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base: bloeys:v0.18.2
Branches Tags
bloeys:dev
bloeys:v0.28.0 bloeys:v0.27.0 bloeys:v0.26.1 bloeys:v0.26.0 bloeys:v0.25.0 bloeys:v0.24.0 bloeys:v0.23.3 bloeys:v0.23.2 bloeys:v0.23.1 bloeys:v0.23.0 bloeys:v0.22.0 bloeys:v0.21.1 bloeys:v0.21.0 bloeys:v0.20.0 bloeys:v0.19.9 bloeys:v0.19.8 bloeys:v0.19.7 bloeys:v0.19.6 bloeys:v0.19.5 bloeys:v0.19.4 bloeys:v0.19.3 bloeys:v0.19.2 bloeys:v0.19.1 bloeys:v0.19.0 bloeys:v0.18.4 bloeys:v0.18.3 bloeys:v0.18.2 bloeys:v0.18.1 bloeys:v0.18.0 bloeys:v0.17.0 bloeys:v0.16.3 bloeys:v0.16.2 bloeys:v0.16.1 bloeys:v0.16.0 bloeys:v0.15.0 bloeys:v0.14.0 bloeys:v0.13.2 bloeys:v0.13.1 bloeys:v0.13.0 bloeys:v0.12.15 bloeys:v0.12.14 bloeys:v0.12.13 bloeys:v0.12.12 bloeys:v0.12.11 bloeys:v0.12.10 bloeys:v0.11.12 bloeys:v0.11.11 bloeys:v0.0.10 bloeys:v0.0.9 bloeys:v0.0.8 bloeys:v0.0.7 bloeys:v0.0.6 bloeys:v0.0.5 bloeys:v0.0.4 bloeys:v0.0.3 bloeys:v0.0.2 bloeys:v0.0.1
...
compare: bloeys:v0.23.3
Branches Tags
bloeys:dev
bloeys:v0.28.0 bloeys:v0.27.0 bloeys:v0.26.1 bloeys:v0.26.0 bloeys:v0.25.0 bloeys:v0.24.0 bloeys:v0.23.3 bloeys:v0.23.2 bloeys:v0.23.1 bloeys:v0.23.0 bloeys:v0.22.0 bloeys:v0.21.1 bloeys:v0.21.0 bloeys:v0.20.0 bloeys:v0.19.9 bloeys:v0.19.8 bloeys:v0.19.7 bloeys:v0.19.6 bloeys:v0.19.5 bloeys:v0.19.4 bloeys:v0.19.3 bloeys:v0.19.2 bloeys:v0.19.1 bloeys:v0.19.0 bloeys:v0.18.4 bloeys:v0.18.3 bloeys:v0.18.2 bloeys:v0.18.1 bloeys:v0.18.0 bloeys:v0.17.0 bloeys:v0.16.3 bloeys:v0.16.2 bloeys:v0.16.1 bloeys:v0.16.0 bloeys:v0.15.0 bloeys:v0.14.0 bloeys:v0.13.2 bloeys:v0.13.1 bloeys:v0.13.0 bloeys:v0.12.15 bloeys:v0.12.14 bloeys:v0.12.13 bloeys:v0.12.12 bloeys:v0.12.11 bloeys:v0.12.10 bloeys:v0.11.12 bloeys:v0.11.11 bloeys:v0.0.10 bloeys:v0.0.9 bloeys:v0.0.8 bloeys:v0.0.7 bloeys:v0.0.6 bloeys:v0.0.5 bloeys:v0.0.4 bloeys:v0.0.3 bloeys:v0.0.2 bloeys:v0.0.1

44 Commits
v0.18.2 ... v0.23.3

Author SHA1 Message Date
bloeys
d523c0951b Get rid of unneeded pointers+update todos 2024-05-01 01:16:33 +04:00
bloeys
abd7079e61 Correct modifier keys input to imgui 2024-04-24 19:56:35 +04:00
bloeys
4d8ccdaf56 Captured/uncaptured mode in input package+comments 2024-04-20 11:53:06 +04:00
bloeys
a131e1b52d Add todo regarding input package 2024-04-20 11:14:29 +04:00
bloeys
f35c217d73 Spotlight shadows 2024-04-16 10:34:30 +04:00
bloeys
fbfcbaa156 Point light shadows+cubemap array fbo+cleanup 2024-04-15 10:49:18 +04:00
bloeys
c4b1dd1b3d Geometry shader support+omnidirectional depth map shader+improvements 2024-04-15 05:09:07 +04:00
bloeys
a5bea5a661 Cubemap depth fbo attachments 2024-04-15 04:16:44 +04:00
bloeys
22ba9ca891 Fix comment 2024-04-15 03:22:25 +04:00
bloeys
92855c52f9 Shader fixes 2024-04-15 03:19:40 +04:00
bloeys
594d342bf0 Remove some stuff 2024-04-14 07:59:40 +04:00
bloeys
bb1946b930 Simple percentage closer filtering for shadows 2024-04-14 07:58:47 +04:00
bloeys
ef2b01059a Update calcshadow 2024-04-14 06:18:41 +04:00
bloeys
5fa6a06079 Clamp to border for depth map+rotating cubes 2024-04-14 06:14:10 +04:00
bloeys
b718611149 Improving shadows 2024-04-14 03:45:48 +04:00
bloeys
be85e20024 Basic directional shadows 2024-04-14 02:50:40 +04:00
bloeys
040228319e Depth fbo+renderer work+texture slots enum+optimize shaders+more 2024-04-13 23:55:52 +04:00
bloeys
ddd8db3cb0 Framebuffers+unlit shader+screen quad shader 2024-04-13 08:03:17 +04:00
bloeys
692167ada2 Split buffer struct into VAO+VBO+IBO structs 2024-04-13 02:59:31 +04:00
bloeys
524ef068f0 Add comment 2024-04-12 23:57:24 +04:00
bloeys
b060dcdbe9 Go 1.22+fix input bug 2024-04-12 23:55:21 +04:00
bloeys
e22525e2ee Default to srgba textures 2024-04-12 23:38:51 +04:00
bloeys
ee61373069 Blinn-phong 2024-04-12 23:28:59 +04:00
bloeys
1f922b6a47 Enable stencil test 2024-04-12 23:02:27 +04:00
bloeys
9d7bdc0196 Improve error messages 2024-04-12 22:40:08 +04:00
bloeys
83922f1908 Spot lights 2024-04-12 21:09:14 +04:00
bloeys
c00f6d97dd Multiple point lights 2024-04-12 08:38:03 +04:00
bloeys
3c0f82a735 Light maps support (diffuse+specular+normal+emission)+imgui bugs 2024-04-12 03:47:30 +04:00
bloeys
c058b82a92 Shader cleanup 2024-04-12 02:17:03 +04:00
bloeys
908e5e96aa Specular lighting 2024-04-12 01:22:05 +04:00
bloeys
c83e263476 Update todos 2024-04-12 00:23:29 +04:00
bloeys
01f06cce1e Handle relative mouse mode mouse pos for imgui 2024-04-11 22:12:33 +04:00
bloeys
20ed804d2a Correctly handle imgui mouse/keyboard capture 2024-04-11 22:07:38 +04:00
bloeys
80ce6d60d2 Proper support for zero handles 2023-10-09 05:03:48 +04:00
bloeys
c998fc26ce Avoid deprecated gl funcs+Improve imgui with srgb 2023-10-08 04:03:54 +04:00
bloeys
81b515197d Properly working MSAA and SRGB :D 2023-10-08 03:20:56 +04:00
bloeys
d703a5270c x8 MSAA 2023-10-07 11:28:59 +04:00
bloeys
caa76c2a5e Remove test changes 2023-10-07 10:58:57 +04:00
bloeys
da50d597f9 Control over srgba textures and srgba framebuffer 2023-10-07 10:58:01 +04:00
bloeys
9f9744a142 Fixed now? 2023-10-07 09:55:57 +04:00
bloeys
b101d54049 Flip textures before uploading to gpu 2023-10-07 09:22:32 +04:00
bloeys
41b5aea185 Use sRGBA on GPU as PNG/JPEG generally uses that nowadays 2023-10-07 08:46:33 +04:00
bloeys
3574318552 Fix iterator bug in Nex() 2023-10-07 01:16:10 +04:00
bloeys
05ccf3e158 Handle one more iterator case 2023-10-06 08:52:27 +04:00
50 changed files with 3071 additions and 638 deletions
Expand all files Collapse all files

4
.github/workflows/build-nmage.yml vendored
View File

@ -9,10 +9,10 @@ jobs:
runs-on: macos-12
steps:
- name: Install golang 1.18
- name: Install golang
uses: actions/setup-go@v3
with:
go-version: '^1.18'
go-version: '>=1.22'
- name: Install assimp-go dylib
run: sudo mkdir -p /usr/local/lib && sudo wget https://github.com/bloeys/assimp-go/releases/download/v0.4.2/libassimp_darwin_amd64.dylib -O /usr/local/lib/libassimp.5.dylib

158
assets/textures.go
View File

@ -4,7 +4,6 @@ import (
"bytes"
"fmt"
"image"
"image/color"
"image/jpeg"
"image/png"
"io"
@ -14,20 +13,31 @@ import (
"unsafe"
"github.com/go-gl/gl/v4.1-core/gl"
"github.com/mandykoh/prism"
)
type ColorFormat int
const (
ColorFormat_RGBA8 ColorFormat = iota
ColorFormat_Unknown ColorFormat = iota
ColorFormat_RGBA8
)
type Texture struct {
//Path only exists for textures loaded from disk
Path string
TexID uint32
Width int32
// Path only exists for textures loaded from disk
Path string
TexID uint32
// Width is the width of the texture in pixels (pixels per row).
// Note that the number of bytes constituting a row is MORE than this (e.g. for RGBA8, bytesPerRow=width*4, since we have 4 bytes per pixel)
Width int32
// Height is the height of the texture in pixels (pixels per column).
// Note that the number of bytes constituting a column is MORE than this (e.g. for RGBA8, bytesPerColumn=height*4, since we have 4 bytes per pixel)
Height int32
// Pixels usually stored in RGBA format
Pixels []byte
}
@ -36,6 +46,7 @@ type TextureLoadOptions struct {
WriteToCache bool
GenMipMaps bool
KeepPixelsInMem bool
NoSrgba bool
}
type Cubemap struct {
@ -67,16 +78,20 @@ func LoadTexturePNG(file string, loadOptions *TextureLoadOptions) (Texture, erro
return Texture{}, err
}
img, err := png.Decode(bytes.NewReader(fileBytes))
bytesReader := bytes.NewReader(fileBytes)
img, err := png.Decode(bytesReader)
if err != nil {
return Texture{}, err
}
nrgbaImg := prism.ConvertImageToNRGBA(img, 2)
tex := Texture{
Path: file,
Path: file,
Pixels: nrgbaImg.Pix,
Width: int32(nrgbaImg.Bounds().Dx()),
Height: int32(nrgbaImg.Bounds().Dy()),
}
tex.Pixels, tex.Width, tex.Height = pixelsFromNrgbaPng(img)
flipImgPixelsVertically(tex.Pixels, int(tex.Width), int(tex.Height), 4)
//Prepare opengl stuff
gl.GenTextures(1, &tex.TexID)
@ -89,7 +104,12 @@ func LoadTexturePNG(file string, loadOptions *TextureLoadOptions) (Texture, erro
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.LINEAR)
// load and generate the texture
gl.TexImage2D(gl.TEXTURE_2D, 0, gl.RGBA8, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
internalFormat := int32(gl.SRGB_ALPHA)
if loadOptions.NoSrgba {
internalFormat = gl.RGBA8
}
gl.TexImage2D(gl.TEXTURE_2D, 0, internalFormat, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
if loadOptions.GenMipMaps {
gl.GenerateMipmap(tex.TexID)
@ -112,8 +132,14 @@ func LoadTextureInMemPngImg(img image.Image, loadOptions *TextureLoadOptions) (T
loadOptions = &TextureLoadOptions{}
}
tex := Texture{}
tex.Pixels, tex.Width, tex.Height = pixelsFromNrgbaPng(img)
nrgbaImg := prism.ConvertImageToNRGBA(img, 2)
tex := Texture{
Path: "",
Pixels: nrgbaImg.Pix,
Height: int32(nrgbaImg.Bounds().Dy()),
Width: int32(nrgbaImg.Bounds().Dx()),
}
flipImgPixelsVertically(tex.Pixels, int(tex.Width), int(tex.Height), 4)
//Prepare opengl stuff
gl.GenTextures(1, &tex.TexID)
@ -126,7 +152,12 @@ func LoadTextureInMemPngImg(img image.Image, loadOptions *TextureLoadOptions) (T
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.LINEAR)
// load and generate the texture
gl.TexImage2D(gl.TEXTURE_2D, 0, gl.RGBA8, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
internalFormat := int32(gl.SRGB_ALPHA)
if loadOptions.NoSrgba {
internalFormat = gl.RGBA8
}
gl.TexImage2D(gl.TEXTURE_2D, 0, internalFormat, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
if loadOptions.GenMipMaps {
gl.GenerateMipmap(tex.TexID)
@ -166,11 +197,14 @@ func LoadTextureJpeg(file string, loadOptions *TextureLoadOptions) (Texture, err
return Texture{}, err
}
nrgbaImg := prism.ConvertImageToNRGBA(img, 2)
tex := Texture{
Path: file,
Path: file,
Pixels: nrgbaImg.Pix,
Height: int32(nrgbaImg.Bounds().Dy()),
Width: int32(nrgbaImg.Bounds().Dx()),
}
tex.Pixels, tex.Width, tex.Height = pixelsFromNrgbaPng(img)
flipImgPixelsVertically(tex.Pixels, int(tex.Width), int(tex.Height), 4)
//Prepare opengl stuff
gl.GenTextures(1, &tex.TexID)
@ -183,7 +217,12 @@ func LoadTextureJpeg(file string, loadOptions *TextureLoadOptions) (Texture, err
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.LINEAR)
// load and generate the texture
gl.TexImage2D(gl.TEXTURE_2D, 0, gl.RGBA8, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
internalFormat := int32(gl.SRGB_ALPHA)
if loadOptions.NoSrgba {
internalFormat = gl.RGBA8
}
gl.TexImage2D(gl.TEXTURE_2D, 0, internalFormat, tex.Width, tex.Height, 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&tex.Pixels[0]))
if loadOptions.GenMipMaps {
gl.GenerateMipmap(tex.TexID)
@ -200,65 +239,19 @@ func LoadTextureJpeg(file string, loadOptions *TextureLoadOptions) (Texture, err
return tex, nil
}
func pixelsFromNrgbaPng(img image.Image) (pixels []byte, width, height int32) {
// LoadCubemapTextures only supports the 'TextureIsSrgba' option
func LoadCubemapTextures(rightTex, leftTex, topTex, botTex, frontTex, backTex string, loadOptions *TextureLoadOptions) (Cubemap, error) {
//NOTE: Load bottom left to top right because this is the texture coordinate system used by OpenGL
//NOTE: We only support 8-bit channels (32-bit colors) for now
i := 0
width, height = int32(img.Bounds().Dx()), int32(img.Bounds().Dy())
pixels = make([]byte, img.Bounds().Dx()*img.Bounds().Dy()*4)
for y := img.Bounds().Dy() - 1; y >= 0; y-- {
for x := 0; x < img.Bounds().Dx(); x++ {
c := color.NRGBAModel.Convert(img.At(x, y)).(color.NRGBA)
pixels[i] = c.R
pixels[i+1] = c.G
pixels[i+2] = c.B
pixels[i+3] = c.A
i += 4
}
if loadOptions == nil {
loadOptions = &TextureLoadOptions{}
}
return pixels, width, height
}
func pixelsFromNrgbaJpg(img image.Image) (pixels []byte, width, height int32) {
//NOTE: Load bottom left to top right because this is the texture coordinate system used by OpenGL
//NOTE: We only support 8-bit channels (32-bit colors) for now
i := 0
width, height = int32(img.Bounds().Dx()), int32(img.Bounds().Dy())
pixels = make([]byte, img.Bounds().Dx()*img.Bounds().Dy()*4)
for y := img.Bounds().Dy() - 1; y >= 0; y-- {
for x := 0; x < img.Bounds().Dx(); x++ {
c := color.NRGBAModel.Convert(img.At(x, y)).(color.NRGBA)
pixels[i] = c.R
pixels[i+1] = c.G
pixels[i+2] = c.B
pixels[i+3] = c.A
i += 4
}
}
return pixels, width, height
}
func LoadCubemapTextures(rightTex, leftTex, topTex, botTex, frontTex, backTex string) (Cubemap, error) {
var imgDecoder func(r io.Reader) (image.Image, error)
var pixelDecoder func(image.Image) ([]byte, int32, int32)
ext := strings.ToLower(path.Ext(rightTex))
if ext == ".jpg" || ext == ".jpeg" {
imgDecoder = jpeg.Decode
pixelDecoder = pixelsFromNrgbaJpg
} else if ext == ".png" {
imgDecoder = png.Decode
pixelDecoder = pixelsFromNrgbaPng
} else {
return Cubemap{}, fmt.Errorf("unknown image extension: %s. Expected one of: .jpg, .jpeg, .png", ext)
}
@ -292,9 +285,16 @@ func LoadCubemapTextures(rightTex, leftTex, topTex, botTex, frontTex, backTex st
return Cubemap{}, err
}
pixels, width, height := pixelDecoder(img)
nrgbaImg := prism.ConvertImageToNRGBA(img, 2)
height := int32(nrgbaImg.Bounds().Dy())
width := int32(nrgbaImg.Bounds().Dx())
gl.TexImage2D(uint32(gl.TEXTURE_CUBE_MAP_POSITIVE_X)+i, 0, gl.RGBA8, int32(width), int32(height), 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&pixels[0]))
internalFormat := int32(gl.SRGB_ALPHA)
if loadOptions.NoSrgba {
internalFormat = gl.RGBA8
}
gl.TexImage2D(uint32(gl.TEXTURE_CUBE_MAP_POSITIVE_X)+i, 0, internalFormat, int32(width), int32(height), 0, gl.RGBA, gl.UNSIGNED_BYTE, unsafe.Pointer(&nrgbaImg.Pix[0]))
}
// set the texture wrapping/filtering options (on the currently bound texture object)
@ -306,3 +306,21 @@ func LoadCubemapTextures(rightTex, leftTex, topTex, botTex, frontTex, backTex st
return cmap, nil
}
func flipImgPixelsVertically(bytes []byte, width, height, bytesPerPixel int) {
// Flip the image vertically such that (e.g. in an image of 10 rows) rows 0<->9, 1<->8, 2<->7 etc are swapped.
// We do this because images are usually stored top-left to bottom-right, while opengl stores textures bottom-left to top-right, so if we don't swap
// rows textures will appear inverted
widthInBytes := width * bytesPerPixel
rowData := make([]byte, width*bytesPerPixel)
for rowNum := 0; rowNum < height/2; rowNum++ {
upperRowStartIndex := rowNum * widthInBytes
lowerRowStartIndex := (height - rowNum - 1) * widthInBytes
copy(rowData, bytes[upperRowStartIndex:upperRowStartIndex+widthInBytes])
copy(bytes[upperRowStartIndex:upperRowStartIndex+widthInBytes], bytes[lowerRowStartIndex:lowerRowStartIndex+widthInBytes])
copy(bytes[lowerRowStartIndex:lowerRowStartIndex+widthInBytes], rowData)
}
}

