This page provides a birds-eye view of performance analysis using Perfetto. The aim is for to orient even people who have no idea what “tracing” is. You should walk away from this page with a good understanding of the available capabilities in Perfetto and how they can be used to improve performance of a system.
Performance analysis is concerned with making software run better. The definition of better varies widely and depends on the situation. Examples include:
Much of the difficulty in improving performance comes from identifying the root cause of performance issues. Modern software systems are complicated, having a lot of components and a web of cross-interactions. Techniques which help engineers understand the execution of a system and pinpoint issues that are critical.
Tracing and profiling are two such widely-used techniques for performance analysis. Perfetto is an open-source suite of tools, combining tracing and profiling to give users powerful insights into their system.
Tracing involves collecting highly detailed data about the execution of a system. A single continuous session of recording is called a trace file or trace for short.
Traces contain enough detail to fully reconstruct the timeline of events. They often include low-level kernel events like scheduler context switches, thread wakeups, syscalls, etc. With the “right” trace, reproduction of a performance bug is not needed as the trace provides all necessary context.
Application code is also instrumented in areas of the program which are considered to be important. This instrumentation keeps track of what the program was doing over time (e.g. which functions were being run, or how long each call took) and context about the execution (e.g. what were the parameters to a function call, or why was a function run).
The level of detail in traces makes it impractical to read traces directly like a log file in all but the simplest cases. Instead, a combination of trace analysis libraries and trace viewers are used. Trace analysis libraries provide a way for users to extract and summarize trace events in a programmatic manner. Trace viewers visualize the events in a trace on a timeline which give users a graphical view of what their system was doing over time.
A good intuition is that logging is to functional testing what tracing is to performance analysis. Tracing is, in a sense, “structured” logging: instead of having arbitrary strings emitted from parts of the system, tracing reflects the detailed state of a system in a structured way to allow reconstruction of the timeline of events.
Moreover, tracing frameworks (like Perfetto) place heavy emphasis on having minimal overhead. This is essential so that the framework does not significantly disrupt whatever is being measured: modern frameworks are fast enough that they can measure execution at the nanosecond level without significantly impacting the execution speed of the program.
Small aside: theoretically, tracing frameworks are powerful enough to act as a logging system as well. However, the utilization of each in practice is different enough that the two tend to be separate.
Metrics are numerical values which track the performance of a system over time. Usually metrics map to high-level concepts. Examples of metrics include: CPU usage, memory usage, network bandwidth, etc. Metrics are collected directly from the app or operating system while the program is running.
After glimpsing the power of tracing, a natural question arises: why bother with high level metrics at all? Why not instead just use use tracing and compute metrics on resulting traces? In some settings, this may indeed be the right approach. In local and lab situations using trace-based metrics, where metrics are computed from traces instead of collecting them directly, is a powerful approach. If a metric regresses, it's easy to open the trace to root cause why that happened.
However, trace-based metrics are not a universal solution. When running in production, the heavyweight nature of traces can make it impractical to collect them 24/7. Computing a metric with a trace can take megabytes of data vs bytes for direct metric collection.
Using metrics is the right choice when you want to understand the performance of a system over time but do not want to or can not pay the cost of collecting traces. In these situations, traces should be used as a root-causing tool. When your metrics show there is a problem, targeted tracing can be rolled out to understand why the regression may have happened.
Profiling involves sampling some usage of a resource by a program. A single continuous session of recording is known as a profile.
Each sample collects the function callstack (i.e. the line of code along with all calling functions). Generally this information is aggregated across the profile. For each seen callstack, the aggregation gives the percentage of usage of the resource by that callstack. By far the most common types of profiling are memory profiling and CPU profiling.
Memory profiling is used to understand which parts of a program are allocating memory on the heap. The profiler generally hooks into malloc
(and free
) calls of a native (C/C++/Rust/etc.) program to sample the callstacks calling malloc
. Information about how many bytes were allocated is also retained. CPU profiling is used for understanding where the program is spending CPU time. The profiler captures the callstack running on a CPU over time. Generally this is done periodically (e.g. every 50ms), but can be also be done when certain events happen in the operating system.
There are two main questions for comparing profiling and tracing:
Traces cannot feasibly capture execution of extreme high frequency events e.g. every function call. Profiling tools fill this niche: by sampling, they can significantly cut down on how much information they store. The statistical nature of profilers are rarely a problem; the sampling algorithms for profilers are specifically designed to capture data which is highly representative of the real resource use.
Aside: a handful of very specialized tracing tools exist which can capture every function call (e.g. magic-trace) but they output gigabytes of data every second which make them impractical for anything beyond investigating tiny snippets of code. They also generally have higher overhead than general purpose tracing tools.
While profilers give callstacks where resources are being used, they lack information about why that happened. For example, why was malloc being called by function foo() so many times? All they say is foo() allocated X bytes over Y calls to malloc
. Traces are excellent at providing this exact context: application instrumentation and low-level kernel events together provide deep insight into why code was run in the first place.
NOTE: Perfetto supports collecting, analyzing and visualizing both profiles and traces at the same time so you can have the best of both worlds!
Perfetto is a suite of tools for performance analysis of software. Its purpose is to empower engineers to understand where resources are being used by their systems. It helps identify the changes they can make to improve performance and verify the impact of those changes.
NOTE: In Perfetto, since profiles and traces can be collected simultaneously, we call everything a “trace” even if it may contain (only) profiling data inside.
Perfetto is highly configurable when it comes to recording traces. There are literally hundreds of knobs which can be tweaked to control what data is collected, how it should be collected, how much information a trace should contain etc.
Record traces on Linux quickstart is a good place to start if you're unfamiliar with Perfetto. For Android developers, Record traces on Android quickstart will be more applicable. The trace configuration page is also useful to consult as a reference.
The following sub-sections give an overview of various points worth considering when recording Perfetto traces.
Perfetto integrates closely with the Linux kernel's ftrace tracing system to record kernel events (e.g. scheduling, syscalls, wakeups). The scheduling, syscall and CPU frequency data source pages give examples of configuring ftrace collection.
Natively supported ftrace events can be found in the fields of this proto message. Perfetto also supports collecting ftrace events it does not natively understand (i.e. it does not have a protobuf message for) as a “generic” events. These events are encoded as key-value pairs, similar to a JSON dictionary.
It is strongly discouraged to rely on generic events for production use cases: the inefficient encoding causes trace size bloat and the trace processor cannot parse them meaningfully. Instead, support should be added for parsing important ftrace events to Perfetto: here is a simple set of steps to follow which are found.
Perfetto has a C++ SDK which can be used to instrument programs to emit tracing events. The SDK is designed to be very low-overhead and is distributed in an “amalgamated” form of a one .cc
and one .h
file, making it easy to integrate in any build system.
A C SDK is under active development and should be available for general usage by Q2 2023. See this doc for details (note viewing this doc requires being a member of this group)
A Java/Kotlin SDK for Android (as a JetPack library). This is under development but there is no set timescale for when an official release will happen.
NOTE: This section is only relevant for Android platform developers or Android app developers with tracing experience. Other readers can safely skip this section.
Perfetto has significant advantages over atrace. Some of the biggest advantages include:
Unfortunately, there are also some downsides:
For now, the recommendation from the Perfetto team is to continue utilizing atrace for most usecases: if you think you have a usecase which would benefit from the SDK, please reach out to the team directly. By mid-2023, significant progress should be made addressing the limitations of the current SDK allowing more widespread adoption of the SDK.