This project is a low overhead sampling profiler for Java that does not suffer from Safepoint bias problem. It features HotSpot-specific APIs to collect stack traces and to track memory allocations. The profiler works with OpenJDK, Oracle JDK and other Java runtimes based on the HotSpot JVM.
async-profiler can trace the following kinds of events:
- CPU cycles
- Hardware and Software performance counters like cache misses, branch misses, page faults, context switches etc.
- Allocations in Java Heap
- Contented lock attempts, including both Java object monitors and ReentrantLocks
See our Wiki or 3 hours playlist to learn about all features.
Current release (2.8.3):
- Linux x64 (glibc): async-profiler-2.8.3-linux-x64.tar.gz
- Linux x64 (musl): async-profiler-2.8.3-linux-musl-x64.tar.gz
- Linux arm64: async-profiler-2.8.3-linux-arm64.tar.gz
- macOS x64/arm64: async-profiler-2.8.3-macos.zip
- Converters between profile formats: converter.jar
(JFR to Flame Graph, JFR to FlameScope, collapsed stacks to Flame Graph)
Note: async-profiler also comes bundled with IntelliJ IDEA Ultimate 2018.3 and later. For more information refer to IntelliJ IDEA documentation.
- Linux / x64 / x86 / arm64 / arm32 / ppc64le
- macOS / x64 / arm64
- Windows / x64 - IntelliJ IDEA 2021.2 and later
In this mode profiler collects stack trace samples that include Java methods, native calls, JVM code and kernel functions.
The general approach is receiving call stacks generated by perf_events
and matching them up with call stacks generated by AsyncGetCallTrace
,
in order to produce an accurate profile of both Java and native code.
Additionally, async-profiler provides a workaround to recover stack traces
in some corner cases
where AsyncGetCallTrace
fails.
This approach has the following advantages compared to using perf_events
directly with a Java agent that translates addresses to Java method names:
-
Works on older Java versions because it doesn't require
-XX:+PreserveFramePointer
, which is only available in JDK 8u60 and later. -
Does not introduce the performance overhead from
-XX:+PreserveFramePointer
, which can in rare cases be as high as 10%. -
Does not require generating a map file to map Java code addresses to method names.
-
Works with interpreter frames.
-
Does not require writing out a perf.data file for further processing in user space scripts.
If you wish to resolve frames within libjvm
, the debug symbols are required.
Instead of detecting CPU-consuming code, the profiler can be configured to collect call sites where the largest amount of heap memory is allocated.
async-profiler does not use intrusive techniques like bytecode instrumentation or expensive DTrace probes which have significant performance impact. It also does not affect Escape Analysis or prevent from JIT optimizations like allocation elimination. Only actual heap allocations are measured.
The profiler features TLAB-driven sampling. It relies on HotSpot-specific callbacks to receive two kinds of notifications:
- when an object is allocated in a newly created TLAB (aqua frames in a Flame Graph);
- when an object is allocated on a slow path outside TLAB (brown frames).
This means not each allocation is counted, but only allocations every N kB, where N is the average size of TLAB. This makes heap sampling very cheap and suitable for production. On the other hand, the collected data may be incomplete, though in practice it will often reflect the top allocation sources.
Sampling interval can be adjusted with --alloc
option.
For example, --alloc 500k
will take one sample after 500 KB of allocated
space on average. However, intervals less than TLAB size will not take effect.
The minimum supported JDK version is 7u40 where the TLAB callbacks appeared.
The allocation profiler requires HotSpot debug symbols. Oracle JDK already has them
embedded in libjvm.so
, but in OpenJDK builds they are typically shipped
in a separate package. For example, to install OpenJDK debug symbols on
Debian / Ubuntu, run:
# apt install openjdk-8-dbg
or for OpenJDK 11:
# apt install openjdk-11-dbg
On CentOS, RHEL and some other RPM-based distributions, this could be done with debuginfo-install utility:
# debuginfo-install java-1.8.0-openjdk
On Gentoo the icedtea
OpenJDK package can be built with the per-package setting
FEATURES="nostrip"
to retain symbols.
The gdb
tool can be used to verify if the debug symbols are properly installed for the libjvm
library.
For example on Linux:
$ gdb $JAVA_HOME/lib/server/libjvm.so -ex 'info address UseG1GC'
This command's output will either contain Symbol "UseG1GC" is at 0xxxxx
or No symbol "UseG1GC" in current context
.
-e wall
option tells async-profiler to sample all threads equally every given
period of time regardless of thread status: Running, Sleeping or Blocked.