4
buffers/buf_usage.go
View File

@ -10,8 +10,10 @@ import (
type BufUsage int
const (
BufUsage_Unknown BufUsage = iota
//Buffer is set only once and used many times
BufUsage_Static BufUsage = iota
BufUsage_Static
//Buffer is changed a lot and used many times
BufUsage_Dynamic
//Buffer is set only once and used by the GPU at most a few times

134
buffers/buffers.go
View File

@ -1,134 +0,0 @@
package buffers
import (
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type Buffer struct {
VAOID uint32
// BufID is the ID of the VBO
BufID uint32
// IndexBufID is the ID of the index/element buffer
IndexBufID uint32
// IndexBufCount is the number of elements in the index buffer
// Updated on SetIndexBufData
IndexBufCount int32
// IndexBufCount int32
Stride int32
layout []Element
}
func (b *Buffer) Bind() {
gl.BindVertexArray(b.VAOID)
}
func (b *Buffer) UnBind() {
gl.BindVertexArray(0)
}
func (b *Buffer) SetData(values []float32) {
gl.BindVertexArray(b.VAOID)
gl.BindBuffer(gl.ARRAY_BUFFER, b.BufID)
sizeInBytes := len(values) * 4
if sizeInBytes == 0 {
gl.BufferData(gl.ARRAY_BUFFER, 0, gl.Ptr(nil), BufUsage_Static.ToGL())
} else {
gl.BufferData(gl.ARRAY_BUFFER, sizeInBytes, gl.Ptr(&values[0]), BufUsage_Static.ToGL())
}
gl.BindVertexArray(0)
gl.BindBuffer(gl.ARRAY_BUFFER, 0)
}
func (b *Buffer) SetDataWithUsage(values []float32, usage BufUsage) {
gl.BindVertexArray(b.VAOID)
gl.BindBuffer(gl.ARRAY_BUFFER, b.BufID)
sizeInBytes := len(values) * 4
if sizeInBytes == 0 {
gl.BufferData(gl.ARRAY_BUFFER, 0, gl.Ptr(nil), usage.ToGL())
} else {
gl.BufferData(gl.ARRAY_BUFFER, sizeInBytes, gl.Ptr(&values[0]), usage.ToGL())
}
gl.BindVertexArray(0)
gl.BindBuffer(gl.ARRAY_BUFFER, 0)
}
func (b *Buffer) SetIndexBufData(values []uint32) {
b.IndexBufCount = int32(len(values))
gl.BindVertexArray(b.VAOID)
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, b.IndexBufID)
sizeInBytes := len(values) * 4
if sizeInBytes == 0 {
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, 0, gl.Ptr(nil), BufUsage_Static.ToGL())
} else {
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, sizeInBytes, gl.Ptr(&values[0]), BufUsage_Static.ToGL())
}
gl.BindVertexArray(0)
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, 0)
}
func (b *Buffer) GetLayout() []Element {
e := make([]Element, len(b.layout))
copy(e, b.layout)
return e
}
// SetLayout updates the layout object and the corresponding vertex attributes.
// Vertex attributes are also enabled.
func (b *Buffer) SetLayout(layout ...Element) {
b.layout = layout
b.Stride = 0
for i := 0; i < len(b.layout); i++ {
b.layout[i].Offset = int(b.Stride)
b.Stride += b.layout[i].Size()
}
//Set opengl stuff
b.Bind()
//NOTE: VBOs are only bound at 'VertexAttribPointer', not BindBUffer, so we need to bind the buffer and vao here
gl.BindBuffer(gl.ARRAY_BUFFER, b.BufID)
for i := 0; i < len(layout); i++ {
gl.EnableVertexAttribArray(uint32(i))
gl.VertexAttribPointerWithOffset(uint32(i), layout[i].ElementType.CompCount(), layout[i].ElementType.GLType(), false, b.Stride, uintptr(layout[i].Offset))
}
b.UnBind()
gl.BindBuffer(gl.ARRAY_BUFFER, 0)
}
func NewBuffer(layout ...Element) Buffer {
b := Buffer{}
gl.GenVertexArrays(1, &b.VAOID)
if b.VAOID == 0 {
logging.ErrLog.Println("Failed to create openGL vertex array object")
}
gl.GenBuffers(1, &b.BufID)
if b.BufID == 0 {
logging.ErrLog.Println("Failed to create openGL buffer")
}
gl.GenBuffers(1, &b.IndexBufID)
if b.IndexBufID == 0 {
logging.ErrLog.Println("Failed to create openGL buffer")
}
b.SetLayout(layout...)
return b
}

