But then I wanted a filter with both an if-action, and an else-action. Worse, I wanted if-A, then do this, if-B, do this, else, do that. GMail filters just aren’t constructed that way. It was going to be a pain to set them up and maintain them.

Looking around for tools, I found gmail-britta, a Ruby DSL. This was the right kind of tool for me, except I don’t write Ruby. I hadn’t found gmail-yaml-filters, but I don’t think I want to write YAML.

gmail-tools looked promising, but my work GMail account wouldn’t let me follow its authentication steps. Honestly, I often run afoul of authentication when trying to use APIs. (See Support windows bar calendar for another project I built in a strange way specifically to avoid having to figure out authentication.)

So naturally, I built my own module to do it: Gefilte Fish is a Python DSL (domain-specific language) of sorts to create GMail filters. (The name is fitting since this is the start of Passover.) Using gefilte, you write Python code to express your filters. Running your program outputs XML that you then import into GMail to create the filters.

The DSL lets you write this to make filters:

from gefilte import GefilteFish

# Make the filter-maker and use its DSL. All of the methods of GitHubFilter
# are now usable as global functions.
fish = GefilteFish()
with fish.dsl():

    # Google's spam moderation messages should never get sent to spam.
    with replyto("noreply-spamdigest@google.com"):
        never_spam()
        mark_important()

    # If the subject and body have these, label it "liked".
    with subject(exact("[Confluence]")).has(exact("liked this page")):
        label("liked")

    with from_("notifications@github.com"):
        # Skip the inbox (archive them).
        skip_inbox().label("github")

        # Delete annoying bot messages.
        with from_("renovate[bot]"):
            delete()

        # GitHub sends to synthetic addresses to provide information.
        with to("author@noreply.github.com"):
            label("mine").star()

        # Notifications from some repos are special.
        with repo("myproject/tasks") as f:
            label("todo")
            with f.elif_(repo("otherproject/something")) as f:
                label("otherproject")
                with f.else_():
                    # But everything else goes into "Code reviews".
                    label("Code reviews")

    # Some inbound addresses come to me, mark them so
    # I understand what I'm # looking at in my inbox.
    for toaddr, the_label in [
        ("info@mycompany.com", "info@"),
        ("security@mycompany.com", "security@"),
        ("con2020@mycompany.com", "con20"),
        ("con2021@mycompany.com", "con21"),
    ]:
        with to(toaddr):
            label(the_label)

print(fish.xml())


To make the DSL flow somewhat naturally, I definitely bent the rules on what is considered good Python. But it let me write succinct descriptions of the filters I want, while still having the power of a programming language.

Here’s what happened: I added a new parameterized test to the coverage.py test suite. It was really slow, so I ran it with timings displayed:

$ tox -qe py39 -- -n 0 -k virtualenv --durations=0 -vvv
... output omitted ...
========================= slowest test durations ==========================
7.14s call     tests/test_process.py::VirtualenvTest::test_making_virtualenv[False]
6.23s call     tests/test_process.py::VirtualenvTest::test_making_virtualenv[True]
0.47s setup    tests/test_process.py::VirtualenvTest::test_making_virtualenv[False]
0.01s setup    tests/test_process.py::VirtualenvTest::test_making_virtualenv[True]
0.01s setup    tests/test_process.py::VirtualenvTest::test_making_virtualenv[False]
0.01s setup    tests/test_process.py::VirtualenvTest::test_making_virtualenv[True]
0.00s teardown tests/test_process.py::VirtualenvTest::test_making_virtualenv[True]
0.00s teardown tests/test_process.py::VirtualenvTest::test_making_virtualenv[True]
0.00s teardown tests/test_process.py::VirtualenvTest::test_making_virtualenv[False]
0.00s teardown tests/test_process.py::VirtualenvTest::test_making_virtualenv[False]
========================= short test summary info =========================
FAILED tests/test_process.py::VirtualenvTest::test_making_virtualenv[False] ...
FAILED tests/test_process.py::VirtualenvTest::test_making_virtualenv[True] ...


Huh, that’s weird: two tests (“call”), but four invocations of my test setup function, and four to the teardown. I’ve only just recently converted this test suite over from a unittest.TestCase foundation, and I have some odd shims in place to reduce the code churn. Thinking about the double-setup, I thought either my shims were wrong, or I was in some strange edge case in how pytest runs tests.

But how to figure out why the setup is called twice for each test run? I decided to use a tool I’ve reached for often in the past: capture the stack information and record it someplace:

def setup_test(self):
    import inspect
    project_home = "/Users/ned/coverage"
    site_packages = ".tox/py39/lib/python3.9/site-packages/"
    with open("/tmp/foo.txt", "a") as foo:
        print("setup_test", file=foo)
        for t in inspect.stack()[::-1]:
            # t is (frame, filename, lineno, function, code_context, index)
            frame, filename, lineno, function = t[:4]
            filename = os.path.relpath(filename, project_home)
            filename = filename.replace(site_packages, "")
            show = "%30s : %s:%d" % (function, filename, lineno)
            print(show, file=foo)


This is my test setup function which is being called too often. I used a low-tech logging technique: append to a temporary file. For each frame in the call stack, I write the function name and where it’s defined. The file paths are long and repetitive, so I make them relative to the project home, and also get rid of the site-packages path I’ll be using.

