mirror of
https://bitbucket.org/s_l_teichmann/mtsatellite
synced 2024-11-11 04:30:22 +01:00
530 lines
11 KiB
Go
530 lines
11 KiB
Go
// Copyright 2014, 2015 by Sascha L. Teichmann
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// Use of this source code is governed by the MIT license
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// that can be found in the LICENSE file.
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package common
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import (
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"container/heap"
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"image"
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"image/color"
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"image/draw"
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"math"
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)
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type Area struct {
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X1, Z1 int16
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X2, Z2 int16
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}
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type Renderer struct {
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width int
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height int
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xOfs int16
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zOfs int16
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yBuffer []int32
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yMin []int32
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cBuffer []int32
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RejectedBlocks int
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SolidBlocks int
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TransparentBlocks int
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spans *SpanPool
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tBuffer []*Span
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}
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type YOrder struct {
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Renderer *Renderer
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blocks []*Block
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capacity int
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}
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func NewYOrder(renderer *Renderer, capacity int) *YOrder {
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return &YOrder{
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Renderer: renderer,
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blocks: make([]*Block, 0, capacity),
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capacity: capacity}
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}
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func (yo *YOrder) Reset() {
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yo.blocks = yo.blocks[0:0]
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}
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func copyData(data []byte) []byte {
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l := len(data)
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ndata := make([]byte, l, Max(l, 8*1024))
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copy(ndata, data)
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return ndata
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}
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func (yo *YOrder) RenderBlock(block *Block, colors *Colors) (err error) {
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var nblock *Block
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if len(yo.blocks) == yo.capacity {
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oblock := yo.blocks[0]
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if oblock.Coord.Y < block.Coord.Y {
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// New one is above highest old. Directly render new.
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err = yo.Renderer.RenderBlock(block, colors)
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return
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}
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// Render old one. Store copy of new in heap.
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heap.Pop(yo)
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err = yo.Renderer.RenderBlock(oblock, colors)
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l := len(block.Data)
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if cap(oblock.Data) < l {
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oblock.Data = make([]byte, l, Max(l, 8*1024))
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} else {
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oblock.Data = oblock.Data[0:l]
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}
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copy(oblock.Data, block.Data)
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oblock.Coord = block.Coord
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nblock = oblock
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} else {
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nblock = &Block{Coord: block.Coord, Data: copyData(block.Data)}
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}
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heap.Push(yo, nblock)
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return
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}
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func (yo *YOrder) Drain(colors *Colors) (err error) {
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for len(yo.blocks) > 0 {
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if err = yo.Renderer.RenderBlock(heap.Pop(yo).(*Block), colors); err != nil {
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return
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}
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}
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return
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}
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func (yo *YOrder) Len() int {
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return len(yo.blocks)
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}
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func (yo *YOrder) Swap(i, j int) {
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yo.blocks[i], yo.blocks[j] = yo.blocks[j], yo.blocks[i]
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}
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func (yo *YOrder) Less(i, j int) bool {
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// Reverse order intented.
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return yo.blocks[i].Coord.Y > yo.blocks[j].Coord.Y
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}
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func (yo *YOrder) Push(x interface{}) {
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yo.blocks = append(yo.blocks, x.(*Block))
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}
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func (yo *YOrder) Pop() (x interface{}) {
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l := len(yo.blocks)
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x = yo.blocks[l-1]
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yo.blocks = yo.blocks[0 : l-1]
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return x
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}
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func NewRenderer(width, height int, transparent bool) (renderer *Renderer) {
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dim := width * height
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pixSize := dim * 16 * 16
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yBuffer := make([]int32, pixSize)
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cBuffer := make([]int32, pixSize)
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yMin := make([]int32, dim)
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var tBuffer []*Span
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var spans *SpanPool
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if transparent {
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tBuffer = make([]*Span, pixSize)
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spans = NewSpanPool()
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}
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renderer = &Renderer{
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width: width,
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height: height,
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yBuffer: yBuffer,
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cBuffer: cBuffer,
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yMin: yMin,
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tBuffer: tBuffer,
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spans: spans}
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renderer.Reset()
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return
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}
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func (r *Renderer) SetPos(xOfs, zOfs int16) {
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r.xOfs = xOfs
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r.zOfs = zOfs
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}
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func (r *Renderer) Reset() {
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for i, n := 0, len(r.yBuffer); i < n; i++ {
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r.yBuffer[i] = math.MinInt32
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r.cBuffer[i] = -1
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}
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for i, n := 0, len(r.yMin); i < n; i++ {
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r.yMin[i] = math.MinInt32
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}
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if r.TransparentBlocks > 0 {
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r.TransparentBlocks = 0
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for i, t := range r.tBuffer {
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if t != nil {
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r.spans.FreeAll(t)
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r.tBuffer[i] = nil
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}
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}
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}
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r.SolidBlocks = 0
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r.RejectedBlocks = 0
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}
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func (r *Renderer) IsFilled() bool {
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for _, y := range r.yMin {
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if y == math.MinInt32 {
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return false
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}
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}
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return true
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}
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func (r *Renderer) IsEmpty() bool {
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return r.SolidBlocks == 0 && r.TransparentBlocks == 0
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}
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func (r *Renderer) RenderBlock(block *Block, colors *Colors) (err error) {
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bx := block.Coord.X - r.xOfs
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bz := block.Coord.Z - r.zOfs
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// We do not need to render the block if the whole 16x16 area
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// is already filled and the block is strictly below.
