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| <p align=right> |
| <i>Last modified |
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| |
| <p>This is the heap profiler we use at Google, to explore how C++ |
| programs manage memory. This facility can be useful for</p> |
| <ul> |
| <li> Figuring out what is in the program heap at any given time |
| <li> Locating memory leaks |
| <li> Finding places that do a lot of allocation |
| </ul> |
| |
| <p>The profiling system instruments all allocations and frees. It |
| keeps track of various pieces of information per allocation site. An |
| allocation site is defined as the active stack trace at the call to |
| <code>malloc</code>, <code>calloc</code>, <code>realloc</code>, or, |
| <code>new</code>.</p> |
| |
| <p>There are three parts to using it: linking the library into an |
| application, running the code, and analyzing the output.</p> |
| |
| |
| <h1>Linking in the Library</h1> |
| |
| <p>To install the heap profiler into your executable, add |
| <code>-ltcmalloc</code> to the link-time step for your executable. |
| Also, while we don't necessarily recommend this form of usage, it's |
| possible to add in the profiler at run-time using |
| <code>LD_PRELOAD</code>: |
| <pre>% env LD_PRELOAD="/usr/lib/libtcmalloc.so" <binary></pre> |
| |
| <p>This does <i>not</i> turn on heap profiling; it just inserts the |
| code. For that reason, it's practical to just always link |
| <code>-ltcmalloc</code> into a binary while developing; that's what we |
| do at Google. (However, since any user can turn on the profiler by |
| setting an environment variable, it's not necessarily recommended to |
| install profiler-linked binaries into a production, running |
| system.) Note that if you wish to use the heap profiler, you must |
| also use the tcmalloc memory-allocation library. There is no way |
| currently to use the heap profiler separate from tcmalloc.</p> |
| |
| |
| <h1>Running the Code</h1> |
| |
| <p>There are several alternatives to actually turn on heap profiling |
| for a given run of an executable:</p> |
| |
| <ol> |
| <li> <p>Define the environment variable HEAPPROFILE to the filename |
| to dump the profile to. For instance, to profile |
| <code>/usr/local/bin/my_binary_compiled_with_tcmalloc</code>:</p> |
| <pre>% env HEAPPROFILE=/tmp/mybin.hprof /usr/local/bin/my_binary_compiled_with_tcmalloc</pre> |
| <li> <p>In your code, bracket the code you want profiled in calls to |
| <code>HeapProfilerStart()</code> and <code>HeapProfilerStop()</code>. |
| (These functions are declared in <code><gperftools/heap-profiler.h></code>.) |
| <code>HeapProfilerStart()</code> will take the |
| profile-filename-prefix as an argument. Then, as often as |
| you'd like before calling <code>HeapProfilerStop()</code>, you |
| can use <code>HeapProfilerDump()</code> or |
| <code>GetHeapProfile()</code> to examine the profile. In case |
| it's useful, <code>IsHeapProfilerRunning()</code> will tell you |
| whether you've already called HeapProfilerStart() or not.</p> |
| </ol> |
| |
| |
| <p>For security reasons, heap profiling will not write to a file -- |
| and is thus not usable -- for setuid programs.</p> |
| |
| <H2>Modifying Runtime Behavior</H2> |
| |
| <p>You can more finely control the behavior of the heap profiler via |
| environment variables.</p> |
| |
| <table frame=box rules=sides cellpadding=5 width=100%> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_ALLOCATION_INTERVAL</code></td> |
| <td>default: 1073741824 (1 Gb)</td> |
| <td> |
| Dump heap profiling information each time the specified number of |
| bytes has been allocated by the program. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_INUSE_INTERVAL</code></td> |
| <td>default: 104857600 (100 Mb)</td> |
| <td> |
| Dump heap profiling information whenever the high-water memory |
| usage mark increases by the specified number of bytes. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_TIME_INTERVAL</code></td> |
| <td>default: 0</td> |
| <td> |
| Dump heap profiling information each time the specified |
| number of seconds has elapsed. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAPPROFILESIGNAL</code></td> |
| <td>default: disabled</td> |
| <td> |
| Dump heap profiling information whenever the specified signal is sent to the |
| process. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_MMAP</code></td> |
| <td>default: false</td> |
| <td> |
| Profile <code>mmap</code>, <code>mremap</code> and <code>sbrk</code> |
| calls in addition |
| to <code>malloc</code>, <code>calloc</code>, <code>realloc</code>, |
| and <code>new</code>. <b>NOTE:</b> this causes the profiler to |