594
buffers/framebuffer.go Executable file
View File

@ -0,0 +1,594 @@
package buffers
import (
"github.com/bloeys/nmage/assert"
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type FramebufferAttachmentType int32
const (
FramebufferAttachmentType_Unknown FramebufferAttachmentType = iota
FramebufferAttachmentType_Texture
FramebufferAttachmentType_Texture_Array
FramebufferAttachmentType_Renderbuffer
FramebufferAttachmentType_Cubemap
FramebufferAttachmentType_Cubemap_Array
)
func (f FramebufferAttachmentType) IsValid() bool {
switch f {
case FramebufferAttachmentType_Texture:
fallthrough
case FramebufferAttachmentType_Texture_Array:
fallthrough
case FramebufferAttachmentType_Renderbuffer:
fallthrough
case FramebufferAttachmentType_Cubemap:
fallthrough
case FramebufferAttachmentType_Cubemap_Array:
return true
default:
return false
}
}
type FramebufferAttachmentDataFormat int32
const (
FramebufferAttachmentDataFormat_Unknown FramebufferAttachmentDataFormat = iota
FramebufferAttachmentDataFormat_R32Int
FramebufferAttachmentDataFormat_RGBA8
FramebufferAttachmentDataFormat_SRGBA
FramebufferAttachmentDataFormat_DepthF32
FramebufferAttachmentDataFormat_Depth24Stencil8
)
func (f FramebufferAttachmentDataFormat) IsColorFormat() bool {
return f == FramebufferAttachmentDataFormat_R32Int ||
f == FramebufferAttachmentDataFormat_RGBA8 ||
f == FramebufferAttachmentDataFormat_SRGBA
}
func (f FramebufferAttachmentDataFormat) IsDepthFormat() bool {
return f == FramebufferAttachmentDataFormat_Depth24Stencil8 ||
f == FramebufferAttachmentDataFormat_DepthF32
}
func (f FramebufferAttachmentDataFormat) GlInternalFormat() int32 {
switch f {
case FramebufferAttachmentDataFormat_R32Int:
return gl.R32I
case FramebufferAttachmentDataFormat_RGBA8:
return gl.RGB8
case FramebufferAttachmentDataFormat_SRGBA:
return gl.SRGB_ALPHA
case FramebufferAttachmentDataFormat_DepthF32:
return gl.DEPTH_COMPONENT
case FramebufferAttachmentDataFormat_Depth24Stencil8:
return gl.DEPTH24_STENCIL8
default:
logging.ErrLog.Fatalf("unknown framebuffer attachment data format. Format=%d\n", f)
return 0
}
}
func (f FramebufferAttachmentDataFormat) GlFormat() uint32 {
switch f {
case FramebufferAttachmentDataFormat_R32Int:
return gl.RED_INTEGER
case FramebufferAttachmentDataFormat_RGBA8:
fallthrough
case FramebufferAttachmentDataFormat_SRGBA:
return gl.RGBA
case FramebufferAttachmentDataFormat_DepthF32:
return gl.DEPTH_COMPONENT
case FramebufferAttachmentDataFormat_Depth24Stencil8:
return gl.DEPTH_STENCIL
default:
logging.ErrLog.Fatalf("unknown framebuffer attachment data format. Format=%d\n", f)
return 0
}
}
type FramebufferAttachment struct {
Id uint32
Type FramebufferAttachmentType
Format FramebufferAttachmentDataFormat
}
type Framebuffer struct {
Id uint32
ClearFlags uint32
Attachments []FramebufferAttachment
ColorAttachmentsCount uint32
Width uint32
Height uint32
}
func (fbo *Framebuffer) Bind() {
gl.BindFramebuffer(gl.FRAMEBUFFER, fbo.Id)
}
func (fbo *Framebuffer) BindWithViewport() {
gl.BindFramebuffer(gl.FRAMEBUFFER, fbo.Id)
gl.Viewport(0, 0, int32(fbo.Width), int32(fbo.Height))
}
// Clear calls gl.Clear with the fob's clear flags.
// Note that the fbo must be complete and bound.
// Calling this without a bound fbo will clear something else, like your screen.
func (fbo *Framebuffer) Clear() {
gl.Clear(fbo.ClearFlags)
}
func (fbo *Framebuffer) UnBind() {
gl.BindFramebuffer(gl.FRAMEBUFFER, 0)
}
func (fbo *Framebuffer) UnBindWithViewport(width, height uint32) {
gl.BindFramebuffer(gl.FRAMEBUFFER, 0)
gl.Viewport(0, 0, int32(width), int32(height))
}
// IsComplete returns true if OpenGL reports that the fbo is complete/usable.
// Note that this function binds and then unbinds the fbo
func (fbo *Framebuffer) IsComplete() bool {
fbo.Bind()
isComplete := gl.CheckFramebufferStatus(gl.FRAMEBUFFER) == gl.FRAMEBUFFER_COMPLETE
fbo.UnBind()
return isComplete
}
func (fbo *Framebuffer) HasColorAttachment() bool {
return fbo.ColorAttachmentsCount > 0
}
func (fbo *Framebuffer) HasDepthAttachment() bool {
for i := 0; i < len(fbo.Attachments); i++ {
a := &fbo.Attachments[i]
if a.Format.IsDepthFormat() {
return true
}
}
return false
}
func (fbo *Framebuffer) NewColorAttachment(
attachType FramebufferAttachmentType,
attachFormat FramebufferAttachmentDataFormat,
) {
if fbo.ColorAttachmentsCount == 8 {
logging.ErrLog.Fatalf("failed creating color attachment for framebuffer due it already having %d attached\n", fbo.ColorAttachmentsCount)
}
if !attachType.IsValid() {
logging.ErrLog.Fatalf("failed creating color attachment for framebuffer due to unknown attachment type. Type=%d\n", attachType)
}
if attachType == FramebufferAttachmentType_Cubemap || attachType == FramebufferAttachmentType_Cubemap_Array {
logging.ErrLog.Fatalf("failed creating color attachment because cubemaps can not be color attachments (at least in this implementation. You might be able to do it manually)\n")
}
if attachType == FramebufferAttachmentType_Texture_Array {
logging.ErrLog.Fatalf("failed creating color attachment because texture arrays can not be color attachments (implementation can be updated to support it or you can do it manually)\n")
}
if !attachFormat.IsColorFormat() {
logging.ErrLog.Fatalf("failed creating color attachment for framebuffer due to attachment data format not being a valid color type. Data format=%d\n", attachFormat)
}
a := FramebufferAttachment{
Type: attachType,
Format: attachFormat,
}
fbo.Bind()
if attachType == FramebufferAttachmentType_Texture {
// Create texture
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_2D, a.Id)
gl.TexImage2D(gl.TEXTURE_2D, 0, attachFormat.GlInternalFormat(), int32(fbo.Width), int32(fbo.Height), 0, attachFormat.GlFormat(), gl.UNSIGNED_BYTE, nil)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.LINEAR)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.LINEAR)
gl.BindTexture(gl.TEXTURE_2D, 0)
// Attach to fbo
gl.FramebufferTexture2D(gl.FRAMEBUFFER, gl.COLOR_ATTACHMENT0+fbo.ColorAttachmentsCount, gl.TEXTURE_2D, a.Id, 0)
} else if attachType == FramebufferAttachmentType_Renderbuffer {
// Create rbo
gl.GenRenderbuffers(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate render buffer for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindRenderbuffer(gl.RENDERBUFFER, a.Id)
gl.RenderbufferStorage(gl.RENDERBUFFER, uint32(attachFormat.GlInternalFormat()), int32(fbo.Width), int32(fbo.Height))
gl.BindRenderbuffer(gl.RENDERBUFFER, 0)
// Attach to fbo
gl.FramebufferRenderbuffer(gl.FRAMEBUFFER, gl.COLOR_ATTACHMENT0+fbo.ColorAttachmentsCount, gl.RENDERBUFFER, a.Id)
}
fbo.UnBind()
fbo.ColorAttachmentsCount++
fbo.ClearFlags |= gl.COLOR_BUFFER_BIT
fbo.Attachments = append(fbo.Attachments, a)
}
// SetNoColorBuffer sets the read and draw buffers of this fbo to 'NONE',
// which tells the graphics driver that we don't want a color buffer for this fbo.
//
// This is required because normally an fbo must have a color buffer to be considered complete, but by
// doing this we get marked as complete even without one.
//
// Usually used when you only care about some other buffer, like a depth buffer.
func (fbo *Framebuffer) SetNoColorBuffer() {
if fbo.HasColorAttachment() {
logging.ErrLog.Fatalf("failed SetNoColorBuffer because framebuffer already has a color attachment\n")
}
fbo.Bind()
gl.DrawBuffer(gl.NONE)
gl.ReadBuffer(gl.NONE)
fbo.UnBind()
}
func (fbo *Framebuffer) NewDepthAttachment(
attachType FramebufferAttachmentType,
attachFormat FramebufferAttachmentDataFormat,
) {
if fbo.HasDepthAttachment() {
logging.ErrLog.Fatalf("failed creating depth attachment for framebuffer because a depth attachment already exists\n")
}
if !attachType.IsValid() {
logging.ErrLog.Fatalf("failed creating depth attachment for framebuffer due to unknown attachment type. Type=%d\n", attachType)
}
if !attachFormat.IsDepthFormat() {
logging.ErrLog.Fatalf("failed creating depth attachment for framebuffer due to attachment data format not being a valid depth-stencil type. Data format=%d\n", attachFormat)
}
if attachType == FramebufferAttachmentType_Cubemap_Array {
logging.ErrLog.Fatalf("failed creating cubemap array depth attachment because 'NewDepthCubemapArrayAttachment' must be used for that\n")
}
if attachType == FramebufferAttachmentType_Texture_Array {
logging.ErrLog.Fatalf("failed creating texture array depth attachment because 'NewDepthTextureArrayAttachment' must be used for that\n")
}
a := FramebufferAttachment{
Type: attachType,
Format: attachFormat,
}
fbo.Bind()
if attachType == FramebufferAttachmentType_Texture {
// Create texture
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_2D, a.Id)
gl.TexImage2D(gl.TEXTURE_2D, 0, attachFormat.GlInternalFormat(), int32(fbo.Width), int32(fbo.Height), 0, attachFormat.GlFormat(), gl.FLOAT, nil)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.NEAREST)
// This is so that any sampling outside the depth map gives a full depth value.
// Useful for example when doing shadow maps where we want things outside
// the range of the texture to not show shadow
borderColor := []float32{1, 1, 1, 1}
gl.TexParameterfv(gl.TEXTURE_2D, gl.TEXTURE_BORDER_COLOR, &borderColor[0])
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_WRAP_S, gl.CLAMP_TO_BORDER)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_WRAP_T, gl.CLAMP_TO_BORDER)
gl.BindTexture(gl.TEXTURE_2D, 0)
// Attach to fbo
gl.FramebufferTexture2D(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, gl.TEXTURE_2D, a.Id, 0)
} else if attachType == FramebufferAttachmentType_Renderbuffer {
// Create rbo
gl.GenRenderbuffers(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate render buffer for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindRenderbuffer(gl.RENDERBUFFER, a.Id)
gl.RenderbufferStorage(gl.RENDERBUFFER, uint32(attachFormat.GlInternalFormat()), int32(fbo.Width), int32(fbo.Height))
gl.BindRenderbuffer(gl.RENDERBUFFER, 0)
// Attach to fbo
gl.FramebufferRenderbuffer(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, gl.RENDERBUFFER, a.Id)
} else if attachType == FramebufferAttachmentType_Cubemap {
// Create cubemap
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_CUBE_MAP, a.Id)
for i := 0; i < 6; i++ {
gl.TexImage2D(uint32(gl.TEXTURE_CUBE_MAP_POSITIVE_X+i), 0, attachFormat.GlInternalFormat(), int32(fbo.Width), int32(fbo.Height), 0, attachFormat.GlFormat(), gl.FLOAT, nil)
}
gl.TexParameteri(gl.TEXTURE_CUBE_MAP, gl.TEXTURE_MIN_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP, gl.TEXTURE_MAG_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP, gl.TEXTURE_WRAP_S, gl.CLAMP_TO_EDGE)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP, gl.TEXTURE_WRAP_T, gl.CLAMP_TO_EDGE)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP, gl.TEXTURE_WRAP_R, gl.CLAMP_TO_EDGE)
gl.BindTexture(gl.TEXTURE_2D, 0)
// Attach to fbo
gl.FramebufferTexture(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, a.Id, 0)
}
fbo.UnBind()
fbo.ClearFlags |= gl.DEPTH_BUFFER_BIT
fbo.Attachments = append(fbo.Attachments, a)
}
func (fbo *Framebuffer) NewDepthCubemapArrayAttachment(
attachFormat FramebufferAttachmentDataFormat,
numCubemaps int32,
) {
if fbo.HasDepthAttachment() {
logging.ErrLog.Fatalf("failed creating cubemap array depth attachment for framebuffer because a depth attachment already exists\n")
}
if !attachFormat.IsDepthFormat() {
logging.ErrLog.Fatalf("failed creating depth attachment for framebuffer due to attachment data format not being a valid depth-stencil type. Data format=%d\n", attachFormat)
}
a := FramebufferAttachment{
Type: FramebufferAttachmentType_Cubemap_Array,
Format: attachFormat,
}
fbo.Bind()
// Create cubemap array
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_CUBE_MAP_ARRAY, a.Id)
gl.TexImage3D(
gl.TEXTURE_CUBE_MAP_ARRAY,
0,
attachFormat.GlInternalFormat(),
int32(fbo.Width),
int32(fbo.Height),
6*numCubemaps,
0,
attachFormat.GlFormat(),
gl.FLOAT,
nil,
)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP_ARRAY, gl.TEXTURE_MIN_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP_ARRAY, gl.TEXTURE_MAG_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP_ARRAY, gl.TEXTURE_WRAP_S, gl.CLAMP_TO_EDGE)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP_ARRAY, gl.TEXTURE_WRAP_T, gl.CLAMP_TO_EDGE)
gl.TexParameteri(gl.TEXTURE_CUBE_MAP_ARRAY, gl.TEXTURE_WRAP_R, gl.CLAMP_TO_EDGE)
gl.BindTexture(gl.TEXTURE_2D, 0)
// Attach to fbo
gl.FramebufferTexture(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, a.Id, 0)
fbo.UnBind()
fbo.ClearFlags |= gl.DEPTH_BUFFER_BIT
fbo.Attachments = append(fbo.Attachments, a)
}
func (fbo *Framebuffer) NewDepthTextureArrayAttachment(
attachFormat FramebufferAttachmentDataFormat,
numTextures int32,
) {
if fbo.HasDepthAttachment() {
logging.ErrLog.Fatalf("failed creating texture array depth attachment for framebuffer because a depth attachment already exists\n")
}
if !attachFormat.IsDepthFormat() {
logging.ErrLog.Fatalf("failed creating depth attachment for framebuffer due to attachment data format not being a valid depth-stencil type. Data format=%d\n", attachFormat)
}
a := FramebufferAttachment{
Type: FramebufferAttachmentType_Texture_Array,
Format: attachFormat,
}
fbo.Bind()
// Create cubemap array
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_2D_ARRAY, a.Id)
gl.TexImage3D(
gl.TEXTURE_2D_ARRAY,
0,
attachFormat.GlInternalFormat(),
int32(fbo.Width),
int32(fbo.Height),
numTextures,
0,
attachFormat.GlFormat(),
gl.FLOAT,
nil,
)
gl.TexParameteri(gl.TEXTURE_2D_ARRAY, gl.TEXTURE_MIN_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_2D_ARRAY, gl.TEXTURE_MAG_FILTER, gl.NEAREST)
// This is so that any sampling outside the depth map gives a full depth value.
// Useful for example when doing shadow maps where we want things outside
// the range of the texture to not show shadow
borderColor := []float32{1, 1, 1, 1}
gl.TexParameterfv(gl.TEXTURE_2D_ARRAY, gl.TEXTURE_BORDER_COLOR, &borderColor[0])
gl.TexParameteri(gl.TEXTURE_2D_ARRAY, gl.TEXTURE_WRAP_S, gl.CLAMP_TO_BORDER)
gl.TexParameteri(gl.TEXTURE_2D_ARRAY, gl.TEXTURE_WRAP_T, gl.CLAMP_TO_BORDER)
gl.BindTexture(gl.TEXTURE_2D_ARRAY, 0)
// Attach to fbo
gl.FramebufferTexture(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, a.Id, 0)
fbo.UnBind()
fbo.ClearFlags |= gl.DEPTH_BUFFER_BIT
fbo.Attachments = append(fbo.Attachments, a)
}
func (fbo *Framebuffer) NewDepthStencilAttachment(
attachType FramebufferAttachmentType,
attachFormat FramebufferAttachmentDataFormat,
) {
if fbo.HasDepthAttachment() {
logging.ErrLog.Fatalf("failed creating depth-stencil attachment for framebuffer because a depth-stencil attachment already exists\n")
}
if !attachType.IsValid() {
logging.ErrLog.Fatalf("failed creating depth-stencil attachment for framebuffer due to unknown attachment type. Type=%d\n", attachType)
}
if !attachFormat.IsDepthFormat() {
logging.ErrLog.Fatalf("failed creating depth-stencil attachment for framebuffer due to attachment data format not being a valid depth-stencil type. Data format=%d\n", attachFormat)
}
a := FramebufferAttachment{
Type: attachType,
Format: attachFormat,
}
fbo.Bind()
if attachType == FramebufferAttachmentType_Texture {
// Create texture
gl.GenTextures(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate texture for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindTexture(gl.TEXTURE_2D, a.Id)
gl.TexImage2D(gl.TEXTURE_2D, 0, attachFormat.GlInternalFormat(), int32(fbo.Width), int32(fbo.Height), 0, attachFormat.GlFormat(), gl.UNSIGNED_INT_24_8, nil)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.NEAREST)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.NEAREST)
gl.BindTexture(gl.TEXTURE_2D, 0)
// Attach to fbo
gl.FramebufferTexture2D(gl.FRAMEBUFFER, gl.DEPTH_STENCIL_ATTACHMENT, gl.TEXTURE_2D, a.Id, 0)
} else if attachType == FramebufferAttachmentType_Renderbuffer {
// Create rbo
gl.GenRenderbuffers(1, &a.Id)
if a.Id == 0 {
logging.ErrLog.Fatalf("failed to generate render buffer for framebuffer. GlError=%d\n", gl.GetError())
}
gl.BindRenderbuffer(gl.RENDERBUFFER, a.Id)
gl.RenderbufferStorage(gl.RENDERBUFFER, uint32(attachFormat.GlInternalFormat()), int32(fbo.Width), int32(fbo.Height))
gl.BindRenderbuffer(gl.RENDERBUFFER, 0)
// Attach to fbo
gl.FramebufferRenderbuffer(gl.FRAMEBUFFER, gl.DEPTH_STENCIL_ATTACHMENT, gl.RENDERBUFFER, a.Id)
}
fbo.UnBind()
fbo.ClearFlags |= gl.DEPTH_BUFFER_BIT | gl.STENCIL_BUFFER_BIT
fbo.Attachments = append(fbo.Attachments, a)
}
// SetCubemapArrayLayerFace 'binds' a single face of a cubemap from the cubemap
// array to the fbo, such that rendering only affects that one face and the others inaccessible.
//
// If this is not called, the default is that the entire cubemap array and all the faces in it
// are bound and available for use when binding the fbo.
func (fbo *Framebuffer) SetCubemapArrayLayerFace(layerFace int32) {
for i := 0; i < len(fbo.Attachments); i++ {
a := &fbo.Attachments[i]
if a.Type != FramebufferAttachmentType_Cubemap_Array {
continue
}
assert.T(a.Format.IsDepthFormat(), "SetCubemapFromArray called but a cubemap array is set on a color attachment, which is not currently handled. Code must be updated!")
gl.FramebufferTextureLayer(gl.FRAMEBUFFER, gl.DEPTH_ATTACHMENT, a.Id, 0, layerFace)
return
}
logging.ErrLog.Fatalf("SetCubemapFromArray failed because no cubemap array attachment was found on fbo. Fbo=%+v\n", *fbo)
}
func (fbo *Framebuffer) Delete() {
if fbo.Id == 0 {
return
}
gl.DeleteFramebuffers(1, &fbo.Id)
fbo.Id = 0
}
func NewFramebuffer(width, height uint32) Framebuffer {
// It is allowed to have attachments of differnt sizes in one FBO,
// but that complicates things (e.g. which size to use for gl.viewport) and I don't see much use
// for it now, so we will have all attachments share size
fbo := Framebuffer{
Width: width,
Height: height,
}
gl.GenFramebuffers(1, &fbo.Id)
if fbo.Id == 0 {
logging.ErrLog.Fatalf("failed to generate framebuffer. GlError=%d\n", gl.GetError())
}
return fbo
}

46
buffers/index_buffer.go Executable file
View File

@ -0,0 +1,46 @@
package buffers
import (
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type IndexBuffer struct {
Id uint32
// IndexBufCount is the number of elements in the index buffer. Updated in IndexBuffer.SetData
IndexBufCount int32
}
func (ib *IndexBuffer) Bind() {
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, ib.Id)
}
func (ib *IndexBuffer) UnBind() {
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, 0)
}
func (ib *IndexBuffer) SetData(values []uint32) {
ib.Bind()
sizeInBytes := len(values) * 4
ib.IndexBufCount = int32(len(values))
if sizeInBytes == 0 {
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, 0, gl.Ptr(nil), BufUsage_Static.ToGL())
} else {
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, sizeInBytes, gl.Ptr(&values[0]), BufUsage_Static.ToGL())
}
}
func NewIndexBuffer() IndexBuffer {
ib := IndexBuffer{}
gl.GenBuffers(1, &ib.Id)
if ib.Id == 0 {
logging.ErrLog.Println("Failed to create OpenGL buffer")
}
return ib
}

54
buffers/vertex_array.go Executable file
View File

@ -0,0 +1,54 @@
package buffers
import (
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type VertexArray struct {
Id uint32
Vbos []VertexBuffer
IndexBuffer IndexBuffer
}
func (va *VertexArray) Bind() {
gl.BindVertexArray(va.Id)
}
func (va *VertexArray) UnBind() {
gl.BindVertexArray(0)
}
func (va *VertexArray) AddVertexBuffer(vbo VertexBuffer) {
// NOTE: VBOs are only bound at 'VertexAttribPointer' (and related) calls
va.Bind()
vbo.Bind()
for i := 0; i < len(vbo.layout); i++ {
l := &vbo.layout[i]
gl.EnableVertexAttribArray(uint32(i))
gl.VertexAttribPointerWithOffset(uint32(i), l.ElementType.CompCount(), l.ElementType.GLType(), false, vbo.Stride, uintptr(l.Offset))
}
}
func (va *VertexArray) SetIndexBuffer(ib IndexBuffer) {
va.Bind()
ib.Bind()
va.IndexBuffer = ib
}
func NewVertexArray() VertexArray {
vao := VertexArray{}
gl.GenVertexArrays(1, &vao.Id)
if vao.Id == 0 {
logging.ErrLog.Println("Failed to create OpenGL vertex array object")
}
return vao
}

63
buffers/vertex_buffer.go Executable file
View File

@ -0,0 +1,63 @@
package buffers
import (
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type VertexBuffer struct {
Id uint32
Stride int32
layout []Element
}
func (vb *VertexBuffer) Bind() {
gl.BindBuffer(gl.ARRAY_BUFFER, vb.Id)
}
func (vb *VertexBuffer) UnBind() {
gl.BindBuffer(gl.ARRAY_BUFFER, 0)
}
func (vb *VertexBuffer) SetData(values []float32, usage BufUsage) {
vb.Bind()
sizeInBytes := len(values) * 4
if sizeInBytes == 0 {
gl.BufferData(gl.ARRAY_BUFFER, 0, gl.Ptr(nil), usage.ToGL())
} else {
gl.BufferData(gl.ARRAY_BUFFER, sizeInBytes, gl.Ptr(&values[0]), usage.ToGL())
}
}
func (vb *VertexBuffer) GetLayout() []Element {
e := make([]Element, len(vb.layout))
copy(e, vb.layout)
return e
}
func (vb *VertexBuffer) SetLayout(layout ...Element) {
vb.Stride = 0
vb.layout = layout
for i := 0; i < len(vb.layout); i++ {
vb.layout[i].Offset = int(vb.Stride)
vb.Stride += vb.layout[i].Size()
}
}
func NewVertexBuffer(layout ...Element) VertexBuffer {
vb := VertexBuffer{}
gl.GenBuffers(1, &vb.Id)
if vb.Id == 0 {
logging.ErrLog.Println("Failed to create OpenGL buffer")
}
vb.SetLayout(layout...)
return vb
}

8
camera/camera.go
View File

@ -59,9 +59,9 @@ func (c *Camera) UpdateRotation(pitch, yaw float32) {
c.Update()
}
func NewPerspective(pos, forward, worldUp *gglm.Vec3, nearClip, farClip, fovRadians, aspectRatio float32) *Camera {
func NewPerspective(pos, forward, worldUp *gglm.Vec3, nearClip, farClip, fovRadians, aspectRatio float32) Camera {
cam := &Camera{
cam := Camera{
Type: Type_Perspective,
Pos: *pos,
Forward: *forward,
@ -78,9 +78,9 @@ func NewPerspective(pos, forward, worldUp *gglm.Vec3, nearClip, farClip, fovRadi
return cam
}
func NewOrthographic(pos, forward, worldUp *gglm.Vec3, nearClip, farClip, left, right, top, bottom float32) *Camera {
func NewOrthographic(pos, forward, worldUp *gglm.Vec3, nearClip, farClip, left, right, top, bottom float32) Camera {
cam := &Camera{
cam := Camera{
Type: Type_Orthographic,
Pos: *pos,
Forward: *forward,

