To expand on Ben Jackson's answer, which is fine, let's look at the original question closely. (See his answer for why bother type questions; this is more about what is going on.)
I'm new to version control and I understand that "committing" is essentially creating a backup while updating the new 'current' version of what you're working on.
This isn't quite right. Backups and and version control are certainly related—exactly how strongly depends on some things that are to some extent matters of opinion—but there are certainly some differences, if only in intent: Backups are typically designed for disaster recovery (machine fails, fire destroys entire building including all storage media, etc.). Version control is typically designed for finer-grained interactions and offers features that backups don't. Backups are typically stored for some time, then jettisoned as "too old": a fresher backup is all that matters. Version control normally saves every committed version forever.
What I don't understand is what staging for is from a practical perspective. Is staging something that exists in name only or does it serve a purpose? When you commit, its going to commit everything anyway, right?
Yes and no. Git's design here is somewhat peculiar. There exist version control systems that don't require a separate staging step. For instance, Mercurial, which is otherwise a lot like Git in terms of usage, doesn't require a separate
hg add step, beyond the very first one that introduces an all-new file. With Mercurial, you use the
hg command that selects some commit, then you do your work, then you run
hg commit, and you're done. With Git, you use
git checkout,1 then you do your work, then you run
git add, and then
git commit. Why the extra
git add step?
The secret here is what Git calls, variously, the index, or the staging area, or sometimes—rarely these days—the cache. These are all names for the same thing.
Edit: I think I may be confusing the terminology. Is a 'staged' file the same thing as a 'tracked' file?
No, but these are related. A tracked file is one that exists in Git's index. To properly understand the index, it's good to start with understanding commits.
Since Git version 2.23, you can use
git switch instead of
git checkout. For this particular case, these two commands do exactly the same thing. The new command exists because
git checkout got over-stuffed with too many things; they got split out into two separate commands,
git switch and
git restore, to make it easier and safer to use Git.
In Git, a commit saves a full snapshot of every file that Git knows about. (Which files does Git know about? We'll see that in the next section.) These snapshots are stored in a special, read-only, Git-only, compressed and de-duplicated form, that in general only Git itself can read. (There's more stuff in each commit than just this snapshot, but that's all we will cover here.)
The de-duplication helps with space: we normally only change a few files, then make a new commit. So most of the files in a commit are mostly the same as the files in the previous commit. By simply re-using those files directly, Git saves lots of space: if we only touched one file, the new commit only takes space for one new copy. Even then it's compressed—sometimes very compressed, though this actually happens later—so that a
.git directory can actually be smaller than the files it contains, once they're expanded out to normal everyday files. The de-duplication is safe because the committed files are frozen for all time. Nobody can go change one, so it's safe for commits to depend on each others' copies.
Because the stored files are in this special, frozen-for-all-time, Git-only format, though, Git has to expand out each file into an ordinary everyday copy. This ordinary copy isn't Git's copy: it is your copy, to do with as you will. Git will just write to these when you tell it to do so, so that you have your copies to work with. These usable copies are in your working tree or work-tree.
What this means is that when you check out some particular commit, there are automatically two copies of each file:
Git has a frozen-for-all-time, Git-ified copy in the current commit. You can't change this copy (though you can of course select a different commit, or make a new commit).
You have, in your work-tree, a normal-format copy. You can do anything you want to this, using any of the commands on your computer.
Other version control systems (including Mercurial as mentioned above) stop here, with these two copies. You just modify your work-tree copy, then commit. Git ... doesn't.
In between these two copies, Git stores a third copy2 of every file. This third copy is in the frozen format, but unlike the frozen copy in the commit, you can change it. To change it, you use
git add command means make the index copy of the file match the work-tree copy. That is, you are telling Git: Replace the frozen-format, de-duplicated copy that's in the index now, by compressing my updated work-tree copy, de-duplicating it, and getting it ready to be frozen into a new commit. If you don't use
git add, the index still holds the frozen-format copy from the current commit.
When you run
git commit, Git packages up whatever is in the index right then to use as the new snapshot. Since it's already in the frozen format, and pre-de-duplicated, Git does not have to do a lot of extra work.
This also explains what untracked files are all about. An untracked file is a file that is in your work-tree but isn't in Git's index right now. It doesn't matter how it the file wound up in this state. Maybe you copied it from some other place on your computer, into your work-tree. Maybe you created it fresh here. Maybe there was a copy in Git's index, but you removed that copy with
git rm --cached. One way or another, there is a copy here in your work-tree, but there isn't a copy in Git's index. If you make a new commit now, that file won't be in the new commit.
git checkout initially fills in Git's index from the commit you check out. So the index starts out matching the commit. Git also fills in your work-tree from this same source. So, initially, all three match. When you change files in your work-tree and
git add them, well, now the index and your work-tree match. Then you run
git commit and Git makes a new commit from the index, and now all three match again.
