# Module 6 — Branches: Sandboxes for Experiments
> **A branch is a disposable copy of your project where the AI can try anything — and `main` never
> finds out unless you decide it should.** This is what turns "let the agent attempt something bold"
> from a gamble into a one-line decision: keep it or throw it away.
---
## Prerequisites
- **Module 2 — Version Control as a Safety Net.** You can `init`, `commit`, read `git diff`/`git
log`/`git status`, and `git restore` an unwanted change. Branches build directly on commits: a
branch is just a label on the commit history you already understand.
- **Module 3 — Version Control for Words.** You first met `git branch`, `git switch -c`, `git merge`,
and `git branch -d` there — on a markdown doc, where a mistake costs nothing and the merge always
fast-forwarded. This module takes those same verbs to *code*, where branches actually diverge and
merges can conflict.
- **Module 4 — Getting the AI Out of the Browser.** The AI now edits your real files directly from
your editor. That's exactly the capability that makes branches matter — you're about to let it edit
files *fast and confidently*, and you want a wall around the blast radius.
- **Module 5 — Commit the AI's Config, Not Just the Code.** Your committed instructions file travels
with the branch automatically, so an agent working on a branch inherits the same setup. (You'll see
this for free in the lab — nothing to do, just notice it.)
Module 2's `git restore` undoes *uncommitted* changes back to your last checkpoint. This module is
the next size up: isolating *a whole line of committed work* so you can keep or discard it as a unit.
---
## Learning objectives
By the end of this module you can:
1. Explain what a branch actually *is* (a movable pointer, not a copy of your files) and direct your
AI agent to create and switch between branches, verifying the result with `git branch`/`git status`.
2. Let the AI make a bold, multi-commit change on a branch while `main` stays untouched and runnable.
3. Decide the experiment's fate and have the agent carry it out: **merge** it into `main` to keep it,
or **delete the branch** to throw it away with zero trace. You make the call and check the result.
4. Read a merge conflict (the `<<<<<<<`/`=======`/`>>>>>>>` markers) and hand it to the AI to
resolve, then verify the resolution is right before the merge completes.
5. Tell the difference between a fast-forward merge and a merge commit, and know which one you got.
---
## Key concepts
### What a branch actually is (quick recap)
You already drove the branch loop by hand in Module 3 (create, merge, delete) on a markdown doc,
where the merge always fast-forwarded because nothing else had moved. You won't re-learn those
commands here. From Module 4 on, the AI runs them for you; this module is about how the AI works
*inside* a branch and how you decide what to keep. So just one line of recap before we get there.
A branch is **a named, movable pointer to a commit.** Your commit history is a chain of snapshots
(Module 2); a branch is a sticky label that points at one of them and moves forward every time you
commit on it. `main` is the branch Git made for you in Module 2; every commit moved that label
forward. You were "on a branch" the whole time.
The property that makes branches the right tool here: **creating one copies nothing.** No second
folder, no duplicated files, no disk cost worth mentioning. Git writes a new label pointing at the
commit you're already on. That's why branches are cheap enough to be disposable, and disposable is
exactly what we want for an AI experiment you might throw away.
### The reframe: a branch is a sandbox you can blow away
You already have the instinct for this. A branch is the Git equivalent of a **scratch VM you can
snapshot and roll back, a staging environment nobody depends on, a feature-flag you can rip out.**
You spin one up precisely *because* you're about to do something you might regret, and you want a
clean way to make it never have happened.
In Module 2 the safety net was "commit, then `restore` if the AI makes a mess." That's perfect for a
single bad edit. But some experiments are bigger than one edit: "rewrite the storage layer," "try a
totally different CLI structure," "add a feature that touches four files." Those take several commits
to even evaluate, and you don't want that half-finished, possibly-broken work sitting on `main`. A
branch gives the whole experiment its own track:
```
main: A───B───C (always runnable; this is your "known good")
\
experiment: D───E───F (the AI's bold attempt, however messy)
```
While you're on `experiment`, `main` is frozen at C: runnable, shippable, untouched. The AI can leave
`experiment` a broken mess at F and `main` doesn't care. When you're done you make one decision:
- **Keep it:** merge `experiment` into `main` (C gains D, E, F).
- **Kill it:** delete `experiment`. D, E, F evaporate. `main` is still exactly C, as if the
experiment never happened.
