Heap profiler

NOTE: heapprofd requires Android 10 or higher

Heapprofd is a tool that tracks heap allocations & deallocations of an Android process within a given time period. The resulting profile can be used to attribute memory usage to particular call-stacks, supporting a mix of both native and java code. The tool can be used by Android platform and app developers to investigate memory issues.

By default, the tool records native allocations and deallocations done with malloc/free (or new/delete). It can be configured to record java heap memory allocations instead: see Java heap sampling below.

On debug Android builds, you can profile all apps and most system services. On “user” builds, you can only use it on apps with the debuggable or profileable manifest flag.

Quickstart

See the Memory Guide for getting started with heapprofd.

UI

Dumps from heapprofd are shown as flamegraphs in the UI after clicking on the diamond. Each diamond corresponds to a snapshot of the allocations and callstacks collected at that point in time.

heapprofd snapshots in the UI tracks

heapprofd flamegraph

SQL

Information about callstacks is written to the following tables:

The allocations themselves are written to heap_profile_allocation.

Offline symbolization data is stored in stack_profile_symbol.

See Example Queries for example SQL queries.

Recording

Heapprofd can be configured and started in three ways.

Manual configuration

This requires manually setting the HeapprofdConfig section of the trace config. The only benefit of doing so is that in this way heap profiling can be enabled alongside any other tracing data sources.

Using the tools/heap_profile script (recommended)

You can use the tools/heap_profile script. If you are having trouble make sure you are using the latest version.

You can target processes either by name (-n com.example.myapp) or by PID (-p 1234). In the first case, the heap profile will be initiated on both on already-running processes that match the package name and new processes launched after the profiling session is started. For the full arguments list see the heap_profile cmdline reference page.

You can use the Perfetto UI to visualize heap dumps. Upload the raw-trace file in your output directory. You will see all heap dumps as diamonds on the timeline, click any of them to get a flamegraph.

Alternatively Speedscope can be used to visualize the gzipped protos, but will only show the “Unreleased malloc size” view.

Using the Recording page of Perfetto UI

You can also use the Perfetto UI to record heapprofd profiles. Tick “Heap profiling” in the trace configuration, enter the processes you want to target, click “Add Device” to pair your phone, and record profiles straight from your browser. This is also possible on Windows.

Viewing the data

Profile Diamond

The resulting profile proto contains four views on the data, for each diamond.

  • Unreleased malloc size: how many bytes were allocated but not freed at this callstack, from the moment the recording was started until the timestamp of the diamond.
  • Total malloc size: how many bytes were allocated (including ones freed at the moment of the dump) at this callstack, from the moment the recording was started until the timestamp of the diamond.
  • Unreleased malloc count: how many allocations without matching frees were done at this callstack, from the moment the recording was started until the timestamp of the diamond.
  • Total malloc count: how many allocations (including ones with matching frees) were done at this callstack, from the moment the recording was started started until the timestamp of the diamond.

(Googlers: You can also open the gzipped protos using http://pprof/)

TIP: you might want to put libart.so as a “Hide regex” when profiling apps.

TIP: Click Left Heavy on the top left for a good visualization.

Continuous dumps

By default, the heap profiler captures all the allocations from the beginning of the recording and stores a single snapshot, shown as a single diamond in the UI, which summarizes all allocations/frees.

It is possible to configure the heap profiler to periodically (not just at the end of the trace) store snapshots (continuous dumps), for example every 5000ms

  • By setting “Continuous dumps interval” in the UI to 5000.
  • By adding
    continuous_dump_config {
      dump_interval_ms: 5000
    }
    
    in the HeapprofdConfig.
  • By adding -c 5000 to the invocation of tools/heap_profile.

Continuous dump flamegraph

The resulting visualization shows multiple diamonds. Clicking on each diamond shows a summary of the allocations/frees from the beginning of the trace until that point (i.e. the summary is cumulative).

Sampling interval

Heapprofd samples heap allocations by hooking calls to malloc/free and C++'s operator new/delete. Given a sampling interval of n bytes, one allocation is sampled, on average, every n bytes allocated. This allows to reduce the performance impact on the target process. The default sampling rate is 4096 bytes.

The easiest way to reason about this is to imagine the memory allocations as a stream of one byte allocations. From this stream, every byte has a 1/n probability of being selected as a sample, and the corresponding callstack gets attributed the complete n bytes. For more accuracy, allocations larger than the sampling interval bypass the sampling logic and are recorded with their true size. See the heapprofd Sampling document for details.