140
engine/engine.go
View File

@ -15,6 +15,13 @@ import (
var (
isInited = false
isSdlButtonLeftDown = false
isSdlButtonMiddleDown = false
isSdlButtonRightDown = false
ImguiRelativeMouseModePosX float32
ImguiRelativeMouseModePosY float32
)
type Window struct {
@ -26,10 +33,13 @@ type Window struct {
func (w *Window) handleInputs() {
input.EventLoopStart()
imIo := imgui.CurrentIO()
// @TODO: Would be nice to have imgui package process its own events via a callback instead of it being part of engine code
imguiCaptureMouse := imIo.WantCaptureMouse()
imguiCaptureKeyboard := imIo.WantCaptureKeyboard()
input.EventLoopStart(imguiCaptureMouse, imguiCaptureKeyboard)
for event := sdl.PollEvent(); event != nil; event = sdl.PollEvent() {
//Fire callbacks
@ -43,42 +53,42 @@ func (w *Window) handleInputs() {
case *sdl.MouseWheelEvent:
input.HandleMouseWheelEvent(e)
xDelta, yDelta := input.GetMouseWheelMotion()
imIo.AddMouseWheelDelta(float32(xDelta), float32(yDelta))
imIo.AddMouseWheelDelta(float32(e.X), float32(e.Y))
case *sdl.KeyboardEvent:
input.HandleKeyboardEvent(e)
// Send modifier key updates to imgui (based on the imgui SDL backend)
imIo.AddKeyEvent(imgui.ModCtrl, e.Keysym.Mod&sdl.KMOD_CTRL != 0)
imIo.AddKeyEvent(imgui.ModShift, e.Keysym.Mod&sdl.KMOD_SHIFT != 0)
imIo.AddKeyEvent(imgui.ModAlt, e.Keysym.Mod&sdl.KMOD_ALT != 0)
imIo.AddKeyEvent(imgui.ModSuper, e.Keysym.Mod&sdl.KMOD_GUI != 0)
imIo.AddKeyEvent(nmageimgui.SdlScancodeToImGuiKey(e.Keysym.Scancode), e.Type == sdl.KEYDOWN)
// Send modifier key updates to imgui
if e.Keysym.Sym == sdl.K_LCTRL || e.Keysym.Sym == sdl.K_RCTRL {
imIo.SetKeyCtrl(e.Type == sdl.KEYDOWN)
}
if e.Keysym.Sym == sdl.K_LSHIFT || e.Keysym.Sym == sdl.K_RSHIFT {
imIo.SetKeyShift(e.Type == sdl.KEYDOWN)
}
if e.Keysym.Sym == sdl.K_LALT || e.Keysym.Sym == sdl.K_RALT {
imIo.SetKeyAlt(e.Type == sdl.KEYDOWN)
}
if e.Keysym.Sym == sdl.K_LGUI || e.Keysym.Sym == sdl.K_RGUI {
imIo.SetKeySuper(e.Type == sdl.KEYDOWN)
}
case *sdl.TextInputEvent:
imIo.AddInputCharactersUTF8(e.GetText())
case *sdl.MouseButtonEvent:
input.HandleMouseBtnEvent(e)
isPressed := e.State == sdl.PRESSED
if e.Button == sdl.BUTTON_LEFT {
isSdlButtonLeftDown = isPressed
} else if e.Button == sdl.BUTTON_MIDDLE {
isSdlButtonMiddleDown = isPressed
} else if e.Button == sdl.BUTTON_RIGHT {
isSdlButtonRightDown = isPressed
}
case *sdl.MouseMotionEvent:
input.HandleMouseMotionEvent(e)
case *sdl.WindowEvent:
if e.Event == sdl.WINDOWEVENT_SIZE_CHANGED {
w.handleWindowResize()
}
@ -88,13 +98,17 @@ func (w *Window) handleInputs() {
}
}
// If a mouse press event came, always pass it as "mouse held this frame", so we don't miss click-release events that are shorter than 1 frame.
x, y, _ := sdl.GetMouseState()
imIo.SetMousePos(imgui.Vec2{X: float32(x), Y: float32(y)})
if sdl.GetRelativeMouseMode() {
imIo.SetMousePos(imgui.Vec2{X: ImguiRelativeMouseModePosX, Y: ImguiRelativeMouseModePosY})
} else {
x, y, _ := sdl.GetMouseState()
imIo.SetMousePos(imgui.Vec2{X: float32(x), Y: float32(y)})
}
imIo.SetMouseButtonDown(0, input.MouseDown(sdl.BUTTON_LEFT))
imIo.SetMouseButtonDown(1, input.MouseDown(sdl.BUTTON_RIGHT))
imIo.SetMouseButtonDown(2, input.MouseDown(sdl.BUTTON_MIDDLE))
// If a mouse press event came, always pass it as "mouse held this frame", so we don't miss click-release events that are shorter than 1 frame.
imIo.SetMouseButtonDown(imgui.MouseButtonLeft, isSdlButtonLeftDown)
imIo.SetMouseButtonDown(imgui.MouseButtonRight, isSdlButtonRightDown)
imIo.SetMouseButtonDown(imgui.MouseButtonMiddle, isSdlButtonMiddleDown)
}
func (w *Window) handleWindowResize() {
@ -133,56 +147,65 @@ func initSDL() error {
sdl.GLSetAttribute(sdl.MAJOR_VERSION, 4)
sdl.GLSetAttribute(sdl.MINOR_VERSION, 1)
// R(0-255) G(0-255) B(0-255)
sdl.GLSetAttribute(sdl.GL_RED_SIZE, 8)
sdl.GLSetAttribute(sdl.GL_GREEN_SIZE, 8)
sdl.GLSetAttribute(sdl.GL_BLUE_SIZE, 8)
sdl.GLSetAttribute(sdl.GL_ALPHA_SIZE, 8)
sdl.GLSetAttribute(sdl.GL_DOUBLEBUFFER, 1)
sdl.GLSetAttribute(sdl.GL_DEPTH_SIZE, 24)
sdl.GLSetAttribute(sdl.GL_STENCIL_SIZE, 8)
sdl.GLSetAttribute(sdl.GL_FRAMEBUFFER_SRGB_CAPABLE, 1)
// Allows us to do MSAA
sdl.GLSetAttribute(sdl.GL_MULTISAMPLEBUFFERS, 1)
sdl.GLSetAttribute(sdl.GL_MULTISAMPLESAMPLES, 4)
sdl.GLSetAttribute(sdl.GL_CONTEXT_PROFILE_MASK, sdl.GL_CONTEXT_PROFILE_CORE)
return nil
}
func CreateOpenGLWindow(title string, x, y, width, height int32, flags WindowFlags, rend renderer.Render) (*Window, error) {
func CreateOpenGLWindow(title string, x, y, width, height int32, flags WindowFlags, rend renderer.Render) (Window, error) {
return createWindow(title, x, y, width, height, WindowFlags_OPENGL|flags, rend)
}
func CreateOpenGLWindowCentered(title string, width, height int32, flags WindowFlags, rend renderer.Render) (*Window, error) {
return createWindow(title, -1, -1, width, height, WindowFlags_OPENGL|flags, rend)
func CreateOpenGLWindowCentered(title string, width, height int32, flags WindowFlags, rend renderer.Render) (Window, error) {
return createWindow(title, sdl.WINDOWPOS_CENTERED, sdl.WINDOWPOS_CENTERED, width, height, WindowFlags_OPENGL|flags, rend)
}
func createWindow(title string, x, y, width, height int32, flags WindowFlags, rend renderer.Render) (*Window, error) {
func createWindow(title string, x, y, width, height int32, flags WindowFlags, rend renderer.Render) (Window, error) {
assert.T(isInited, "engine.Init was not called!")
if x == -1 && y == -1 {
x = sdl.WINDOWPOS_CENTERED
y = sdl.WINDOWPOS_CENTERED
}
assert.T(isInited, "engine.Init() was not called!")
sdlWin, err := sdl.CreateWindow(title, x, y, width, height, uint32(flags))
if err != nil {
return nil, err
}
win := &Window{
SDLWin: sdlWin,
win := Window{
SDLWin: nil,
EventCallbacks: make([]func(sdl.Event), 0),
Rend: rend,
}
win.GlCtx, err = sdlWin.GLCreateContext()
var err error
win.SDLWin, err = sdl.CreateWindow(title, x, y, width, height, uint32(flags))
if err != nil {
return nil, err
return win, err
}
win.GlCtx, err = win.SDLWin.GLCreateContext()
if err != nil {
return win, err
}
err = initOpenGL()
if err != nil {
return nil, err
return win, err
}
// Get rid of the blinding white startup screen (unfortunately there is still one frame of white)
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT | gl.STENCIL_BUFFER_BIT)
win.SDLWin.GLSwap()
return win, err
}
@ -193,19 +216,31 @@ func initOpenGL() error {
}
gl.Enable(gl.DEPTH_TEST)
gl.Enable(gl.STENCIL_TEST)
gl.Enable(gl.CULL_FACE)
gl.CullFace(gl.BACK)
gl.FrontFace(gl.CCW)
gl.Enable(gl.BLEND)
gl.Enable(gl.MULTISAMPLE)
gl.Enable(gl.FRAMEBUFFER_SRGB)
gl.BlendFunc(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA)
gl.ClearColor(0, 0, 0, 1)
return nil
}
func SetSrgbFramebuffer(isEnabled bool) {
if isEnabled {
gl.Enable(gl.FRAMEBUFFER_SRGB)
} else {
gl.Disable(gl.FRAMEBUFFER_SRGB)
}
}
func SetVSync(enabled bool) {
assert.T(isInited, "engine.Init was not called!")
if enabled {
sdl.GLSetSwapInterval(1)
@ -213,3 +248,12 @@ func SetVSync(enabled bool) {
sdl.GLSetSwapInterval(0)
}
}
func SetMSAA(isEnabled bool) {
if isEnabled {
gl.Enable(gl.MULTISAMPLE)
} else {
gl.Disable(gl.MULTISAMPLE)
}
}

9
go.mod
View File

@ -1,6 +1,6 @@
module github.com/bloeys/nmage
go 1.18
go 1.22
require github.com/veandco/go-sdl2 v0.4.35
@ -11,4 +11,9 @@ require (
github.com/bloeys/gglm v0.43.0
)
require github.com/AllenDang/cimgui-go v0.0.0-20230720025235-f2ff398a66b2
require (
github.com/AllenDang/cimgui-go v0.0.0-20230720025235-f2ff398a66b2
github.com/mandykoh/prism v0.35.1
)
require github.com/mandykoh/go-parallel v0.1.0 // indirect

30
go.sum
View File

@ -6,5 +6,35 @@ github.com/bloeys/gglm v0.43.0 h1:ZpOghR3PHfpkigTDh+FqxLsF0gN8CD6s/bWoei6LyxI=
github.com/bloeys/gglm v0.43.0/go.mod h1:qwJQ0WzV191wAMwlGicbfbChbKoSedMk7gFFX6GnyOk=
github.com/go-gl/gl v0.0.0-20211210172815-726fda9656d6 h1:zDw5v7qm4yH7N8C8uWd+8Ii9rROdgWxQuGoJ9WDXxfk=
github.com/go-gl/gl v0.0.0-20211210172815-726fda9656d6/go.mod h1:9YTyiznxEY1fVinfM7RvRcjRHbw2xLBJ3AAGIT0I4Nw=
github.com/mandykoh/go-parallel v0.1.0 h1:7vJMNMC4dsbgZdkAb2A8tV5ENY1v7VxIO1wzQWZoT8k=
github.com/mandykoh/go-parallel v0.1.0/go.mod h1:lkYHqG1JNTaSS6lG+PgFCnyMd2VDy8pH9jN9pY899ig=
github.com/mandykoh/prism v0.35.1 h1:JbQfQarANxSWlgJEpjv+E7DvtrqBaVP1YgJfZPvo6ME=
github.com/mandykoh/prism v0.35.1/go.mod h1:3miB3EAJ0IggYl/4eBB5MmawRbyJI1gKDtbrVvk8Q9I=
github.com/veandco/go-sdl2 v0.4.35 h1:NohzsfageDWGtCd9nf7Pc3sokMK/MOK+UA2QMJARWzQ=
github.com/veandco/go-sdl2 v0.4.35/go.mod h1:OROqMhHD43nT4/i9crJukyVecjPNYYuCofep6SNiAjY=
github.com/yuin/goldmark v1.4.13/go.mod h1:6yULJ656Px+3vBD8DxQVa3kxgyrAnzto9xy5taEt/CY=
golang.org/x/crypto v0.0.0-20190308221718-c2843e01d9a2/go.mod h1:djNgcEr1/C05ACkg1iLfiJU5Ep61QUkGW8qpdssI0+w=
golang.org/x/crypto v0.0.0-20210921155107-089bfa567519/go.mod h1:GvvjBRRGRdwPK5ydBHafDWAxML/pGHZbMvKqRZ5+Abc=
golang.org/x/image v0.5.0 h1:5JMiNunQeQw++mMOz48/ISeNu3Iweh/JaZU8ZLqHRrI=
golang.org/x/image v0.5.0/go.mod h1:FVC7BI/5Ym8R25iw5OLsgshdUBbT1h5jZTpA+mvAdZ4=
golang.org/x/mod v0.6.0-dev.0.20220419223038-86c51ed26bb4/go.mod h1:jJ57K6gSWd91VN4djpZkiMVwK6gcyfeH4XE8wZrZaV4=
golang.org/x/net v0.0.0-20190620200207-3b0461eec859/go.mod h1:z5CRVTTTmAJ677TzLLGU+0bjPO0LkuOLi4/5GtJWs/s=
golang.org/x/net v0.0.0-20210226172049-e18ecbb05110/go.mod h1:m0MpNAwzfU5UDzcl9v0D8zg8gWTRqZa9RBIspLL5mdg=
golang.org/x/net v0.0.0-20220722155237-a158d28d115b/go.mod h1:XRhObCWvk6IyKnWLug+ECip1KBveYUHfp+8e9klMJ9c=
golang.org/x/sync v0.0.0-20190423024810-112230192c58/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sync v0.0.0-20220722155255-886fb9371eb4/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
golang.org/x/sys v0.0.0-20190215142949-d0b11bdaac8a/go.mod h1:STP8DvDyc/dI5b8T5hshtkjS+E42TnysNCUPdjciGhY=
golang.org/x/sys v0.0.0-20201119102817-f84b799fce68/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
golang.org/x/sys v0.0.0-20210615035016-665e8c7367d1/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/sys v0.0.0-20220520151302-bc2c85ada10a/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/sys v0.0.0-20220722155257-8c9f86f7a55f/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
golang.org/x/term v0.0.0-20201126162022-7de9c90e9dd1/go.mod h1:bj7SfCRtBDWHUb9snDiAeCFNEtKQo2Wmx5Cou7ajbmo=
golang.org/x/term v0.0.0-20210927222741-03fcf44c2211/go.mod h1:jbD1KX2456YbFQfuXm/mYQcufACuNUgVhRMnK/tPxf8=
golang.org/x/text v0.3.0/go.mod h1:NqM8EUOU14njkJ3fqMW+pc6Ldnwhi/IjpwHt7yyuwOQ=
golang.org/x/text v0.3.3/go.mod h1:5Zoc/QRtKVWzQhOtBMvqHzDpF6irO9z98xDceosuGiQ=
golang.org/x/text v0.3.7/go.mod h1:u+2+/6zg+i71rQMx5EYifcz6MCKuco9NR6JIITiCfzQ=
golang.org/x/text v0.7.0/go.mod h1:mrYo+phRRbMaCq/xk9113O4dZlRixOauAjOtrjsXDZ8=
golang.org/x/tools v0.0.0-20180917221912-90fa682c2a6e/go.mod h1:n7NCudcB/nEzxVGmLbDWY5pfWTLqBcC2KZ6jyYvM4mQ=
golang.org/x/tools v0.0.0-20191119224855-298f0cb1881e/go.mod h1:b+2E5dAYhXwXZwtnZ6UAqBI28+e2cm9otk0dWdXHAEo=
golang.org/x/tools v0.1.12/go.mod h1:hNGJHUnrk76NpqgfD5Aqm5Crs+Hm0VOH/i9J2+nxYbc=
golang.org/x/xerrors v0.0.0-20190717185122-a985d3407aa7/go.mod h1:I/5z698sn9Ka8TeJc9MKroUUfqBBauWjQqLJ2OPfmY0=