For instance, this can be helpful when profiling application start-up time.
Wall-clock profiler is most useful in per-thread mode: -t
.
Example: ./profiler.sh -e wall -t -i 5ms -f result.html 8983
-e ClassName.methodName
option instruments the given Java method
in order to record all invocations of this method with the stack traces.
Example: -e java.util.Properties.getProperty
will profile all places
where getProperty
method is called from.
Only non-native Java methods are supported. To profile a native method,
use hardware breakpoint event instead, e.g. -e Java_java_lang_Throwable_fillInStackTrace
Be aware that if you attach async-profiler at runtime, the first instrumentation of a non-native Java method may cause the deoptimization of all compiled methods. The subsequent instrumentation flushes only the dependent code.
The massive CodeCache flush doesn't occur if attaching async-profiler as an agent.
Here are some useful native methods that you may want to profile:
G1CollectedHeap::humongous_obj_allocate
- trace the humongous allocation of the G1 GC,JVM_StartThread
- trace the new thread creation,Java_java_lang_ClassLoader_defineClass1
- trace class loading.
Make sure the JAVA_HOME
environment variable points to your JDK installation,
and then run make
. GCC is required. After building, the profiler agent binary
will be in the build
subdirectory. Additionally, a small application jattach
that can load the agent into the target process will also be compiled to the
build
subdirectory.
As of Linux 4.6, capturing kernel call stacks using perf_events
from a non-root
process requires setting two runtime variables. You can set them using
sysctl or as follows:
# sysctl kernel.perf_event_paranoid=1
# sysctl kernel.kptr_restrict=0
To run the agent and pass commands to it, the helper script profiler.sh
is provided. A typical workflow would be to launch your Java application,
attach the agent and start profiling, exercise your performance scenario, and
then stop profiling. The agent's output, including the profiling results, will
be displayed in the Java application's standard output.
Example:
$ jps
9234 Jps
8983 Computey
$ ./profiler.sh start 8983
$ ./profiler.sh stop 8983
The following may be used in lieu of the pid
(8983):
- The keyword
jps
, which will use the most recently launched Java process. - The application name as it appears in the
jps
output: e.g.Computey
Alternatively, you may specify -d
(duration) argument to profile
the application for a fixed period of time with a single command.
$ ./profiler.sh -d 30 8983
By default, the profiling frequency is 100Hz (every 10ms of CPU time). Here is a sample of the output printed to the Java application's terminal:
--- Execution profile ---
Total samples: 687
Unknown (native): 1 (0.15%)
--- 6790000000 (98.84%) ns, 679 samples
[ 0] Primes.isPrime
[ 1] Primes.primesThread
[ 2] Primes.access$000
[ 3] Primes$1.run
[ 4] java.lang.Thread.run
... a lot of output omitted for brevity ...
ns percent samples top
---------- ------- ------- ---
6790000000 98.84% 679 Primes.isPrime
40000000 0.58% 4 __do_softirq
... more output omitted ...
This indicates that the hottest method was Primes.isPrime
, and the hottest
call stack leading to it comes from Primes.primesThread
.
If you need to profile some code as soon as the JVM starts up, instead of using the profiler.sh
script,
it is possible to attach async-profiler as an agent on the command line. For example:
$ java -agentpath:/path/to/libasyncProfiler.so=start,event=cpu,file=profile.html ...
Agent library is configured through the JVMTI argument interface.
The format of the arguments string is described
in the source code.
The profiler.sh
script actually converts command line arguments to that format.
For instance, -e wall
is converted to event=wall
, -f profile.html
is converted to file=profile.html
, and so on. However, some arguments are processed
directly by profiler.sh
script. E.g. -d 5
results in 3 actions:
attaching profiler agent with start command, sleeping for 5 seconds,
and then attaching the agent again with stop command.
It is possible to profile CPU, allocations, and locks at the same time. Or, instead of CPU, you may choose any other execution event: wall-clock, perf event, tracepoint, Java method, etc.
The only output format that supports multiple events together is JFR. The recording will contain the following event types:
jdk.ExecutionSample
jdk.ObjectAllocationInNewTLAB
(alloc)jdk.ObjectAllocationOutsideTLAB
(alloc)jdk.JavaMonitorEnter
(lock)jdk.ThreadPark
(lock)
To start profiling cpu + allocations + locks together, specify
./profiler.sh -e cpu,alloc,lock -f profile.jfr ...
or use --alloc
and --lock
parameters with the desired threshold:
./profiler.sh -e cpu --alloc 2m --lock 10ms -f profile.jfr ...