That "kill it, no trace" path is the one this module exists for. It's the difference between "I have
to carefully undo everything the AI did" and "I delete the branch."
### Switching branches changes your files
One detail trips people up the first time. When you switch to another branch, **Git rewrites the
files in your folder to match that branch.** Switch to `experiment` and the AI's half-built feature
appears in your editor. Switch back to `main` and it's gone; your files are back to commit C. Same
folder, different contents, instantly.
This is why you can't switch with uncommitted changes lying around that would be clobbered. Git stops
you, because switching would silently throw work away. The fix is the Module 2 habit: commit (or
stash) before you switch. On a branch, "commit often" pays off again, since each commit is a safe
point to switch away from. When the agent is driving, this is one of the things you verify after it
works: `git status` clean before a switch.
> **One folder, one branch at a time.** Switching swaps the *whole* folder between branches, so you
> can only have one branch checked out at once. The moment you want *two* branches live at the same
> time (say, two agents working in parallel without overwriting each other's files) you've hit the
> limit of branches alone. That's what **Module 7 (Worktrees)** solves: multiple working directories
> from one repo. Branches are the concept; worktrees are how you run several at once.
### Merging: keeping the experiment
Merging takes the commits from one branch and brings them into another. The receiving branch (usually
`main`) is the one you switch to, and the other branch merges into it. You don't type this; you tell
the agent "merge `experiment` into `main`," and it runs the equivalent of `git merge experiment`.
There are two outcomes, and it's worth recognizing which you got when you read the log:
- **Fast-forward.** If `main` hasn't moved since you branched (still at C), Git slides the `main`
label forward to F. The history stays a straight line. This is the common case for a solo
experiment.
- **Merge commit.** If `main` *did* move on (you committed to `main` while `experiment` was off doing
its thing), the two lines of history diverged. Git stitches them together with a new commit that
has two parents.
Git picks between these based on whether the branches diverged. You recognize them in the log: a
fast-forward is a straight line, a merge commit is a visible fork-and-join.
```console
$ git log --oneline --graph
* 9f3c1a2 Merge branch 'experiment'
|\
| * 4b8d0e1 Add task priorities (experiment)
* | 2a1f9c7 Fix list ordering on main
|/
* 7c0e3d4 Initial tasks app
```
After a successful merge the branch has done its job, and `git branch -d experiment` deletes it. The
lowercase `-d` refuses if the branch isn't fully merged, which is a safety check. Again, the agent
runs this once you've decided; you confirm the branch is gone with `git branch`.
### Discarding: killing the experiment
This is the payoff. The AI tried something bold on the branch, you looked at it, and you don't want
it. You don't undo anything. You don't `restore` file by file. You switch away and delete the branch
(`git switch main`, then `git branch -D experiment`, which force-deletes even though it was never
merged). The agent runs both on your say-so.
That's it. The experiment is gone. `main` never changed. `git log` on `main` shows no sign it ever
happened. **The whole bold attempt cost you one branch and one delete.**
This is the mental shift the module is selling: when discarding is this cheap, you stop being precious
about what you let the AI try. Risky refactor? Branch it. Want to compare two approaches? A branch
each, keep the winner, delete the loser. The branch is the unit of "maybe."
### Merge conflicts: when two changes collide
Most merges just work — Git is good at combining changes that touch *different* lines. A **conflict**
happens only when two branches changed **the same lines** in different ways, and Git refuses to
guess which one you meant. It stops the merge and marks the collision *inside the file* so you can
decide:
```python
<<<<<<< HEAD
print("usage: python cli.py [add
| list | done | stats]")
=======
print("usage: python cli.py [add | list | done | purge]")
>>>>>>> experiment
```
Read it like this:
- `<<<<<<< HEAD` to `=======` is **your current branch's version** (the branch you're merging *into*
— `main`, here).
- `=======` to `>>>>>>> experiment` is **the incoming branch's version**.
- Both markers and the divider are real text Git inserted into your file. Resolving means **editing
the file so it contains the version you want and deleting all three marker lines.**
Resolving isn't picking a side mechanically. It's deciding what the line *should* say. Often that's
one side; sometimes it's a blend of both (here, a usage string that lists *both* `stats` and `purge`).