259
input/input.go
View File

@ -1,6 +1,23 @@
// The input package provides an interface to mouse and keyboard inputs
// like key clicks and releases, along with some higher level constructs like
// pressed/released this frames, double clicks, and normalized inputs.
//
// The input package has two sets of functions for most cases, where one
// is in the form 'xy' and the other 'xyCaptured'. The captured form
// always returns normal events even if the mouse or keyboard are captured
// by the UI system. The 'xy' form however will return zero/false if the
// respective input device is currently captured (with the exception of mouse position, that is always correctly returned).
//
// For most cases, you want to use the 'xy' form. For example, you only want to receive
// key down events for game character movement when the UI isn't capturing the keyboard,
// because otherwise the character will move while typing in a UI textbox.
//
// The functions IsMouseCaptured and IsKeyboardCaptured are also available.
package input
import "github.com/veandco/go-sdl2/sdl"
import (
"github.com/veandco/go-sdl2/sdl"
)
type keyState struct {
Key sdl.Keycode
@ -31,24 +48,33 @@ type mouseWheelState struct {
}
var (
keyMap = make(map[sdl.Keycode]*keyState)
mouseBtnMap = make(map[int]*mouseBtnState)
mouseMotion = mouseMotionState{}
mouseWheel = mouseWheelState{}
quitRequested bool
mouseWheel = mouseWheelState{}
mouseMotion = mouseMotionState{}
mouseBtnMap = make(map[int]mouseBtnState)
keyMap = make(map[sdl.Keycode]keyState)
isQuitRequested bool
isMouseCaptured bool
isKeyboardCaptured bool
)
func EventLoopStart() {
func EventLoopStart(mouseGotCaptured, keyboardGotCaptured bool) {
for _, v := range keyMap {
isMouseCaptured = mouseGotCaptured
isKeyboardCaptured = keyboardGotCaptured
// Update per-frame state
for k, v := range keyMap {
v.IsPressedThisFrame = false
v.IsReleasedThisFrame = false
keyMap[k] = v
}
for _, v := range mouseBtnMap {
for k, v := range mouseBtnMap {
v.IsPressedThisFrame = false
v.IsReleasedThisFrame = false
v.IsDoubleClicked = false
mouseBtnMap[k] = v
}
mouseMotion.XDelta = 0
@ -57,42 +83,62 @@ func EventLoopStart() {
mouseWheel.XDelta = 0
mouseWheel.YDelta = 0
quitRequested = false
isQuitRequested = false
}
func ClearKeyboardState() {
clear(keyMap)
}
func ClearMouseState() {
clear(mouseBtnMap)
mouseMotion = mouseMotionState{}
mouseWheel = mouseWheelState{}
}
func HandleQuitEvent(e *sdl.QuitEvent) {
quitRequested = true
isQuitRequested = true
}
func IsMouseCaptured() bool {
return isMouseCaptured
}
func IsKeyboardCaptured() bool {
return isKeyboardCaptured
}
func IsQuitClicked() bool {
return quitRequested
return isQuitRequested
}
func HandleKeyboardEvent(e *sdl.KeyboardEvent) {
ks := keyMap[e.Keysym.Sym]
if ks == nil {
ks = &keyState{Key: e.Keysym.Sym}
keyMap[ks.Key] = ks
ks, ok := keyMap[e.Keysym.Sym]
if !ok {
ks = keyState{Key: e.Keysym.Sym}
}
ks.State = int(e.State)
ks.IsPressedThisFrame = e.State == sdl.PRESSED && e.Repeat == 0
ks.IsReleasedThisFrame = e.State == sdl.RELEASED && e.Repeat == 0
keyMap[ks.Key] = ks
}
func HandleMouseBtnEvent(e *sdl.MouseButtonEvent) {
mb := mouseBtnMap[int(e.Button)]
if mb == nil {
mb = &mouseBtnState{Btn: int(e.Button)}
mouseBtnMap[int(e.Button)] = mb
mb, ok := mouseBtnMap[int(e.Button)]
if !ok {
mb = mouseBtnState{Btn: int(e.Button)}
}
mb.State = int(e.State)
mb.IsDoubleClicked = e.Clicks == 2 && e.State == sdl.PRESSED
mb.IsPressedThisFrame = e.State == sdl.PRESSED
mb.IsReleasedThisFrame = e.State == sdl.RELEASED
mouseBtnMap[int(e.Button)] = mb
}
func HandleMouseMotionEvent(e *sdl.MouseMotionEvent) {
@ -109,18 +155,36 @@ func HandleMouseWheelEvent(e *sdl.MouseWheelEvent) {
mouseWheel.YDelta = e.Y
}
//GetMousePos returns the window coordinates of the mouse
// GetMousePos returns the window coordinates of the mouse regardless of whether the mouse is captured or not
func GetMousePos() (x, y int32) {
return mouseMotion.XPos, mouseMotion.YPos
}
//GetMouseMotion returns how many pixels were moved last frame
// GetMouseMotion returns how many pixels were moved last frame
func GetMouseMotion() (xDelta, yDelta int32) {
if isMouseCaptured {
return 0, 0
}
return GetMouseMotionCaptured()
}
func GetMouseMotionCaptured() (xDelta, yDelta int32) {
return mouseMotion.XDelta, mouseMotion.YDelta
}
func GetMouseMotionNorm() (xDelta, yDelta int32) {
if isMouseCaptured {
return 0, 0
}
return GetMouseMotionNormCaptured()
}
func GetMouseMotionNormCaptured() (xDelta, yDelta int32) {
x, y := mouseMotion.XDelta, mouseMotion.YDelta
if x > 0 {
x = 1
@ -138,12 +202,31 @@ func GetMouseMotionNorm() (xDelta, yDelta int32) {
}
func GetMouseWheelMotion() (xDelta, yDelta int32) {
if isMouseCaptured {
return 0, 0
}
return GetMouseWheelMotionCaptured()
}
func GetMouseWheelMotionCaptured() (xDelta, yDelta int32) {
return mouseWheel.XDelta, mouseWheel.YDelta
}
//GetMouseWheelXNorm returns 1 if mouse wheel xDelta > 0, -1 if xDelta < 0, and 0 otherwise
// GetMouseWheelXNorm returns 1 if mouse wheel xDelta > 0, -1 if xDelta < 0, and 0 otherwise
func GetMouseWheelXNorm() int32 {
if isMouseCaptured {
return 0
}
return GetMouseWheelXNormCaptured()
}
// GetMouseWheelXNormCaptured returns 1 if mouse wheel xDelta > 0, -1 if xDelta < 0, and 0 otherwise
func GetMouseWheelXNormCaptured() int32 {
if mouseWheel.XDelta > 0 {
return 1
} else if mouseWheel.XDelta < 0 {
@ -153,9 +236,19 @@ func GetMouseWheelXNorm() int32 {
return 0
}
//returns 1 if mouse wheel yDelta > 0, -1 if yDelta < 0, and 0 otherwise
// GetMouseWheelYNorm returns 1 if mouse wheel yDelta > 0, -1 if yDelta < 0, and 0 otherwise
func GetMouseWheelYNorm() int32 {
if isMouseCaptured {
return 0
}
return GetMouseWheelYNormCaptured()
}
// GetMouseWheelYNormCaptured returns 1 if mouse wheel yDelta > 0, -1 if yDelta < 0, and 0 otherwise
func GetMouseWheelYNormCaptured() int32 {
if mouseWheel.YDelta > 0 {
return 1
} else if mouseWheel.YDelta < 0 {
@ -167,8 +260,17 @@ func GetMouseWheelYNorm() int32 {
func KeyClicked(kc sdl.Keycode) bool {
ks := keyMap[kc]
if ks == nil {
if isKeyboardCaptured {
return false
}
return KeyClickedCaptured(kc)
}
func KeyClickedCaptured(kc sdl.Keycode) bool {
ks, ok := keyMap[kc]
if !ok {
return false
}
@ -177,8 +279,17 @@ func KeyClicked(kc sdl.Keycode) bool {
func KeyReleased(kc sdl.Keycode) bool {
ks := keyMap[kc]
if ks == nil {
if isKeyboardCaptured {
return false
}
return KeyReleasedCaptured(kc)
}
func KeyReleasedCaptured(kc sdl.Keycode) bool {
ks, ok := keyMap[kc]
if !ok {
return false
}
@ -187,8 +298,17 @@ func KeyReleased(kc sdl.Keycode) bool {
func KeyDown(kc sdl.Keycode) bool {
ks := keyMap[kc]
if ks == nil {
if isKeyboardCaptured {
return false
}
return KeyDownCaptured(kc)
}
func KeyDownCaptured(kc sdl.Keycode) bool {
ks, ok := keyMap[kc]
if !ok {
return false
}
@ -197,8 +317,17 @@ func KeyDown(kc sdl.Keycode) bool {
func KeyUp(kc sdl.Keycode) bool {
ks := keyMap[kc]
if ks == nil {
if isKeyboardCaptured {
return false
}
return KeyUpCaptured(kc)
}
func KeyUpCaptured(kc sdl.Keycode) bool {
ks, ok := keyMap[kc]
if !ok {
return true
}
@ -207,8 +336,17 @@ func KeyUp(kc sdl.Keycode) bool {
func MouseClicked(mb int) bool {
btn := mouseBtnMap[mb]
if btn == nil {
if isMouseCaptured {
return false
}
return MouseClickedCaptued(mb)
}
func MouseClickedCaptued(mb int) bool {
btn, ok := mouseBtnMap[mb]
if !ok {
return false
}
@ -217,8 +355,17 @@ func MouseClicked(mb int) bool {
func MouseDoubleClicked(mb int) bool {
btn := mouseBtnMap[mb]
if btn == nil {
if isMouseCaptured {
return false
}
return MouseDoubleClickedCaptured(mb)
}
func MouseDoubleClickedCaptured(mb int) bool {
btn, ok := mouseBtnMap[mb]
if !ok {
return false
}
@ -226,8 +373,18 @@ func MouseDoubleClicked(mb int) bool {
}
func MouseReleased(mb int) bool {
btn := mouseBtnMap[mb]
if btn == nil {
if isMouseCaptured {
return false
}
return MouseReleasedCaptured(mb)
}
func MouseReleasedCaptured(mb int) bool {
btn, ok := mouseBtnMap[mb]
if !ok {
return false
}
@ -236,8 +393,17 @@ func MouseReleased(mb int) bool {
func MouseDown(mb int) bool {
btn := mouseBtnMap[mb]
if btn == nil {
if isMouseCaptured {
return false
}
return MouseDownCaptued(mb)
}
func MouseDownCaptued(mb int) bool {
btn, ok := mouseBtnMap[mb]
if !ok {
return false
}
@ -246,8 +412,17 @@ func MouseDown(mb int) bool {
func MouseUp(mb int) bool {
btn := mouseBtnMap[mb]
if btn == nil {
if isMouseCaptured {
return false
}
return MouseUpCaptured(mb)
}
func MouseUpCaptured(mb int) bool {
btn, ok := mouseBtnMap[mb]
if !ok {
return true
}

1161
main.go
View File

File diff suppressed because it is too large Load Diff

114
materials/material.go
View File

@ -8,30 +8,92 @@ import (
"github.com/go-gl/gl/v4.1-core/gl"
)
type TextureSlot uint32
const (
TextureSlot_Diffuse TextureSlot = 0
TextureSlot_Specular TextureSlot = 1
TextureSlot_Normal TextureSlot = 2
TextureSlot_Emission TextureSlot = 3
TextureSlot_Cubemap TextureSlot = 10
TextureSlot_Cubemap_Array TextureSlot = 11
TextureSlot_ShadowMap1 TextureSlot = 12
TextureSlot_ShadowMap_Array1 TextureSlot = 13
)
type Material struct {
Name string
ShaderProg shaders.ShaderProgram
DiffuseTex uint32
UnifLocs map[string]int32
AttribLocs map[string]int32
// @TODO do this in a better way. Perhaps something like how we do fbo attachments
// Phong shading
DiffuseTex uint32
SpecularTex uint32
NormalTex uint32
EmissionTex uint32
// Shininess of specular highlights
Shininess float32
// Cubemaps
CubemapTex uint32
CubemapArrayTex uint32
// Shadowmaps
ShadowMapTex1 uint32
ShadowMapTexArray1 uint32
}
func (m *Material) Bind() {
gl.UseProgram(m.ShaderProg.ID)
m.ShaderProg.Bind()
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, m.DiffuseTex)
if m.DiffuseTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Diffuse))
gl.BindTexture(gl.TEXTURE_2D, m.DiffuseTex)
}
if m.SpecularTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Specular))
gl.BindTexture(gl.TEXTURE_2D, m.SpecularTex)
}
if m.NormalTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Normal))
gl.BindTexture(gl.TEXTURE_2D, m.NormalTex)
}
if m.EmissionTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Emission))
gl.BindTexture(gl.TEXTURE_2D, m.EmissionTex)
}
if m.CubemapTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Cubemap))
gl.BindTexture(gl.TEXTURE_CUBE_MAP, m.CubemapTex)
}
if m.CubemapArrayTex != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_Cubemap_Array))
gl.BindTexture(gl.TEXTURE_CUBE_MAP_ARRAY, m.CubemapArrayTex)
}
if m.ShadowMapTex1 != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_ShadowMap1))
gl.BindTexture(gl.TEXTURE_2D, m.ShadowMapTex1)
}
if m.ShadowMapTexArray1 != 0 {
gl.ActiveTexture(uint32(gl.TEXTURE0 + TextureSlot_ShadowMap_Array1))
gl.BindTexture(gl.TEXTURE_2D_ARRAY, m.ShadowMapTexArray1)
}
}
func (m *Material) UnBind() {
gl.UseProgram(0)
//TODO: Should we unbind textures here? Are these two lines needed?
// gl.ActiveTexture(gl.TEXTURE0)
// gl.BindTexture(gl.TEXTURE_2D, 0)
}
func (m *Material) GetAttribLoc(attribName string) int32 {
@ -41,7 +103,7 @@ func (m *Material) GetAttribLoc(attribName string) int32 {
return loc
}
loc = gl.GetAttribLocation(m.ShaderProg.ID, gl.Str(attribName+"\x00"))
loc = gl.GetAttribLocation(m.ShaderProg.Id, gl.Str(attribName+"\x00"))
assert.T(loc != -1, "Attribute '"+attribName+"' doesn't exist on material "+m.Name)
m.AttribLocs[attribName] = loc
return loc
@ -54,7 +116,7 @@ func (m *Material) GetUnifLoc(uniformName string) int32 {
return loc
}
loc = gl.GetUniformLocation(m.ShaderProg.ID, gl.Str(uniformName+"\x00"))
loc = gl.GetUniformLocation(m.ShaderProg.Id, gl.Str(uniformName+"\x00"))
assert.T(loc != -1, "Uniform '"+uniformName+"' doesn't exist on material "+m.Name)
m.UnifLocs[uniformName] = loc
return loc
@ -69,57 +131,57 @@ func (m *Material) DisableAttribute(attribName string) {
}
func (m *Material) SetUnifInt32(uniformName string, val int32) {
gl.ProgramUniform1i(m.ShaderProg.ID, m.GetUnifLoc(uniformName), val)
gl.ProgramUniform1i(m.ShaderProg.Id, m.GetUnifLoc(uniformName), val)
}
func (m *Material) SetUnifFloat32(uniformName string, val float32) {
gl.ProgramUniform1f(m.ShaderProg.ID, m.GetUnifLoc(uniformName), val)
gl.ProgramUniform1f(m.ShaderProg.Id, m.GetUnifLoc(uniformName), val)
}
func (m *Material) SetUnifVec2(uniformName string, vec2 *gglm.Vec2) {
gl.ProgramUniform2fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, &vec2.Data[0])
gl.ProgramUniform2fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, &vec2.Data[0])
}
func (m *Material) SetUnifVec3(uniformName string, vec3 *gglm.Vec3) {
gl.ProgramUniform3fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, &vec3.Data[0])
gl.ProgramUniform3fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, &vec3.Data[0])
}
func (m *Material) SetUnifVec4(uniformName string, vec4 *gglm.Vec4) {
gl.ProgramUniform4fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, &vec4.Data[0])
gl.ProgramUniform4fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, &vec4.Data[0])
}
func (m *Material) SetUnifMat2(uniformName string, mat2 *gglm.Mat2) {
gl.ProgramUniformMatrix2fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, false, &mat2.Data[0][0])
gl.ProgramUniformMatrix2fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, false, &mat2.Data[0][0])
}
func (m *Material) SetUnifMat3(uniformName string, mat3 *gglm.Mat3) {
gl.ProgramUniformMatrix3fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, false, &mat3.Data[0][0])
gl.ProgramUniformMatrix3fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, false, &mat3.Data[0][0])
}
func (m *Material) SetUnifMat4(uniformName string, mat4 *gglm.Mat4) {
gl.ProgramUniformMatrix4fv(m.ShaderProg.ID, m.GetUnifLoc(uniformName), 1, false, &mat4.Data[0][0])
gl.ProgramUniformMatrix4fv(m.ShaderProg.Id, m.GetUnifLoc(uniformName), 1, false, &mat4.Data[0][0])
}
func (m *Material) Delete() {
gl.DeleteProgram(m.ShaderProg.ID)
gl.DeleteProgram(m.ShaderProg.Id)
}
func NewMaterial(matName, shaderPath string) *Material {
func NewMaterial(matName, shaderPath string) Material {
shdrProg, err := shaders.LoadAndCompileCombinedShader(shaderPath)
if err != nil {
logging.ErrLog.Fatalln("Failed to create new material. Err: ", err)
logging.ErrLog.Fatalf("Failed to create new material '%s'. Err: %s\n", matName, err.Error())
}
return &Material{Name: matName, ShaderProg: shdrProg, UnifLocs: make(map[string]int32), AttribLocs: make(map[string]int32)}
return Material{Name: matName, ShaderProg: shdrProg, UnifLocs: make(map[string]int32), AttribLocs: make(map[string]int32)}
}
func NewMaterialSrc(matName string, shaderSrc []byte) *Material {
func NewMaterialSrc(matName string, shaderSrc []byte) Material {
shdrProg, err := shaders.LoadAndCompileCombinedShaderSrc(shaderSrc)
if err != nil {
logging.ErrLog.Fatalln("Failed to create new material. Err: ", err)
logging.ErrLog.Fatalf("Failed to create new material '%s'. Err: %s\n", matName, err.Error())
}
return &Material{Name: matName, ShaderProg: shdrProg, UnifLocs: make(map[string]int32), AttribLocs: make(map[string]int32)}
return Material{Name: matName, ShaderProg: shdrProg, UnifLocs: make(map[string]int32), AttribLocs: make(map[string]int32)}
}

