Seeking around in an HTTP object

Imagine there’s a giant ZIP file on a HTTP server, and you want to know what’s inside it. You don’t know if it’s got what you are looking for, and you don’t want to download the whole thing. Is it possible to do something like unzip -l https://example.com/giant.zip ?

This is not a theoretical problem just to demonstrate something in Go. In fact, I wasn’t looking to write an article at all, except that I wanted to know the structure of the bulk patent downloads from the US Patent and Trademark Office (USPTO) from those ZIP files. Or, I thought, how cool would it be to be able to fetch individual images of some of the patents issued in 1790 out of these tarfiles?

Go take a look. There’s hundreds of huge ZIP and tarfiles to explore there!

The ZIP file format has a table of contents in it, located at the end. So on local disk, “unzip -l” is as simple as “seek to the end, find the TOC, parse it and print it”. And in fact, we can see that’s how Go is going to proceed, because the zip.NewReader function wants a file it will be able to seek around in. As for TAR files, they were designed for a time when tape streamed and memory was scarce, so their table of contents is interleaved among the files themselves.

But we’re not on local disk, we’ve given ourselves the challenge of reading from a URL. What to do? Where to start?

We’ve got a couple things to check and then we can plan a way forward. The equivalent of seeking and reading from a file for HTTP is the Range header. So, do the USPTO servers support the Range header? That’s easy enough to check using curl and an HTTP HEAD request:

1 2 3 4 5 6 7 8 9 10 $ curl -I https://bulkdata.uspto.gov/data/patent/officialgazette/2017/e-OG20170103_1434-1.zip HTTP/1.1 200 OK Date: Mon, 11 Dec 2017 21:10:26 GMT Server: Apache Last-Modified: Tue, 03 Jan 2017 11:58:45 GMT ETag: "afb8ac8-5452f63e0a82f" Accept-Ranges: bytes Content-Length: 184257224 X-Frame-Options: DENY Content-Type: application/zip

Note the “Accept-Ranges” header in there, which says that we can send byte ranges to it. Range headers let you implement the HTTP equivalent of the operating system’s random-access reads (i.e. the io.ReaderAt interface).

So it would theoretically be possible to pick and choose which bytes we download from the web server, in order to download only the parts of a file that have the metadata (table of contents) in it.

Now we need an implementation of the ZIP file format that will let us replace the “read next table of contents header” part with an implementation of read that reads only the metadata, using an HTTP GET with a Range header. And that is where Go’s archive/zip and archive/tar packages come in!

As we’ve already noted, zip.NewReader is chomping at the bit to start seeking. However as we take a look at TAR, we find a problem. The tar.NewReader method takes an io.Reader. The problem with the io.Reader is that it does not let us get random access to the resource, like io.ReaderAt does. It is implemented that way because it makes the tar package more adaptable. In particular, you can hook the Go tar package directly up to the compress/gzip package and read tar.gz files – as long as you are content to read them sequentially and not jump around in them, as we wish to.

So what to do? Use the source, Luke! Go dig into the Next method, and look around. That’s where we’d expect it to go find the next piece of metadata. Within a few lines, we find an intriguing function call, to skipUnread. And there, we find something very interesting:

1 2 3 4 5 6 7 8 9 10 11 12 13 // skipUnread skips any unread bytes in the existing file entry, as well as any alignment padding. func ( tr * Reader ) skipUnread () { nr := tr . numBytes () + tr . pad // number of bytes to skip tr . curr , tr . pad = nil , 0 if sr , ok := tr . r .( io . Seeker ); ok { if _ , err := sr . Seek ( nr , os . SEEK_CUR ); err == nil { return } } _ , tr . err = io . CopyN ( ioutil . Discard , tr . r , nr ) } // Note : This is from Go 1.4 , which had a simpler skipUnread than go 1.9 does .

The type assertion in there says, “if the io.Reader is actually capable of seeking as well, then instead of reading and discarding, we seek directly to the right place”. Eureka! We just need to send an io.Reader into tar.NewReader that also satisfies io.Seeker (thus, it is an io.ReadSeeker).

So, now go check out package github.com/jeffallen/seekinghttp which is, as it’s name implies, a package for seeking around in HTTP objects (source on Github).