This works, it gave me four stack traces, one for each setup call. But all four were identical:

setup_test
                      <module> : igor.py:424
                          main : igor.py:416
           do_test_with_tracer : igor.py:216
                     run_tests : igor.py:133
                          main : _pytest/config/__init__.py:84
                      __call__ : pluggy/hooks.py:286
                     _hookexec : pluggy/manager.py:93
                      <lambda> : pluggy/manager.py:84
                    _multicall : pluggy/callers.py:187
           pytest_cmdline_main : _pytest/main.py:243
                  wrap_session : _pytest/main.py:206
                         _main : _pytest/main.py:250
                      __call__ : pluggy/hooks.py:286
                     _hookexec : pluggy/manager.py:93
                      <lambda> : pluggy/manager.py:84
                    _multicall : pluggy/callers.py:187
            pytest_runtestloop : _pytest/main.py:271
                      __call__ : pluggy/hooks.py:286
                     _hookexec : pluggy/manager.py:93
                      <lambda> : pluggy/manager.py:84
                    _multicall : pluggy/callers.py:187
       pytest_runtest_protocol : flaky/flaky_pytest_plugin.py:94
       pytest_runtest_protocol : _pytest/runner.py:78
               runtestprotocol : _pytest/runner.py:87
               call_and_report : flaky/flaky_pytest_plugin.py:138
             call_runtest_hook : _pytest/runner.py:197
                     from_call : _pytest/runner.py:226
                      <lambda> : _pytest/runner.py:198
                      __call__ : pluggy/hooks.py:286
                     _hookexec : pluggy/manager.py:93
                      <lambda> : pluggy/manager.py:84
                    _multicall : pluggy/callers.py:187
          pytest_runtest_setup : _pytest/runner.py:116
                       prepare : _pytest/runner.py:362
                         setup : _pytest/python.py:1468
                  fillfixtures : _pytest/fixtures.py:296
                 _fillfixtures : _pytest/fixtures.py:469
               getfixturevalue : _pytest/fixtures.py:479
        _get_active_fixturedef : _pytest/fixtures.py:502
        _compute_fixture_value : _pytest/fixtures.py:587
                       execute : _pytest/fixtures.py:894
                      __call__ : pluggy/hooks.py:286
                     _hookexec : pluggy/manager.py:93
                      <lambda> : pluggy/manager.py:84
                    _multicall : pluggy/callers.py:187
          pytest_fixture_setup : _pytest/fixtures.py:936
             call_fixture_func : _pytest/fixtures.py:795
             connect_to_pytest : tests/mixins.py:33
                    setup_test : tests/test_process.py:1651


I had hoped that perhaps the first and second calls would have slightly different stack traces, and the difference would point me to the reasons for the multiple calls. Since the stacks were the same, there must be loops involved somewhere. How to find where in the stack they were?

If I were familiar with the code in question, reading one stack trace might point me to the right place. But pytest is opaque to me, and I didn’t want to start digging in. I’ve got a few different pytest features at play here, so it seemed like it was going to be difficult.

The stack traces were the same, because they only show the static aspects of the calls: who calls who, from where. But the stacks differ in the specific instances of the calls to the functions. The very top frame is the same (there’s only one execution of the main program), and the very bottom frame is different (there are four executions of my test setup function). If we find the highest frame that differs between two stacks, then we know which the loop is calling the setup function twice.

My first thought was to show the id of the frame objects, but ids get reused as objects are reused from free-lists. Instead, why not just tag them explicitly? Every frame has its own set of local variables, stored in a dictionary attached to the frame. I write an integer into each frame, which is the number of times we’ve seen that frame.

Now the loop over frames also checks the locals of each frame. If our visit count isn’t there, initialize it to zero, and if it is there, increment it. The visit count is added to the stack display, and we’re good to go:

def setup_test(self):
    import inspect
    project_home = "/Users/ned/coverage"
    site_packages = ".tox/py39/lib/python3.9/site-packages/"
    with open("/tmp/foo.txt", "a") as foo:
        print("setup_test", file=foo)
        for t in inspect.stack()[::-1]:
            # t is (frame, filename, lineno, function, code_context, index)
            frame, filename, lineno, function = t[:4]
            visits = frame.f_locals.get("$visits", 0)       ## new
            frame.f_locals["$visits"] = visits + 1          ## new
            filename = os.path.relpath(filename, project_home)
            filename = filename.replace(site_packages, "")
            show = "%30s :  %d  %s:%d" % (function, visits, filename, lineno)
            print(show, file=foo)