59
meshes/mesh.go
View File

@ -2,7 +2,6 @@ package meshes
import (
"errors"
"fmt"
"github.com/bloeys/assimp-go/asig"
"github.com/bloeys/gglm/gglm"
@ -18,39 +17,43 @@ type SubMesh struct {
type Mesh struct {
Name string
Buf buffers.Buffer
Vao buffers.VertexArray
SubMeshes []SubMesh
}
func NewMesh(name, modelPath string, postProcessFlags asig.PostProcess) (*Mesh, error) {
func NewMesh(name, modelPath string, postProcessFlags asig.PostProcess) (Mesh, error) {
scene, release, err := asig.ImportFile(modelPath, asig.PostProcessTriangulate|postProcessFlags)
if err != nil {
return nil, errors.New("Failed to load model. Err: " + err.Error())
return Mesh{}, errors.New("Failed to load model. Err: " + err.Error())
}
defer release()
if len(scene.Meshes) == 0 {
return nil, errors.New("No meshes found in file: " + modelPath)
return Mesh{}, errors.New("No meshes found in file: " + modelPath)
}
mesh := &Mesh{
mesh := Mesh{
Name: name,
Buf: buffers.NewBuffer(),
Vao: buffers.NewVertexArray(),
SubMeshes: make([]SubMesh, 0, 1),
}
vbo := buffers.NewVertexBuffer()
ibo := buffers.NewIndexBuffer()
// Initial sizes assuming one submesh that has vertex pos+normals+texCoords, and 3 indices per face
var vertexBufData []float32 = make([]float32, 0, len(scene.Meshes[0].Vertices)*3*3*2)
var indexBufData []uint32 = make([]uint32, 0, len(scene.Meshes[0].Faces)*3)
// fmt.Printf("\nMesh %s has %d meshe(s) with first mesh having %d vertices\n", name, len(scene.Meshes), len(scene.Meshes[0].Vertices))
for i := 0; i < len(scene.Meshes); i++ {
sceneMesh := scene.Meshes[i]
if len(sceneMesh.TexCoords[0]) == 0 {
sceneMesh.TexCoords[0] = make([]gglm.Vec3, len(sceneMesh.Vertices))
println("Zeroing tex coords for submesh", i)
}
layoutToUse := []buffers.Element{{ElementType: buffers.DataTypeVec3}, {ElementType: buffers.DataTypeVec3}, {ElementType: buffers.DataTypeVec2}}
@ -59,17 +62,20 @@ func NewMesh(name, modelPath string, postProcessFlags asig.PostProcess) (*Mesh,
}
if i == 0 {
mesh.Buf.SetLayout(layoutToUse...)
vbo.SetLayout(layoutToUse...)
} else {
// @NOTE: Require that all submeshes have the same vertex buffer layout
firstSubmeshLayout := mesh.Buf.GetLayout()
assert.T(len(firstSubmeshLayout) == len(layoutToUse), fmt.Sprintf("Vertex layout of submesh %d does not equal vertex layout of the first submesh. Original layout: %v; This layout: %v", i, firstSubmeshLayout, layoutToUse))
// @TODO @NOTE: This requirement is because we are using one VAO+VBO for all
// the meshes and so the buffer must have one format.
//
// If we want to allow different layouts then we can simply create one vbo per layout and put
// meshes of the same layout in the same vbo, and we store the index of the vbo the mesh
// uses in the submesh struct.
firstSubmeshLayout := vbo.GetLayout()
assert.T(len(firstSubmeshLayout) == len(layoutToUse), "Vertex layout of submesh '%d' of mesh '%s' at path '%s' does not equal vertex layout of the first submesh. Original layout: %v; This layout: %v", i, name, modelPath, firstSubmeshLayout, layoutToUse)
for i := 0; i < len(firstSubmeshLayout); i++ {
if firstSubmeshLayout[i].ElementType != layoutToUse[i].ElementType {
panic(fmt.Sprintf("Vertex layout of submesh %d does not equal vertex layout of the first submesh. Original layout: %v; This layout: %v", i, firstSubmeshLayout, layoutToUse))
}
assert.T(firstSubmeshLayout[i].ElementType == layoutToUse[i].ElementType, "Vertex layout of submesh '%d' of mesh '%s' at path '%s' does not equal vertex layout of the first submesh. Original layout: %v; This layout: %v", i, name, modelPath, firstSubmeshLayout, layoutToUse)
}
}
@ -82,7 +88,7 @@ func NewMesh(name, modelPath string, postProcessFlags asig.PostProcess) (*Mesh,
mesh.SubMeshes = append(mesh.SubMeshes, SubMesh{
// Index of the vertex to start from (e.g. if index buffer says use vertex 5, and BaseVertex=3, the vertex used will be vertex 8)
BaseVertex: int32(len(vertexBufData)*4) / mesh.Buf.Stride,
BaseVertex: int32(len(vertexBufData)*4) / vbo.Stride,
// Which index (in the index buffer) to start from
BaseIndex: uint32(len(indexBufData)),
// How many indices in this submesh
@ -93,9 +99,16 @@ func NewMesh(name, modelPath string, postProcessFlags asig.PostProcess) (*Mesh,
indexBufData = append(indexBufData, indices...)
}
// fmt.Printf("!!! Vertex count: %d; Submeshes: %+v\n", len(vertexBufData)*4/int(mesh.Buf.Stride), mesh.SubMeshes)
mesh.Buf.SetData(vertexBufData)
mesh.Buf.SetIndexBufData(indexBufData)
vbo.SetData(vertexBufData, buffers.BufUsage_Static)
ibo.SetData(indexBufData)
mesh.Vao.AddVertexBuffer(vbo)
mesh.Vao.SetIndexBuffer(ibo)
// This is needed so that if you load meshes one after the other the
// following mesh doesn't attach its vbo/ibo to this vao
mesh.Vao.UnBind()
return mesh, nil
}
@ -119,9 +132,9 @@ type arrToInterleave struct {
func (a *arrToInterleave) get(i int) []float32 {
assert.T(len(a.V2s) == 0 || len(a.V3s) == 0, "One array should be set in arrToInterleave, but both arrays are set")
assert.T(len(a.V2s) == 0 || len(a.V4s) == 0, "One array should be set in arrToInterleave, but both arrays are set")
assert.T(len(a.V3s) == 0 || len(a.V4s) == 0, "One array should be set in arrToInterleave, but both arrays are set")
assert.T(len(a.V2s) == 0 || len(a.V3s) == 0, "One array should be set in arrToInterleave, but multiple arrays are set")
assert.T(len(a.V2s) == 0 || len(a.V4s) == 0, "One array should be set in arrToInterleave, but multiple arrays are set")
assert.T(len(a.V3s) == 0 || len(a.V4s) == 0, "One array should be set in arrToInterleave, but multiple arrays are set")
if len(a.V2s) > 0 {
return a.V2s[i].Data[:]
@ -173,7 +186,7 @@ func interleave(arrs ...arrToInterleave) []float32 {
func flattenFaces(faces []asig.Face) []uint32 {
assert.T(len(faces[0].Indices) == 3, fmt.Sprintf("Face doesn't have 3 indices. Index count: %v\n", len(faces[0].Indices)))
assert.T(len(faces[0].Indices) == 3, "Face doesn't have 3 indices. Index count: %v\n", len(faces[0].Indices))
uints := make([]uint32, len(faces)*3)
for i := 0; i < len(faces); i++ {

21
registry/iterator.go
View File

@ -29,12 +29,10 @@ func (it *Iterator[T]) Next() (*T, Handle) {
return nil, 0
}
// This does two things:
//
// First is if IsDone() only checked 'remainingItems', then when Next() returns the last item IsDone() will immediately be true which will cause loops to exit before processing that last item!
// If IsDone() only checked 'remainingItems', then when Next() returns the last item IsDone() will immediately be true which will cause loops to exit before processing the last item!
// However, with this check IsDone will remain false until Next() is called at least one more time after returning the last item which ensures the last item is processed in the loop.
//
// Secondly, if the iterator is created on an empty registry, the IsDone() check above won't pass, however the check here will correctly handle the case and make IsDone start returning true
// In cases where iterator is created on an empty registry, IsDone() will report true and the above check will return early
if it.remainingItems == 0 {
it.currIndex = -1
return nil, 0
@ -47,9 +45,10 @@ func (it *Iterator[T]) Next() (*T, Handle) {
continue
}
it.remainingItems--
item := &it.registry.Items[it.currIndex]
it.currIndex++
return &it.registry.Items[it.currIndex], handle
it.remainingItems--
return item, handle
}
// If we reached here means we iterated to the end and didn't find anything, which probably
@ -62,5 +61,13 @@ func (it *Iterator[T]) Next() (*T, Handle) {
}
func (it *Iterator[T]) IsDone() bool {
return it.currIndex == -1 && it.remainingItems == 0
if it.remainingItems != 0 {
return false
}
// We have two cases here:
// 1. Index of zero means Next() never returned an item. Remaining items of zero without returning anything means we have an empty registry and so its safe to report done
// 2. Negative index means Next() has detected we reached the end and that its safe to report being done
return it.currIndex <= 0
}

4
registry/registry.go
View File

@ -77,6 +77,10 @@ func (r *Registry[T]) New() (*T, Handle) {
func (r *Registry[T]) Get(id Handle) *T {
if id.IsZero() {
return nil
}
index := id.Index()
assert.T(index < uint64(len(r.Handles)), "Failed to get entity because of invalid entity handle. Handle index is %d while registry only has %d slots. Handle: %+v", index, r.ItemCount, id)

6
registry/registry_handle.go
View File

@ -16,6 +16,12 @@ const (
// Byte 1: Generation; Byte 2: Flags; Bytes 3-8: Index
type Handle uint64
// IsZero reports whether the handle is in its default 'zero' state.
// A zero handle is an invalid handle that does NOT point to any entity
func (h Handle) IsZero() bool {
return h == 0
}
func (h Handle) HasFlag(ef HandleFlag) bool {
return h.Flags()&ef > 0
}

48
renderer/rend3dgl/rend3dgl.go
View File

@ -2,6 +2,7 @@ package rend3dgl
import (
"github.com/bloeys/gglm/gglm"
"github.com/bloeys/nmage/buffers"
"github.com/bloeys/nmage/materials"
"github.com/bloeys/nmage/meshes"
"github.com/bloeys/nmage/renderer"
@ -11,23 +12,56 @@ import (
var _ renderer.Render = &Rend3DGL{}
type Rend3DGL struct {
BoundVao *buffers.VertexArray
BoundMesh *meshes.Mesh
BoundMat *materials.Material
}
func (r3d *Rend3DGL) Draw(mesh *meshes.Mesh, trMat *gglm.TrMat, mat *materials.Material) {
func (r *Rend3DGL) DrawMesh(mesh *meshes.Mesh, modelMat *gglm.TrMat, mat *materials.Material) {
if mesh != r3d.BoundMesh {
mesh.Buf.Bind()
r3d.BoundMesh = mesh
if mesh != r.BoundMesh {
mesh.Vao.Bind()
r.BoundMesh = mesh
}
if mat != r3d.BoundMat {
if mat != r.BoundMat {
mat.Bind()
r3d.BoundMat = mat
r.BoundMat = mat
}
mat.SetUnifMat4("modelMat", &trMat.Mat4)
mat.SetUnifMat4("modelMat", &modelMat.Mat4)
for i := 0; i < len(mesh.SubMeshes); i++ {
gl.DrawElementsBaseVertexWithOffset(gl.TRIANGLES, mesh.SubMeshes[i].IndexCount, gl.UNSIGNED_INT, uintptr(mesh.SubMeshes[i].BaseIndex), mesh.SubMeshes[i].BaseVertex)
}
}
func (r *Rend3DGL) DrawVertexArray(mat *materials.Material, vao *buffers.VertexArray, firstElement int32, elementCount int32) {
if vao != r.BoundVao {
vao.Bind()
r.BoundVao = vao
}
if mat != r.BoundMat {
mat.Bind()
r.BoundMat = mat
}
gl.DrawArrays(gl.TRIANGLES, firstElement, elementCount)
}
func (r *Rend3DGL) DrawCubemap(mesh *meshes.Mesh, mat *materials.Material) {
if mesh != r.BoundMesh {
mesh.Vao.Bind()
r.BoundMesh = mesh
}
if mat != r.BoundMat {
mat.Bind()
r.BoundMat = mat
}
for i := 0; i < len(mesh.SubMeshes); i++ {
gl.DrawElementsBaseVertexWithOffset(gl.TRIANGLES, mesh.SubMeshes[i].IndexCount, gl.UNSIGNED_INT, uintptr(mesh.SubMeshes[i].BaseIndex), mesh.SubMeshes[i].BaseVertex)

5
renderer/renderer.go
View File

@ -2,11 +2,14 @@ package renderer
import (
"github.com/bloeys/gglm/gglm"
"github.com/bloeys/nmage/buffers"
"github.com/bloeys/nmage/materials"
"github.com/bloeys/nmage/meshes"
)
type Render interface {
Draw(mesh *meshes.Mesh, trMat *gglm.TrMat, mat *materials.Material)
DrawMesh(mesh *meshes.Mesh, trMat *gglm.TrMat, mat *materials.Material)
DrawVertexArray(mat *materials.Material, vao *buffers.VertexArray, firstElement int32, count int32)
DrawCubemap(mesh *meshes.Mesh, mat *materials.Material)
FrameEnd()
}

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res/models/color-cube.fbx
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res/models/cube.fbx Executable file
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res/models/plane.fbx Executable file
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54
res/shaders/array-depth-map.glsl Executable file
View File