This is the kind of bounded reasoning task the AI is good at: it sees both versions and the
surrounding code, so you hand it the conflict and let it produce the combined version. Once the file
is correct and marker-free, telling Git the conflict is settled is two more commands the agent runs
(`git add cli.py` to mark the file resolved, then `git commit` to complete the merge).
`git status` during a conflict is your map; it lists every file still "unmerged." Your job is the
verify: read the resolution, confirm it's what you meant, and check `git status` comes back clean. If
things go sideways, `git merge --abort` rewinds to before the merge with no harm done.
---
## The AI angle
Everything above is standard Git. Here's why it matters *more* in an AI-assisted workflow, not less:
- **The branch is the blast-radius container for an autonomous attempt.** An agent editing your files
directly (Module 4) is fast and confident — including when it's confidently wrong across four
files. On `main`, cleaning that up is a chore. On a branch, you delete the branch. The riskier and
more autonomous the AI work, the more a branch earns its keep — which is why this concept underpins
everything in Unit 5, where agents run with far less supervision.
- **"Throw it away" is the feature, not the failure.** With copy-paste, a rejected AI attempt still
cost you the manual work of pasting it in and the manual work of ripping it back out. With a
branch, a rejected attempt costs *nothing* — `git branch -D` and it's as if it never happened. That
flips the economics: you can let the AI try things you'd never risk if undoing were expensive.
- **Compare, don't commit-and-hope.** Ask the AI for approach A on one branch and approach B on
another. Run both. Keep the winner, delete the loser. You're using branches as cheap A/B
experiments on implementation — something that's painful without them and trivial with them.
- **Conflicts are a great place to put the AI to work.** A merge conflict is a small, perfectly
bounded reasoning task: here are two versions of the same lines and the surrounding code — produce
the correct combined version. The AI can see both sides and the intent. You still decide whether
its resolution is right (it can absolutely merge two changes into something that satisfies neither),
but "explain this conflict and propose a resolution" is one of the highest-hit-rate uses of an
editor-integrated agent. You'll do exactly this in the lab.
---
## Hands-on lab
**Lab language:** shell (Git commands), driving the `tasks-app` from Modules 1–2 with your
editor-integrated AI from Module 4.
You'll do three things: let the AI try a bold change on a branch, decide its fate, and then
deliberately create and resolve a merge conflict — using the AI to help resolve it.
**You'll need:**
- The `tasks-app` Git repo from Module 2 (committed, clean working tree — run `git status` and make
sure it says "nothing to commit").
- Your editor-integrated AI from Module 4.
- Git (you've had it since Module 2).
> Throughout, "ask your AI" now means your **editor-integrated** agent (Module 4) editing the files
> directly — no more copy-paste. After it edits, you still read `git diff` before committing. That
> habit doesn't go away; the branch just decides how *much* damage a bad diff can do.
### Part A — Branch it and let the AI go bold
1. Make sure you're in the repo, then **tell the agent to set up the branch.** Ask:
> *"We're on the `tasks-app` repo. Confirm we're on `main` with a clean working tree, then create
> a branch called `experiment/priorities` and switch to it."*
Then **verify** it did what you asked, by hand:
```bash
cd ~/ai-workflow-course/tasks-app
git status # should be clean, on experiment/priorities
git branch # the * should be on experiment/priorities
```
You're not typing the branch commands; you're confirming the agent ran them correctly. This is the
pattern for the whole module: you direct, the agent does the git, you check.
2. Give the AI a deliberately *bold* task, the kind you'd hesitate to run straight on `main`:
> *"Add task priorities (low/medium/high) to this app. Store a priority on each task, let me set
> it when adding (`add "thing" --priority high`), show it in `list`, and sort `list` so high
> priority comes first. Change whatever files you need to."*
Let it edit `tasks.py` and `cli.py` freely. This is a multi-file change: nerve-wracking on `main`,
relaxed on a branch.
3. Review the change, then have the agent commit it **on the branch**. First read the diff and run
the app yourself:
```bash
git diff # read what it actually changed
python cli.py add "ship module 6" --priority high
python cli.py add "water plants" --priority low
python cli.py list # see if priorities work and sort
```
Once the diff looks right and the feature runs, tell the agent:
> *"Commit this on the branch with a message like 'Add task priorities (experiment)'."*
The agent decides what to stage and writes the commit. Confirm it landed with `git log --oneline`.
