TRUSTED_PACKET_SEQUENCE_ID = 9010
# --- Define Track UUIDs ---
frontend_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
auth_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
database_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
cache_track_uuid = uuid.uuid4().int & ((1 << 63) - 1)
# Helper to define a TrackDescriptor
def define_custom_track(track_uuid, name):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
# 1. Define the tracks
define_custom_track(frontend_track_uuid, "Frontend Service")
define_custom_track(auth_track_uuid, "Auth Service")
define_custom_track(database_track_uuid, "Database Service")
define_custom_track(cache_track_uuid, "Cache Service")
# Helper to add slice with correlation ID
def add_correlated_slice(ts_start, ts_end, track_uuid, slice_name, correlation_id):
# Start slice
packet = builder.add_packet()
packet.timestamp = ts_start
packet.track_event.type = TrackEvent.TYPE_SLICE_BEGIN
packet.track_event.track_uuid = track_uuid
packet.track_event.name = slice_name
packet.track_event.correlation_id = correlation_id
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# End slice
packet = builder.add_packet()
packet.timestamp = ts_end
packet.track_event.type = TrackEvent.TYPE_SLICE_END
packet.track_event.track_uuid = track_uuid
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# --- Request #42: All slices with correlation_id = 42 ---
REQUEST_42_ID = 42
add_correlated_slice(1000, 1200, frontend_track_uuid, "Handle Request #42", REQUEST_42_ID)
add_correlated_slice(1100, 1400, auth_track_uuid, "Authenticate Request #42", REQUEST_42_ID)
add_correlated_slice(1350, 1600, database_track_uuid, "Query for Request #42", REQUEST_42_ID)
# --- Request #123: All slices with correlation_id = 123 ---
REQUEST_123_ID = 123
add_correlated_slice(2000, 2300, frontend_track_uuid, "Handle Request #123", REQUEST_123_ID)
add_correlated_slice(2100, 2500, database_track_uuid, "Query for Request #123", REQUEST_123_ID)
add_correlated_slice(2400, 2600, cache_track_uuid, "Cache Request #123", REQUEST_123_ID)
By default, the Perfetto UI merges tracks that share the same name. This is
often the desired behavior for grouping related asynchronous events. However,
there are scenarios where you need more explicit control. You can override this
default merging logic using the sibling_merge_behavior and sibling_merge_key
fields in the TrackDescriptor.
This allows you to:
The sibling_merge_behavior field can be set to one of the following values:
SIBLING_MERGE_BEHAVIOR_BY_TRACK_NAME (the default): Merges sibling tracks
that have the same name.SIBLING_MERGE_BEHAVIOR_NONE: Prevents the track from being merged with any
of its siblings.SIBLING_MERGE_BEHAVIOR_BY_SIBLING_MERGE_KEY: Merges sibling tracks that have
the same sibling_merge_key string.In this example, we create two tracks with the same name. By setting their
sibling_merge_behavior to SIBLING_MERGE_BEHAVIOR_NONE, we ensure they are
always displayed as distinct tracks in the UI.
TRUSTED_PACKET_SEQUENCE_ID = 9003
# --- Define Track UUIDs ---
track1_uuid = 1
track2_uuid = 2
# Helper to define a TrackDescriptor
def define_custom_track(track_uuid, name):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
desc.sibling_merge_behavior = TrackDescriptor.SIBLING_MERGE_BEHAVIOR_NONE
# 1. Define the tracks
define_custom_track(track1_uuid, "My Separate Track")
define_custom_track(track2_uuid, "My Separate Track")
# Helper to add a slice event
def add_slice_event(ts, event_type, event_track_uuid, name=None):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = event_type
packet.track_event.track_uuid = event_track_uuid
if name:
packet.track_event.name = name
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 2. Add events to the tracks
add_slice_event(ts=1000, event_type=TrackEvent.TYPE_SLICE_BEGIN, event_track_uuid=track1_uuid, name="Slice 1")
add_slice_event(ts=1100, event_type=TrackEvent.TYPE_SLICE_END, event_track_uuid=track1_uuid)
add_slice_event(ts=1200, event_type=TrackEvent.TYPE_SLICE_BEGIN, event_track_uuid=track2_uuid, name="Slice 2")
add_slice_event(ts=1300, event_type=TrackEvent.TYPE_SLICE_END, event_track_uuid=track2_uuid)
In this example, we create two tracks with different names but the same
sibling_merge_key. By setting their sibling_merge_behavior to
SIBLING_MERGE_BEHAVIOR_BY_SIBLING_MERGE_KEY, we instruct the UI to merge them
into a single visual track. The name of the merged group will be taken from one
of the tracks (usually the one with the lower UUID).