@ -0,0 +1,54 @@
//shader:vertex
#version 410
layout(location=0) in vec3 vertPosIn;
uniform mat4 modelMat;
void main()
{
gl_Position = modelMat * vec4(vertPosIn, 1);
}
//shader:geometry
#version 410
layout (triangles) in;
#define NUM_PROJ_VIEW_MATS 4
// 3 * NUM_PROJ_VIEW_MATS
layout (triangle_strip, max_vertices=12) out;
// This is the same number as max spot lights or whatever else is being rendered
uniform mat4 projViewMats[NUM_PROJ_VIEW_MATS];
out vec4 FragPos;
void main()
{
for(int projViewMatIndex = 0; projViewMatIndex < NUM_PROJ_VIEW_MATS; projViewMatIndex++){
gl_Layer = projViewMatIndex;
mat4 projViewMat = projViewMats[projViewMatIndex];
for(int i = 0; i < 3; i++)
{
FragPos = gl_in[i].gl_Position;
gl_Position = projViewMat * FragPos;
EmitVertex();
}
EndPrimitive();
}
}
//shader:fragment
#version 410
in vec4 FragPos;
void main()
{
// This implicitly writes to the depth buffer with no color operations
// Equivalent: gl_FragDepth = gl_FragCoord.z;
}

9
res/shaders/debug-depth.glsl
View File

@ -13,17 +13,18 @@ out vec3 fragPos;
//MVP = Model View Projection
uniform mat4 modelMat;
uniform mat4 viewMat;
uniform mat4 projMat;
uniform mat4 projViewMat;
void main()
{
vertNormal = mat3(transpose(inverse(modelMat))) * vertNormalIn;
vertUV0 = vertUV0In;
vertColor = vertColorIn;
fragPos = vec3(modelMat * vec4(vertPosIn, 1.0));
gl_Position = projMat * viewMat * modelMat * vec4(vertPosIn, 1.0);
vec4 modelVert = modelMat * vec4(vertPosIn, 1);
fragPos = modelVert.xyz;
gl_Position = projViewMat * modelVert;
}
//shader:fragment

21
res/shaders/depth-map.glsl Executable file
View File

@ -0,0 +1,21 @@
//shader:vertex
#version 410
layout(location=0) in vec3 vertPosIn;
uniform mat4 modelMat;
uniform mat4 projViewMat;
void main()
{
gl_Position = projViewMat * modelMat * vec4(vertPosIn, 1);
}
//shader:fragment
#version 410
void main()
{
// This implicitly writes to the depth buffer with no color operations
// Equivalent: gl_FragDepth = gl_FragCoord.z;
}

47
res/shaders/imgui.glsl Executable file
View File

@ -0,0 +1,47 @@
//shader:vertex
#version 410
uniform mat4 ProjMtx;
in vec2 Position;
in vec2 UV;
in vec4 Color;
out vec2 Frag_UV;
out vec4 Frag_Color;
// Imgui doesn't handle srgb correctly, and looks too bright and wrong in srgb buffers (see: https://github.com/ocornut/imgui/issues/578).
// While not a complete fix (that would require changes in imgui itself), moving incoming srgba colors to linear in the vertex shader helps make things look better.
vec4 srgba_to_linear(vec4 srgbaColor){
#define gamma_correction 2.2
return vec4(
pow(srgbaColor.r, gamma_correction),
pow(srgbaColor.g, gamma_correction),
pow(srgbaColor.b, gamma_correction),
srgbaColor.a
);
}
void main()
{
Frag_UV = UV;
Frag_Color = srgba_to_linear(Color);
gl_Position = ProjMtx * vec4(Position.xy, 0, 1);
}
//shader:fragment
#version 410
uniform sampler2D Texture;
in vec2 Frag_UV;
in vec4 Frag_Color;
out vec4 Out_Color;
void main()
{
Out_Color = vec4(Frag_Color.rgb, Frag_Color.a * texture(Texture, Frag_UV.st).r);
}

65
res/shaders/omnidirectional-depth-map.glsl Executable file
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@ -0,0 +1,65 @@
//shader:vertex
#version 410
layout(location=0) in vec3 vertPosIn;
uniform mat4 modelMat;
void main()
{
gl_Position = modelMat * vec4(vertPosIn, 1);
}
//shader:geometry
#version 410
layout (triangles) in;
// Cubemap means 6 faces, and the
// input 3 triangle vertices are drawn once per face, so 6*3=18
layout (triangle_strip, max_vertices=18) out;
uniform int cubemapIndex;
uniform mat4 cubemapProjViewMats[6];
out vec4 FragPos;
void main()
{
for(int face = 0; face < 6; ++face)
{
// Built in variable that specifies which cubemap face we are rendering to
// and only works when a cubemap is attached to the active fbo.
//
// We use an additional index here because our fbo has a cubemap array
gl_Layer = (cubemapIndex * 6) + face;
// Transform each triangle vertex
for(int i = 0; i < 3; ++i)
{
FragPos = gl_in[i].gl_Position;
gl_Position = cubemapProjViewMats[face] * FragPos;
EmitVertex();
}
EndPrimitive();
}
}
//shader:fragment
#version 410
in vec4 FragPos;
uniform vec3 lightPos;
uniform float farPlane;
void main()
{
// Get distance between fragment and light source
float lightDistance = length(FragPos.xyz - lightPos);
// Map to [0, 1] by dividing by far plane and use it as our depth
lightDistance = lightDistance / farPlane;
gl_FragDepth = lightDistance;
}

45
res/shaders/screen-quad.glsl Executable file
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@ -0,0 +1,45 @@
//shader:vertex
#version 410
out vec2 vertUV0;
// Hardcoded vertex positions for a fullscreen quad.
// Format: vec4(pos.x, pos.y, uv0.x, uv0.y)
vec4 quadData[6] = vec4[](
vec4(-1.0, 1.0, 0.0, 1.0),
vec4(-1.0, -1.0, 0.0, 0.0),
vec4(1.0, -1.0, 1.0, 0.0),
vec4(-1.0, 1.0, 0.0, 1.0),
vec4(1.0, -1.0, 1.0, 0.0),
vec4(1.0, 1.0, 1.0, 1.0)
);
uniform vec2 scale = vec2(1, 1);
uniform vec2 offset = vec2(0, 0);
void main()
{
vec4 vertData = quadData[gl_VertexID];
vertUV0 = vertData.zw;
gl_Position = vec4((vertData.xy * scale) + offset, 0.0, 1.0);
}
//shader:fragment
#version 410
struct Material {
sampler2D diffuse;
};
uniform Material material;
in vec2 vertUV0;
out vec4 fragColor;
void main()
{
vec4 diffuseTexColor = texture(material.diffuse, vertUV0);
fragColor = vec4(diffuseTexColor.rgb, 1);
}

54
res/shaders/simple-unlit.glsl Executable file
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@ -0,0 +1,54 @@
//shader:vertex
#version 410
layout(location=0) in vec3 vertPosIn;
layout(location=1) in vec3 vertNormalIn;
layout(location=2) in vec2 vertUV0In;
layout(location=3) in vec3 vertColorIn;
out vec3 vertNormal;
out vec2 vertUV0;
out vec3 vertColor;
out vec3 fragPos;
//MVP = Model View Projection
uniform mat4 modelMat;
uniform mat4 projViewMat;
void main()
{
// @TODO: Calculate this on the CPU and send it as a uniform
//
// This produces the normal matrix that multiplies with the model normal to produce the
// world space normal. Based on 'One last thing' section from: https://learnopengl.com/Lighting/Basic-Lighting
vertNormal = mat3(transpose(inverse(modelMat))) * vertNormalIn;
vertUV0 = vertUV0In;
vertColor = vertColorIn;
vec4 modelVert = modelMat * vec4(vertPosIn, 1);
fragPos = modelVert.xyz;
gl_Position = projViewMat * modelVert;
}
//shader:fragment
#version 410
struct Material {
sampler2D diffuse;
};
uniform Material material;
in vec3 vertColor;
in vec3 vertNormal;
in vec2 vertUV0;
in vec3 fragPos;
out vec4 fragColor;
void main()
{
vec4 diffuseTexColor = texture(material.diffuse, vertUV0);
fragColor = vec4(diffuseTexColor.rgb, 1);
}

297
res/shaders/simple.glsl
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@ -6,50 +6,311 @@ layout(location=1) in vec3 vertNormalIn;
layout(location=2) in vec2 vertUV0In;
layout(location=3) in vec3 vertColorIn;
uniform mat4 modelMat;
uniform mat4 projViewMat;
uniform mat4 dirLightProjViewMat;
#define NUM_SPOT_LIGHTS 4
uniform mat4 spotLightProjViewMats[NUM_SPOT_LIGHTS];
out vec3 vertNormal;
out vec2 vertUV0;
out vec3 vertColor;
out vec3 fragPos;
//MVP = Model View Projection
uniform mat4 modelMat;
uniform mat4 viewMat;
uniform mat4 projMat;
out vec4 fragPosDirLight;
out vec4 fragPosSpotLight[NUM_SPOT_LIGHTS];
void main()
{
// @TODO: Calculate this on the CPU and send it as a uniform
//
// This produces the normal matrix that multiplies with the model normal to produce the
// world space normal. Based on 'One last thing' section from: https://learnopengl.com/Lighting/Basic-Lighting
vertNormal = mat3(transpose(inverse(modelMat))) * vertNormalIn;
vertUV0 = vertUV0In;
vertColor = vertColorIn;
fragPos = vec3(modelMat * vec4(vertPosIn, 1.0));
gl_Position = projMat * viewMat * modelMat * vec4(vertPosIn, 1.0);
vec4 modelVert = modelMat * vec4(vertPosIn, 1);
fragPos = modelVert.xyz;
fragPosDirLight = dirLightProjViewMat * vec4(fragPos, 1);
for (int i = 0; i < NUM_SPOT_LIGHTS; i++)
fragPosSpotLight[i] = spotLightProjViewMats[i] * vec4(fragPos, 1);
gl_Position = projViewMat * modelVert;
}
//shader:fragment
#version 410
uniform float ambientStrength = 0;
uniform vec3 ambientLightColor = vec3(1, 1, 1);
struct Material {
sampler2D diffuse;
sampler2D specular;
// sampler2D normal;
sampler2D emission;
float shininess;
};
uniform vec3 lightPos1;
uniform vec3 lightColor1;
uniform Material material;
uniform sampler2D diffTex;
struct DirLight {
vec3 dir;
vec3 diffuseColor;
vec3 specularColor;
sampler2D shadowMap;
};
uniform DirLight dirLight;
struct PointLight {
vec3 pos;
vec3 diffuseColor;
vec3 specularColor;
float constant;
float linear;
float quadratic;
float farPlane;
};
#define NUM_POINT_LIGHTS 8
uniform PointLight pointLights[NUM_POINT_LIGHTS];
uniform samplerCubeArray pointLightCubeShadowMaps;
struct SpotLight {
vec3 pos;
vec3 dir;
vec3 diffuseColor;
vec3 specularColor;
float innerCutoff;
float outerCutoff;
};
#define NUM_SPOT_LIGHTS 4
uniform SpotLight spotLights[NUM_SPOT_LIGHTS];
uniform sampler2DArray spotLightShadowMaps;
uniform vec3 camPos;
uniform vec3 ambientColor = vec3(0.2, 0.2, 0.2);
in vec3 vertColor;
in vec3 vertNormal;
in vec2 vertUV0;
in vec3 fragPos;
in vec4 fragPosDirLight;
in vec4 fragPosSpotLight[NUM_SPOT_LIGHTS];
out vec4 fragColor;
// Global variables used as cache for lighting calculations
vec4 diffuseTexColor;
vec4 specularTexColor;
vec4 emissionTexColor;
vec3 normalizedVertNorm;
vec3 viewDir;
float CalcDirShadow(sampler2D shadowMap, vec3 lightDir)
{
// Move from clip space to NDC
vec3 projCoords = fragPosDirLight.xyz / fragPosDirLight.w;
// Move from [-1,1] to [0, 1]
projCoords = projCoords * 0.5 + 0.5;
// If sampling outside the depth texture then force 'no shadow'
if(projCoords.z > 1)
return 0;
// currentDepth is the fragment depth from the light's perspective
float currentDepth = projCoords.z;
// Bias in the range [0.005, 0.05] depending on the angle, where a higher
// angle gives a higher bias, as shadow acne gets worse with angle
float bias = max(0.05 * (1 - dot(normalizedVertNorm, lightDir)), 0.005);
// 'Percentage Close Filtering'.
// Basically get soft shadows by averaging this texel and surrounding ones
float shadow = 0;
vec2 texelSize = 1 / textureSize(shadowMap, 0);
for(int x = -1; x <= 1; x++)
{
for(int y = -1; y <= 1; y++)
{
float pcfDepth = texture(shadowMap, projCoords.xy + vec2(x, y) * texelSize).r;
// If our depth is larger than the lights closest depth at the texel we checked (projCoords),
// then there is something closer to the light than us, and so we are in shadow
shadow += currentDepth - bias > pcfDepth ? 1 : 0;
}
}
shadow /= 9;
return shadow;
}
vec3 CalcDirLight()
{
vec3 lightDir = normalize(-dirLight.dir);
// Diffuse
float diffuseAmount = max(0.0, dot(normalizedVertNorm, lightDir));
vec3 finalDiffuse = diffuseAmount * dirLight.diffuseColor * diffuseTexColor.rgb;
// Specular
vec3 halfwayDir = normalize(lightDir + viewDir);
float specularAmount = pow(max(dot(normalizedVertNorm, halfwayDir), 0.0), material.shininess);
vec3 finalSpecular = specularAmount * dirLight.specularColor * specularTexColor.rgb;
// Shadow
float shadow = CalcDirShadow(dirLight.shadowMap, lightDir);
return (finalDiffuse + finalSpecular) * (1 - shadow);
}
float CalcPointShadow(int lightIndex, vec3 lightPos, vec3 lightDir, float farPlane) {
vec3 lightToFrag = fragPos - lightPos;
float closestDepth = texture(pointLightCubeShadowMaps, vec4(lightToFrag, lightIndex)).r;
// We stored depth in the cubemap in the range [0, 1], so now we move back to [0, farPlane]
closestDepth *= farPlane;
// Get depth of current fragment
float currentDepth = length(lightToFrag);
float bias = max(0.05 * (1 - dot(normalizedVertNorm, lightDir)), 0.005);
float shadow = currentDepth - bias > closestDepth ? 1.0 : 0.0;
return shadow;
}
vec3 CalcPointLight(PointLight pointLight, int lightIndex)
{
// Ignore unset lights
if (pointLight.constant == 0){
return vec3(0);
}
vec3 lightDir = normalize(pointLight.pos - fragPos);
// Diffuse
float diffuseAmount = max(0.0, dot(normalizedVertNorm, lightDir));
vec3 finalDiffuse = diffuseAmount * pointLight.diffuseColor * diffuseTexColor.rgb;
// Specular
vec3 halfwayDir = normalize(lightDir + viewDir);
float specularAmount = pow(max(dot(normalizedVertNorm, halfwayDir), 0.0), material.shininess);
vec3 finalSpecular = specularAmount * pointLight.specularColor * specularTexColor.rgb;
// Attenuation
float distToLight = length(pointLight.pos - fragPos);
float attenuation = 1 / (pointLight.constant + pointLight.linear * distToLight + pointLight.quadratic * (distToLight * distToLight));
// Shadow
float shadow = CalcPointShadow(lightIndex, pointLight.pos, lightDir, pointLight.farPlane);
return (finalDiffuse + finalSpecular) * attenuation * (1 - shadow);
}
float CalcSpotShadow(vec3 lightDir, int lightIndex)
{
// Move from clip space to NDC
vec3 projCoords = fragPosSpotLight[lightIndex].xyz / fragPosSpotLight[lightIndex].w;
// Move from [-1,1] to [0, 1]
projCoords = projCoords * 0.5 + 0.5;
// If sampling outside the depth texture then force 'no shadow'
if(projCoords.z > 1)
return 0;
// currentDepth is the fragment depth from the light's perspective
float currentDepth = projCoords.z;
// Bias in the range [0.005, 0.05] depending on the angle, where a higher
// angle gives a higher bias, as shadow acne gets worse with angle
float bias = max(0.05 * (1 - dot(normalizedVertNorm, lightDir)), 0.005);
// 'Percentage Close Filtering'.
// Basically get soft shadows by averaging this texel and surrounding ones
float shadow = 0;
vec2 texelSize = 1 / textureSize(spotLightShadowMaps, 0).xy;
for(int x = -1; x <= 1; x++)
{
for(int y = -1; y <= 1; y++)
{
float pcfDepth = texture(spotLightShadowMaps, vec3(projCoords.xy + vec2(x, y) * texelSize, lightIndex)).r;
// If our depth is larger than the lights closest depth at the texel we checked (projCoords),
// then there is something closer to the light than us, and so we are in shadow
shadow += currentDepth - bias > pcfDepth ? 1 : 0;
}
}
shadow /= 9;
return shadow;
}
vec3 CalcSpotLight(SpotLight light, int lightIndex)
{
if (light.innerCutoff == 0)
return vec3(0);
vec3 fragToLightDir = normalize(light.pos - fragPos);
// Spot light cone with full intensity within inner cutoff,
// and falloff between inner-outer cutoffs, and zero
// light after outer cutoff
float theta = dot(fragToLightDir, normalize(-light.dir));
float epsilon = (light.innerCutoff - light.outerCutoff);
float intensity = clamp((theta - light.outerCutoff) / epsilon, float(0), float(1));
if (intensity == 0)
return vec3(0);
// Diffuse
float diffuseAmount = max(0.0, dot(normalizedVertNorm, fragToLightDir));
vec3 finalDiffuse = diffuseAmount * light.diffuseColor * diffuseTexColor.rgb;
// Specular
vec3 halfwayDir = normalize(fragToLightDir + viewDir);
float specularAmount = pow(max(dot(normalizedVertNorm, halfwayDir), 0.0), material.shininess);
vec3 finalSpecular = specularAmount * light.specularColor * specularTexColor.rgb;
// Shadow
float shadow = CalcSpotShadow(fragToLightDir, lightIndex);
return (finalDiffuse + finalSpecular) * intensity * (1 - shadow);
}
void main()
{
vec3 lightDir = normalize(lightPos1 - fragPos);
float diffStrength = max(0.0, dot(normalize(vertNormal), lightDir));
// Shared values
diffuseTexColor = texture(material.diffuse, vertUV0);
specularTexColor = texture(material.specular, vertUV0);
emissionTexColor = texture(material.emission, vertUV0);
vec3 finalAmbientColor = ambientLightColor * ambientStrength;
vec4 texColor = texture(diffTex, vertUV0);
fragColor = vec4(texColor.rgb * vertColor * (finalAmbientColor + diffStrength*lightColor1) , texColor.a);
}
normalizedVertNorm = normalize(vertNormal);
viewDir = normalize(camPos - fragPos);
// Light contributions
vec3 finalColor = CalcDirLight();
for (int i = 0; i < NUM_POINT_LIGHTS; i++)
{
finalColor += CalcPointLight(pointLights[i], i);
}
for (int i = 0; i < NUM_SPOT_LIGHTS; i++)
{
finalColor += CalcSpotLight(spotLights[i], i);
}
vec3 finalEmission = emissionTexColor.rgb;
vec3 finalAmbient = ambientColor * diffuseTexColor.rgb;
fragColor = vec4(finalColor + finalAmbient + finalEmission, 1);
}

