Debugging and Profiling

A golden rule in programming is that code does not do what you expect it to do, but what you tell it to do. Bridging that gap can sometimes be a quite difficult feat. In this lecture we are going to cover useful techniques for dealing with buggy and resource hungry code: debugging and profiling.


Printf debugging and Logging

“The most effective debugging tool is still careful thought, coupled with judiciously placed print statements” — Brian Kernighan, Unix for Beginners.

A first approach to debug a program is to add print statements around where you have detected the problem, and keep iterating until you have extracted enough information to understand what is responsible for the issue.

A second approach is to use logging in your program, instead of ad hoc print statements. Logging is better than regular print statements for several reasons:

Here is an example code that logs messages:

$ python
# Raw output as with just prints
$ python log
# Log formatted output
$ python log ERROR
# Print only ERROR levels and above
$ python color
# Color formatted output

One of my favorite tips for making logs more readable is to color code them. By now you probably have realized that your terminal uses colors to make things more readable. But how does it do it? Programs like ls or grep are using ANSI escape codes, which are special sequences of characters to indicate your shell to change the color of the output. For example, executing echo -e "\e[38;2;255;0;0mThis is red\e[0m" prints the message This is red in red on your terminal, as long as it supports true color. If your terminal doesn’t support this (e.g. macOS’s, you can use the more universally supported escape codes for 16 color choices, for example echo -e "\e[31;1mThis is red\e[0m".

The following script shows how to print many RGB colors into your terminal (again, as long as it supports true color).

#!/usr/bin/env bash
for R in $(seq 0 20 255); do
    for G in $(seq 0 20 255); do
        for B in $(seq 0 20 255); do
            printf "\e[38;2;${R};${G};${B}m█\e[0m";

Third party logs

As you start building larger software systems you will most probably run into dependencies that run as separate programs. Web servers, databases or message brokers are common examples of this kind of dependencies. When interacting with these systems it is often necessary to read their logs, since client side error messages might not suffice.

Luckily, most programs write their own logs somewhere in your system. In UNIX systems, it is commonplace for programs to write their logs under /var/log. For instance, the NGINX webserver places its logs under /var/log/nginx. More recently, systems have started using a system log, which is increasingly where all of your log messages go. Most (but not all) Linux systems use systemd, a system daemon that controls many things in your system such as which services are enabled and running. systemd places the logs under /var/log/journal in a specialized format and you can use the journalctl command to display the messages. Similarly, on macOS there is still /var/log/system.log but an increasing number of tools use the system log, that can be displayed with log show. On most UNIX systems you can also use the dmesg command to access the kernel log.

For logging under the system logs you can use the logger shell program. Here’s an example of using logger and how to check that the entry made it to the system logs. Moreover, most programming languages have bindings logging to the system log.

logger "Hello Logs"
# On macOS
log show --last 1m | grep Hello
# On Linux
journalctl --since "1m ago" | grep Hello

As we saw in the data wrangling lecture, logs can be quite verbose and they require some level of processing and filtering to get the information you want. If you find yourself heavily filtering through journalctl and log show you can consider using their flags, which can perform a first pass of filtering of their output. There are also some tools like lnav, that provide an improved presentation and navigation for log files.


When printf debugging is not enough you should use a debugger. Debuggers are programs that let you interact with the execution of a program, allowing the following:

Many programming languages come with some form of debugger. In Python this is the Python Debugger pdb.

Here is a brief description of some of the commands pdb supports:

Let’s go through an example of using pdb to fix the following buggy python code. (See the lecture video).

def bubble_sort(arr):
    n = len(arr)
    for i in range(n):
        for j in range(n):
            if arr[j] > arr[j+1]:
                arr[j] = arr[j+1]
                arr[j+1] = arr[j]
    return arr

print(bubble_sort([4, 2, 1, 8, 7, 6]))

Note that since Python is an interpreted language we can use the pdb shell to execute commands and to execute instructions. ipdb is an improved pdb that uses the IPython REPL enabling tab completion, syntax highlighting, better tracebacks, and better introspection while retaining the same interface as the pdb module.

For more low level programming you will probably want to look into gdb (and its quality of life modification pwndbg) and lldb. They are optimized for C-like language debugging but will let you probe pretty much any process and get its current machine state: registers, stack, program counter, &c.

Specialized Tools

Even if what you are trying to debug is a black box binary there are tools that can help you with that. Whenever programs need to perform actions that only the kernel can, they use System Calls. There are commands that let you trace the syscalls your program makes. In Linux there’s strace and macOS and BSD have dtrace. dtrace can be tricky to use because it uses its own D language, but there is a wrapper called dtruss that provides an interface more similar to strace (more details here).