| profile calls internal to tcmalloc, since tcmalloc and friends use |
| mmap and sbrk internally for allocations. One partial solution is |
| to filter these allocations out when running <code>pprof</code>, |
| with something like |
| <code>pprof --ignore='DoAllocWithArena|SbrkSysAllocator::Alloc|MmapSysAllocator::Alloc</code>. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_ONLY_MMAP</code></td> |
| <td>default: false</td> |
| <td> |
| Only profile <code>mmap</code>, <code>mremap</code>, and <code>sbrk</code> |
| calls; do not profile |
| <code>malloc</code>, <code>calloc</code>, <code>realloc</code>, |
| or <code>new</code>. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>HEAP_PROFILE_MMAP_LOG</code></td> |
| <td>default: false</td> |
| <td> |
| Log <code>mmap</code>/<code>munmap</code> calls. |
| </td> |
| </tr> |
| |
| </table> |
| |
| <H2>Checking for Leaks</H2> |
| |
| <p>You can use the heap profiler to manually check for leaks, for |
| instance by reading the profiler output and looking for large |
| allocations. However, for that task, it's easier to use the <A |
| HREF="heap_checker.html">automatic heap-checking facility</A> built |
| into tcmalloc.</p> |
| |
| |
| <h1><a name="pprof">Analyzing the Output</a></h1> |
| |
| <p>If heap-profiling is turned on in a program, the program will |
| periodically write profiles to the filesystem. The sequence of |
| profiles will be named:</p> |
| <pre> |
| <prefix>.0000.heap |
| <prefix>.0001.heap |
| <prefix>.0002.heap |
| ... |
| </pre> |
| <p>where <code><prefix></code> is the filename-prefix supplied |
| when running the code (e.g. via the <code>HEAPPROFILE</code> |
| environment variable). Note that if the supplied prefix |
| does not start with a <code>/</code>, the profile files will be |
| written to the program's working directory.</p> |
| |
| <p>The profile output can be viewed by passing it to the |
| <code>pprof</code> tool -- the same tool that's used to analyze <A |
| HREF="cpuprofile.html">CPU profiles</A>. |
| |
| <p>Here are some examples. These examples assume the binary is named |
| <code>gfs_master</code>, and a sequence of heap profile files can be |
| found in files named:</p> |
| <pre> |
| /tmp/profile.0001.heap |
| /tmp/profile.0002.heap |
| ... |
| /tmp/profile.0100.heap |
| </pre> |
| |
| <h3>Why is a process so big</h3> |
| |
| <pre> |
| % pprof --gv gfs_master /tmp/profile.0100.heap |
| </pre> |
| |
| <p>This command will pop-up a <code>gv</code> window that displays |
| the profile information as a directed graph. Here is a portion |
| of the resulting output:</p> |
| |
| <p><center> |
| <img src="heap-example1.png"> |
| </center></p> |
| |
| A few explanations: |
| <ul> |
| <li> <code>GFS_MasterChunk::AddServer</code> accounts for 255.6 MB |
| of the live memory, which is 25% of the total live memory. |
| <li> <code>GFS_MasterChunkTable::UpdateState</code> is directly |
| accountable for 176.2 MB of the live memory (i.e., it directly |
| allocated 176.2 MB that has not been freed yet). Furthermore, |
| it and its callees are responsible for 729.9 MB. The |
| labels on the outgoing edges give a good indication of the |
| amount allocated by each callee. |
| </ul> |
| |
| <h3>Comparing Profiles</h3> |
| |
| <p>You often want to skip allocations during the initialization phase |
| of a program so you can find gradual memory leaks. One simple way to |
| do this is to compare two profiles -- both collected after the program |
| has been running for a while. Specify the name of the first profile |
| using the <code>--base</code> option. For example:</p> |
| <pre> |
| % pprof --base=/tmp/profile.0004.heap gfs_master /tmp/profile.0100.heap |
| </pre> |
| |
| <p>The memory-usage in <code>/tmp/profile.0004.heap</code> will be |
| subtracted from the memory-usage in |
| <code>/tmp/profile.0100.heap</code> and the result will be |
| displayed.</p> |
| |
| <h3>Text display</h3> |
| |
| <pre> |
| % pprof --text gfs_master /tmp/profile.0100.heap |
| 255.6 24.7% 24.7% 255.6 24.7% GFS_MasterChunk::AddServer |
| 184.6 17.8% 42.5% 298.8 28.8% GFS_MasterChunkTable::Create |
| 176.2 17.0% 59.5% 729.9 70.5% GFS_MasterChunkTable::UpdateState |
| 169.8 16.4% 75.9% 169.8 16.4% PendingClone::PendingClone |
| 76.3 7.4% 83.3% 76.3 7.4% __default_alloc_template::_S_chunk_alloc |
| 49.5 4.8% 88.0% 49.5 4.8% hashtable::resize |
| ... |
| </pre> |
| |
| <p> |
| <ul> |
| <li> The first column contains the direct memory use in MB. |
| <li> The fourth column contains memory use by the procedure |
| and all of its callees. |
| <li> The second and fifth columns are just percentage |
| representations of the numbers in the first and fourth columns. |