Now the stacks are still the same, except the visit counts differ. Here’s the stack from the second call to the test setup:

setup_test
                      <module> :  1  igor.py:424
                          main :  1  igor.py:416
           do_test_with_tracer :  1  igor.py:216
                     run_tests :  1  igor.py:133
                          main :  1  _pytest/config/__init__.py:84
                      __call__ :  1  pluggy/hooks.py:286
                     _hookexec :  1  pluggy/manager.py:93
                      <lambda> :  1  pluggy/manager.py:84
                    _multicall :  1  pluggy/callers.py:187
           pytest_cmdline_main :  1  _pytest/main.py:243
                  wrap_session :  1  _pytest/main.py:206
                         _main :  1  _pytest/main.py:250
                      __call__ :  1  pluggy/hooks.py:286
                     _hookexec :  1  pluggy/manager.py:93
                      <lambda> :  1  pluggy/manager.py:84
                    _multicall :  1  pluggy/callers.py:187
            pytest_runtestloop :  1  _pytest/main.py:271
                      __call__ :  1  pluggy/hooks.py:286
                     _hookexec :  1  pluggy/manager.py:93
                      <lambda> :  1  pluggy/manager.py:84
                    _multicall :  1  pluggy/callers.py:187
       pytest_runtest_protocol :  1  flaky/flaky_pytest_plugin.py:94
       pytest_runtest_protocol :  0  _pytest/runner.py:78
               runtestprotocol :  0  _pytest/runner.py:87
               call_and_report :  0  flaky/flaky_pytest_plugin.py:138
             call_runtest_hook :  0  _pytest/runner.py:197
                     from_call :  0  _pytest/runner.py:226
                      <lambda> :  0  _pytest/runner.py:198
                      __call__ :  0  pluggy/hooks.py:286
                     _hookexec :  0  pluggy/manager.py:93
                      <lambda> :  0  pluggy/manager.py:84
                    _multicall :  0  pluggy/callers.py:187
          pytest_runtest_setup :  0  _pytest/runner.py:116
                       prepare :  0  _pytest/runner.py:362
                         setup :  0  _pytest/python.py:1468
                  fillfixtures :  0  _pytest/fixtures.py:296
                 _fillfixtures :  0  _pytest/fixtures.py:469
               getfixturevalue :  0  _pytest/fixtures.py:479
        _get_active_fixturedef :  0  _pytest/fixtures.py:502
        _compute_fixture_value :  0  _pytest/fixtures.py:587
                       execute :  0  _pytest/fixtures.py:894
                      __call__ :  0  pluggy/hooks.py:286
                     _hookexec :  0  pluggy/manager.py:93
                      <lambda> :  0  pluggy/manager.py:84
                    _multicall :  0  pluggy/callers.py:187
          pytest_fixture_setup :  0  _pytest/fixtures.py:936
             call_fixture_func :  0  _pytest/fixtures.py:795
             connect_to_pytest :  0  tests/mixins.py:33
                    setup_test :  0  tests/test_process.py:1651


The 1’s are frames that were the same from the first call to the second, and the 0’s are new frames. We can clearly see that flaky_pytest_plugin.py has the loop that calls the setup a second time.

Typical: once you know the answer, it’s obvious! I use the pytest-flaky plugin to automatically retry tests that fail. My new slow test isn’t just slow, it’s also a failing test (for now). So pytest-flaky is running it again.

The real mystery isn’t why the setup is called twice, but why the actual run of the test is only reported once. I checked: it’s not just the setup that runs twice, the body of the test is also running twice.

When I made the test pass, the double execution went away, because pytest-flaky wasn’t re-running the failed test.

This is a classic machete-mode debugging story: the problem was easier to dissect with dynamic tools rather than static; I hacked in some gross code to get me the information I needed; I didn’t know if it would work well, but it did.

BTW, it seems a bit presumptuous to promote this column of numbers to a “visualization,” but it is a good way to see the looping nature of the test runner. Here’s the fourth call stack:

setup_test
                      <module> :  3  igor.py:424
                          main :  3  igor.py:416
           do_test_with_tracer :  3  igor.py:216
                     run_tests :  3  igor.py:133
                          main :  3  _pytest/config/__init__.py:84
                      __call__ :  3  pluggy/hooks.py:286
                     _hookexec :  3  pluggy/manager.py:93
                      <lambda> :  3  pluggy/manager.py:84
                    _multicall :  3  pluggy/callers.py:187
           pytest_cmdline_main :  3  _pytest/main.py:243
                  wrap_session :  3  _pytest/main.py:206
                         _main :  3  _pytest/main.py:250
                      __call__ :  3  pluggy/hooks.py:286
                     _hookexec :  3  pluggy/manager.py:93
                      <lambda> :  3  pluggy/manager.py:84
                    _multicall :  3  pluggy/callers.py:187
            pytest_runtestloop :  3  _pytest/main.py:271
                      __call__ :  1  pluggy/hooks.py:286
                     _hookexec :  1  pluggy/manager.py:93
                      <lambda> :  1  pluggy/manager.py:84
                    _multicall :  1  pluggy/callers.py:187
       pytest_runtest_protocol :  1  flaky/flaky_pytest_plugin.py:94
       pytest_runtest_protocol :  0  _pytest/runner.py:78
               runtestprotocol :  0  _pytest/runner.py:87
               call_and_report :  0  flaky/flaky_pytest_plugin.py:138
             call_runtest_hook :  0  _pytest/runner.py:197
                     from_call :  0  _pytest/runner.py:226
                      <lambda> :  0  _pytest/runner.py:198
                      __call__ :  0  pluggy/hooks.py:286
                     _hookexec :  0  pluggy/manager.py:93
                      <lambda> :  0  pluggy/manager.py:84
                    _multicall :  0  pluggy/callers.py:187
          pytest_runtest_setup :  0  _pytest/runner.py:116
                       prepare :  0  _pytest/runner.py:362
                         setup :  0  _pytest/python.py:1468
                  fillfixtures :  0  _pytest/fixtures.py:296
                 _fillfixtures :  0  _pytest/fixtures.py:469
               getfixturevalue :  0  _pytest/fixtures.py:479
        _get_active_fixturedef :  0  _pytest/fixtures.py:502
        _compute_fixture_value :  0  _pytest/fixtures.py:587
                       execute :  0  _pytest/fixtures.py:894
                      __call__ :  0  pluggy/hooks.py:286
                     _hookexec :  0  pluggy/manager.py:93
                      <lambda> :  0  pluggy/manager.py:84
                    _multicall :  0  pluggy/callers.py:187
          pytest_fixture_setup :  0  _pytest/fixtures.py:936
             call_fixture_func :  0  _pytest/fixtures.py:795
             connect_to_pytest :  0  tests/mixins.py:33
                    setup_test :  0  tests/test_process.py:1651