The same, when starting profiler as an agent:
-agentpath:/path/to/libasyncProfiler.so=start,event=cpu,alloc=2m,lock=10ms,file=profile.jfr
async-profiler provides out-of-the-box Flame Graph support.
Specify -o flamegraph
argument to dump profiling results as an interactive HTML Flame Graph.
Also, Flame Graph output format will be chosen automatically if the target filename ends with .html
.
$ jps
9234 Jps
8983 Computey
$ ./profiler.sh -d 30 -f /tmp/flamegraph.html 8983
The following is a complete list of the command-line options accepted by
profiler.sh
script.
-
start
- starts profiling in semi-automatic mode, i.e. profiler will run untilstop
command is explicitly called. -
resume
- starts or resumes earlier profiling session that has been stopped. All the collected data remains valid. The profiling options are not preserved between sessions, and should be specified again. -
stop
- stops profiling and prints the report. -
dump
- dump collected data without stopping profiling session. -
check
- check if the specified profiling event is available. -
status
- prints profiling status: whether profiler is active and for how long. -
list
- show the list of profiling events available for the target process (if PID is specified) or for the default JVM. -
-d N
- the profiling duration, in seconds. If nostart
,resume
,stop
orstatus
option is given, the profiler will run for the specified period of time and then automatically stop.
Example:./profiler.sh -d 30 8983
-
-e event
- the profiling event:cpu
,alloc
,lock
,cache-misses
etc. Uselist
to see the complete list of available events.In allocation profiling mode the top frame of every call trace is the class of the allocated object, and the counter is the heap pressure (the total size of allocated TLABs or objects outside TLAB).
In lock profiling mode the top frame is the class of lock/monitor, and the counter is number of nanoseconds it took to enter this lock/monitor.
Two special event types are supported on Linux: hardware breakpoints and kernel tracepoints:
-e mem:<func>[:rwx]
sets read/write/exec breakpoint at function<func>
. The format ofmem
event is the same as inperf-record
. Execution breakpoints can be also specified by the function name, e.g.-e malloc
will trace all calls of nativemalloc
function.-e trace:<id>
sets a kernel tracepoint. It is possible to specify tracepoint symbolic name, e.g.-e syscalls:sys_enter_open
will trace allopen
syscalls.
-
-i N
- sets the profiling interval in nanoseconds or in other units, if N is followed byms
(for milliseconds),us
(for microseconds), ors
(for seconds). Only CPU active time is counted. No samples are collected while CPU is idle. The default is 10000000 (10ms).
Example:./profiler.sh -i 500us 8983
-
--alloc N
- allocation profiling interval in bytes or in other units, if N is followed byk
(kilobytes),m
(megabytes), org
(gigabytes). -
--lock N
- lock profiling threshold in nanoseconds (or other units). In lock profiling mode, record contended locks that the JVM has waited for longer than the specified duration. -
-j N
- sets the Java stack profiling depth. This option will be ignored if N is greater than default 2048.
Example:./profiler.sh -j 30 8983
-
-t
- profile threads separately. Each stack trace will end with a frame that denotes a single thread.
Example:./profiler.sh -t 8983
-
-s
- print simple class names instead of FQN. -
-g
- print method signatures. -
-a
- annotate JIT compiled methods with_[j]
and inlined methods with_[i]
. -
-l
- prepend library names to symbols, e.g.libjvm.so`JVM_DefineClassWithSource
. -
-o fmt
- specifies what information to dump when profiling ends.fmt
can be one of the following options:traces[=N]
- dump call traces (at most N samples);flat[=N]
- dump flat profile (top N hot methods);
can be combined withtraces
, e.g.traces=200,flat=200
jfr
- dump events in Java Flight Recorder format readable by Java Mission Control. This does not require JDK commercial features to be enabled.collapsed
- dump collapsed call traces in the format used by FlameGraph script. This is a collection of call stacks, where each line is a semicolon separated list of frames followed by a counter.flamegraph
- produce Flame Graph in HTML format.tree
- produce Call Tree in HTML format.
--reverse
option will generate backtrace view.
-
--total
- count the total value of the collected metric instead of the number of samples, e.g. total allocation size. -
--chunksize N
,--chunktime N
- approximate size and time limits for a single JFR chunk. Example:./profiler.sh -f profile.jfr --chunksize 100m --chunktime 1h 8983
-
-I include
,-X exclude
- filter stack traces by the given pattern(s).-I
defines the name pattern that must be present in the stack traces, while-X
is the pattern that must not occur in any of stack traces in the output.-I
and-X
options can be specified multiple times. A pattern may begin or end with a star*
that denotes any (possibly empty) sequence of characters.