| <li> The third column is a cumulative sum of the second column |
| (i.e., the <code>k</code>th entry in the third column is the |
| sum of the first <code>k</code> entries in the second column.) |
| </ul> |
| |
| <h3>Ignoring or focusing on specific regions</h3> |
| |
| <p>The following command will give a graphical display of a subset of |
| the call-graph. Only paths in the call-graph that match the regular |
| expression <code>DataBuffer</code> are included:</p> |
| <pre> |
| % pprof --gv --focus=DataBuffer gfs_master /tmp/profile.0100.heap |
| </pre> |
| |
| <p>Similarly, the following command will omit all paths subset of the |
| call-graph. All paths in the call-graph that match the regular |
| expression <code>DataBuffer</code> are discarded:</p> |
| <pre> |
| % pprof --gv --ignore=DataBuffer gfs_master /tmp/profile.0100.heap |
| </pre> |
| |
| <h3>Total allocations + object-level information</h3> |
| |
| <p>All of the previous examples have displayed the amount of in-use |
| space. I.e., the number of bytes that have been allocated but not |
| freed. You can also get other types of information by supplying a |
| flag to <code>pprof</code>:</p> |
| |
| <center> |
| <table frame=box rules=sides cellpadding=5 width=100%> |
| |
| <tr valign=top> |
| <td><code>--inuse_space</code></td> |
| <td> |
| Display the number of in-use megabytes (i.e. space that has |
| been allocated but not freed). This is the default. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>--inuse_objects</code></td> |
| <td> |
| Display the number of in-use objects (i.e. number of |
| objects that have been allocated but not freed). |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>--alloc_space</code></td> |
| <td> |
| Display the number of allocated megabytes. This includes |
| the space that has since been de-allocated. Use this |
| if you want to find the main allocation sites in the |
| program. |
| </td> |
| </tr> |
| |
| <tr valign=top> |
| <td><code>--alloc_objects</code></td> |
| <td> |
| Display the number of allocated objects. This includes |
| the objects that have since been de-allocated. Use this |
| if you want to find the main allocation sites in the |
| program. |
| </td> |
| |
| </table> |
| </center> |
| |
| |
| <h3>Interactive mode</a></h3> |
| |
| <p>By default -- if you don't specify any flags to the contrary -- |
| pprof runs in interactive mode. At the <code>(pprof)</code> prompt, |
| you can run many of the commands described above. You can type |
| <code>help</code> for a list of what commands are available in |
| interactive mode.</p> |
| |
| |
| <h1>Caveats</h1> |
| |
| <ul> |
| <li> Heap profiling requires the use of libtcmalloc. This |
| requirement may be removed in a future version of the heap |
| profiler, and the heap profiler separated out into its own |
| library. |
| |
| <li> If the program linked in a library that was not compiled |
| with enough symbolic information, all samples associated |
| with the library may be charged to the last symbol found |
| in the program before the library. This will artificially |
| inflate the count for that symbol. |
| |
| <li> If you run the program on one machine, and profile it on |
| another, and the shared libraries are different on the two |
| machines, the profiling output may be confusing: samples that |
| fall within the shared libaries may be assigned to arbitrary |
| procedures. |
| |
| <li> Several libraries, such as some STL implementations, do their |
| own memory management. This may cause strange profiling |
| results. We have code in libtcmalloc to cause STL to use |
| tcmalloc for memory management (which in our tests is better |
| than STL's internal management), though it only works for some |
| STL implementations. |
| |
| <li> If your program forks, the children will also be profiled |
| (since they inherit the same HEAPPROFILE setting). Each |
| process is profiled separately; to distinguish the child |
| profiles from the parent profile and from each other, all |
| children will have their process-id attached to the HEAPPROFILE |
| name. |
| |
| <li> Due to a hack we make to work around a possible gcc bug, your |
| profiles may end up named strangely if the first character of |
| your HEAPPROFILE variable has ascii value greater than 127. |
| This should be exceedingly rare, but if you need to use such a |
| name, just set prepend <code>./</code> to your filename: |
| <code>HEAPPROFILE=./Ägypten</code>. |
| </ul> |
| |
| <hr> |
| <address>Sanjay Ghemawat |
| <!-- Created: Tue Dec 19 10:43:14 PST 2000 --> |
| </address> |
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