Below are some examples of using strace or dtruss to show stat syscall traces for an execution of ls. For a deeper dive into strace, this is a good read.

# On Linux
sudo strace -e lstat ls -l > /dev/null
# On macOS
sudo dtruss -t lstat64_extended ls -l > /dev/null

Under some circumstances, you may need to look at the network packets to figure out the issue in your program. Tools like tcpdump and Wireshark are network packet analyzers that let you read the contents of network packets and filter them based on different criteria.

For web development, the Chrome/Firefox developer tools are quite handy. They feature a large number of tools, including:

Static Analysis

For some issues you do not need to run any code. For example, just by carefully looking at a piece of code you could realize that your loop variable is shadowing an already existing variable or function name; or that a program reads a variable before defining it. Here is where static analysis tools come into play. Static analysis programs take source code as input and analyze it using coding rules to reason about its correctness.

In the following Python snippet there are several mistakes. First, our loop variable foo shadows the previous definition of the function foo. We also wrote baz instead of bar in the last line, so the program will crash after completing the sleep call (which will take one minute).

import time

def foo():
    return 42

for foo in range(5):
bar = 1
bar *= 0.2

Static analysis tools can identify this kind of issues. When we run pyflakes on the code we get the errors related to both bugs. mypy is another tool that can detect type checking issues. Here, mypy will warn us that bar is initially an int and is then casted to a float. Again, note that all these issues were detected without having to run the code.

In the shell tools lecture we covered shellcheck, which is a similar tool for shell scripts.

$ pyflakes redefinition of unused 'foo' from line 3 undefined name 'baz'

$ mypy error: Incompatible types in assignment (expression has type "int", variable has type "Callable[[], Any]") error: Incompatible types in assignment (expression has type "float", variable has type "int") error: Name 'baz' is not defined
Found 3 errors in 1 file (checked 1 source file)

Most editors and IDEs support displaying the output of these tools within the editor itself, highlighting the locations of warnings and errors. This is often called code linting and it can also be used to display other types of issues such as stylistic violations or insecure constructs.

In vim, the plugins ale or syntastic will let you do that. For Python, pylint and pep8 are examples of stylistic linters and bandit is a tool designed to find common security issues. For other languages people have compiled comprehensive lists of useful static analysis tools, such as Awesome Static Analysis (you may want to take a look at the Writing section) and for linters there is Awesome Linters.

A complementary tool to stylistic linting are code formatters such as black for Python, gofmt for Go, rustfmt for Rust or prettier for JavaScript, HTML and CSS. These tools autoformat your code so that it’s consistent with common stylistic patterns for the given programming language. Although you might be unwilling to give stylistic control about your code, standardizing code format will help other people read your code and will make you better at reading other people’s (stylistically standardized) code.


Even if your code functionally behaves as you would expect, that might not be good enough if it takes all your CPU or memory in the process. Algorithms classes often teach big O notation but not how to find hot spots in your programs. Since premature optimization is the root of all evil, you should learn about profilers and monitoring tools. They will help you understand which parts of your program are taking most of the time and/or resources so you can focus on optimizing those parts.


Similarly to the debugging case, in many scenarios it can be enough to just print the time it took your code between two points. Here is an example in Python using the time module.

import time, random
n = random.randint(1, 10) * 100

# Get current time
start = time.time()

# Do some work
print("Sleeping for {} ms".format(n))

# Compute time between start and now
print(time.time() - start)

# Output
# Sleeping for 500 ms
# 0.5713930130004883

However, wall clock time can be misleading since your computer might be running other processes at the same time or waiting for events to happen. It is common for tools to make a distinction between Real, User and Sys time. In general, User + Sys tells you how much time your process actually spent in the CPU (more detailed explanation here).

For example, try running a command that performs an HTTP request and prefixing it with time. Under a slow connection you might get an output like the one below. Here it took over 2 seconds for the request to complete but the process only took 15ms of CPU user time and 12ms of kernel CPU time.

$ time curl &> /dev/null`
real    0m2.561s
user    0m0.015s
sys     0m0.012s



Most of the time when people refer to profilers they actually mean CPU profilers, which are the most common. There are two main types of CPU profilers: tracing and sampling profilers. Tracing profilers keep a record of every function call your program makes whereas sampling profilers probe your program periodically (commonly every millisecond) and record the program’s stack. They use these records to present aggregate statistics of what your program spent the most time doing. Here is a good intro article if you want more detail on this topic.

Most programming languages have some sort of command line profiler that you can use to analyze your code. They often integrate with full fledged IDEs but for this lecture we are going to focus on the command line tools themselves.