Startup profiling

When specifying a target process name (as opposite to the PID), new processes matching that name are profiled from their startup. The resulting profile will contain all allocations done between the start of the process and the end of the profiling session.

On Android, Java apps are usually not exec()-ed from scratch, but fork()-ed from the zygote, which then specializes into the desired app. If the app's name matches a name specified in the profiling session, profiling will be enabled as part of the zygote specialization. The resulting profile contains all allocations done between that point in zygote specialization and the end of the profiling session. Some allocations done early in the specialization process are not accounted for.

At the trace proto level, the resulting ProfilePacket will have the from_startup field set to true in the corresponding ProcessHeapSamples message. This is not surfaced in the converted pprof compatible proto.

Runtime profiling

When a profiling session is started, all matching processes (by name or PID) are enumerated and are signalled to request profiling. Profiling isn't actually enabled until a few hundred milliseconds after the next allocation that is done by the application. If the application is idle when profiling is requested, and then does a burst of allocations, these may be missed.

The resulting profile will contain all allocations done between when profiling is enabled, and the end of the profiling session.

The resulting ProfilePacket will have from_startup set to false in the corresponding ProcessHeapSamples message. This does not get surfaced in the converted pprof compatible proto.

Concurrent profiling sessions

If multiple sessions name the same target process (either by name or PID), only the first relevant session will profile the process. The other sessions will report that the process had already been profiled when converting to the pprof compatible proto.

If you see this message but do not expect any other sessions, run

adb shell killall perfetto

to stop any concurrent sessions that may be running.

The resulting ProfilePacket will have rejected_concurrent set to true in otherwise empty corresponding ProcessHeapSamples message. This does not get surfaced in the converted pprof compatible proto.

Target processes

Depending on the build of Android that heapprofd is run on, some processes are not be eligible to be profiled.

On user (i.e. production, non-rootable) builds, only Java applications with either the profileable or the debuggable manifest flag set can be profiled. Profiling requests for non-profileable/debuggable processes will result in an empty profile.

On userdebug builds, all processes except for a small set of critical services can be profiled (to find the set of disallowed targets, look for never_profile_heap in heapprofd.te. This restriction can be lifted by disabling SELinux by running adb shell su root setenforce 0 or by passing --disable-selinux to the heap_profile script.

userdebug setenforce 0userdebuguser
critical native serviceYNN
native serviceYYN
appYYN
profileable appYYY
debuggable appYYY

To mark an app as profileable, put <profileable android:shell="true"/> into the <application> section of the app manifest.

<manifest ...>
    <application>
        <profileable android:shell="true"/>
        ...
    </application>
</manifest>

Java heap sampling

NOTE: Java heap sampling is available on Android 12 or higher

NOTE: Java heap sampling is not to be confused with Java heap dumps

Heapprofd can be configured to track Java allocations instead of native ones.

Unlike java heap dumps (which show the retention graph of a snapshot of the live objects) but like native heap profiles, java heap samples show callstacks of allocations over time of the entire profile.

Java heap samples only show callstacks of when objects are created, not when they're deleted or garbage collected.

javaheapsamples

The resulting profile proto contains two views on the data:

  • Total allocation size: how many bytes were allocated at this callstack over time of the profile until this point. The bytes might have been freed or not, the tool does not keep track of that.
  • Total allocation count: how many object were allocated at this callstack over time of the profile until this point. The objects might have been freed or not, the tool does not keep track of that.

Java heap samples are useful to understand memory churn showing the call stack of which parts of the code large allocations are attributed to as well as the allocation type from the ART runtime.

DEDUPED frames

If the name of a Java method includes [DEDUPED], this means that multiple methods share the same code. ART only stores the name of a single one in its metadata, which is displayed here. This is not necessarily the one that was called.

Triggering heap snapshots on demand

Heap snapshot are recorded into the trace either at regular time intervals, if using the continuous_dump_config field, or at the end of the session.

You can also trigger a snapshot of all currently profiled processes by running adb shell killall -USR1 heapprofd. This can be useful in lab tests for recording the current memory usage of the target in a specific state.

This dump will show up in addition to the dump at the end of the profile that is always produced. You can create multiple of these dumps, and they will be enumerated in the output directory.

Symbolization

Set up llvm-symbolizer

You only need to do this once.

To use symbolization, your system must have llvm-symbolizer installed and accessible from $PATH as llvm-symbolizer. On Debian, you can install it using sudo apt install llvm.

