package d2render

import (
	"encoding/binary"
	"image"
	"image/color"
	"sync"
	"time"

	"github.com/OpenDiablo2/OpenDiablo2/d2helper"

	"github.com/OpenDiablo2/OpenDiablo2/d2data/d2datadict"

	"github.com/hajimehoshi/ebiten"
)

// Sprite represents a type of object in D2 that is comprised of one or more frames and directions
type Sprite struct {
	Directions         uint32
	FramesPerDirection uint32
	atlas              *ebiten.Image
	atlasBytes         []byte
	Frames             []*SpriteFrame
	SpecialFrameTime   int
	StopOnLastFrame    bool
	X, Y               int
	Frame, Direction   uint8
	Blend              bool
	LastFrameTime      time.Time
	Animate            bool
	ColorMod           color.Color
	visible            bool
}

// SpriteFrame represents a single frame of a sprite
type SpriteFrame struct {
	Flip      uint32
	Width     uint32
	Height    uint32
	OffsetX   int32
	OffsetY   int32
	Unknown   uint32
	NextBlock uint32
	Length    uint32
	ImageData []int16
	FrameData []byte
	Image     *ebiten.Image
	cached    bool
}

// CreateSprite creates an instance of a sprite
func CreateSprite(data []byte, palette d2datadict.PaletteRec) *Sprite {
	result := &Sprite{
		X:                  50,
		Y:                  50,
		Frame:              0,
		Direction:          0,
		Blend:              false,
		ColorMod:           nil,
		Directions:         binary.LittleEndian.Uint32(data[16:20]),
		FramesPerDirection: binary.LittleEndian.Uint32(data[20:24]),
		Animate:            false,
		LastFrameTime:      time.Now(),
		SpecialFrameTime:   -1,
		StopOnLastFrame:    false,
	}
	dataPointer := uint32(24)
	totalFrames := result.Directions * result.FramesPerDirection
	framePointers := make([]uint32, totalFrames)
	for i := uint32(0); i < totalFrames; i++ {
		framePointers[i] = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
		dataPointer += 4
	}
	result.Frames = make([]*SpriteFrame, totalFrames)
	wg := sync.WaitGroup{}
	wg.Add(int(totalFrames))
	for i := uint32(0); i < totalFrames; i++ {
		go func(i uint32) {
			defer wg.Done()
			dataPointer := framePointers[i]
			result.Frames[i] = &SpriteFrame{}
			result.Frames[i].Flip = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].Width = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].Height = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].OffsetX = d2helper.BytesToInt32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].OffsetY = d2helper.BytesToInt32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].Unknown = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].NextBlock = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].Length = binary.LittleEndian.Uint32(data[dataPointer : dataPointer+4])
			dataPointer += 4
			result.Frames[i].ImageData = make([]int16, result.Frames[i].Width*result.Frames[i].Height)
			for fi := range result.Frames[i].ImageData {
				result.Frames[i].ImageData[fi] = -1
			}

			x := uint32(0)
			y := result.Frames[i].Height - 1
			for true {
				b := data[dataPointer]
				dataPointer++
				if b == 0x80 {
					if y == 0 {
						break
					}
					y--
					x = 0
				} else if (b & 0x80) > 0 {
					transparentPixels := b & 0x7F
					for ti := byte(0); ti < transparentPixels; ti++ {
						result.Frames[i].ImageData[x+(y*result.Frames[i].Width)+uint32(ti)] = -1
					}
					x += uint32(transparentPixels)
				} else {
					for bi := 0; bi < int(b); bi++ {
						result.Frames[i].ImageData[x+(y*result.Frames[i].Width)+uint32(bi)] = int16(data[dataPointer])
						dataPointer++
					}
					x += uint32(b)
				}
			}
			result.Frames[i].FrameData = make([]byte, result.Frames[i].Width*result.Frames[i].Height*4)
			for ii := uint32(0); ii < result.Frames[i].Width*result.Frames[i].Height; ii++ {
				if result.Frames[i].ImageData[ii] < 1 { // TODO: Is this == -1 or < 1?
					continue
				}
				result.Frames[i].FrameData[ii*4] = palette.Colors[result.Frames[i].ImageData[ii]].R
				result.Frames[i].FrameData[(ii*4)+1] = palette.Colors[result.Frames[i].ImageData[ii]].G
				result.Frames[i].FrameData[(ii*4)+2] = palette.Colors[result.Frames[i].ImageData[ii]].B
				result.Frames[i].FrameData[(ii*4)+3] = 0xFF
			}
			//newImage, _ := ebiten.NewImageFromImage(img, ebiten.FilterNearest)
			//result.Frames[i].Image = newImage
			//img = nil
		}(i)
	}
	wg.Wait()
	totalWidth := 0
	totalHeight := 0
	frame := 0
	for d := 0; d < int(result.Directions); d++ {
		curMaxWidth := 0
		for f := 0; f < int(result.FramesPerDirection); f++ {
			curMaxWidth = int(d2helper.Max(uint32(curMaxWidth), result.Frames[frame].Width))
			totalHeight += int(result.Frames[frame].Height)
			frame++
		}
		totalWidth += curMaxWidth
	}
	result.atlas, _ = ebiten.NewImage(totalWidth, totalHeight, ebiten.FilterNearest)
	result.atlasBytes = make([]byte, totalWidth*totalHeight*4)
	frame = 0
	curX := 0
	curY := 0
	for d := 0; d < int(result.Directions); d++ {
		curMaxWidth := 0
		for f := 0; f < int(result.FramesPerDirection); f++ {
			curMaxWidth = int(d2helper.Max(uint32(curMaxWidth), result.Frames[frame].Width))
			result.Frames[frame].Image = result.atlas.SubImage(image.Rect(curX, curY, curX+int(result.Frames[frame].Width), curY+int(result.Frames[frame].Height))).(*ebiten.Image)
			curY += int(result.Frames[frame].Height)
			frame++
		}
		curX += curMaxWidth
		curY = 0
	}
	return result
}