4. Now prove the isolation. Ask the agent to switch back to `main`, then watch the feature
**disappear**:
> *"Switch back to `main`."*
```bash
python cli.py list # no priorities; main is exactly as you left it
```
Your bold change exists only on the branch. `main` never saw it, and that's the whole point.
### Part B — Decide its fate
**The decision is yours; the execution is the agent's.** Pick the path that matches reality. Do at
least one; ideally do **Path 2 (discard)** on this experiment so you feel how clean it is, then re-run
Part A and do **Path 1 (keep)** so you've done both.
**Path 1 — Keep it (merge).** Tell the agent:
> *"Merge `experiment/priorities` into `main`, then delete the branch."*
Then verify the result yourself:
```bash
git log --oneline --graph # straight line = fast-forward merge
python cli.py list # the feature is now on main
git branch # experiment/priorities is gone
```
**Path 2 — Throw it away (discard).** Tell the agent:
> *"Switch to `main` and discard the `experiment/priorities` branch entirely."*
Then verify:
```bash
git log --oneline # no trace of the experiment on main
python cli.py list # main is untouched, exactly as before
git branch # the branch is gone
```
Notice what you did *not* do in Path 2: no file-by-file `restore`, no manual undo, no hunting through
diffs. The agent deleted a label and the entire experiment was gone. That's the economics shift: bold
AI attempts become free to reject.
### Part C — Create a merge conflict and resolve it with the AI
Merge conflicts have an outsized reputation for difficulty. You'll engineer a guaranteed one by having
**two branches change the same line in different ways**, then resolve it with the agent.
> **Starting state.** By now your `tasks-app` has accumulated commands from earlier modules, so your
> `usage:` line is longer than the bare `[add | list | done ]` you started with — and
> that's fine. This lab works *regardless* of what's on that line, because the collision is just "two
> branches each appended a different new command to the same usage line." To make it reproduce even on
> a carried-forward app, we deliberately add two commands you **haven't** built yet — `stats` and
> `purge`. (Any two brand-new commands would do; the point is the same line, edited two ways.) The
> marker examples below show the shape; your real markers will carry your fuller usage string.
1. From a clean `main`, set up the first branch and the `stats` command in one instruction to the
agent:
> *"From `main`, create a branch `feature/stats`, add a `stats` command to `cli.py` that prints how
> many tasks are total, done, and pending, update the usage string to include it, then commit it
> with the message 'Add stats command'."*
Verify the agent edited the usage line and committed:
```bash
git diff main # the usage line changed + the command was added
git log --oneline # the commit is there, on feature/stats
```
2. Now the second branch, which touches **the same usage line** a different way:
> *"Switch back to `main`, create a branch `feature/purge`, add a `purge` command to `cli.py` that
> removes all completed (done) tasks, update the usage string to include it, then commit it with
> the message 'Add purge command'."*
Verify the collision is set up:
```bash
git diff main # feature/purge edited the same usage line
```
Both branches changed the same `usage:` line, each adding a *different* command. Git won't be able
to auto-merge that line.
3. Now trigger the conflict. Tell the agent:
> *"You're on `feature/purge`. Merge `feature/stats` into it."*
Git stops with a conflict. Confirm the conflict state yourself:
```bash
git status # cli.py listed under "Unmerged paths"
```
4. Open `cli.py` and find the conflict markers around the usage line (your usage string will be
longer — it carries the commands from earlier modules — but the collision is exactly this: both
branches appended a different new command to it):
```python
<<<<<<< HEAD
print("usage: python cli.py [add | list | done | purge]")
=======
print("usage: python cli.py [add | list | done | stats]")
>>>>>>> feature/stats
```
(The command bodies for `stats` and `purge` touch different lines, so Git merged *those* cleanly
on its own — the only collision is the usage string both branches edited.)