Example:./profiler.sh -I 'Primes.*' -I 'java/*' -X '*Unsafe.park*' 8983
-
--title TITLE
,--minwidth PERCENT
,--reverse
- FlameGraph parameters.
Example:./profiler.sh -f profile.html --title "Sample CPU profile" --minwidth 0.5 8983
-
-f FILENAME
- the file name to dump the profile information to.
%p
in the file name is expanded to the PID of the target JVM;
%t
- to the timestamp;
%n{MAX}
- to the sequence number;
%{ENV}
- to the value of the given environment variable.
Example:./profiler.sh -o collapsed -f /tmp/traces-%t.txt 8983
-
--loop TIME
- run profiler in a loop (continuous profiling). The argument is either a clock time (hh:mm:ss
) or a loop duration ins
econds,m
inutes,h
ours, ord
ays. Make sure the filename includes a timestamp pattern, or the output will be overwritten on each iteration.
Example:./profiler.sh --loop 1h -f /var/log/profile-%t.jfr 8983
-
--all-user
- include only user-mode events. This option is helpful when kernel profiling is restricted byperf_event_paranoid
settings. -
--sched
- group threads by Linux-specific scheduling policy: BATCH/IDLE/OTHER. -
--cstack MODE
- how to walk native frames (C stack). Possible modes arefp
(Frame Pointer),dwarf
(DWARF unwind info),lbr
(Last Branch Record, available on Haswell since Linux 4.1), andno
(do not collect C stack).By default, C stack is shown in cpu, itimer, wall-clock and perf-events profiles. Java-level events like
alloc
andlock
collect only Java stack. -
--begin function
,--end function
- automatically start/stop profiling when the specified native function is executed. -
--ttsp
- time-to-safepoint profiling. An alias for
--begin SafepointSynchronize::begin --end RuntimeService::record_safepoint_synchronized
It is not a separate event type, but rather a constraint. Whatever event type you choose (e.g.cpu
orwall
), the profiler will work as usual, except that only events between the safepoint request and the start of the VM operation will be recorded. -
--jfrsync CONFIG
- start Java Flight Recording with the given configuration synchronously with the profiler. The output .jfr file will include all regular JFR events, except that execution samples will be obtained from async-profiler. This option implies-o jfr
.CONFIG
is a predefined JFR profile or a JFR configuration file (.jfc).
Example:
./profiler.sh -e cpu --jfrsync profile -f combined.jfr 8983
-
--fdtransfer
- runs "fdtransfer" alongside, which is a small program providing an interface for the profiler to access,perf_event_open
even while this syscall is unavailable for the profiled process (due to low privileges). See Profiling Java in a container. -
-v
,--version
- prints the version of profiler library. If PID is specified, gets the version of the library loaded into the given process.
It is possible to profile Java processes running in a Docker or LXC container both from within a container and from the host system.
When profiling from the host, pid
should be the Java process ID in the host
namespace. Use ps aux | grep java
or docker top <container>
to find
the process ID.
async-profiler should be run from the host by a privileged user - it will
automatically switch to the proper pid/mount namespace and change
user credentials to match the target process. Also make sure that
the target container can access libasyncProfiler.so
by the same
absolute path as on the host.
By default, Docker container restricts the access to perf_event_open
syscall. There are 3 alternatives to allow profiling in a container:
- You can modify the seccomp profile
or disable it altogether with
--security-opt seccomp=unconfined
option. In addition,--cap-add SYS_ADMIN
may be required. - You can use "fdtransfer": see the help for
--fdtransfer
. - Last, you may fall back to
-e itimer
profiling mode, see Troubleshooting.
-
macOS profiling is limited to user space code only.