In Python we can use the cProfile module to profile time per function call. Here is a simple example that implements a rudimentary grep in Python:

#!/usr/bin/env python

import sys, re

def grep(pattern, file):
    with open(file, 'r') as f:
        for i, line in enumerate(f.readlines()):
            pattern = re.compile(pattern)
            match =
            if match is not None:
                print("{}: {}".format(i, line), end="")

if __name__ == '__main__':
    times = int(sys.argv[1])
    pattern = sys.argv[2]
    for i in range(times):
        for file in sys.argv[3:]:
            grep(pattern, file)

We can profile this code using the following command. Analyzing the output we can see that IO is taking most of the time and that compiling the regex takes a fair amount of time as well. Since the regex only needs to be compiled once, we can factor it out of the for.

$ python -m cProfile -s tottime 1000 '^(import|\s*def)[^,]*$' *.py

[omitted program output]

 ncalls  tottime  percall  cumtime  percall filename:lineno(function)
     8000    0.266    0.000    0.292    0.000 {built-in method}
     8000    0.153    0.000    0.894    0.000
    17000    0.101    0.000    0.101    0.000 {built-in method builtins.print}
     8000    0.100    0.000    0.129    0.000 {method 'readlines' of '_io._IOBase' objects}
    93000    0.097    0.000    0.111    0.000
    93000    0.069    0.000    0.069    0.000 {method 'search' of '_sre.SRE_Pattern' objects}
    93000    0.030    0.000    0.141    0.000
    17000    0.019    0.000    0.029    0.000
        1    0.017    0.017    0.911    0.911<module>)

[omitted lines]

A caveat of Python’s cProfile profiler (and many profilers for that matter) is that they display time per function call. That can become unintuitive really fast, specially if you are using third party libraries in your code since internal function calls are also accounted for. A more intuitive way of displaying profiling information is to include the time taken per line of code, which is what line profilers do.

For instance, the following piece of Python code performs a request to the class website and parses the response to get all URLs in the page:

#!/usr/bin/env python
import requests
from bs4 import BeautifulSoup

# This is a decorator that tells line_profiler
# that we want to analyze this function
def get_urls():
    response = requests.get('')
    s = BeautifulSoup(response.content, 'lxml')
    urls = []
    for url in s.find_all('a'):

if __name__ == '__main__':

If we used Python’s cProfile profiler we’d get over 2500 lines of output, and even with sorting it’d be hard to understand where the time is being spent. A quick run with line_profiler shows the time taken per line:

$ kernprof -l -v
Wrote profile results to
Timer unit: 1e-06 s

Total time: 0.636188 s
Function: get_urls at line 5

Line #  Hits         Time  Per Hit   % Time  Line Contents
 5                                           @profile
 6                                           def get_urls():
 7         1     613909.0 613909.0     96.5      response = requests.get('')
 8         1      21559.0  21559.0      3.4      s = BeautifulSoup(response.content, 'lxml')
 9         1          2.0      2.0      0.0      urls = []
10        25        685.0     27.4      0.1      for url in s.find_all('a'):
11        24         33.0      1.4      0.0          urls.append(url['href'])


In languages like C or C++ memory leaks can cause your program to never release memory that it doesn’t need anymore. To help in the process of memory debugging you can use tools like Valgrind that will help you identify memory leaks.

In garbage collected languages like Python it is still useful to use a memory profiler because as long as you have pointers to objects in memory they won’t be garbage collected. Here’s an example program and its associated output when running it with memory-profiler (note the decorator like in line-profiler).

def my_func():
    a = [1] * (10 ** 6)
    b = [2] * (2 * 10 ** 7)
    del b
    return a

if __name__ == '__main__':
$ python -m memory_profiler
Line #    Mem usage  Increment   Line Contents
     3                           @profile
     4      5.97 MB    0.00 MB   def my_func():
     5     13.61 MB    7.64 MB       a = [1] * (10 ** 6)
     6    166.20 MB  152.59 MB       b = [2] * (2 * 10 ** 7)
     7     13.61 MB -152.59 MB       del b
     8     13.61 MB    0.00 MB       return a

Event Profiling

As it was the case for strace for debugging, you might want to ignore the specifics of the code that you are running and treat it like a black box when profiling. The perf command abstracts CPU differences away and does not report time or memory, but instead it reports system events related to your programs. For example, perf can easily report poor cache locality, high amounts of page faults or livelocks. Here is an overview of the command:


Profiler output for real world programs will contain large amounts of information because of the inherent complexity of software projects. Humans are visual creatures and are quite terrible at reading large amounts of numbers and making sense of them. Thus there are many tools for displaying profiler’s output in an easier to parse way.

One common way to display CPU profiling information for sampling profilers is to use a Flame Graph, which will display a hierarchy of function calls across the Y axis and time taken proportional to the X axis. They are also interactive, letting you zoom into specific parts of the program and get their stack traces (try clicking in the image below).