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blockY := int32(block.Coord.Y) << 4
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pos := int(bz)*r.width + int(bx)
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if blockY < r.yMin[pos] {
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r.RejectedBlocks++
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return
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}
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// Decoding is pretty expensive so do it that late.
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var db *DecodedBlock
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if db, err = NewDecodedBlock(block.Data, colors); err != nil {
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return
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}
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if db.AirOnly() {
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r.RejectedBlocks++
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return
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}
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w := r.width << 4
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ofs := int(bz)*w<<4 + int(bx)<<4
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yB := r.yBuffer
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yMin := int32(math.MaxInt32)
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if db.Transparent && r.tBuffer != nil {
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r.TransparentBlocks++
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for z := 0; z < 16; z++ {
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for x := 0; x < 16; x++ {
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currentY := yB[ofs]
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if currentY < blockY {
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for y := 15; y >= 0; y-- {
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if c, ok := db.Content(x, y, z); ok {
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cY := blockY + int32(y)
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if colors.IsTransparent(c) {
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r.tBuffer[ofs] = r.spans.Insert(r.tBuffer[ofs], cY, c)
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} else {
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r.cBuffer[ofs] = c
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currentY = cY
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yB[ofs] = currentY
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break
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}
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}
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}
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}
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if currentY < yMin {
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yMin = currentY
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}
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ofs++
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}
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ofs += w - 16
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}
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} else {
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r.SolidBlocks++
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for z := 0; z < 16; z++ {
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for x := 0; x < 16; x++ {
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currentY := yB[ofs]
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if currentY < blockY {
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for y := 15; y >= 0; y-- {
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if c, ok := db.Content(x, y, z); ok {
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r.cBuffer[ofs] = c
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currentY = blockY + int32(y)
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yB[ofs] = currentY
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break
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}
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}
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}
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if currentY < yMin {
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yMin = currentY
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}
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ofs++
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}
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ofs += w - 16
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}
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}
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r.yMin[pos] = yMin
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return
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}
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func (a Area) contains(x, z int16) bool {
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return x >= a.X1 && x <= a.X2 && z >= a.Z1 && z <= a.Z2
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}
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func (a Area) higher() bool {
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return a.Z2-a.Z1 > a.X2-a.X1
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}
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func areasContain(areas []Area, x, z int16) bool {
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for _, r := range areas {
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if r.contains(x, z) {
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return true
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}
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}
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return false
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}
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// UncoveredAreas implements a greedy algorithm to figure out
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// a list of disjunct areas of free regions in the domain
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// to the (x, z) block plane.
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// oldAreas are searched and found free areas are appended
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// to newAreas which ist return.
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// This is useful to spatial query only blocks from db
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// that are not below already rendered blocks.
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func (r *Renderer) UncoveredAreas(newAreas, oldAreas []Area) []Area {
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yM := r.yMin
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// Scan old areas.
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for _, oldArea := range oldAreas {
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for z := oldArea.Z1; z <= oldArea.Z2; z++ {
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row := z * int16(r.width)
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for x := oldArea.X1; x <= oldArea.X2; x++ {
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// Uncovered and not in list of new areas?
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if yM[row+x] > math.MinInt32 || areasContain(newAreas, x, z) {
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continue
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}
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area := Area{X1: x, Z1: z, X2: x, Z2: z}
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// Try to extend the area in x and/or z till no further extension is possible.
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for extendDirs := 1 | 2; extendDirs != 0; {
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var xFirst bool
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// Try to extend in the direction with most gain
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// of blocks.
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if area.higher() { // Higher means to win more blocks in x direction.
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xFirst = true
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}
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dirs:
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for i := 0; i < 2; i++ {
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if xFirst {
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// Extension in x possible?
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if extendDirs&1 == 1 {
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nx := area.X2 + 1
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if nx >= int16(r.width) {
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extendDirs &= ^1
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continue
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}
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// Scan line below current area if its fully free.
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for nz := area.Z1; nz <= area.Z2; nz++ {
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if yM[nz*int16(r.width)+nx] > math.MinInt32 || areasContain(newAreas, nx, nz) {
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extendDirs &= ^1
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continue dirs
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}
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}
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// free -> extend
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area.X2 = nx
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}
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} else if extendDirs&2 == 2 {
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// Symmetric case in z direction
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nz := area.Z2 + 1
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if nz >= int16(r.height) {
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extendDirs &= ^2
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continue
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}
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// Scan line right beside the area if its free.