The 3’s change to 1’s at _pytest/main.py:271, which is the loop over the tests to run. Cool :)

I help organize Boston Python. It’s a great group. We’ve been active during the pandemic, in fact, we’ve added new kinds of events during this time.

One of the things we’re trying to get started is a Study Group based on the observation that teaching is a great way to learn. The idea is to form a small but dedicated group of beginner-to-intermediate learners. They would take turns tackling a topic and presenting it informally to the group.

Here’s the problem: how do you make a space that feels right for beginners when you have thousands of experts in the group who also want to join in?

Beginners:

• Beginners can be shy and uncertain, both about the topic and about whether this space is even for them.
• They don’t want to appear dumb. They are afraid they will look foolish, or will be ridiculed.
• They don’t know that everyone has uncertainties and gaps in their knowledge. They don’t know that not knowing something is inevitable, and can be conquered.

Experts:

• Experts want to help. They have knowledge and want to share it.
• Can forget how hard it is to be a beginner.
• Experts can be blind to how their speaking is keeping other people quiet. There’s limited space for talking, but more importantly, expert-level speaking can set the tone that you must be expert-level to speak.

Experts are very good at occupying these spaces. They are comfortable speaking, and eager to share their knowledge. How do we ensure that they don’t monopolize the discussion?

Beginners can be shy, and reluctant to speak. They may feel like they don’t know enough to even ask a question. They don’t want to appear dumb. They hear the experts around them, and feel even more certain that this is not for them.

The experts could have the best intentions: they want to help the beginners. They are interested in the subject, and have useful bits of information to contribute.

I’m looking for ideas to solve these problems!

How to keep the balance of attendees right:

• Explicitly label the event as “for beginning to intermediate learners.”
• Send a reminder email about the event, asking people to select themselves out of the event: “We’re really excited that this idea has gotten so much interest. Our goal was to have a smaller conversational group for beginning learners. If that doesn’t sound like you, now is a good opportunity to step back to make space for others.”
• Have other events labelled for experts so they have a space of their own.
• Invite specific people one-on-one to increase the number of “right” people.
• more ideas?

How to encourage beginners to join the group:

• Use lots of words to underscore the welcoming nature of the group, and that beginners are welcome.
• Invite specific people one-on-one so they feel sure it’s for them, and that they are wanted.
• more ideas?

How to encourage beginners to speak in the group:

• Ice-breaker question
• Set an expectation that everyone will ask at least one question.
• Be especially supportive when someone asks a really basic question.
• Contact them individually to ask if they have anything they want to ask, and help them get it asked.
• more ideas?

How to encourage beginners to lead a session:

• Demonstrate vulnerability while leading.
• Offer to pair with them instead of having them do it alone.
• more ideas?

Like I said, I’m looking for ideas. The more I run events, the more interested I am in helping beginners get started.

Planning

Each walk is kept in a GPX file. I can get a picture of where we’ve been on previous walks by looking at them as a collection. Dérive is a simple elegant site that will map a set of GPX files dropped onto it. It’s open-source, and they even implemented a feature request I made.

To plan the walks, I originally used gmap-pedometer.com, but now I use On The Go Map. Both will create a route between two points automatically. On The Go has a big clean layout, and I can tweak the plan by dragging new points in the middle of the route as needed. Gmap-pedometer has more options for map sources, but I found On The Go was better at knowing where I could walk, and making correct routes automatically.

It helps to have a good planning tool because I want to get the right distance, not too short and not too long. I also want to include new streets we haven’t visited before.

I use Google Street View to take a look at spots I’m uncertain about. Is that a street or driveway? Can you get from the end of that street into the park next to it?

Walking

Before heading out, I print the map, on paper! It’s easier than fiddling with the phone, and I can draw on it if we go off-plan or if I want to make a note of something we saw along the way.

I use my phone to figure out where I am when I am uncertain, and I have a link to a large map of all of our previous walks if I want to consider an ad-hoc addition.