This package implements not only io.ReadSeeker, but also io.ReaderAt. Why? Because, as I mentioned above, reading a ZIP file requires an io.ReaderAt. It also needs the length of the file passed to it, so that it can look at the end of the file for the table of contents. The HTTP HEAD method works nicely to get the Content-Length of the HTTP object, without downloading the entire thing.

A command-line tool to get the table of contents of tar and zip files remotely is in remote-archive-ls. Turn on the “-debug” option in order to see what’s happening. It is fascinating to watch as the TAR or ZIP readers from Go’s standard library “call back” into our code and ask for a few bytes here, a few bytes there.

Soon after I first got this program working, I found a serious flaw. Here’s an example run:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 $ ./remote-archive-ls -debug 'https://bulkdata.uspto.gov/data/patent/grant/multipagepdf/1790_1999/grant_pdf_17900731_18641101.tar' 2017 /12/12 00 :07:38 got read len 512 2017 /12/12 00 :07:38 ReadAt len 512 off 0 2017 /12/12 00 :07:38 Start HTTP GET with Range: bytes = 0 -511 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/ 2017 /12/12 00 :07:39 got read len 512 2017 /12/12 00 :07:39 ReadAt len 512 off 512 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 512 -1023 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/00/ 2017 /12/12 00 :07:39 got read len 512 2017 /12/12 00 :07:39 ReadAt len 512 off 1024 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 1024 -1535 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/00/000/ 2017 /12/12 00 :07:39 got read len 512 2017 /12/12 00 :07:39 ReadAt len 512 off 1536 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 1536 -2047 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/00/000/001/ 2017 /12/12 00 :07:39 got read len 512 2017 /12/12 00 :07:39 ReadAt len 512 off 2048 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 2048 -2559 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/00/000/001/us-patent-image.xml 2017 /12/12 00 :07:39 got seek 0 1 2017 /12/12 00 :07:39 got seek 982 1 2017 /12/12 00 :07:39 got read len 42 2017 /12/12 00 :07:39 ReadAt len 42 off 3542 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 3542 -3583 2017 /12/12 00 :07:39 HTTP ok. 2017 /12/12 00 :07:39 got read len 512 2017 /12/12 00 :07:39 ReadAt len 512 off 3584 2017 /12/12 00 :07:39 Start HTTP GET with Range: bytes = 3584 -4095 2017 /12/12 00 :07:39 HTTP ok. File: 00000001 -X009741H/00/000/001/00000001.pdf 2017 /12/12 00 :07:39 got seek 0 1 2017 /12/12 00 :07:39 got seek 320840 1 2017 /12/12 00 :07:39 got read len 184 2017 /12/12 00 :07:39 ReadAt len 184 off 324936 ...etc...

Can you see the problem? That’s a whole lot of HTTP transactions! The TAR reader is working through the TAR stream a little bit at a time, issuing a stream of tiny reads. All of those short HTTP transactions are hard on the server, and terrible for our throughput, since each one entails many round-trips to the server.

The solution, of course, is caching. Instead of reading just the first 512 bytes that the TAR reader asks for, I read 10 times that many, so that the next several reads will be serviced directly from cache. If there is a read that is outside of the cache, we assume that the other reads will come in that area as well, and drop the entire current cache, in order to fill it with 10x the current read amount from the new current offset.

The fact that the TAR reader sends a lot of small reads points out something very important about buffering. Giving the results of os.Open directly to tar.NewReader isn’t very clever, especially if your plan is to jump through the file looking for metadata. While it is true that *os.File implements io.ReadSeeker, we now know that TAR is going to issue a huge number of small system calls to the kernel. The solution, much like caching was the solution above, might be to use the bufio package to buffer the *os.File, so that the small reads that TAR is issuing will come out of RAM instead of going to the operating system. But be careful: is it really the solution? Does bufio.Reader really implement io.ReadSeeker and io.ReadAt like we need? (Spoiler: it doesn’t; maybe one of you readers would like to show us how to speed up Go’s tar using a replacement for bufio next advent season?)

I hope you have enjoyed this little trip through the standard library and HTTP, taking a look at how to work together with the standard library in order to help it achieve more than it was was written to do, so that it can help you get your job done. When you implement io.Reader and friends, you get a chance to go behind the scenes of the libraries you are calling into, and feed them data from places their authors never expected!