githaven-fork/modules/avatar/identicon/identicon.go
zeripath 1319ba6742
Use minio/sha256-simd for accelerated SHA256 (#23052)
minio/sha256-simd provides additional acceleration for SHA256 using
AVX512, SHA Extensions for x86 and ARM64 for ARM.

It provides a drop-in replacement for crypto/sha256 and if the
extensions are not available it falls back to standard crypto/sha256.

---------

Signed-off-by: Andrew Thornton <art27@cantab.net>
Co-authored-by: John Olheiser <john.olheiser@gmail.com>
2023-02-22 14:21:46 -05:00

142 lines
3.8 KiB
Go

// Copyright 2021 The Gitea Authors. All rights reserved.
// SPDX-License-Identifier: MIT
// Copied and modified from https://github.com/issue9/identicon/ (MIT License)
// Generate pseudo-random avatars by IP, E-mail, etc.
package identicon
import (
"fmt"
"image"
"image/color"
"github.com/minio/sha256-simd"
)
const minImageSize = 16
// Identicon is used to generate pseudo-random avatars
type Identicon struct {
foreColors []color.Color
backColor color.Color
size int
rect image.Rectangle
}
// New returns an Identicon struct with the correct settings
// size image size
// back background color
// fore all possible foreground colors. only one foreground color will be picked randomly for one image
func New(size int, back color.Color, fore ...color.Color) (*Identicon, error) {
if len(fore) == 0 {
return nil, fmt.Errorf("foreground is not set")
}
if size < minImageSize {
return nil, fmt.Errorf("size %d is smaller than min size %d", size, minImageSize)
}
return &Identicon{
foreColors: fore,
backColor: back,
size: size,
rect: image.Rect(0, 0, size, size),
}, nil
}
// Make generates an avatar by data
func (i *Identicon) Make(data []byte) image.Image {
h := sha256.New()
h.Write(data)
sum := h.Sum(nil)
b1 := int(sum[0]+sum[1]+sum[2]) % len(blocks)
b2 := int(sum[3]+sum[4]+sum[5]) % len(blocks)
c := int(sum[6]+sum[7]+sum[8]) % len(centerBlocks)
b1Angle := int(sum[9]+sum[10]) % 4
b2Angle := int(sum[11]+sum[12]) % 4
foreColor := int(sum[11]+sum[12]+sum[15]) % len(i.foreColors)
return i.render(c, b1, b2, b1Angle, b2Angle, foreColor)
}
func (i *Identicon) render(c, b1, b2, b1Angle, b2Angle, foreColor int) image.Image {
p := image.NewPaletted(i.rect, []color.Color{i.backColor, i.foreColors[foreColor]})
drawBlocks(p, i.size, centerBlocks[c], blocks[b1], blocks[b2], b1Angle, b2Angle)
return p
}
/*
# Algorithm
Origin: An image is splitted into 9 areas
```
-------------
| 1 | 2 | 3 |
-------------
| 4 | 5 | 6 |
-------------
| 7 | 8 | 9 |
-------------
```
Area 1/3/9/7 use a 90-degree rotating pattern.
Area 1/3/9/7 use another 90-degree rotating pattern.
Area 5 uses a random pattern.
The Patched Fix: make the image left-right mirrored to get rid of something like "swastika"
*/
// draw blocks to the paletted
// c: the block drawer for the center block
// b1,b2: the block drawers for other blocks (around the center block)
// b1Angle,b2Angle: the angle for the rotation of b1/b2
func drawBlocks(p *image.Paletted, size int, c, b1, b2 blockFunc, b1Angle, b2Angle int) {
nextAngle := func(a int) int {
return (a + 1) % 4
}
padding := (size % 3) / 2 // in cased the size can not be aligned by 3 blocks.
blockSize := size / 3
twoBlockSize := 2 * blockSize
// center
c(p, blockSize+padding, blockSize+padding, blockSize, 0)
// left top (1)
b1(p, 0+padding, 0+padding, blockSize, b1Angle)
// center top (2)
b2(p, blockSize+padding, 0+padding, blockSize, b2Angle)
b1Angle = nextAngle(b1Angle)
b2Angle = nextAngle(b2Angle)
// right top (3)
// b1(p, twoBlockSize+padding, 0+padding, blockSize, b1Angle)
// right middle (6)
// b2(p, twoBlockSize+padding, blockSize+padding, blockSize, b2Angle)
b1Angle = nextAngle(b1Angle)
b2Angle = nextAngle(b2Angle)
// right bottom (9)
// b1(p, twoBlockSize+padding, twoBlockSize+padding, blockSize, b1Angle)
// center bottom (8)
b2(p, blockSize+padding, twoBlockSize+padding, blockSize, b2Angle)
b1Angle = nextAngle(b1Angle)
b2Angle = nextAngle(b2Angle)
// lef bottom (7)
b1(p, 0+padding, twoBlockSize+padding, blockSize, b1Angle)
// left middle (4)
b2(p, 0+padding, blockSize+padding, blockSize, b2Angle)
// then we make it left-right mirror, so we didn't draw 3/6/9 before
for x := 0; x < size/2; x++ {
for y := 0; y < size; y++ {
p.SetColorIndex(size-x, y, p.ColorIndexAt(x, y))
}
}
}