stevenbooru/vendor/src/github.com/nfnt/resize/README.md

Resize
======

Image resizing for the [Go programming language](http://golang.org) with common interpolation methods.

[![Build Status](https://travis-ci.org/nfnt/resize.svg)](https://travis-ci.org/nfnt/resize)

Installation
------------

```bash
$ go get github.com/nfnt/resize
```

It's that easy!

Usage
-----

This package needs at least Go 1.1. Import package with

```go
import "github.com/nfnt/resize"
```

The resize package provides 2 functions:

* `resize.Resize` creates a scaled image with new dimensions (`width`, `height`) using the interpolation function `interp`.
  If either `width` or `height` is set to 0, it will be set to an aspect ratio preserving value.
* `resize.Thumbnail` downscales an image preserving its aspect ratio to the maximum dimensions (`maxWidth`, `maxHeight`).
  It will return the original image if original sizes are smaller than the provided dimensions.

```go
resize.Resize(width, height uint, img image.Image, interp resize.InterpolationFunction) image.Image
resize.Thumbnail(maxWidth, maxHeight uint, img image.Image, interp resize.InterpolationFunction) image.Image
```

The provided interpolation functions are (from fast to slow execution time)

- `NearestNeighbor`: [Nearest-neighbor interpolation](http://en.wikipedia.org/wiki/Nearest-neighbor_interpolation)
- `Bilinear`: [Bilinear interpolation](http://en.wikipedia.org/wiki/Bilinear_interpolation)
- `Bicubic`: [Bicubic interpolation](http://en.wikipedia.org/wiki/Bicubic_interpolation)
- `MitchellNetravali`: [Mitchell-Netravali interpolation](http://dl.acm.org/citation.cfm?id=378514)
- `Lanczos2`: [Lanczos resampling](http://en.wikipedia.org/wiki/Lanczos_resampling) with a=2
- `Lanczos3`: [Lanczos resampling](http://en.wikipedia.org/wiki/Lanczos_resampling) with a=3

Which of these methods gives the best results depends on your use case.

Sample usage:

```go
package main

import (
	"github.com/nfnt/resize"
	"image/jpeg"
	"log"
	"os"
)

func main() {
	// open "test.jpg"
	file, err := os.Open("test.jpg")
	if err != nil {
		log.Fatal(err)
	}

	// decode jpeg into image.Image
	img, err := jpeg.Decode(file)
	if err != nil {
		log.Fatal(err)
	}
	file.Close()

	// resize to width 1000 using Lanczos resampling
	// and preserve aspect ratio
	m := resize.Resize(1000, 0, img, resize.Lanczos3)

	out, err := os.Create("test_resized.jpg")
	if err != nil {
		log.Fatal(err)
	}
	defer out.Close()

	// write new image to file
	jpeg.Encode(out, m, nil)
}
```

Caveats
-------

* Optimized access routines are used for `image.RGBA`, `image.NRGBA`, `image.RGBA64`, `image.NRGBA64`, `image.YCbCr`, `image.Gray`, and `image.Gray16` types. All other image types are accessed in a generic way that will result in slow processing speed.
* JPEG images are stored in `image.YCbCr`. This image format stores data in a way that will decrease processing speed. A resize may be up to 2 times slower than with `image.RGBA`. 


Downsizing Samples
-------

Downsizing is not as simple as it might look like. Images have to be filtered before they are scaled down, otherwise aliasing might occur.
Filtering is highly subjective: Applying too much will blur the whole image, too little will make aliasing become apparent.
Resize tries to provide sane defaults that should suffice in most cases.

### Artificial sample

Original image
![Rings](http://nfnt.github.com/img/rings_lg_orig.png)

<table>
<tr>
<th><img src="http://nfnt.github.com/img/rings_300_NearestNeighbor.png" /><br>Nearest-Neighbor</th>
<th><img src="http://nfnt.github.com/img/rings_300_Bilinear.png" /><br>Bilinear</th>
</tr>
<tr>
<th><img src="http://nfnt.github.com/img/rings_300_Bicubic.png" /><br>Bicubic</th>
<th><img src="http://nfnt.github.com/img/rings_300_MitchellNetravali.png" /><br>Mitchell-Netravali</th>
</tr>
<tr>
<th><img src="http://nfnt.github.com/img/rings_300_Lanczos2.png" /><br>Lanczos2</th>
<th><img src="http://nfnt.github.com/img/rings_300_Lanczos3.png" /><br>Lanczos3</th>
</tr>
</table>

### Real-Life sample

Original image  
![Original](http://nfnt.github.com/img/IMG_3694_720.jpg)

<table>
<tr>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_NearestNeighbor.png" /><br>Nearest-Neighbor</th>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_Bilinear.png" /><br>Bilinear</th>
</tr>
<tr>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_Bicubic.png" /><br>Bicubic</th>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_MitchellNetravali.png" /><br>Mitchell-Netravali</th>
</tr>
<tr>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_Lanczos2.png" /><br>Lanczos2</th>
<th><img src="http://nfnt.github.com/img/IMG_3694_300_Lanczos3.png" /><br>Lanczos3</th>
</tr>
</table>


License
-------

Copyright (c) 2012 Jan Schlicht <janschlicht@gmail.com>
Resize is released under a MIT style license.
Add dependencies 2015-07-31 15:17:14 +00:00			`Resize`
			`======`

			`Image resizing for the [Go programming language](http://golang.org) with common interpolation methods.`