There might be apps that can track my walk automatically. I’ve used some in the past that captured an approximation, so I would rather map them myself.

Recording

Back home after the walk, I can use the route from On The Go Map, or re-plot it if needed. On The Go gives me the GPX file to add to my collection, and gives me the distance walked for my stats spreadsheet.

When I want to know more about the history of the place we’ve been, I use Mapjunction. It’s a great dual-view of two maps at once, of your choice. For example, you can look at the current streets and the same region 100 years ago to understand how things have changed.

To produce the animated GIF in the last post, I cobbled together a program using a bunch of tools I didn’t fully understand! The result is gpxmapper. It uses Fiona to read the GPX files, Shapely to compute and plot the geometries, and Cartopy to draw the maps. This was definitely a copy-paste patchwork, so don’t take it as the work of an expert. It works, but I can’t promise it does it the best way.

I got some inspiration and headstart from a recent Boston Python presentation: On Python and Positioning: An Introduction to Working with Geospatial Data in Python with GeoPandas by Heather Kusmierz.

The program writes out a pile of PNG files, then uses ImageMagick and Gifsicle to wrangle them into a good animated GIF. A large static version of the total walks is posted online for me to refer to in the field if needed.

•    •    •

Some of this might surprise you as low-tech. For a software engineer, I tend toward low-tech. And as I mentioned in the last post, this whole walking endeavor has given me a much deeper understanding of the neighborhoods around me. Working with the maps to plan and record the walks is part of that process, so I’m not looking to make it more automated.

That said, if you have suggestions, I’m interested to learn!

Nat and I have also been doing a lot of what we’ve always done together: walking. We both need exercise and a change of perspective, and Susan needs some time without expectations.

So we walk most mornings, whenever the weather and our schedules allow. Our distance has gradually increased, up to about six miles each day.

We’ve been walking since the pandemic started in March, but I only thought to start tracking and mapping the walks at the end of April. To keep it interesting, I’ve planned routes to take us down new streets every day, with the goal of visiting “every” street, whatever that means.

Here are our 191 walks totalling 1025 miles (so far!):

Part of the fun of this has been learning more about mapping tools, but I’ll save those details for another blog post. (Now at Mapping walks.)

I’ve really liked seeing places close to home that I have never been to, neighborhoods within walking distance I never had a reason to visit. I’m lucky to live in a varied area: to the west are some of the most expensive properties in Massachusetts, to the east are true urban areas, north-east is an upscale shopping district, south is expansive park land.

Because this is Boston, there’s plenty of history. Here are a few tidbits I discovered along the way:

• The Longyear mansion, a 64-room stone mansion dismantled in Michigan and reconstructed as a 100-room mansion in Brookline.
• The Roxbury parting stone, a 1744 directional marker.
• Boston Zoo’s Abandoned bear cages.

While walking I listen to lots of podcasts, since Nat is not big on talking. I try to keep alert for interesting sights, even if they are not History. Some of those go on my Instagram.

I watched The World Before Your Feet, a documentary about Matt Green walking all 8000 miles of the streets of New York City. Parts of his effort were familiar to me, but there were differences. Of course, the scale of the undertaking. But also, my walks always begin and end at our house, so there is a lot of repeated ground. Nat wants to walk fast, and we have Zoom calls to get back to, so leisurely chats with storekeepers are not an option. I envy Matt’s ability to stop and really look at things in depth.

But even so, walking these neighborhoods has given me a shift in perspective. You can notice things while walking that you’d never see while driving. I find now that even when I drive through these neighborhoods, I see things more as a walker would. Will that wear off once we go back to being more car-centric? Or will all this street-level familiarity stick with me?

People talk about the silver linings of the pandemic. For me, these walks, the things I’ve discovered, my different relationship to the neighborhoods, and the routine with Nat, have been a definite silver lining. I’m not sure what of these walks will persist beyond the pandemic. I hope some of it does.

Her latest video, Perspective Juggling, is eye-opening. It’s filmed from above, presenting a fresh view of the juggling. This makes some of the tricks more understandable by seeing the hands move more while the balls seem to move less. Other tricks somehow seem more mysterious. All of them are fluid and mesmerizing.

Take a look:

As a juggler, the only improvement I would make would be to flip it around so that her hands reach up toward the top, to be more like a first-person view.

Each harmonograph is determined by a few dozen parameter values, which are chosen randomly. The number of parameters depends on the number of pendulums, which defaults to 3.

Click a thumbnail to see a larger version. The large-image pages have thumbnails of “adjacent” images. Each harmonograph is determined by a few dozen parameter values. For each parameter, four nearby values are substituted, giving four thumbnails for each parameter. Clicking an adjacent thumbnail continues your exploration of the parameter space:

The settings dialog lets you adjust the number of pendulums (which determines the number of parameters) and the kinds of symmetry you are interested in.

I started this because I wanted to understand how the parameters affected the outcome, but I was also interested to give it a purely visual design. As an engineer, it was tempting to present the values of the parameters quantitatively, but I like the simplicity of just clicking curves you like.