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row2 := nz * int16(r.width)
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for nx := area.X1; nx <= area.X2; nx++ {
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if yM[row2+nx] > math.MinInt32 || areasContain(newAreas, nx, nz) {
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extendDirs &= ^2
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continue dirs
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}
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}
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area.Z2 = nz
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}
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// Switch to other search direction (x -> z or z -> x)
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xFirst = !xFirst
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}
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}
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// At this point the area is extended to max.
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newAreas = append(newAreas, area)
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}
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}
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}
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return newAreas
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}
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func (r *Renderer) CreateImage(colors []color.RGBA, background color.RGBA) *image.RGBA {
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pw, ph := r.width<<4, r.height<<4
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image := image.NewRGBA(image.Rect(0, 0, pw, ph))
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ofs, numCols := 0, int32(len(colors))
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for z := ph - 1; z >= 0; z-- {
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for x := 0; x < pw; x++ {
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colIdx := r.cBuffer[ofs]
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if colIdx >= 0 && colIdx < numCols {
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image.Set(x, z, colors[colIdx])
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} else {
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image.Set(x, z, background)
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}
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ofs++
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}
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}
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return image
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}
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func safeColor(x int32) uint8 {
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switch {
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case x < 0:
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return 0
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case x > 255:
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return 255
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default:
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return uint8(x)
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}
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}
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func BackgroundImage(width, height int, bg color.RGBA) *image.RGBA {
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m := image.NewRGBA(image.Rect(0, 0, width, height))
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draw.Draw(m, m.Bounds(), &image.Uniform{bg}, image.ZP, draw.Src)
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return m
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}
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func (r *Renderer) CreateShadedImage(
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xOfs, zOfs, width, height int,
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cols *Colors, background color.RGBA) *image.RGBA {
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image := image.NewRGBA(image.Rect(0, 0, width, height))
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pw := r.width << 4
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cs := cols.Colors
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ofs, numCols := zOfs*pw+xOfs, int32(len(cs))
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stride := pw - width
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istride := image.Stride + 4*width
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iofs := image.PixOffset(0, height-1)
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pix := image.Pix
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if r.TransparentBlocks > 0 { // Fast path for transparent images.
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for z := height - 1; z >= 0; z-- {
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for x := 0; x < width; x++ {
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colIdx := r.cBuffer[ofs]
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if colIdx < 0 || colIdx >= numCols {
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pix[iofs] = background.R
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pix[iofs+1] = background.G
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pix[iofs+2] = background.B
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pix[iofs+3] = 0xff
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} else {
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y := r.yBuffer[ofs]
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t := r.tBuffer[ofs]
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opaque := t == nil || t.Top() < y
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var y1, y2 int32
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if x == 0 {
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y1 = y
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} else {
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y1 = r.yBuffer[ofs-1]
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if opaque {
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if s := r.tBuffer[ofs-1]; s != nil {
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y1 = max32(y1, s.Top())
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}
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}
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}
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if z == 0 {
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y2 = y
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} else {
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y2 = r.yBuffer[ofs+pw]
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if opaque {
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if s := r.tBuffer[ofs+pw]; s != nil {
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y1 = max32(y1, s.Top())
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}
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}
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}
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d := ((y - y1) + (y - y2)) * 12
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if d > 36 {
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d = 36
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}
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col := cs[colIdx]
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col = color.RGBA{
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R: safeColor(int32(col.R) + d),
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G: safeColor(int32(col.G) + d),
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B: safeColor(int32(col.B) + d),
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A: 0xff}
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if !opaque {
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col = cols.BlendColors(t, col, y)
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}
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pix[iofs] = col.R
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pix[iofs+1] = col.G
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pix[iofs+2] = col.B
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pix[iofs+3] = col.A
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}
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iofs += 4
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ofs++
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}
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ofs += stride
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iofs -= istride
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}
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} else { // Solid images.
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for z := height - 1; z >= 0; z-- {
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for x := 0; x < width; x++ {
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colIdx := r.cBuffer[ofs]
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if colIdx < 0 || colIdx >= numCols {
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pix[iofs] = background.R
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pix[iofs+1] = background.G
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pix[iofs+2] = background.B
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pix[iofs+3] = 0xff
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} else {
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var y, y1, y2 int32
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y = r.yBuffer[ofs]
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if x == 0 {
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y1 = y
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} else {
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y1 = r.yBuffer[ofs-1]
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}
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if z == 0 {
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y2 = y
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} else {
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y2 = r.yBuffer[ofs+pw]
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}
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d := ((y - y1) + (y - y2)) * 12
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if d > 36 {
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d = 36
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}
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col := cs[colIdx]
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pix[iofs] = safeColor(int32(col.R) + d)
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pix[iofs+1] = safeColor(int32(col.G) + d)
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pix[iofs+2] = safeColor(int32(col.B) + d)
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pix[iofs+3] = 0xff
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}
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iofs += 4
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ofs++
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}
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ofs += stride
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iofs -= istride
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}
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}
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return image
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}
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