158

I've been using cProfile to profile my code, and it's been working great. I also use gprof2dot.py to visualize the results (makes it a little clearer).

However, cProfile (and most other Python profilers I've seen so far) seem to only profile at the function-call level. This causes confusion when certain functions are called from different places - I have no idea if call #1 or call #2 is taking up the majority of the time. This gets even worse when the function in question is six levels deep, called from seven other places.

How do I get a line-by-line profiling?

Instead of this:

function #12, total time: 2.0s

I'd like to see something like this:

function #12 (called from somefile.py:102) 0.5s
function #12 (called from main.py:12) 1.5s

cProfile does show how much of the total time "transfers" to the parent, but again this connection is lost when you have a bunch of layers and interconnected calls.

Ideally, I'd love to have a GUI that would parse through the data, then show me my source file with a total time given to each line. Something like this:

main.py:

a = 1 # 0.0s
result = func(a) # 0.4s
c = 1000 # 0.0s
result = func(c) # 5.0s

Then I'd be able to click on the second "func(c)" call to see what's taking up time in that call, separate from the "func(a)" call. Does that make sense?

2
  • 2
    My guess is that you would be interested in pstats.print_callers. An example is here. Oct 13, 2010 at 20:18
  • Muhammad, that's definitely helpful! At least it fixes one problem: separating function calls depending on origin. I think Joe Kington's answer is closer to my goal, but print_callers() definitely gets me halfway there. Thanks! Oct 14, 2010 at 15:25

5 Answers 5

141

I believe that's what Robert Kern's line_profiler is intended for. From the link:

File: pystone.py
Function: Proc2 at line 149
Total time: 0.606656 s

Line #      Hits         Time  Per Hit   % Time  Line Contents
==============================================================
   149                                           @profile
   150                                           def Proc2(IntParIO):
   151     50000        82003      1.6     13.5      IntLoc = IntParIO + 10
   152     50000        63162      1.3     10.4      while 1:
   153     50000        69065      1.4     11.4          if Char1Glob == 'A':
   154     50000        66354      1.3     10.9              IntLoc = IntLoc - 1
   155     50000        67263      1.3     11.1              IntParIO = IntLoc - IntGlob
   156     50000        65494      1.3     10.8              EnumLoc = Ident1
   157     50000        68001      1.4     11.2          if EnumLoc == Ident1:
   158     50000        63739      1.3     10.5              break
   159     50000        61575      1.2     10.1      return IntParIO
18
  • 12
    Does line_profiler work with Python 3? I couldn't get any information on that. Jul 23, 2012 at 15:02
  • 3
    line_profiler does not show hits and time for me. Can anyone tell me why? And how to solve?
    – I159
    Jan 6, 2013 at 12:03
  • 7
    Here's the decorator I wrote: gist.github.com/kylegibson/6583590. If you're running nosetests, be sure to use the -s option so stdout is printed immediately. Sep 16, 2013 at 17:14
  • 6
    how does the python script that produces this output look like? import line_profiler; and then ?
    – Zhubarb
    Mar 11, 2014 at 12:19
  • 20
    can anyone show how to actually use this library? The readme teaches how to install, and answers various FAQs, but doesn't mention how to use it after a pip install..
    – cryanbhu
    Jul 25, 2018 at 3:28
65

You could also use pprofile(pypi). If you want to profile the entire execution, it does not require source code modification. You can also profile a subset of a larger program in two ways:

  • toggle profiling when reaching a specific point in the code, such as:

    import pprofile
    profiler = pprofile.Profile()
    with profiler:
        some_code
    # Process profile content: generate a cachegrind file and send it to user.
    