Because Git makes new commits from the index, we can put things this way: Git's index holds the next commit you plan to make. This ignores the expanded role that Git's index takes on during a conflicted merge, but we'd like to ignore that for now anyway. :-)
That's all there is to it—but it's still pretty complicated! It's particularly tricky because there's no easy way to see exactly what is in Git's index.3 But there is a Git command that tells you what's going on, in a way that's pretty useful, and that command is
2Technically, this isn't actually a copy at all. Instead, it's a reference to the Git-ified file, pre-de-duplicated and everything. There's more stuff in here as well, such as the mode, file name, a staging number, and some cache data to make Git go fast. But unless you get into working with some of Git's low-level commands—
git ls-files --stage and
git update-index in particular—you can just think of it as a copy.
git ls-files --stage command will show you the names and staging numbers of every file in Git's index, but usually this isn't very useful anyway.
git status command actually works by running two separate
git diff commands for you (and also doing some other useful stuff, such as telling you which branch you're on).
git diff compares the current commit—which, remember, is frozen for all time—to whatever is in Git's index. For files that are the same, Git will say nothing at all. For files that are different, Git will tell you that this file is staged for commit. This includes all-new files—if the commit doesn't have
sub.py in it, but the index does have
sub.py in it, then this file is added—and any removed files, that were (and are) in the commit but aren't in the index any more (
git rm, perhaps).
git diff compares all the files in Git's index to the files in your work-tree. For files that are the same, Git says nothing at all. For files that are different, Git will tell you that this file is not staged for commit. Unlike the first diff, this particular list doesn't include files that are all-new: if the file
untracked exists in your work-tree, but not in Git's index, Git just adds it to the list of untracked files.4
At the end, having accumulated these untracked files in a list,
git status will announce those files' names too, but there's a special exception: if a file's name is listed in a
.gitignore file, that suppresses this last listing. Note that listing a tracked file—one that's in Git's index—in a
.gitignore has no effect here: the file is in the index, so it gets compared, and gets committed, even if it's listed in
.gitignore. The ignore file only suppresses the "untracked file" complaints.5
4When using the short version of
git status -s—the untracked files aren't as separated-out, but the principle is the same. Accumulating the files like this also lets
git status summarize a bunch of untracked files' names by just printing a directory name, sometimes. To get the full list, use
git status -uall or
git status -u.
5Listing a file also makes en-masse add many file operations like
git add . or
git add * skip over the untracked file. This part gets a little more complicated, since you can use
git add --force to add a file that would normally be skipped. There are some other normally-minor special cases, all of which add up to this: the file
.gitignore might be more properly called
.git-do-not-complain-about-these-untracked-files-and-do-not-auto-add-them or something equally unwieldy. But that's too ridiculous, so
.gitignore it is.
git add -u,
git commit -a, etc
There are several handy shortcuts to know about here:
git add . will add all updated files in the current directory and any sub-directory. This respects
.gitignore, so if a file that is currently untracked is not complained-about by
git status, it won't be auto-added.
git add -u will auto-add all updated files anywhere in your work-tree.6 This affects only tracked files. Note that if you've removed the work-tree copy, this will remove the index copy too (
git add does this as part of its make the index match the work-tree thing).
git add -A is like running
git add . from the top level of your work-tree (but see footnote 6).
Besides these, you can run
git commit -a, which is roughly equivalent7 to running
git add -u and then
git commit. That is, this gets you the same behavior that is convenient in Mercurial.
I generally advise against the
git commit -a pattern: I find that it's better to use
git status often, look closely at the output, and if the status is not what you expected, figure out why that's the case. Using
git commit -a, it's too easy to accidentally modify a file and commit a change you didn't intend to commit. But this is mostly a matter of taste / opinion.
6If your Git version predates Git 2.0, be careful here:
git add -u only works on the current directory and sub-directories, so you must climb to the top level of your work-tree first. The
git add -A option has a similar issue.
7I say roughly equivalent because
git commit -a actually works by making an extra index, and using that other index to do the commit. If the commit works, you get the same effect as doing
git add -u && git commit. If the commit doesn't work—if you make Git skip the commit in any of the many ways you can do that—then no files are
git add-ed afterward, because Git throws out the temporary extra index and goes back to using the main index.
There are additional complications that come in if you use
git commit --only here. In this case, Git creates a third index, and things get very tricky, especially if you use pre-commit hooks. This is another reason to use separate
git add operations.