Symbolize your profile

If the profiled binary or libraries do not have symbol names, you can symbolize profiles offline. Even if they do, you might want to symbolize in order to get inlined function and line number information. All tools (traceconv, trace_processor_shell, the heap_profile script) support specifying the PERFETTO_BINARY_PATH as an environment variable.

PERFETTO_BINARY_PATH=somedir tools/heap_profile --name ${NAME}

You can persist symbols for a trace by running PERFETTO_BINARY_PATH=somedir tools/traceconv symbolize raw-trace > symbols. You can then concatenate the symbols to the trace ( cat raw-trace symbols > symbolized-trace) and the symbols will part of symbolized-trace. The tools/heap_profile script will also generate this file in your output directory, if PERFETTO_BINARY_PATH is used.

The symbol file is the first with matching Build ID in the following order:

  1. absolute path of library file relative to binary path.
  2. absolute path of library file relative to binary path, but with base.apk! removed from filename.
  3. basename of library file relative to binary path.
  4. basename of library file relative to binary path, but with base.apk! removed from filename.
  5. in the subdirectory .build-id: the first two hex digits of the build-id as subdirectory, then the rest of the hex digits, with “.debug” appended. See https://fedoraproject.org/wiki/RolandMcGrath/BuildID#Find_files_by_build_ID

For example, “/system/lib/base.apk!foo.so” with build id abcd1234, is looked for at:

  1. $PERFETTO_BINARY_PATH/system/lib/base.apk!foo.so
  2. $PERFETTO_BINARY_PATH/system/lib/foo.so
  3. $PERFETTO_BINARY_PATH/base.apk!foo.so
  4. $PERFETTO_BINARY_PATH/foo.so
  5. $PERFETTO_BINARY_PATH/.build-id/ab/cd1234.debug

Alternatively, you can set the PERFETTO_SYMBOLIZER_MODE environment variable to index, and the symbolizer will recursively search the given directory for an ELF file with the given build id. This way, you will not have to worry about correct filenames.

Deobfuscation

If your profile contains obfuscated Java methods (like fsd.a), you can provide a deobfuscation map to turn them back into human readable. To do so, use the PERFETTO_PROGUARD_MAP environment variable, using the format packagename=map_filename[:packagename=map_filename...], e.g. PERFETTO_PROGUARD_MAP=com.example.pkg1=foo.txt:com.example.pkg2=bar.txt. All tools (traceconv, trace_processor_shell, the heap_profile script) support specifying the PERFETTO_PROGUARD_MAP as an environment variable.

You can get a deobfuscation map for your trace using tools/traceconv deobfuscate. Then concatenate the resulting file to your trace to get a deobfuscated version of it (the input trace should be in the perfetto format, otherwise concatenation will not produce a reasonable output).

PERFETTO_PROGUARD_MAP=com.example.pkg=proguard_map.txt tools/traceconv deobfuscate ${TRACE} > deobfuscation_map
cat ${TRACE} deobfuscation_map > deobfuscated_trace

deobfuscated_trace can be viewed in the Perfetto UI.

Troubleshooting

Buffer overrun

If the rate of allocations is too high for heapprofd to keep up, the profiling session will end early due to a buffer overrun. If the buffer overrun is caused by a transient spike in allocations, increasing the shared memory buffer size (passing --shmem-size to tools/heap_profile) can resolve the issue. Otherwise the sampling interval can be increased (at the expense of lower accuracy in the resulting profile) by passing --interval=16000 or higher.

Profile is empty

Check whether your target process is eligible to be profiled by consulting Target processes above.

Also check the Known Issues.

Implausible callstacks

If you see a callstack that seems to impossible from looking at the code, make sure no DEDUPED frames are involved.

Also, if your code is linked using Identical Code Folding (ICF), i.e. passing -Wl,--icf=... to the linker, most trivial functions, often constructors and destructors, can be aliased to binary-equivalent operators of completely unrelated classes.

Symbolization: Could not find library

When symbolizing a profile, you might come across messages like this:

Could not find /data/app/invalid.app-wFgo3GRaod02wSvPZQ==/lib/arm64/somelib.so
(Build ID: 44b7138abd5957b8d0a56ce86216d478).

Check whether your library (in this example somelib.so) exists in PERFETTO_BINARY_PATH. Then compare the Build ID to the one in your symbol file, which you can get by running readelf -n /path/in/binary/path/somelib.so. If it does not match, the symbolized file has a different version than the one on device, and cannot be used for symbolization. If it does, try moving somelib.so to the root of PERFETTO_BINARY_PATH and try again.

