📚 speedtest-resize - Awesome Go Library for Benchmarks
Compare various Image resize algorithms for the Go language.
Detailed Description of speedtest-resize
speedtest-resize
Compare various Image resize algorithms for the Go language
I am writing a web gallery called gonagall in Go (https://github.com/fawick/gonagall). For that, I need a efficient solution for scaling and resizing a lot of images (mostly JPGs) to generate thumbnails and bandwidth-friendly sized copies from high-resolution original photo files.
In this project I compare the speed of a few selected image resizing algorithms with each other as well as with ImageMagick and GraphicsMagick. The competitors are
- https://github.com/nfnt/resize, Pure golang image resizing, more precisely only Nearest-Neighbor interpolation that comes with that Go package.
- https://github.com/disintegration/gift Again, I use one of the fastest algorithms of the package. Here, it's called 'Box'
- https://github.com/disintegration/imaging Again, I use one of the fastest algorithms of the package. Here, it's called 'Box'
- https://github.com/anthonynsimon/bild A collection of parallel image processing algorithms in pure Go ('NearestNeighbor' algorithm)
- ImageMagick convert with the options
-resize 150x150>
- ImageMagick convert with the
options
-define "jpeg:size=300x300 -thumbnail 150x150>
.-thumbnail
is considered to be faster than resize, and the-define
will reduce the size (in terms of memory footprint) of the original image on reading. - GraphicsMagick convert with the
options
-define "jpeg:size=300x300 -thumbnail 150x150>
. - https://github.com/gographics/imagick Go wrapper for the MagickWand API, again the Box algorithm is used for the sake of comparing the results.
- https://github.com/lazywei/go-opencv Go binding for OpenCV, using the fastest algorithm.
- https://github.com/bamiaux/rez, pure go resizer, using bilinear interpolation in these tests
- https://github.com/DAddYE/vips, bindings for libvips (http://www.vips.ecs.soton.ac.uk/index.php?title=Libvips)
- https://github.com/daddye/trez, an image resizer build on top of OpenCV and jpeg-turbo
- https://camlistore.org/pkg/images/fastjpeg, package fastjpeg uses djpeg(1), from the Independent JPEG Group's (www.ijg.org) jpeg package, to quickly down-sample images on load
- External command
vipsthumbnail
with parameters-s 150
(https://github.com/libvips/libvips) - External command
epeg
with parameters-m 150
(https://github.com/mattes/epeg)
Installation
To run the tests go get
the source and compile/run it:
$ go get -u github.com/fawick/speedtest-resize -tags all
$ cd $GOPATH/src/speedtest-resize
$ go run main.go <jpg file folder>
Alternatively, call the go command (or the compiled binary) from the image folder without supplying a parameter
$ cd <jpg file folder>
$ go run $GOPATH/src/speedtest-resize/main.go
A the package requires different 3rdparty libraries to be installed, you can use build tags to control what libraries to use. The following build tags are available:
Tag | Description |
---|---|
opencv | Include lazywei/go-opencv in the tests. |
imagick | Include gographics/imagick in the tests. |
vips | Include DAddYE/vips in the tests . |
fastjpeg | Include camlistore/fastjpeg in the tests . |
all | An alias for opencv imagick fastjpeg vips . |
nopure | Don't include the Pure Golang packages |
noexec | Don't run the tests that execute other programs. |
The default go get
without any tags will try the packages that are pure go
and the external programs but not use any non-Go library.
Benchmark
Im my test scenario all of these tools/packages are unleashed on a directory containing JPG photo files, all of which have a resolution of 5616x3744 pixels (aspect ratio 2:1, both landscape and portrait).
For each tool/package and for all files, the total time for loading the original file, scaling the image to a thumbnail of 150x100 pixels, and writing it to a new JPG file is measured. In the end, the total runtime for processing the 10 first files and the average time per file is printed for each tool/package.
The scenario is run on a Intel(R) Pentium(R) Dual T2390 @ 1.86GHz running Ubuntu 14.04. Here are the results:
Table | Time (avg.) | Size (avg.) | Pure Go |
---|---|---|---|
vipsthumbnail | 0.120s | 0.065% | |
ImageMagick_thumbnail | 0.326s | 0.242% | |
vips | 0.339s | 0.100% | |
magickwand_box | 1.148s | 0.538% | |
ImageMagick_resize | 2.316s | 0.626% | |
rez_bilinear | 2.913s | 0.053% | X |
Nfnt_NearestNeighbor | 3.498s | 0.057% | X |
imaging_box | 4.734s | 0.057% | X |
gift_box | 4.746s | 0.057% | X |
Yet another scenario ran by lazywei, 2.5GHz Intel Core i5, Mac OS X 10.9.1:
Tables | Average time per file |
---|---|
magickwand_box | 155.371531ms |
imaging_Box | 463.459339ms |
Nfnt_NearestNeighbor | 1.436507946s |
OpenCv | 97.353041ms |
Yet another scenario ran by bamiaux, 3.3GHz Intel Core i5, win 7:
Tables | Average time per file |
---|---|
rez_bilinear | 148ms |
imaging_Box | 243ms |
Nfnt_NearestNeighbor | 233ms |
A new scenario ran by nono, 3.4GHz Intel Core i7, Ubuntu 16.10:
Table | Time (file avg.) | Size (file avg.) | Pure Go |
---|---|---|---|
ImageMagick_thumbnail | 0.057s | 0.361% | |
vips | 0.070s | 0.260% | |
epeg | 0.079s | 0.207% | |
fastjpeg | 0.082s | 0.186% | |
opencv | 0.110s | 0.597% | |
vipsthumbnail | 0.115s | 0.441% | |
GraphicsMagick_thumbnail | 0.172s | 0.427% | |
magickwand_box | 0.190s | 0.575% | |
T-REZ | 0.204s | 0.323% | |
rez_bilinear | 0.349s | 0.140% | X |
x_image_draw | 0.370s | 0.160% | X |
imaging_box | 0.439s | 0.146% | X |
gift_box | 0.440s | 0.146% | X |
Nfnt_NearestNeighbor | 0.447s | 0.146% | X |
bild_resize | 0.515s | 0.206% | X |
ImageMagick_resize | 0.568s | 0.542% |
So, what is to learn from that? While all of the currently existing pure-Go-language solutions do a pretty good job in generating good-looking thumbnails, they are much slower than the veteran dedicated image processing toolboxes. That is hardly surprising, given that both ImageMagick and GraphicsMagick have been around for decades and have been optimized to work as efficient as possible. Go and its image processing packages are still the new kids on the block, and while they work pretty neat for the occasional tweak of an image or two, I rather not use them as the default image processor in gonagall yet.
I was surprised to find that GraphicsMagick was slower than ImageMagick in my test scenario, as I expected it to be exactly the other way around with GraphicsMagick's fancy multi-processor algorithms.
While the imagick Wrapper is written in Go, it uses CGO bindings of the C MagickWand API. It outperforms the pure-Go approaches (five times faster than http://github.com/disintegration/imaging) but it still slower than calling ImageMagick in an external process. Of the above 1.13 seconds, only around 275 millisecs were used for resizing and saving an individual file, while over 850 ms were used by simply loading the file. I wonder how much optimization can still be done in the imagick loading routines.
Holy cow! vipsthumbnail
is blazing fast.