I repeated a trick I’ve used in other mathy visual toys: when you download a PNG file of an image, the parameter values are stored in a data island in the file. You can re-upload the image, and Flourish will extract the parameters and put you back into the parameter-space exploration at that point.

This is one of those side projects that let me use different sorts of things than I usually do: numpy, SVG, sass, Docker, and so on. I had more ideas for things to add (there is color in the code but not the UI). Maybe someday I will build them.

BTW, I am happy that my first post of 2021 is called “Flourish.” I hope it is a harbinger of things to come.

The misconception starts because git presents commits as diffs, and lets you manipulate them (rebase, cherry-pick, etc) as if they were diffs. But internally, git commits are not diffs, they are complete copies of the file at each revision that changes the file.

At first glance, this seems dumb: why store the whole file over again just because one line changed? The reason is speed and immutability. If git stored each commit as a diff against the previous version (as RCS did), then getting the latest version of a file would require replaying all the diffs against the very first version of the file, getting slower and slower as the repo accumulated more commits. This means the most common checkout would get worse and worse over time.

If git stored the latest version of a file, and diffs going backward in time (as Subversion does), then getting older versions would get slower and slower, which isn’t so bad. But it would require re-writing the previous commit each time a new commit was made. This would ruin git’s hash-based immutability.

So, surprisingly, git stores the full contents of the file each time the file changes. I wanted to see this for myself, so I did an experiment.

First, make a new git repo:

$ mkdir gitsize
$ cd gitsize
$ git init
Initialized empty Git repository in /tmp/gitsize/.git/


I used a Python program (makebig.py) to create large files with repeatably random contents and one changeable word in the middle:

# Make a 1Mb randomish file, repeatably

import random, sys

random.seed(int(sys.argv[1]))

for lineno in range(2048):
    if lineno == 1000:
        print(sys.argv[2])
    print("".join(chr(random.randint(32, 126)) for _ in range(512)))


Let’s make a big file with “one” in the middle, and commit it:

$ python /tmp/makebig.py 1 one > one.txt
$ ls -lh
total 2136
-rw-r--r--  1 ned  wheel   1.0M Dec 19 11:13 one.txt
$ git add one.txt
$ git commit -m "One"
[master (root-commit) 8fceff3] One
 1 file changed, 2049 insertions(+)
 create mode 100644 one.txt


Git stores everything in the .git directory, with the file contents in the .git/objects directory:

$ ls -Rlh .git/objects/*
.git/objects/13:
total 1720
-r--r--r--  1 ned  wheel   859K Dec 19 11:14 b581d8695866f880eac2fef47c2594bbebbb3b

.git/objects/7d:
total 8
-r--r--r--  1 ned  wheel    52B Dec 19 11:14 32a67a911e8a04ad1703712481afe93b00c7af

.git/objects/8f:
total 8
-r--r--r--  1 ned  wheel   127B Dec 19 11:14 ceff3e3926764197742b01639a42765e34cd72

.git/objects/info:

.git/objects/pack:


Git stores three kinds of things: blobs, trees, and commits. We now have one of each. Blobs store the file contents. You can see the b581d8 blob is 859Kb, which is our 1Mb file with a little compression applied.

Now we change the file just a little bit by writing it over again with a different word in the middle:

$ python /tmp/makebig.py 1 one-changed > one.txt
$ git diff
diff --git a/one.txt b/one.txt
index 13b581d..b13026a 100644
--- a/one.txt
+++ b/one.txt
@@ -998,7 +998,7 @@ wLh&#DvF%em\Bb}^Y<gk?5vR8npq{ ~".][T|@.At@~fGYf<0/=cth`e}/}='qBFb&FP?+ENmAA:_g+0
 u$d|\v=y$oi@\, (o`=a49|!r\LL^B:y.f)*@5^bR\,Ck=i (.. snipped)
 lbY#m++>32X>^gh\/q34})uxZ"e/p;Ybb9\k,UTLPb*?3l7 (.. snipped)
 B11\\!x]jM9m't"KD%|,&r(lfh%vfT}~{jOQYBb?|TZ(<<R (.. snipped)
-one
+one-changed
 >Mu2P-/=8Z+A&"#@'"8*~fb]kkn;>}Ie.)wGjjHsbO5Nw]" (.. snipped)
 Vl {Q)k|{E!vF*@S')U5bK3u1fInN*ZrIe{-qXW}Fr`6*#N (.. snipped)
 3lF#jR!"JxXjAvih 4I6E\W:Y.*}b@eZ8xl-"*c/!pe"$Mx (.. snipped)


Commit the change, and we can look again at the .git storage:

$ git commit -am "One, changed"
[master a2410c8] One, changed
 1 file changed, 1 insertion(+), 1 deletion(-)
$ ls -Rlh .git/objects/*
.git/objects/0e:
total 8
-r--r--r--  1 ned  wheel    52B Dec 19 11:22 2de9f34b9140c3e99c5d5106a1078d22aa9063

.git/objects/13:
total 1720
-r--r--r--  1 ned  wheel   859K Dec 19 11:14 b581d8695866f880eac2fef47c2594bbebbb3b

.git/objects/7d:
total 8
-r--r--r--  1 ned  wheel    52B Dec 19 11:14 32a67a911e8a04ad1703712481afe93b00c7af