5. **Resolve it with the AI.** This is exactly the bounded task the agent is good at. Ask:
> *"`cli.py` has a merge conflict on the usage line. I want the final version to list BOTH the
> `stats` and `purge` commands. Resolve the conflict and remove the markers."*
It should produce a single, marker-free line listing both commands, e.g.:
```python
print("usage: python cli.py [add | list | done | stats | purge]")
```
**Verify its work — this is the part the AI can get subtly wrong.** A conflict resolver can
confidently drop one side, leave a stray marker, or "blend" the lines into something that runs but
means the wrong thing. Read the result and run it:
```bash
git diff # check ONLY what you intended changed; no markers remain
python cli.py # run with no args — see the merged usage string
python cli.py stats # both commands actually work
python cli.py purge
```
6. Once you've verified the resolution, have the agent finish the merge:
> *"The resolution looks right. Stage `cli.py` and complete the merge."*
Then confirm the merge landed as a merge commit:
```bash
git log --oneline --graph # the fork-and-join: this is a merge commit
```
You just resolved a real merge conflict: you directed it, the agent did the plumbing, and you
verified the result. The marker syntax is identical no matter the file or the project. Once you can
read those three lines and check the resolution, a conflict is a short, routine task.
> **Guaranteed-conflict generator.** AI edits are nondeterministic, so if the agent didn't touch the
> same line on both branches and you *didn't* get a conflict in step 3, run the helper script to
> manufacture one deterministically, then practice steps 4–6 on it. Copy it into your `tasks-app`
> first (the course's lab scripts live in the course repo, not in `tasks-app` — see Module 4's
> *You'll need*), then run it from inside the repo:
>
> ```bash
> cp ~/ai-workflow-course/the-workflow-course/modules/06-branches-sandboxes-for-experiments/lab/make-conflict.sh .
> bash make-conflict.sh
> ```
>
> It creates two branches that both edit the same line of `README.md`, leaving you mid-conflict with
> on-screen instructions. From there, hand it to the agent the same way (step 5), then verify. The
> resolution mechanic is identical to the code case above.
---
## Where it breaks
The honest limits, so you don't over-trust the sandbox:
- **A branch isolates *files in the repo*, nothing else.** Switching branches rewrites your tracked
files — it does **not** roll back a database the app wrote to, files Git is ignoring, running
processes, or anything outside version control. If your AI experiment ran a migration or wrote to
`tasks.json` (which the Module 2 `.gitignore` excludes), deleting the branch won't undo *that*. The
sandbox is the repo, not the world. (Real environment isolation is a later problem — containers,
Module 16.)
- **Branches are local until you push them.** Everything in this module lives on your laptop. A
branch isn't shared, backed up, or visible to anyone else until there's a remote — that's
**Module 8**. Right now `git branch -D` deletes work that exists nowhere else, permanently. Treat
an unpushed branch as exactly as fragile as the rest of your local-only repo.
- **The AI can resolve a conflict into something plausible and wrong.** It sees both sides and the
intent, which makes it good at this — but "good" isn't "trusted." A resolution that runs cleanly can
still mean the wrong thing (silently keeping the worse of two changes, or merging two behaviors
into one that satisfies neither). The `git diff` + run-it check in the lab isn't optional ceremony;
it's the actual safeguard. Reviewing AI output is its own discipline — Module 10.
- **Long-lived branches drift and conflict harder.** The longer a branch lives away from `main`, the
more `main` moves underneath it and the gnarlier the eventual merge. The defense is the same as
"commit often": branch small, merge soon, delete promptly. A branch that's been open for three
weeks is a future conflict, not a sandbox.
- **Force-delete (`-D`) and `merge --abort` are sharp.** `-D` discards unmerged commits with no
confirmation; `--abort` throws away an in-progress resolution. Both are exactly what you want at
the right moment and a foot-gun at the wrong one. Know which one you're reaching for.
---
## Check for understanding
**You're done when:**
- You directed the agent to branch, let the AI make a multi-file change on it, and confirmed `main`
was untouched by switching back and seeing the change vanish.
- You have **discarded** an experiment (the agent ran `git branch -D`) and confirmed `main` shows no
trace, and you have **merged** one in and seen it land on `main`.
- You can explain, in one sentence, why creating a branch costs essentially nothing (it's a movable
pointer, not a copy).
- You deliberately created a merge conflict, read the `<<<<<<<`/`=======`/`>>>>>>>` markers, had the
AI resolve it to a marker-free file that runs, verified the result, and let the agent complete the
merge.
- You can name the limit: a branch isolates tracked files, not your database, ignored files, or the
outside world.
When "let the agent try something wild" feels like a one-line decision instead of a risk assessment,
you've got it. Module 7 takes the next step: running several of these branches *live at the same
time* in separate working directories, so multiple agents can work in parallel without colliding.