Call graphs or control flow graphs display the relationships between subroutines within a program by including functions as nodes and functions calls between them as directed edges. When coupled with profiling information such as the number of calls and time taken, call graphs can be quite useful for interpreting the flow of a program. In Python you can use the pycallgraph library to generate them.

Call Graph

Resource Monitoring

Sometimes, the first step towards analyzing the performance of your program is to understand what its actual resource consumption is. Programs often run slowly when they are resource constrained, e.g. without enough memory or on a slow network connection. There are a myriad of command line tools for probing and displaying different system resources like CPU usage, memory usage, network, disk usage and so on.

If you want to test these tools you can also artificially impose loads on the machine using the stress command.

Specialized tools

Sometimes, black box benchmarking is all you need to determine what software to use. Tools like hyperfine let you quickly benchmark command line programs. For instance, in the shell tools and scripting lecture we recommended fd over find. We can use hyperfine to compare them in tasks we run often. E.g. in the example below fd was 20x faster than find in my machine.

$ hyperfine --warmup 3 'fd -e jpg' 'find . -iname "*.jpg"'
Benchmark #1: fd -e jpg
  Time (mean ± σ):      51.4 ms ±   2.9 ms    [User: 121.0 ms, System: 160.5 ms]
  Range (min … max):    44.2 ms …  60.1 ms    56 runs

Benchmark #2: find . -iname "*.jpg"
  Time (mean ± σ):      1.126 s ±  0.101 s    [User: 141.1 ms, System: 956.1 ms]
  Range (min … max):    0.975 s …  1.287 s    10 runs

  'fd -e jpg' ran
   21.89 ± 2.33 times faster than 'find . -iname "*.jpg"'

As it was the case for debugging, browsers also come with a fantastic set of tools for profiling webpage loading, letting you figure out where time is being spent (loading, rendering, scripting, &c). More info for Firefox and Chrome.



  1. Use journalctl on Linux or log show on macOS to get the super user accesses and commands in the last day. If there aren’t any you can execute some harmless commands such as sudo ls and check again.

  2. Do this hands on pdb tutorial to familiarize yourself with the commands. For a more in depth tutorial read this.

  3. Install shellcheck and try checking the following script. What is wrong with the code? Fix it. Install a linter plugin in your editor so you can get your warnings automatically.

    ## Example: a typical script with several problems
    for f in $(ls *.m3u)
      grep -qi hq.*mp3 $f \
        && echo -e 'Playlist $f contains a HQ file in mp3 format'
  4. (Advanced) Read about reversible debugging and get a simple example working using rr or RevPDB.


  5. Here are some sorting algorithm implementations. Use cProfile and line_profiler to compare the runtime of insertion sort and quicksort. What is the bottleneck of each algorithm? Use then memory_profiler to check the memory consumption, why is insertion sort better? Check now the inplace version of quicksort. Challenge: Use perf to look at the cycle counts and cache hits and misses of each algorithm.

  6. Here’s some (arguably convoluted) Python code for computing Fibonacci numbers using a function for each number.

    #!/usr/bin/env python
    def fib0(): return 0
    def fib1(): return 1
    s = """def fib{}(): return fib{}() + fib{}()"""
    if __name__ == '__main__':
        for n in range(2, 10):
            exec(s.format(n, n-1, n-2))
        # from functools import lru_cache
        # for n in range(10):
        #     exec("fib{} = lru_cache(1)(fib{})".format(n, n))

    Put the code into a file and make it executable. Install pycallgraph. Run the code as is with pycallgraph graphviz -- ./ and check the pycallgraph.png file. How many times is fib0 called?. We can do better than that by memoizing the functions. Uncomment the commented lines and regenerate the images. How many times are we calling each fibN function now?

  7. A common issue is that a port you want to listen on is already taken by another process. Let’s learn how to discover that process pid. First execute python -m http.server 4444 to start a minimal web server listening on port 4444. On a separate terminal run lsof | grep LISTEN to print all listening processes and ports. Find that process pid and terminate it by running kill <PID>.

  8. Limiting processes resources can be another handy tool in your toolbox. Try running stress -c 3 and visualize the CPU consumption with htop. Now, execute taskset --cpu-list 0,2 stress -c 3 and visualize it. Is stress taking three CPUs? Why not? Read man taskset. Challenge: achieve the same using cgroups. Try limiting the memory consumption of stress -m.

  9. (Advanced) The command curl performs a HTTP request an fetches information about your public IP. Open Wireshark and try to sniff the request and reply packets that curl sent and received. (Hint: Use the http filter to just watch HTTP packets).

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