.git/objects/8f:
total 8
-r--r--r--  1 ned  wheel   127B Dec 19 11:14 ceff3e3926764197742b01639a42765e34cd72

.git/objects/a2:
total 8
-r--r--r--  1 ned  wheel   163B Dec 19 11:22 410c8b799b7829e1360649011754739e0a5c50

.git/objects/b1:
total 1720
-r--r--r--  1 ned  wheel   859K Dec 19 11:22 3026a4c10928821aa2b89b3e67d766dfbd533a

.git/objects/info:

.git/objects/pack:


Now, as promised, there are two blobs, each 859Kb. The original file contents are still in blob b581d8, and there’s a new blob (3026a4) to hold the updated contents.

Even though we changed just one line in a 2000-line file, git stores the full contents of both revisions of the file.

Isn’t this terrible!? Won’t my repos balloon to unmanageable sizes? Nope, because git has another trick up its sleeve. It can store those blobs in “pack files”, which store repeated sequences of bytes once.

Git will automatically pack blobs when it makes sense to, but we can ask it to explicitly in order to see them in action:

$ git gc --aggressive
Enumerating objects: 6, done.
Counting objects: 100% (6/6), done.
Delta compression using up to 8 threads
Compressing objects: 100% (4/4), done.
Writing objects: 100% (6/6), done.
Total 6 (delta 1), reused 0 (delta 0), pack-reused 0
$ ls -Rlh .git/objects/*
.git/objects/info:
total 16
-rw-r--r--  1 ned  wheel   1.2K Dec 19 11:41 commit-graph
-rw-r--r--  1 ned  wheel    54B Dec 19 11:41 packs

.git/objects/pack:
total 1720
-r--r--r--  1 ned  wheel   1.2K Dec 19 11:41 pack-a0d87c64abc0f03070fd14449891fe20ca98926b.idx
-r--r--r--  1 ned  wheel   855K Dec 19 11:41 pack-a0d87c64abc0f03070fd14449891fe20ca98926b.pack


Now instead of individual blob files, we have one pack file. And it’s a little smaller than either of the blobs!

This may seem like a semantic game: doesn’t this show that commits are deltas? It’s not the same, for a few reasons:

• Reconstructing a file doesn’t require revisiting its history. Every revision is available with the same amount of effort.
• The sharing between blobs is at a conceptually different layer than the blob storage. Git stores a commit as a full snapshot of all of the files’ contents. The file contents might be stored in a shared-bytes way within the pack files.
• The object model is full-file contents in blobs, and commits referencing those blobs. If you removed pack files from the implementation, the conceptual model and all operations would work the same, just take more disk space.
• The storage savings in a pack file are not limited to a single file. If two files (or two revisions of two different files) are very similar, their bytes will be shared.

To demonstrate this last point, we’ll make another file with almost the same contents as one.txt:

$ python /tmp/makebig.py 1 two > two.txt
$ ls -lh
total 4280
-rw-r--r--  1 ned  wheel   1.0M Dec 19 11:18 one.txt
-rw-r--r--  1 ned  wheel   1.0M Dec 19 11:49 two.txt
$ git add two.txt
$ git commit -m "Two"
[master 079baa5] Two
 1 file changed, 2049 insertions(+)
 create mode 100644 two.txt
$ git gc --aggressive
Enumerating objects: 9, done.
Counting objects: 100% (9/9), done.
Delta compression using up to 8 threads
Compressing objects: 100% (7/7), done.
Writing objects: 100% (9/9), done.
Total 9 (delta 2), reused 4 (delta 0), pack-reused 0
$ ls -Rlh .git/objects/*
.git/objects/info:
total 16
-rw-r--r--  1 ned  wheel   1.2K Dec 19 11:50 commit-graph
-rw-r--r--  1 ned  wheel    54B Dec 19 11:50 packs

.git/objects/pack:
total 1720
-r--r--r--  1 ned  wheel   1.3K Dec 19 11:50 pack-36b681bfc8ebef963bb8a7dcfe65addab822f5d4.idx
-r--r--r--  1 ned  wheel   855K Dec 19 11:50 pack-36b681bfc8ebef963bb8a7dcfe65addab822f5d4.pack


Now we have two separate source files in our working tree, each 1Mb. But in the .git storage there is still just one 855Kb pack file. The parts of one.txt and two.txt that are the same are only stored once.