TRUSTED_PACKET_SEQUENCE_ID = 9004
# --- Define Track UUIDs ---
track1_uuid = 1
track2_uuid = 2
# Helper to define a TrackDescriptor
def define_custom_track(track_uuid, name, merge_key):
packet = builder.add_packet()
desc = packet.track_descriptor
desc.uuid = track_uuid
desc.name = name
desc.sibling_merge_behavior = TrackDescriptor.SIBLING_MERGE_BEHAVIOR_BY_SIBLING_MERGE_KEY
desc.sibling_merge_key = merge_key
# 1. Define the tracks with the same merge key
define_custom_track(track1_uuid, "HTTP GET", "conn-123")
define_custom_track(track2_uuid, "HTTP POST", "conn-123")
# Helper to add a slice event
def add_slice_event(ts, event_type, event_track_uuid, name=None):
packet = builder.add_packet()
packet.timestamp = ts
packet.track_event.type = event_type
packet.track_event.track_uuid = event_track_uuid
if name:
packet.track_event.name = name
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
# 2. Add events to the tracks
add_slice_event(ts=1000, event_type=TrackEvent.TYPE_SLICE_BEGIN, event_track_uuid=track1_uuid, name="GET /data")
add_slice_event(ts=1100, event_type=TrackEvent.TYPE_SLICE_END, event_track_uuid=track1_uuid)
add_slice_event(ts=1200, event_type=TrackEvent.TYPE_SLICE_BEGIN, event_track_uuid=track2_uuid, name="POST /submit")
add_slice_event(ts=1300, event_type=TrackEvent.TYPE_SLICE_END, event_track_uuid=track2_uuid)
All the examples so far have used the TraceProtoBuilder, which builds the
entire trace in memory before writing it to a file. This is simple and effective
for moderately sized traces, but can lead to high memory consumption if you are
generating traces with millions of events.
For these scenarios, the StreamingTraceProtoBuilder is the recommended
solution. It writes each TracePacket to a file as it's created, keeping memory
usage minimal regardless of the trace size.
The API for the streaming builder is slightly different:
StreamingTraceProtoBuilder with a
file-like object opened in binary write mode.builder.add_packet(), you call
builder.create_packet() to get a new, empty TracePacket.builder.write_packet(packet) to serialize and write it to the file.Here is a complete, standalone Python script that demonstrates how to use the
StreamingTraceProtoBuilder. It is based on the "Creating Basic Timeline
Slices" example from the
Getting Started guide.
You can save this code as a new file (e.g., streaming_converter.py) and run
it.
#!/usr/bin/env python3
import uuid
from perfetto.trace_builder.proto_builder import StreamingTraceProtoBuilder
from perfetto.protos.perfetto.trace.perfetto_trace_pb2 import TrackEvent
def populate_packets(builder: StreamingTraceProtoBuilder):
"""
This function defines and writes TracePackets to the stream.
Args:
builder: An instance of StreamingTraceProtoBuilder.
"""
# Define a unique ID for this sequence of packets
TRUSTED_PACKET_SEQUENCE_ID = 1001
# Define a unique UUID for your custom track
CUSTOM_TRACK_UUID = 12345678
# 1. Define the Custom Track
packet = builder.create_packet()
packet.track_descriptor.uuid = CUSTOM_TRACK_UUID
packet.track_descriptor.name = "My Custom Data Timeline"
builder.write_packet(packet)
# 2. Emit events for this custom track
# Example Event 1: "Task A"
packet = builder.create_packet()
packet.timestamp = 1000
packet.track_event.type = TrackEvent.TYPE_SLICE_BEGIN
packet.track_event.track_uuid = CUSTOM_TRACK_UUID
packet.track_event.name = "Task A"
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
builder.write_packet(packet)
packet = builder.create_packet()
packet.timestamp = 1500
packet.track_event.type = TrackEvent.TYPE_SLICE_END
packet.track_event.track_uuid = CUSTOM_TRACK_UUID
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
builder.write_packet(packet)
# Example Event 2: "Task B"
packet = builder.create_packet()
packet.timestamp = 1600
packet.track_event.type = TrackEvent.TYPE_SLICE_BEGIN
packet.track_event.track_uuid = CUSTOM_TRACK_UUID
packet.track_event.name = "Task B"
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
builder.write_packet(packet)
packet = builder.create_packet()
packet.timestamp = 1800
packet.track_event.type = TrackEvent.TYPE_SLICE_END
packet.track_event.track_uuid = CUSTOM_TRACK_UUID
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
builder.write_packet(packet)
# Example Event 3: An instantaneous event
packet = builder.create_packet()
packet.timestamp = 1900
packet.track_event.type = TrackEvent.TYPE_INSTANT
packet.track_event.track_uuid = CUSTOM_TRACK_UUID
packet.track_event.name = "Milestone Y"
packet.trusted_packet_sequence_id = TRUSTED_PACKET_SEQUENCE_ID
builder.write_packet(packet)
def main():
"""
Initializes the StreamingTraceProtoBuilder and calls populate_packets
to write the trace to a file.
"""
output_filename = "my_streamed_trace.pftrace"
with open(output_filename, 'wb') as f:
builder = StreamingTraceProtoBuilder(f)
populate_packets(builder)
print(f"Trace written to {output_filename}")
print(f"Open with [https://ui.perfetto.dev](https://ui.perfetto.dev).")
if __name__ == "__main__":
main()