Only one frame shown

If you only see a single frame for functions in a specific library, make sure that the library has unwind information. We need one of

  • .gnu_debugdata
  • .eh_frame (+ preferably .eh_frame_hdr)
  • .debug_frame.

Frame-pointer unwinding is not supported.

To check if an ELF file has any of those, run

$ readelf -S file.so | grep "gnu_debugdata\|eh_frame\|debug_frame"
  [12] .eh_frame_hdr     PROGBITS         000000000000c2b0  0000c2b0
  [13] .eh_frame         PROGBITS         0000000000011000  00011000
  [24] .gnu_debugdata    PROGBITS         0000000000000000  000f7292

If this does not show one or more of the sections, change your build system to not strip them.

(non-Android) Linux support

NOTE: Do not use this for production purposes.

You can use a standalone library to profile memory allocations on Linux. First build Perfetto. You only need to do this once.

tools/setup_all_configs.py
ninja -C out/linux_clang_release

Then, run traced

out/linux_clang_release/traced

Start the profile (e.g. targeting trace_processor_shell)

tools/heap_profile -n trace_processor_shell --print-config  | \
out/linux_clang_release/perfetto \
  -c - --txt \
  -o ~/heapprofd-trace

Finally, run your target (e.g. trace_processor_shell) with LD_PRELOAD

LD_PRELOAD=out/linux_clang_release/libheapprofd_glibc_preload.so out/linux_clang_release/trace_processor_shell <trace>

Then, Ctrl-C the Perfetto invocation and upload ~/heapprofd-trace to the Perfetto UI.

NOTE: by default, heapprofd lazily initalizes to avoid blocking your program's main thread. However, if your program makes memory allocations on startup, these can be missed. To avoid this from happening, set the enironment variable PERFETTO_HEAPPROFD_BLOCKING_INIT=1; on the first malloc, your program will be blocked until heapprofd initializes fully but means every allocation will be correctly tracked.

Known Issues

Android 13

  • Unwinding java frames might not work properly, depending on the ART module version in use. The UI reports a single “unknown” frame at the top of the stack in this case. The problem is fixed in Android 13 QPR1.

Android 12

  • Unwinding java frames might not work properly, depending on the ART module version in use. The UI reports a single “unknown” frame at the top of the stack in this case.

Android 11

  • 32-bit programs cannot be targeted on 64-bit devices.
  • Setting sampling_interval_bytes to 0 crashes the target process. This is an invalid config that should be rejected instead.
  • For startup profiles, some frame names might be missing. This will be resolved in Android 12.
  • Failed to send control socket byte. is displayed in logcat at the end of every profile. This is benign.
  • The object count may be incorrect in dump_at_max profiles.
  • Choosing a low shared memory buffer size and block_client mode might lock up the target process.

Android 10

  • Function names in libraries with load bias might be incorrect. Use offline symbolization to resolve this issue.
  • For startup profiles, some frame names might be missing. This will be resolved in Android 12.
  • 32-bit programs cannot be targeted on 64-bit devices.
  • x86 / x86_64 platforms are not supported. This includes the Android Cuttlefish. emulator.
  • On ARM32, the bottom-most frame is always ERROR 2. This is harmless and the callstacks are still complete.
  • If heapprofd is run standalone (by running heapprofd in a root shell, rather than through init), /dev/socket/heapprofd get assigned an incorrect SELinux domain. You will not be able to profile any processes unless you disable SELinux enforcement. Run restorecon /dev/socket/heapprofd in a root shell to resolve.
  • Using vfork(2) or clone(2) with CLONE_VM and allocating / freeing memory in the child process will prematurely end the profile. java.lang.Runtime.exec does this, calling it will prematurely end the profile. Note that this is in violation of the POSIX standard.
  • Setting sampling_interval_bytes to 0 crashes the target process. This is an invalid config that should be rejected instead.
  • Failed to send control socket byte. is displayed in logcat at the end of every profile. This is benign.
  • The object count may be incorrect in dump_at_max profiles.
  • Choosing a low shared memory buffer size and block_client mode might lock up the target process.

Heapprofd vs malloc_info() vs RSS

When using heapprofd and interpreting results, it is important to know the precise meaning of the different memory metrics that can be obtained from the operating system.

heapprofd gives you the number of bytes the target program requested from the default C/C++ allocator. If you are profiling a Java app from startup, allocations that happen early in the application's initialization will not be visible to heapprofd. Native services that do not fork from the Zygote are not affected by this.

malloc_info is a libc function that gives you information about the allocator. This can be triggered on userdebug builds by using am dumpheap -m <PID> /data/local/tmp/heap.txt. This will in general be more than the memory seen by heapprofd, depending on the allocator not all memory is immediately freed. In particular, jemalloc retains some freed memory in thread caches.