As another example, let’s change two.txt completely by using a different random seed, commit it, then change it back again:

$ python /tmp/makebig.py 2 two > two.txt
$ git commit -am "Two, completely changed"
[master 6dac887] Two, completely changed
 1 file changed, 2049 insertions(+), 2049 deletions(-)
 rewrite two.txt (86%)
$ python /tmp/makebig.py 1 two > two.txt
$ git commit -am "Never mind, I liked it the old way"
[master c06ad2f] Never mind, I liked it the old way
 1 file changed, 2049 insertions(+), 2049 deletions(-)
 rewrite two.txt (86%)


Looking at the storage, our pack file is twice the size, because we’ve had two completely different 1Mb-chunks of data. But thinking about two.txt, its first and third revisions were nearly identical, so they can share bytes in the pack file:

$ git gc --aggressive
Enumerating objects: 13, done.
Counting objects: 100% (13/13), done.
Delta compression using up to 8 threads
Compressing objects: 100% (11/11), done.
Writing objects: 100% (13/13), done.
Total 13 (delta 3), reused 6 (delta 0), pack-reused 0
$ ls -Rlh .git/objects/*
.git/objects/info:
total 16
-rw-r--r--  1 ned  wheel   1.3K Dec 19 11:58 commit-graph
-rw-r--r--  1 ned  wheel    54B Dec 19 11:58 packs

.git/objects/pack:
total 3432
-r--r--r--  1 ned  wheel   1.4K Dec 19 11:58 pack-49f264f911dc97e529dc56a4f6ad450f8013f720.idx
-r--r--r--  1 ned  wheel   1.7M Dec 19 11:58 pack-49f264f911dc97e529dc56a4f6ad450f8013f720.pack


If git stored diffs, we’d need two different megabyte-sized diffs for the two complete changes we’ve made to two.txt.

Note that in this experiment I have used “git gc” to force the storage into its most compact form. You typically wouldn’t do this. Git will automatically repack files when it makes sense to.

Git doesn’t store diffs, it stores the complete contents of the file at each revision. But beneath those full-file snapshots is clever redundancy-removing byte storage that makes the total size even smaller than a diff-based system could achieve.

If you want to know more, How Git Works is a good overview, and Git Internals - Git Objects is the authoritative reference.

To run my experiment, I used ImageMagick to create a test favicon.ico, and also some different-sized png files. So I would know what I was looking at, each size is actually a different visual image: the 32-pixel icon shows “32”, and so on.

This is how I made them:

for size in 16 32 48 ; do
    magick convert \
        -background lightgray \
        -fill black \
        -size ${size}x${size} \
        -gravity center \
        -bordercolor black \
        -border 1 \
        label:${size} \
        icon_${size}.bmp
done
for size in 16 32 48 64 96 128 256; do
    magick convert \
        -background lime \
        -fill black \
        -size ${size}x${size} \
        -gravity center \
        -bordercolor black \
        -border 1 \
        label:${size} \
        icon_${size}.png
done
magick convert *.bmp favicon.ico


Playing with these a bit showed me that favicon.ico is not that reliable, and the simplest thing to do that works well is just to use a 32-pixel PNG file.

I wanted to make an icon of a circled Sleepy Snake image. I started with GIMP, but got lost in selections, paths, and alpha channels, so I went back to ImageMagick:

magick convert SleePYsnake.png \
    -background white -alpha remove -alpha off \
    SleePYwhite.png
magick convert \
    -size 3600x3600 xc:Purple -fill LightBlue \
    -stroke black -strokewidth 30 \
    -draw "circle 1100,1000 1100,1700" -transparent LightBlue \
    mask.png
magick convert SleePYwhite.png mask.png -composite temp.png
magick convert temp.png -transparent Purple temp2.png
magick convert temp2.png -crop 1430x1430+385+285 +repage round.png
magick convert round.png -resize 32x32 round_32.png


Probably some of these steps could be combined. The ImageMagick execution model is still a bit baffling to me. It made these intermediate steps:

I made that montage made with:

magick montage \
    SleePYsnake.png SleePYwhite.png mask.png temp.png temp2.png round.png \
    -geometry 300x300 -background '#ccc' -mode concatenate -tile 2x \
    favicon_stages.png


In the end, I got the result I wanted:

Mad Libs is a language game. One person, the reader, has a story with blanks in it. The other player(s) provide words to go in the blanks, but they don’t know the story. The result is usually funny.

For example, the story might be:

There was a tiny     (adjective)          (noun)     who was feeling very     (adjective)    . After     (verb)    ’ing, she felt     (adjective)    .

(An actual story would be longer, usually a full paragraph.) The reader will ask for the words, either in order, or randomized:

Give me an adjective.
“Purple”.
Give ma a noun.
“Barn”.
A verb.
“Jump”.
Another adjective.
“Lumpy”.
Another adjective.
“Perturbed”.

Then the reader presents the finished story:

There was a tiny perturbed barn who was feeling very purple. After jumping, she felt lumpy.

To do this in software, the program will be the reader, prompting the user for words, and then output the finished story. There are a few different ways you could structure it, of different complexities:

• Hard-code the story in the code.
• Represent the story in a data structure (maybe a list?) in the code.
• Read the story from a data file, to make it easier to use different stories.
• Provide a way to edit stories.
• Make a Mad Libs web application.

Each of these has design choices to be made. How will you separate the text from the blanks? How will you indicate what kind of word goes in each blank? How complex a story structure will you allow?

There are other bells and whistles you can add along the way, for any of the stages of complexity:

• Randomize the order the words are requested.
• Have a way for a provided word to be re-used in the story for some coherence.
• Stories that have random paths through them, so that it is not always the same story, giving more variety.
• Smarter text manipulation, so that “a” or “an” would be used appropriately with a provided word.

If you are interested, you can read the details of how I approached it years ago with my son: Programming madlibs.