func (v *Sprite) cacheFrame(frame int) {
	if v.Frames[frame].cached {
		return
	}

	r := v.Frames[frame].Image.Bounds().Min
	curX := r.X
	curY := r.Y
	totalWidth := v.atlas.Bounds().Max.X
	for y := 0; y < int(v.Frames[frame].Height); y++ {
		for x := 0; x < int(v.Frames[frame].Width); x++ {
			pix := (x + (y * int(v.Frames[frame].Width))) * 4
			idx := (curX + x + ((curY + y) * totalWidth)) * 4
			v.atlasBytes[idx] = v.Frames[frame].FrameData[pix]
			v.atlasBytes[idx+1] = v.Frames[frame].FrameData[pix+1]
			v.atlasBytes[idx+2] = v.Frames[frame].FrameData[pix+2]
			v.atlasBytes[idx+3] = v.Frames[frame].FrameData[pix+3]
		}
	}
	v.atlas.ReplacePixels(v.atlasBytes)
	v.Frames[frame].cached = true
}

// GetSize returns the size of the sprite
func (v *Sprite) GetSize() (uint32, uint32) {
	frame := v.Frames[uint32(v.Frame)+(uint32(v.Direction)*v.FramesPerDirection)]
	return frame.Width, frame.Height
}

func (v *Sprite) updateAnimation() {
	if !v.Animate {
		return
	}
	var timePerFrame time.Duration

	if v.SpecialFrameTime >= 0 {
		timePerFrame = time.Duration(float64(time.Millisecond) * (float64(v.SpecialFrameTime) / float64(len(v.Frames))))
	} else {
		timePerFrame = time.Duration(float64(time.Second) * (1.0 / float64(len(v.Frames))))
	}
	for time.Now().Sub(v.LastFrameTime) >= timePerFrame {
		v.LastFrameTime = v.LastFrameTime.Add(timePerFrame)
		v.Frame++
		if v.Frame >= uint8(v.FramesPerDirection) {
			if v.StopOnLastFrame {
				v.Frame = uint8(v.FramesPerDirection) - 1
			} else {
				v.Frame = 0
			}
		}
	}
}

func (v *Sprite) ResetAnimation() {
	v.LastFrameTime = time.Now()
	v.Frame = 0
}

func (v *Sprite) OnLastFrame() bool {
	return v.Frame == uint8(v.FramesPerDirection-1)
}

// GetFrameSize returns the size of the specific frame
func (v *Sprite) GetFrameSize(frame int) (width, height uint32) {
	width = v.Frames[frame].Width
	height = v.Frames[frame].Height
	return
}

// GetTotalFrames returns the number of frames in this sprite (for all directions)
func (v *Sprite) GetTotalFrames() int {
	return len(v.Frames)
}

// Draw draws the sprite onto the target
func (v *Sprite) Draw(target *ebiten.Image) {
	v.updateAnimation()
	opts := &ebiten.DrawImageOptions{}
	frame := v.Frames[uint32(v.Frame)+(uint32(v.Direction)*v.FramesPerDirection)]
	if !frame.cached {
		v.cacheFrame(int(v.Frame) + (int(v.Direction) * int(v.FramesPerDirection)))
	}
	opts.GeoM.Translate(
		float64(int32(v.X)+frame.OffsetX),
		float64((int32(v.Y) - int32(frame.Height) + frame.OffsetY)),
	)
	if v.Blend {
		opts.CompositeMode = ebiten.CompositeModeLighter
	} else {
		opts.CompositeMode = ebiten.CompositeModeSourceOver
	}
	if v.ColorMod != nil {
		opts.ColorM = d2helper.ColorToColorM(v.ColorMod)
	}
	target.DrawImage(frame.Image, opts)
}

// DrawSegments draws the sprite via a grid of segments
func (v *Sprite) DrawSegments(target *ebiten.Image, xSegments, ySegments, offset int) {
	v.updateAnimation()
	yOffset := int32(0)
	for y := 0; y < ySegments; y++ {
		xOffset := int32(0)
		biggestYOffset := int32(0)
		for x := 0; x < xSegments; x++ {
			frame := v.Frames[uint32(x+(y*xSegments)+(offset*xSegments*ySegments))]
			if !frame.cached {
				v.cacheFrame(x + (y * xSegments) + (offset * xSegments * ySegments))
			}
			opts := &ebiten.DrawImageOptions{}
			opts.GeoM.Translate(
				float64(int32(v.X)+frame.OffsetX+xOffset),
				float64(int32(v.Y)+frame.OffsetY+yOffset),
			)
			if v.Blend {
				opts.CompositeMode = ebiten.CompositeModeLighter
			} else {
				opts.CompositeMode = ebiten.CompositeModeSourceOver
			}
			if v.ColorMod != nil {
				opts.ColorM = d2helper.ColorToColorM(v.ColorMod)
			}
			target.DrawImage(frame.Image, opts)
			xOffset += int32(frame.Width)
			biggestYOffset = d2helper.MaxInt32(biggestYOffset, int32(frame.Height))
		}
		yOffset += biggestYOffset
	}
}

// MoveTo moves the sprite to the specified coordinates
func (v *Sprite) MoveTo(x, y int) {
	v.X = x
	v.Y = y
}

// GetLocation returns the location of the sprite
func (v *Sprite) GetLocation() (int, int) {
	return v.X, v.Y
}