html lang="en" { head { m4_include(head.gsp) } body { header { div { h1 {-Moving Files the Right Way} m4_include(nav.gsp) } figure .quote { blockquote { p {= I think the OpenBSD crowd is a bunch of masturbating monkeys, in that they make such a big deal about concentrating on security to the point where they pretty much admit that nothing else matters to them. } } figcaption {-Linus Torvalds} } } main { p { em {- You can find the @code{-mmv} git repository over at @a href="https://git.sr.ht/~mango/mmv" target="_blank" {-sourcehut} or @a href="https://github.com/Mango0x45/mmv" target="_blank" {-GitHub}. } } p {- NOTE: As of the @a href="https://git.sr.ht/~mango/mmv/refs/v1.2.0" {-v1.2.0} release there is now also the @code{-mcp} utility. It behaves the same as the @code{-mmv} utility but it copies files instead of moving them. It also doesn’t support the ‘@code{--n}’ flag as it doesn’t need to deal with backups. } h2 {-Table of Contents} ul { li {a href="#prologue" {-Prologue}} li {a href="#moving" {-Advanced Moving and Pitfalls}} li {a href="#mapping" {-Name Mapping with @code{-mmv}}} li {a href="#newlines" {-Filenames with Embedded Newlines}} ul { li {a href="0-flag" {-The Simple Case}} li {a href="#e-flag" {-Encoding Newlines}} } li {a href="#i-flag" {-Individual Execution}} li {a href="#safety" {-Safety}} li {a href="#examples" {-Examples}} } h2 #prologue {-Prologue} p {- File moving and renaming is one of the most common tasks we undertake on the command-line. We basically always do this with the @code{-mv} utility, and it gets the job done most of the time. Want to rename one file? Use @code{-mv}! Want to move a bunch of files into a directory? Use @code{-mv}! How could @code{-mv} ever go wrong? Well I’m glad you asked! } h2 #moving {-Advanced Moving and Pitfalls} p {- Let’s start off nice and simple. You just inherited a C project that uses the sacrilegious @a href="https://en.wikipedia.org/wiki/Camel_case" target="_blank" {-camelCase} naming convention for its files: } figure { pre { m4_fmt_code(ls-files.sh.gsp) } } p {- This deeply upsets you, as it upsets me. So you decide you want to switch all these files to use @a href="https://en.wikipedia.org/wiki/Snake_case" target="_blank" {-snake_case}, like a normal person. Well how would you do this? You use @code{-mv}! This is what you might end up doing: } figure { pre { m4_fmt_code(manual-mv.sh.gsp) } } p {- Well… it works I guess, but it’s a pretty shitty way of renaming these files. Luckily we only had 5, but what if this was a much larger project with many more files to rename? Things would get tedious. So instead we can use a pipeline for this: } figure { pre { m4_fmt_code(camel-to-snake-naïve.sh.gsp) } } aside { p {- The given example assumes your @code{-sed} implementation supports ‘@code{-\\L}’ which is a non-standard m4_abbr(GNU) extension. } } p {- That works and it gets the job done, but it’s not really ideal is it? There are a couple of issues with this. } ol { li { p {- You’re writing more complicated code. This has the obvious drawback of potentially being more error-prone, but also risks taking more time to write than you’d like as you might have forgotten if @code{-xargs} actually has an ‘@code{--L}’ option or not (which would require reading the @a href="https://www.man7.org/linux/man-pages/man1/xargs.1.html" target="_blank" { code {-xargs(1)} } manual). } } li { p {- If you try to rename the file @em{-foo} to @em{-bar} but @em{-bar} already exists, you end up deleting a file you may not have wanted to. } } li { p {- In a similar vein to the previous point, you need to be very careful about schemes like renaming the file @em{-a} to @em{-b} and @em{-b} to @em{-c}. You run the risk of turning @em{-a} into @em{-c} and losing the file @em{-b} entirely. } } li { p {- Moving symbolic links is its own whole can of worms. If a symlink points to a relative location then you need to make sure you keep pointing to the right place. If the symlink is absolute however then you can leave it untouched. But what if the symlink points to a file that you’re moving as part of your batch move operation? Now you need to handle that too. } } } h2 #mapping {-Name Mapping with @code{-mmv}} p {- What is @code{-mmv}? It’s the solution to all your problems, that’s what it is! @code{-mmv} takes as its argument(s) a utility and that utilities arguments and uses that to create a mapping between old and new filenames — similar to the @code{-map()} function found in many programming languages. I think to best convey how the tool functions, I should provide an example. Let’s try to do the same thing we did previously where we tried to turn camelCase files to snake_case, but using @code{-mmv}: } figure { pre { m4_fmt_code(camel-to-snake-smart.sh.gsp) } } p {-Let me break down how this works.