-
On most Linux systems,
perf_events
captures call stacks with a maximum depth of 127 frames. On recent Linux kernels, this can be configured usingsysctl kernel.perf_event_max_stack
or by writing to the/proc/sys/kernel/perf_event_max_stack
file. -
Profiler allocates 8kB perf_event buffer for each thread of the target process. Make sure
/proc/sys/kernel/perf_event_mlock_kb
value is large enough (more than8 * threads
) when running under unprivileged user. Otherwise the message "perf_event mmap failed: Operation not permitted" will be printed, and no native stack traces will be collected. -
There is no bullet-proof guarantee that the
perf_events
overflow signal is delivered to the Java thread in a way that guarantees no other code has run, which means that in some rare cases, the captured Java stack might not match the captured native (user+kernel) stack. -
You will not see the non-Java frames preceding the Java frames on the stack. For example, if
start_thread
calledJavaMain
and then your Java code started running, you will not see the first two frames in the resulting stack. On the other hand, you will see non-Java frames (user and kernel) invoked by your Java code. -
No Java stacks will be collected if
-XX:MaxJavaStackTraceDepth
is zero or negative. -
Too short profiling interval may cause continuous interruption of heavy system calls like
clone()
, so that it will never complete; see #97. The workaround is simply to increase the interval. -
When agent is not loaded at JVM startup (by using -agentpath option) it is highly recommended to use
-XX:+UnlockDiagnosticVMOptions -XX:+DebugNonSafepoints
JVM flags. Without those flags the profiler will still work correctly but results might be less accurate. For example, without-XX:+DebugNonSafepoints
there is a high chance that simple inlined methods will not appear in the profile. When the agent is attached at runtime,CompiledMethodLoad
JVMTI event enables debug info, but only for methods compiled after attaching.
Failed to change credentials to match the target process: Operation not permitted
Due to limitation of HotSpot Dynamic Attach mechanism, the profiler must be run
by exactly the same user (and group) as the owner of target JVM process.
If profiler is run by a different user, it will try to automatically change
current user and group. This will likely succeed for root
, but not for
other users, resulting in the above error.
Could not start attach mechanism: No such file or directory
The profiler cannot establish communication with the target JVM through UNIX domain socket.
Usually this happens in one of the following cases:
- Attach socket
/tmp/.java_pidNNN
has been deleted. It is a common practice to clean/tmp
automatically with some scheduled script. Configure the cleanup software to exclude.java_pid*
files from deletion.
How to check: runlsof -p PID | grep java_pid
If it lists a socket file, but the file does not exist, then this is exactly the described problem. - JVM is started with
-XX:+DisableAttachMechanism
option. /tmp
directory of Java process is not physically the same directory as/tmp
of your shell, because Java is running in a container or inchroot
environment.jattach
attempts to solve this automatically, but it might lack the required permissions to do so.
Checkstrace build/jattach PID properties
- JVM is busy and cannot reach a safepoint. For instance,
JVM is in the middle of long-running garbage collection.
How to check: runkill -3 PID
. Healthy JVM process should print a thread dump and heap info in its console.
Failed to inject profiler into <pid>
The connection with the target JVM has been established, but JVM is unable to load profiler shared library.
Make sure the user of JVM process has permissions to access libasyncProfiler.so
by exactly the same absolute path.
For more information see #78.
No access to perf events. Try --fdtransfer or --all-user option or 'sysctl kernel.perf_event_paranoid=1'
or
Perf events unavailable
perf_event_open()
syscall has failed.
Typical reasons include:
/proc/sys/kernel/perf_event_paranoid
is set to restricted mode (>=2).- seccomp disables
perf_event_open
API in a container. - OS runs under a hypervisor that does not virtualize performance counters.
- perf_event_open API is not supported on this system, e.g. WSL.
For permissions-related reasons (such as 1 and 2), using --fdtransfer
while running the profiler
as a privileged user will allow using perf_events.
If changing the configuration is not possible, you may fall back to
-e itimer
profiling mode. It is similar to cpu
mode, but does not
require perf_events support. As a drawback, there will be no kernel
stack traces.
No AllocTracer symbols found. Are JDK debug symbols installed?
The OpenJDK debug symbols are required for allocation profiling. See Installing Debug Symbols for more details. If the error message persists after a successful installation of the debug symbols, it is possible that the JDK was upgraded when installing the debug symbols. In this case, profiling any Java process which had started prior to the installation will continue to display this message, since the process had loaded the older version of the JDK which lacked debug symbols. Restarting the affected Java processes should resolve the issue.
VMStructs unavailable. Unsupported JVM?
JVM shared library does not export gHotSpotVMStructs*
symbols -
apparently this is not a HotSpot JVM. Sometimes the same message
can be also caused by an incorrectly built JDK
(see #218).
In these cases installing JDK debug symbols may solve the problem.
Could not parse symbols from <libname.so>
Async-profiler was unable to parse non-Java function names because of
the corrupted contents in /proc/[pid]/maps
. The problem is known to
occur in a container when running Ubuntu with Linux kernel 5.x.
This is the OS bug, see https://bugs.launchpad.net/ubuntu/+source/linux/+bug/1843018.
Could not open output file
Output file is written by the target JVM process, not by the profiler script.
Make sure the path specified in -f
option is correct and is accessible by the JVM.