As ijw notes, there are several ways to create an archive file header. If cross-platform portability is going to be an issue at all - or if you need to switch between 32-bit and 64-bit builds of the software on the same platform, even - then you need to ensure that the sizes and layouts of the fields are fully understood on all platforms.
Per-file Metadata
One way to do that is to use a fixed format binary header with types of known size and endianness. This is what ijw suggested. However, you will need to handle long file names, and so you will need to store a length (probably in a 2-byte unsigned integer) and then follow that with the actual pathname.
The alternative, and generally now favoured technique, is to use printable fields (often called ASCII format, though that is something of a misnomer). The time is recorded as the decimal number of seconds since the Epoch converted to a string, etc. This is what modern ar
archives use; it is what GNU tar
does (more or less; there are some historical quirks that make that more confusing); it is what cpio -c
(which is usually the default these days) does. The fields might be separated by nulls or spaces; there is an easy way to detect the end of the header; the header contains information about the file name (not necessarily as directly as you'd like or expect, but again, that is usually because the format has evolved over the years), and then is followed by the actual data. Somehow, you know the size of each field, and the file which the header describes, so that you can read the data reliably.
Efficiency is a red herring. The conversion to/from the text format is so swift by comparison with the first disk access that there is essentially no measurable performance issue. And the guaranteed portability typically far outweighs the (microscopic) performance benefit from using binary data format instead - doubly so when the binary data has to be transformed on input or output anyway to get it into an architecture-neutral format.
Central Index vs Distributed Index
The other issue to consider is whether the index of files in the archive is centralized (at the front, or at the end) or distributed (the metadata for each file immediately precedes the data for the file). There are some advantages to each format - generally, systems use the distributed version because you can write the information for each file without knowing how many files there are to process in total (for example, because you are recursively archiving a directory's contents). Having a central index up front means you can list the files without reading the whole archive - distributed metadata means you have to read the whole file. However, the central index complicates the building of the archive.
Note that even with a distributed index, you will normally need a header for the archive as a whole so that you can detect that the file is in the format you expect. Typically, there is some sort of marker information (!<arch>\n
for an ar
archive, usually; %PDF-1.2\n
at the start of a PDF file, etc) to reassure you that the file contains what you expect. There might be some overall (archive-level) metadata. Then you will have the first file metadata followed by the file data, repeating until the end of archive (which might, or might not, have a formal end marker - more metadata).
[H]ow would I go about implementing it in the 'fixed format binary header' you suggested. I am having trouble with deciding what commands/functions are needed.
I intended to suggest that you do not go with a fixed format binary header; you should use a text-based header format. If you can work out how to do the binary format, be my guest (I've done it numerous times over the years - that doesn't mean I think it is a good idea).
So, some pointers here towards the 'text header' format.
For the file metadata, you might define that you include:
- size
- mode (permissions, type)
- owner
- group
- modification time
- length of name
- name
You might reasonably decide that your file sizes are limited to 64-bit unsigned integer quantities, which means 20 decimal digits. The mode might be printed as a 16-bit octal number, requiring 6 octal digits. The owner and group might be printed as UID and GID values (rather than name), in which case you could use 10 digits for each. Alternatively, you could decide to use names, but you should then allow for names up to say 32 characters each. Note that names are typically more portable than numbers. Neither name nor number is of much relevance on the receiving machine unless you extract the data as root (but why would you want to do that?). The modification time is classically a 32-bit signed integer, representing the number of seconds since the Epoch (1970-01-01 00:00:00Z). You should allow for the Y2038 bug by allowing the number of seconds to grow bigger than the 32-bit quantity; you might decide that 12 leading digits will take you beyond the Y10K crisis (by a factor of 4 or so), and this is good enough; you might decide to allow for fractional seconds too. Together, this suggests that 26 spaces for the timestamp should be overkill. You can decide that each field will be separated from the next by a space (for legibility - think 'ease of debugging'!). You might reasonably decide that all file names will be restricted to 4 decimal digits in total length.
You need to know how to format the types portably - #include <inttypes.h>
is your friend.
You then devise a format string for printing (writing) the file metadata, and a parallel string for scanning (reading) the file metadata.
Printing:
"%20" PRIu64 " %06o %-.32s %-.32s %26" PRIu64 " %-4d %s\n"
This prints the name too. It terminates the header with a newline. The total size is 127 bytes plus the length of the file name. That's probably excessive, but you can tweak the numbers to suit yourself.
Scanning:
"%" SCNu64 " %o %.32s %.32s %" SCNu64 "%d"
This does not scan the name; you need to create the scanner for the name carefully, not least because you need to read spaces in the name. In fact, the code for scanning the user name and group name both assume no spaces too. If that is not acceptable (that is, names may contain spaces), then you need a more complex scan format, or something other than sscanf()
to process the input data.
I'm assuming a 64-bit integer for the time field, rather than mixing up fractional seconds, etc, even though there's enough space to allow for fractional seconds. You'd likely save some space here.