    # You can also write the result to the console:
    profiler.print_stats()
    
    # Or to a file:
    profiler.dump_stats("/tmp/profiler_stats.txt")
    
  • toggle profiling asynchronously from call stack (requires a way to trigger this code in considered application, for example a signal handler or an available worker thread) by using statistical profiling:

    import pprofile
    profiler = pprofile.StatisticalProfile()
    statistical_profiler_thread = pprofile.StatisticalThread(
        profiler=profiler,
    )
    with statistical_profiler_thread:
        sleep(n)
    # Likewise, process profile content
    

Code annotation output format is much like line profiler:

$ pprofile --threads 0 demo/threads.py
Command line: ['demo/threads.py']
Total duration: 1.00573s
File: demo/threads.py
File duration: 1.00168s (99.60%)
Line #|      Hits|         Time| Time per hit|      %|Source code
------+----------+-------------+-------------+-------+-----------
     1|         2|  3.21865e-05|  1.60933e-05|  0.00%|import threading
     2|         1|  5.96046e-06|  5.96046e-06|  0.00%|import time
     3|         0|            0|            0|  0.00%|
     4|         2|   1.5974e-05|  7.98702e-06|  0.00%|def func():
     5|         1|      1.00111|      1.00111| 99.54%|  time.sleep(1)
     6|         0|            0|            0|  0.00%|
     7|         2|  2.00272e-05|  1.00136e-05|  0.00%|def func2():
     8|         1|  1.69277e-05|  1.69277e-05|  0.00%|  pass
     9|         0|            0|            0|  0.00%|
    10|         1|  1.81198e-05|  1.81198e-05|  0.00%|t1 = threading.Thread(target=func)
(call)|         1|  0.000610828|  0.000610828|  0.06%|# /usr/lib/python2.7/threading.py:436 __init__
    11|         1|  1.52588e-05|  1.52588e-05|  0.00%|t2 = threading.Thread(target=func)
(call)|         1|  0.000438929|  0.000438929|  0.04%|# /usr/lib/python2.7/threading.py:436 __init__
    12|         1|  4.79221e-05|  4.79221e-05|  0.00%|t1.start()
(call)|         1|  0.000843048|  0.000843048|  0.08%|# /usr/lib/python2.7/threading.py:485 start
    13|         1|  6.48499e-05|  6.48499e-05|  0.01%|t2.start()
(call)|         1|   0.00115609|   0.00115609|  0.11%|# /usr/lib/python2.7/threading.py:485 start
    14|         1|  0.000205994|  0.000205994|  0.02%|(func(), func2())
(call)|         1|      1.00112|      1.00112| 99.54%|# demo/threads.py:4 func
(call)|         1|  3.09944e-05|  3.09944e-05|  0.00%|# demo/threads.py:7 func2
    15|         1|  7.62939e-05|  7.62939e-05|  0.01%|t1.join()
(call)|         1|  0.000423908|  0.000423908|  0.04%|# /usr/lib/python2.7/threading.py:653 join
    16|         1|  5.26905e-05|  5.26905e-05|  0.01%|t2.join()
(call)|         1|  0.000320196|  0.000320196|  0.03%|# /usr/lib/python2.7/threading.py:653 join

Note that because pprofile does not rely on code modification it can profile top-level module statements, allowing to profile program startup time (how long it takes to import modules, initialise globals, ...).

It can generate cachegrind-formatted output, so you can use kcachegrind to browse large results easily.

Disclosure: I am pprofile author.

8
  • 1
    +1 Thank you for your contribution. It looks well-done. I have a little different perspective - measuring inclusive time taken by statements and functions is one objective. Finding out what can be done to make the code faster is a different objective. The difference becomes painfully obvious as the code gets large - like 10^6 lines of code. The code can be wasting large percents of time. The way I find it is by taking a small number of very detailed samples, and examining them with a human eye - not summarizing. The problem is exposed by the fraction of time it wastes. Feb 2, 2015 at 14:18
  • 1
    You are right, I didn't mention pprofile usage when one wants to profile a smaller subset. I edited my post to add examples of this.
    – vpelletier
    Feb 3, 2015 at 6:54
  • 4
    This is exactly what I was looking for: non-intrusive and extensive.
    – egpbos
    Oct 5, 2016 at 6:30
  • 1
    Nice tool, but it runs several times slower than the original code.
    – rominf
    Nov 19, 2018 at 10:13
  • 1
    In deterministic mode it does have a significant overhead - the flip side of portability. On slower code, I recommend using the statistic mode, which has a ridiculously small overhead - at the expense of trace imprecision and readability. But it can be a first step too: identify hot-spot in statistic mode, produce a smaller case triggering the identified hot-spot, and use deterministic profiling to get all the details.
    – vpelletier
    Nov 2, 2020 at 10:31
17

Just to improve @Joe Kington 's above-mentioned answer.