} p {- @code{-mmv} starts by reading a series of filenames separated by newlines from the standard input. Yes, sometimes filenames have newlines in them and yes there is a way to handle them but I shall get to that later. The filenames that @code{-mmv} reads from the standard input will be referred to as the @em{-input files}. Once all the input files have been read, the utility specified by the arguments is spawned; in this case that would be @code{-sed} with the argument @code{-'s/[A-Z]/‌\\L_&/g'}. The input files are then piped into @code{-sed} the exact same way that they would have been if we ran the above commands without @code{-mmv}, and the output of @code{-sed} then forms what will be referred to as the @em{-output files}. Once a complete list of output files is accumulated, each input file gets renamed to its corresponding output file. } p {- Let’s look at a simpler example. Say we want to rename 2 files in the current directory to use lowercase letters, we could use the following command: } figure { pre { m4_fmt_code(mmv-tr.sh.gsp) } } p {- In the above example @code{-mmv} reads 2 lines from standard input, those being @em{-LICENSE} and @em{-README}. Those are our 2 input files now. The @code{-tr} utility is then spawned and the input files are piped into it. We can simulate this in the shell: } figure { pre { m4_fmt_code(tr.sh.gsp) } } p {- As you can see above, @code{-tr} has produced 2 lines of output; these are our 2 output files. Since we now have our 2 input files and 2 output files, @code{-mmv} can go ahead and rename the files. In this case it will rename @em{-LICENSE} to @em{-license} and @em{-README} to @em{-readme}. For some examples, check the @a href="#examples" {-examples} section of this page down below. } h2 #newlines {-Filenames with Embedded Newlines} p {- People are retarded, and as a result we have filenames with newlines in them. All it would have taken to solve this issue for everyone was for literally @strong{-anybody} during the early UNIX days to go “@em{-hey, this is a bad idea!}”, but alas, we must deal with this. Newlines are of course not the only special characters filenames can contain, but they are the single most infuriating to deal with; the UNIX utilities all being line-oriented really doesn’t work well with these files. } p {- So how does @code{-mmv} deal with special characters, and newlines in particular? Well it does so by providing the user with the @code{--0} and @code{--e} flags: } dl { dt { code{--0} } dd { p {- Tell @code{-mmv} to expect its input to not be separated by newlines (‘@code{-\\n}’), but by NUL bytes (‘@code{-\\0}’). NUL bytes are the only characters not allowed in filenames besides forward slashes, so they are an obvious choice for an alternative separator. } } dt { code{--e} } dd { p {- Encode newlines in filenames before passing them to the provided utility. Newline characters are replaced by the literal string ‘@code{-\\n}’ and backslashes by the literal string ‘@code{-\\\\}’. After processing, the resulting output is decoded again. } p {- If combined with the @code{--0} flag, then while input will be read assuming a NUL-byte input-separator, the encoded input files will be written to the spawned process newline-separated. } } } h3 id="0-flag" {-The Simple Case} p {- In order to better understand these flags and how they work let’s go though another example. We have 2 files — one with and one without an embedded newline — and our goal is to simply reverse these filenames. In this example I am going to be displaying newlines in filenames with the “@code{-$'\\n'}” syntax as this is how my shell displays embedded newlines. } p {- We can start by just trying to naïvely pass these 2 files to @code{-mmv} and use @code{-rev} to reverse the names, but this doesn’t work: } figure { pre { m4_fmt_code(mmv-rev.sh.gsp) } } p {- The reason this doesn’t work is because due to the line-oriented nature of @code{-ls} and @code{-rev}, we are actually trying to rename the files @em{-foo}, @em{-bar}, and @em{-baz} to the new filenames @em{-zab}, @em{-rab}, and @em{-oof}. As can be seen in the following diagram, the embedded newline is causing our input to be ambiguous and @code{-mmv} can’t reliably proceed anymore @x-ref{-1}: } figure { object data="conflict.svg" type="image/svg+xml" {-} } aside { p data-ref="1" {- The reason you get a cryptic “file not found” error message is because @code{-mmv} tries to assert that all the input files actually exist before doing anything. Since “foo” isn’t a real file, we error out. } } p {- The first thing we need to do in order to proceed is to pass the @code{--0} flag to @code{-mmv}. This will tell @code{-mmv} that we want to use the NUL-byte as our input separator and not the newline. We also need @code{-ls} to actually provide us with the filenames delimited by NUL-bytes. Luckily m4_abbr(GNU) @code{-ls} gives us the @code{---zero} flag to do just that: } figure { pre { m4_fmt_code(mmv-rev-zero.sh.gsp) } } p {- So we’re getting places, but we aren’t quite there yet. The issue we’re getting now is that @code{-mmv} received 2 input files from the standard input, but @code{-rev} produced 3 output files. Why is that? Well let’s try our hand at a little bit of command-line debugging with @code{-sed}: } figure { pre { m4_fmt_code(sed-debugging.sh.gsp) } } p {- If you aren’t quite sure what the above is doing, here’s a quick summary: } ul { li {- The @code{--U} flag given to @code{-ls} tells it not to sort our output. This is purely just to keep this example clear to the reader. } li {- The @code{--n} flag given to @code{-sed} tells it not to print the input line automatically at the end of the provided script. } li {- The @code{-l} command in @code{-sed} prints the current input in a “visually unambiguous form”. } } p {- In the @code{-sed} output, we can see that @samp{-$} represents the end of a line, and @samp{-\\000} represents the NUL-byte. All looks good here, we have two inputs separated by NUL-bytes. Now let’s try to throw in @code{-rev}: } figure { pre { m4_fmt_code(sed-debugging-rev.sh.gsp) } } p {- Well wouldn’t you know it? Since @code{-rev} @em{-also} works with newline-separated input, it reversed out NUL-byte separators and now gives us 3 outputs. Luckily the folks over at @em{-util-linux} provided us with the @code{--0} flag here too, so that we can properly handle NUL-delimited input. Combining all of this together we get a final working product: } figure { pre { m4_fmt_code(reverse-embedded-newline.sh.gsp) } } h3 #e-flag {-Encoding Newlines} p {- Sometimes we want to rename a bunch of files, but the command we want to use doesn’t support NUL-bytes as nicely as we would like. In these cases, you may want to consider encoding your newline characters into the literal string ‘@code{-\\n}’ and then passing your input newline-separated to your given command with the @code{--e} flag. } p {- For a real-world example, perhaps you want to edit some filenames in vim, or whatever other editor you use. Well we can do this incredibly easily with the @code{-vipe} utility from the @a href="https://joeyh.name/code/moreutils/" {-moreutils} collection. The @code{-vipe} command simply reads input from the standard input, opens it up in your editor, and then prints the resulting output to the standard output; perfect for @code{-mmv}! We do not really want to deal with NUL-bytes in our text-editor though, so let’s just encode our newlines: } figure { pre { m4_fmt_code(vipe.sh.gsp) } } aside { p {- Notice how you still need to pass the @code{--0} flag to @code{-mmv} know that our input files may have embedded newlines. } } p {- When running the above code example, you will see the following in your editor: } figure { pre { m4_fmt_code(vim.gsp) } } p {- After you exit your editor, @code{-mmv} will decode all occurrences of ‘@code{-\\n}’ back into a newline, and all occurrences of ‘@code{-\\\\}’ back into a backslash: } figure { object data="e-flag.svg" type="image/svg+xml" {-} } h2 #i-flag {-Individual Execution} p {- The previous examples are great and all, but what do you do if your mapping command doesn’t have the concept of an input separator at all? This is where the @code{--i} flag comes into play. With the @code{--i} flag we can get @code{-mmv} to execute our mapping command for every input filename. This means that as long as we can work with a complete buffer, we don’t need to worry about separators. } p {- To be honest, I cannot really think of any situation where you might actually need to do this. If you can think of one, please @a href="mailto:mail@thomasvoss.com" {-email me} and I’ll update the example on this page. Regardless, let’s imagine that we wanted to rename some files so that their filenames are replaced with their filename @a href="https://en.wikipedia.org/wiki/SHA-1" target="_blank" {-m4_abbr(SHA)-1 hash}. On Linux we have the @code{-sha1sum} program which reads input from the standard input and outputs the m4_abbr(SHA)-1 hash. This is how we would use it with @code{-mmv}: } figure { pre { m4_fmt_code(sha1sum-long-example.sh.gsp) } } p {- Another approach is to invoke @code{-mmv} twice: } figure { pre { m4_fmt_code(sha1sum-short-example.sh.gsp) } } p {- If you are confused about why we need to make a call to @code{-awk}, it’s because the @code{-sha1sum} program outputs 2 columns of data. The first column is our hash and the second column is the filename where the to-be-hashed data was read from. We don’t want the second column. } p {- Unlike in previous examples where one process was spawned to map all our filenames, with the @code{--i} flag we are spawning a new instance for each filename. If you struggle to visualize this, perhaps the following diagrams help: } figure { figcaption {-Invoking @code{-mmv} without @code{--i}} object data="without-i-flag.svg" type="image/svg+xml" {-} } figure { figcaption {-Invoking @code{-mmv} with @code{--i}} object data="with-i-flag.svg" type="image/svg+xml" {-} } h2 #safety {-Safety} p {- When compared to the standard @code{-for f in *; do mv $f …; done} or @code{-ls | … | xargs -L2 mv} constructs, @code{-mmv} is significantly more safe to use. These are some of the safety features that are built into the tool: } ol { li {- If the number of input- and output files differs, execution is aborted before making any changes. } li {- If an input file is renamed to the name of another input file, the second input file is not lost (i.e. you can rename @em{-a} to @em{-b} and @em{-b} to @em{-a} with no problem). } li {- All input files must be unique and all output files must be unique. Otherwise execution is aborted before making any changes. } li {- In the case that something goes wrong during execution (perhaps you tried to move a file to a non-existent directory, or a syscall failed), a backup of your input files is saved automatically by @code{-mmv} for recovery. } } p {- Due to the way @code{-mmv} handles #2, when things do go wrong you may find that all of your input files have disappeared. Don’t worry though, @code{-mmv} takes a backup of your code before doing anything. If you run @code{-mmv} with the @code{--v} option for verbose output, you’ll notice it backing up your stuff in the @code{-$XDG_CACHE_DIR} directory: } figure { pre { m4_fmt_code(mmv-verbose.sh.gsp) } } p {- Upon successful execution the @code{-$XDG_CACHE_DIR/mmv/TIMESTAMP} directory will be automatically removed, but it remains when things go wrong so that you can recover any missing data. The names of the backup-subdirectories in the @code{-$XDG_CACHE_DIR/mmv} directory are timestamps of when the directories were created. This should make it easier for you to figure out which directory you need to recover if you happen to have multiple of these. } h2 #examples {-Examples} aside { p {- All of these examples are ripped straight from the @code{-mmv(1)} manual page. If you installed @code{-mmv} through a package manager or via @code{-make install} then you should have the manual installed on your system. } } p {-Swap the files @em{-foo} and @em{-bar}:} figure { pre { m4_fmt_code(examples/swap.sh.gsp) } } p {- Rename all files in the current directory to use hyphens (‘-’) instead of spaces: } figure { pre { m4_fmt_code(examples/hyphens.sh.gsp) } } p {- Rename a given list of movies to use lowercase letters and hyphens instead of uppercase letters and spaces, and number them so that they’re properly ordered in globs (e.g. rename @em{-The Return of the King.mp4} to @em{-02-the-return-of-the-king.mp4}): } figure { pre { m4_fmt_code(examples/number.sh.gsp) } } p {- Rename files interactively in your editor while encoding newline into the literal string ‘@code{-\\n}’, making use of @code { a href="https://linux.die.net/man/1/vipe" target="_blank" {-vipe(1)} } from @em{-moreutils}: } figure { pre { m4_fmt_code(examples/vipe.sh.gsp) } } p {- Rename all C source code- and header files in a git repository to use snake_case instead of camelCase using the m4_abbr(GNU) @code { a href="https://www.man7.org/linux/man-pages/man1/sed.1.html" target="_blank" {-sed(1)} } ‘@code{-\\n}’ extension: } figure { pre { m4_fmt_code(examples/camel-to-snake.sh.gsp) } } p {- Lowercase all filenames within a directory hierarchy which may contain newline characters: } figure { pre { m4_fmt_code(examples/lowercase.sh.gsp) } } p {- Map filenames which may contain newlines in the current directory with the command ‘@code{-cmd}’, which itself does not support nul-byte separated entries. This only works assuming your mapping doesn’t require any context outside of the given input filename (for example, you would not be able to number your files as this requires knowledge of the input files position in the input list): } figure { pre { m4_fmt_code(examples/i-flag.sh.gsp) } } } hr{} footer { m4_footer } } }