			`[![Build Status](https://travis-ci.org/nfnt/resize.svg)](https://travis-ci.org/nfnt/resize)`

			`Installation`
			`------------`

			```bash
			`$ go get github.com/nfnt/resize`
			```

			`It's that easy!`

			`Usage`
			`-----`

			`This package needs at least Go 1.1. Import package with`

			```go
			`import "github.com/nfnt/resize"`
			```

			`The resize package provides 2 functions:`

			* `resize.Resize` creates a scaled image with new dimensions (`width`, `height`) using the interpolation function `interp`.
			If either `width` or `height` is set to 0, it will be set to an aspect ratio preserving value.
			* `resize.Thumbnail` downscales an image preserving its aspect ratio to the maximum dimensions (`maxWidth`, `maxHeight`).
			`It will return the original image if original sizes are smaller than the provided dimensions.`

			```go
			`resize.Resize(width, height uint, img image.Image, interp resize.InterpolationFunction) image.Image`
			`resize.Thumbnail(maxWidth, maxHeight uint, img image.Image, interp resize.InterpolationFunction) image.Image`
			```

			`The provided interpolation functions are (from fast to slow execution time)`

			- `NearestNeighbor`: [Nearest-neighbor interpolation](http://en.wikipedia.org/wiki/Nearest-neighbor_interpolation)
			- `Bilinear`: [Bilinear interpolation](http://en.wikipedia.org/wiki/Bilinear_interpolation)
			- `Bicubic`: [Bicubic interpolation](http://en.wikipedia.org/wiki/Bicubic_interpolation)
			- `MitchellNetravali`: [Mitchell-Netravali interpolation](http://dl.acm.org/citation.cfm?id=378514)
			- `Lanczos2`: [Lanczos resampling](http://en.wikipedia.org/wiki/Lanczos_resampling) with a=2
			- `Lanczos3`: [Lanczos resampling](http://en.wikipedia.org/wiki/Lanczos_resampling) with a=3

			`Which of these methods gives the best results depends on your use case.`

			`Sample usage:`

			```go
			`package main`

			`import (`
			`"github.com/nfnt/resize"`
			`"image/jpeg"`
			`"log"`
			`"os"`
			`)`

			`func main() {`
			`// open "test.jpg"`
			`file, err := os.Open("test.jpg")`
			`if err != nil {`
			`log.Fatal(err)`
			`}`

			`// decode jpeg into image.Image`
			`img, err := jpeg.Decode(file)`
			`if err != nil {`
			`log.Fatal(err)`
			`}`
			`file.Close()`

			`// resize to width 1000 using Lanczos resampling`
			`// and preserve aspect ratio`
			`m := resize.Resize(1000, 0, img, resize.Lanczos3)`

			`out, err := os.Create("test_resized.jpg")`
			`if err != nil {`
			`log.Fatal(err)`
			`}`
			`defer out.Close()`

			`// write new image to file`
			`jpeg.Encode(out, m, nil)`
			`}`
			```

			`Caveats`
			`-------`

			* Optimized access routines are used for `image.RGBA`, `image.NRGBA`, `image.RGBA64`, `image.NRGBA64`, `image.YCbCr`, `image.Gray`, and `image.Gray16` types. All other image types are accessed in a generic way that will result in slow processing speed.
			* JPEG images are stored in `image.YCbCr`. This image format stores data in a way that will decrease processing speed. A resize may be up to 2 times slower than with `image.RGBA`.


			`Downsizing Samples`
			`-------`

			`Downsizing is not as simple as it might look like. Images have to be filtered before they are scaled down, otherwise aliasing might occur.`
			`Filtering is highly subjective: Applying too much will blur the whole image, too little will make aliasing become apparent.`
			`Resize tries to provide sane defaults that should suffice in most cases.`

			`### Artificial sample`

			`Original image`
			`![Rings](http://nfnt.github.com/img/rings_lg_orig.png)`

			`<table>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/rings_300_NearestNeighbor.png" /><br>Nearest-Neighbor</th>`
			`<th><img src="http://nfnt.github.com/img/rings_300_Bilinear.png" /><br>Bilinear</th>`
			`</tr>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/rings_300_Bicubic.png" /><br>Bicubic</th>`
			`<th><img src="http://nfnt.github.com/img/rings_300_MitchellNetravali.png" /><br>Mitchell-Netravali</th>`
			`</tr>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/rings_300_Lanczos2.png" /><br>Lanczos2</th>`
			`<th><img src="http://nfnt.github.com/img/rings_300_Lanczos3.png" /><br>Lanczos3</th>`
			`</tr>`
			`</table>`

			`### Real-Life sample`

			`Original image`
			`![Original](http://nfnt.github.com/img/IMG_3694_720.jpg)`

			`<table>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_NearestNeighbor.png" /><br>Nearest-Neighbor</th>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_Bilinear.png" /><br>Bilinear</th>`
			`</tr>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_Bicubic.png" /><br>Bicubic</th>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_MitchellNetravali.png" /><br>Mitchell-Netravali</th>`
			`</tr>`
			`<tr>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_Lanczos2.png" /><br>Lanczos2</th>`
			`<th><img src="http://nfnt.github.com/img/IMG_3694_300_Lanczos3.png" /><br>Lanczos3</th>`
			`</tr>`
			`</table>`


			`License`
			`-------`

			`Copyright (c) 2012 Jan Schlicht <janschlicht@gmail.com>`
			`Resize is released under a MIT style license.`