For Python 3.x, use line_profiler:


Installation:

pip install line_profiler

Usage:

Suppose you have the program main.py and within it, functions fun_a() and fun_b() that you want to profile with respect to time; you will need to use the decorator @profile just before the function definitions. For e.g.,

@profile
def fun_a():
    #do something

@profile
def fun_b():
    #do something more

if __name__ == '__main__':
    fun_a()
    fun_b()

The program can be profiled by executing the shell command:

$ kernprof -l -v main.py

The arguments can be fetched using $ kernprof -h

Usage: kernprof [-s setupfile] [-o output_file_path] scriptfile [arg] ...

Options:
  --version             show program's version number and exit
  -h, --help            show this help message and exit
  -l, --line-by-line    Use the line-by-line profiler from the line_profiler
                        module instead of Profile. Implies --builtin.
  -b, --builtin         Put 'profile' in the builtins. Use 'profile.enable()'
                        and 'profile.disable()' in your code to turn it on and
                        off, or '@profile' to decorate a single function, or
                        'with profile:' to profile a single section of code.
  -o OUTFILE, --outfile=OUTFILE
                        Save stats to <outfile>
  -s SETUP, --setup=SETUP
                        Code to execute before the code to profile
  -v, --view            View the results of the profile in addition to saving
                        it.

The results will be printed on the console as:

Total time: 17.6699 s
File: main.py
Function: fun_a at line 5

Line #      Hits         Time  Per Hit   % Time  Line Contents
==============================================================
    5                                           @profile
    6                                           def fun_a():
...


EDIT: The results from the profilers can be parsed using the TAMPPA package. Using it, we can get line-by-line desired plots as plot

3
  • The instructions are accurate but the graph is misleading, because line_profiler does not profile memory usage (memory_profiler does, but it often fails). I'd recommend using (my) Scalene profiler instead, if you're on Mac OS X or Linux: pip install -U scalene, github.com/emeryberger/scalene -- it simultaneously does line-level profiling of CPU time and memory (and more!). Aug 16, 2020 at 13:54
  • Hello @emeryberger, the plot shown is done by a new package: TAMPPA. although its subject to issues. I know there are many ways. Thank you for sharing one. I would recommend submitting a detailed answer here :) Have you submitted an issue for 'memory_profiler' ?
    – Pe Dro
    Aug 16, 2020 at 15:17
  • I can get Scalene profiler to work, could you provide an exmaple?
    – MBV
    Jan 29 at 17:58
10

You can take help of line_profiler package for this

1. 1st install the package:

    pip install line_profiler

2. Use magic command to load the package to your python/notebook environment

    %load_ext line_profiler

3. If you want to profile the codes for a function then
do as follows:

    %lprun -f demo_func demo_func(arg1, arg2)

you will get a nice formatted output with all the details if you follow these steps :)

Line #      Hits      Time    Per Hit   % Time  Line Contents
 1                                           def demo_func(a,b):
 2         1        248.0    248.0     64.8      print(a+b)
 3         1         40.0     40.0     10.4      print(a)
 4         1         94.0     94.0     24.5      print(a*b)
 5         1          1.0      1.0      0.3      return a/b
1
  • I followed the exact same steps but it didn't show the Line Contents saying "Are you sure you are running this program from the same directory that you ran the profiler from? Continuing without the function's contents." What could be the reason? Jun 22 at 21:57
1

PyVmMonitor has a live-view which can help you there (you can connect to a running program and get statistics from it).

See: http://www.pyvmmonitor.com/

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