Heap RSS is the amount of memory requested from the operating system by the allocator. This is larger than the previous two numbers because memory can only be obtained in page size chunks, and fragmentation causes some of that memory to be wasted. This can be obtained by running adb shell dumpsys meminfo <PID> and looking at the “Private Dirty” column. RSS can also end up being smaller than the other two if the device kernel uses memory compression (ZRAM, enabled by default on recent versions of android) and the memory of the process get swapped out onto ZRAM.

heapprofdmalloc_infoRSS
from native startupxxx
after zygote initxxx
before zygote initxx
thread cachesxx
fragmentationx

If you observe high RSS or malloc_info metrics but heapprofd does not match, you might be hitting some pathological fragmentation problem in the allocator.

Convert to pprof

You can use traceconv to convert the heap dumps in a trace into the pprof format. These can then be viewed using the pprof CLI or a UI (e.g. Speedscope, or Google-internal pprof/).

tools/traceconv profile /tmp/profile

This will create a directory in /tmp/ containing the heap dumps. Run:

gzip /tmp/heap_profile-XXXXXX/*.pb

to get gzipped protos, which tools handling pprof profile protos expect.

Example SQL Queries

We can get the callstacks that allocated using an SQL Query in the Trace Processor. For each frame, we get one row for the number of allocated bytes, where count and size is positive, and, if any of them were already freed, another line with negative count and size. The sum of those gets us the Unreleased malloc size view.

select a.callsite_id, a.ts, a.upid, f.name, f.rel_pc, m.build_id, m.name as mapping_name,
        sum(a.size) as space_size, sum(a.count) as space_count
      from heap_profile_allocation a join
           stack_profile_callsite c ON (a.callsite_id = c.id) join
           stack_profile_frame f ON (c.frame_id = f.id) join
           stack_profile_mapping m ON (f.mapping = m.id)
      group by 1, 2, 3, 4, 5, 6, 7 order by space_size desc;
callsite_idtsupidnamerel_pcbuild_idmapping_namespace_sizespace_count
666051malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so1064964
19251malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so266241
142151malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so266241
153751malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so266241
884351malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so264241
861851malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so245764
375051malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so122881
282051malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so81922
378851malloc2447168126fd../apex/com.android.runtime/lib64/bionic/libc.so81922

We can see all the functions are “malloc” and “realloc”, which is not terribly informative. Usually we are interested in the cumulative bytes allocated in a function (otherwise, we will always only see malloc / realloc). Chasing the parent_id of a callsite (not shown in this table) recursively is very hard in SQL.

There is an experimental table that surfaces this information. The API is subject to change.

select
  name,
  map_name,
  cumulative_size
from experimental_flamegraph(
  -- The type of the profile from which the flamegraph is being generated.
  -- Always 'native' for native heap profiles.
  'native',
  -- The timestamp of the heap profile.
  8300973884377,
  -- Timestamp constraints: not relevant and always null for native heap
  -- profiles.
  NULL,
  -- The upid of the heap profile.
  1,
  -- The upid group: not relevant and always null for native heap profiles.
  NULL,
  -- A regex for focusing on a particular node in the heapgraph: for advanced
  -- use only.
  NULL
)
order by abs(cumulative_size) desc;
namemap_namecumulative_size
__start_thread/apex/com.android.runtime/lib64/bionic/libc.so392608
_ZL15__pthread_startPv/apex/com.android.runtime/lib64/bionic/libc.so392608
_ZN13thread_data_t10trampolineEPKS/system/lib64/libutils.so199496
_ZN7android14AndroidRuntime15javaThreadShellEPv/system/lib64/libandroid_runtime.so199496
_ZN7android6Thread11_threadLoopEPv/system/lib64/libutils.so199496
_ZN3art6Thread14CreateCallbackEPv/apex/com.android.art/lib64/libart.so193112
_ZN3art35InvokeVirtualOrInterface.../apex/com.android.art/lib64/libart.so193112
_ZN3art9ArtMethod6InvokeEPNS_6ThreadEPjjPNS_6JValueEPKc/apex/com.android.art/lib64/libart.so193112
art_quick_invoke_stub/apex/com.android.art/lib64/libart.so193112