5
res/shaders/skybox.glsl
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@ -8,13 +8,12 @@ layout(location=3) in vec3 vertColorIn;
out vec3 vertUV0;
uniform mat4 viewMat;
uniform mat4 projMat;
uniform mat4 projViewMat;
void main()
{
vertUV0 = vec3(vertPosIn.x, vertPosIn.y, -vertPosIn.z);
vec4 pos = projMat * viewMat * vec4(vertPosIn, 1.0);
vec4 pos = projViewMat * vec4(vertPosIn, 1.0);
gl_Position = pos.xyww;
}

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46
shaders/shader_program.go
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@ -6,32 +6,48 @@ import (
)
type ShaderProgram struct {
ID uint32
VertShaderID uint32
FragShaderID uint32
Id uint32
VertShaderId uint32
FragShaderId uint32
GeomShaderId uint32
}
func (sp *ShaderProgram) AttachShader(shader Shader) {
gl.AttachShader(sp.ID, shader.ID)
switch shader.ShaderType {
case VertexShaderType:
sp.VertShaderID = shader.ID
case FragmentShaderType:
sp.FragShaderID = shader.ID
gl.AttachShader(sp.Id, shader.Id)
switch shader.Type {
case ShaderType_Vertex:
sp.VertShaderId = shader.Id
case ShaderType_Fragment:
sp.FragShaderId = shader.Id
case ShaderType_Geometry:
sp.GeomShaderId = shader.Id
default:
logging.ErrLog.Println("Unknown shader type ", shader.ShaderType, " for ID ", shader.ID)
logging.ErrLog.Fatalf("Unknown shader type '%d' for shader id '%d'\n", shader.Type, shader.Id)
}
}
func (sp *ShaderProgram) Link() {
gl.LinkProgram(sp.ID)
gl.LinkProgram(sp.Id)
if sp.VertShaderID != 0 {
gl.DeleteShader(sp.VertShaderID)
if sp.VertShaderId != 0 {
gl.DeleteShader(sp.VertShaderId)
}
if sp.FragShaderID != 0 {
gl.DeleteShader(sp.FragShaderID)
if sp.FragShaderId != 0 {
gl.DeleteShader(sp.FragShaderId)
}
if sp.GeomShaderId != 0 {
gl.DeleteShader(sp.GeomShaderId)
}
}
func (s *ShaderProgram) Bind() {
gl.UseProgram(s.Id)
}
func (s *ShaderProgram) UnBind() {
gl.UseProgram(0)
}

29
shaders/shader_types.go
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@ -1,10 +1,31 @@
package shaders
import "github.com/go-gl/gl/v4.1-core/gl"
import (
"github.com/bloeys/nmage/logging"
"github.com/go-gl/gl/v4.1-core/gl"
)
type ShaderType int
type ShaderType int32
func (s ShaderType) ToGl() uint32 {
switch s {
case ShaderType_Vertex:
return gl.VERTEX_SHADER
case ShaderType_Fragment:
return gl.FRAGMENT_SHADER
case ShaderType_Geometry:
return gl.GEOMETRY_SHADER
default:
logging.ErrLog.Fatalf("Unknown shader type '%d'\n", s)
return 0
}
}
const (
VertexShaderType ShaderType = gl.VERTEX_SHADER
FragmentShaderType ShaderType = gl.FRAGMENT_SHADER
ShaderType_Unknown ShaderType = iota
ShaderType_Vertex
ShaderType_Fragment
ShaderType_Geometry
)

62
shaders/shaders.go
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@ -3,6 +3,7 @@ package shaders
import (
"bytes"
"errors"
"fmt"
"os"
"strings"
@ -11,12 +12,13 @@ import (
)
type Shader struct {
ID uint32
ShaderType ShaderType
Id uint32
Type ShaderType
}
func (s Shader) Delete() {
gl.DeleteShader(s.ID)
func (s *Shader) Delete() {
gl.DeleteShader(s.Id)
s.Id = 0
}
func NewShaderProgram() (ShaderProgram, error) {
@ -26,7 +28,7 @@ func NewShaderProgram() (ShaderProgram, error) {
return ShaderProgram{}, errors.New("failed to create shader program")
}
return ShaderProgram{ID: id}, nil
return ShaderProgram{Id: id}, nil
}
func LoadAndCompileCombinedShader(shaderPath string) (ShaderProgram, error) {
@ -43,8 +45,8 @@ func LoadAndCompileCombinedShader(shaderPath string) (ShaderProgram, error) {
func LoadAndCompileCombinedShaderSrc(shaderSrc []byte) (ShaderProgram, error) {
shaderSources := bytes.Split(shaderSrc, []byte("//shader:"))
if len(shaderSources) == 1 {
return ShaderProgram{}, errors.New("failed to read combined shader. Did not find '//shader:vertex' or '//shader:fragment'")
if len(shaderSources) < 2 {
return ShaderProgram{}, errors.New("failed to read combined shader. The minimum shader types to have are '//shader:vertex' and '//shader:fragment'")
}
shdrProg, err := NewShaderProgram()
@ -65,12 +67,15 @@ func LoadAndCompileCombinedShaderSrc(shaderSrc []byte) (ShaderProgram, error) {
var shdrType ShaderType
if bytes.HasPrefix(src, []byte("vertex")) {
src = src[6:]
shdrType = VertexShaderType
shdrType = ShaderType_Vertex
} else if bytes.HasPrefix(src, []byte("fragment")) {
src = src[8:]
shdrType = FragmentShaderType
shdrType = ShaderType_Fragment
} else if bytes.HasPrefix(src, []byte("geometry")) {
src = src[8:]
shdrType = ShaderType_Geometry
} else {
return ShaderProgram{}, errors.New("unknown shader type. Must be '//shader:vertex' or '//shader:fragment'")
return ShaderProgram{}, errors.New("unknown shader type. Must be '//shader:vertex' or '//shader:fragment' or '//shader:geometry'")
}
shdr, err := CompileShaderOfType(src, shdrType)
@ -83,7 +88,15 @@ func LoadAndCompileCombinedShaderSrc(shaderSrc []byte) (ShaderProgram, error) {
}
if loadedShdrCount == 0 {
return ShaderProgram{}, errors.New("no valid shaders found. Please put '//shader:vertex' or '//shader:fragment' before your shaders")
return ShaderProgram{}, errors.New("no valid shaders found. Please put '//shader:vertex' or '//shader:fragment' or '//shader:geometry' before your shaders")
}
if shdrProg.VertShaderId == 0 {
return ShaderProgram{}, errors.New("no valid vertex shader found. Please put '//shader:vertex' before your vertex shader")
}
if shdrProg.FragShaderId == 0 {
return ShaderProgram{}, errors.New("no valid fragment shader found. Please put '//shader:fragment' before your vertex shader")
}
shdrProg.Link()
@ -92,41 +105,40 @@ func LoadAndCompileCombinedShaderSrc(shaderSrc []byte) (ShaderProgram, error) {
func CompileShaderOfType(shaderSource []byte, shaderType ShaderType) (Shader, error) {
shaderID := gl.CreateShader(uint32(shaderType))
if shaderID == 0 {
logging.ErrLog.Println("Failed to create shader.")
return Shader{}, errors.New("failed to create shader")
shaderId := gl.CreateShader(shaderType.ToGl())
if shaderId == 0 {
return Shader{}, fmt.Errorf("failed to create OpenGl shader. OpenGl Error=%d", gl.GetError())
}
//Load shader source and compile
shaderCStr, shaderFree := gl.Strs(string(shaderSource) + "\x00")
defer shaderFree()
gl.ShaderSource(shaderID, 1, shaderCStr, nil)
gl.ShaderSource(shaderId, 1, shaderCStr, nil)
gl.CompileShader(shaderID)
if err := getShaderCompileErrors(shaderID); err != nil {
gl.DeleteShader(shaderID)
gl.CompileShader(shaderId)
if err := getShaderCompileErrors(shaderId); err != nil {
gl.DeleteShader(shaderId)
return Shader{}, err
}
return Shader{ID: shaderID, ShaderType: shaderType}, nil
return Shader{Id: shaderId, Type: shaderType}, nil
}
func getShaderCompileErrors(shaderID uint32) error {
func getShaderCompileErrors(shaderId uint32) error {
var compiledSuccessfully int32
gl.GetShaderiv(shaderID, gl.COMPILE_STATUS, &compiledSuccessfully)
gl.GetShaderiv(shaderId, gl.COMPILE_STATUS, &compiledSuccessfully)
if compiledSuccessfully == gl.TRUE {
return nil
}
var logLength int32
gl.GetShaderiv(shaderID, gl.INFO_LOG_LENGTH, &logLength)
gl.GetShaderiv(shaderId, gl.INFO_LOG_LENGTH, &logLength)
log := gl.Str(strings.Repeat("\x00", int(logLength)))
gl.GetShaderInfoLog(shaderID, logLength, nil, log)
gl.GetShaderInfoLog(shaderId, logLength, nil, log)
errMsg := gl.GoStr(log)
logging.ErrLog.Println("Compilation of shader with id ", shaderID, " failed. Err: ", errMsg)
logging.ErrLog.Println("Compilation of shader with id ", shaderId, " failed. Err: ", errMsg)
return errors.New(errMsg)
}

54
ui/imgui/imgui.go
View File

@ -12,11 +12,12 @@ import (
type ImguiInfo struct {
ImCtx imgui.Context
Mat *materials.Material
Mat materials.Material
VaoID uint32
VboID uint32
IndexBufID uint32
TexID uint32
// This is a pointer so we can send a stable pointer to C code
TexID *uint32
}
func (i *ImguiInfo) FrameStart(winWidth, winHeight float32) {
@ -67,7 +68,7 @@ func (i *ImguiInfo) Render(winWidth, winHeight float32, fbWidth, fbHeight int32)
i.Mat.Bind()
i.Mat.SetUnifInt32("Texture", 0)
//PERF: only update the ortho matrix on window resize
// @PERF: only update the ortho matrix on window resize
orthoMat := gglm.Ortho(0, float32(winWidth), 0, float32(winHeight), 0, 20)
i.Mat.SetUnifMat4("ProjMtx", &orthoMat.Mat4)
gl.BindSampler(0, 0) // Rely on combined texture/sampler state.
@ -108,11 +109,12 @@ func (i *ImguiInfo) Render(winWidth, winHeight float32, fbWidth, fbHeight int32)
cmd.CallUserCallback(list)
} else {
gl.BindTexture(gl.TEXTURE_2D, i.TexID)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, *i.TexID)
clipRect := cmd.ClipRect()
gl.Scissor(int32(clipRect.X), int32(fbHeight)-int32(clipRect.W), int32(clipRect.Z-clipRect.X), int32(clipRect.W-clipRect.Y))
gl.DrawElementsBaseVertex(gl.TRIANGLES, int32(cmd.ElemCount()), uint32(drawType), gl.PtrOffset(int(cmd.IdxOffset())*indexSize), int32(cmd.VtxOffset()))
gl.DrawElementsBaseVertexWithOffset(gl.TRIANGLES, int32(cmd.ElemCount()), uint32(drawType), uintptr(int(cmd.IdxOffset())*indexSize), int32(cmd.VtxOffset()))
}
}
}
@ -141,13 +143,14 @@ func (i *ImguiInfo) AddFontTTF(fontPath string, fontSize float32, fontConfig *im
f := a.AddFontFromFileTTFV(fontPath, fontSize, fontConfigToUse, glyphRangesToUse.Data())
pixels, width, height, _ := a.GetTextureDataAsAlpha8()
gl.BindTexture(gl.TEXTURE_2D, i.TexID)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, *i.TexID)
gl.TexImage2D(gl.TEXTURE_2D, 0, gl.RED, int32(width), int32(height), 0, gl.RED, gl.UNSIGNED_BYTE, pixels)
return f
}
const imguiShdrSrc = `
const DefaultImguiShader = `
//shader:vertex
#version 410
@ -160,10 +163,24 @@ in vec4 Color;
out vec2 Frag_UV;
out vec4 Frag_Color;
// Imgui doesn't handle srgb correctly, and looks too bright and wrong in srgb buffers (see: https://github.com/ocornut/imgui/issues/578).
// While not a complete fix (that would require changes in imgui itself), moving incoming srgba colors to linear in the vertex shader helps make things look better.
vec4 srgba_to_linear(vec4 srgbaColor){
#define gamma_correction 2.2
return vec4(
pow(srgbaColor.r, gamma_correction),
pow(srgbaColor.g, gamma_correction),
pow(srgbaColor.b, gamma_correction),
srgbaColor.a
);
}
void main()
{
Frag_UV = UV;
Frag_Color = Color;
Frag_Color = srgba_to_linear(Color);
gl_Position = ProjMtx * vec4(Position.xy, 0, 1);
}
@ -183,11 +200,21 @@ void main()
}
`
func NewImGui() ImguiInfo {
// NewImGui setups imgui using the passed shader.
// If the path is empty a default nMage shader is used
func NewImGui(shaderPath string) ImguiInfo {
var imguiMat materials.Material
if shaderPath == "" {
imguiMat = materials.NewMaterialSrc("ImGUI Mat", []byte(DefaultImguiShader))
} else {
imguiMat = materials.NewMaterial("ImGUI Mat", shaderPath)
}
imguiInfo := ImguiInfo{
ImCtx: imgui.CreateContext(),
Mat: materials.NewMaterialSrc("ImGUI Mat", []byte(imguiShdrSrc)),
Mat: imguiMat,
TexID: new(uint32),
}
io := imgui.CurrentIO()
@ -197,10 +224,11 @@ func NewImGui() ImguiInfo {
gl.GenVertexArrays(1, &imguiInfo.VaoID)
gl.GenBuffers(1, &imguiInfo.VboID)
gl.GenBuffers(1, &imguiInfo.IndexBufID)
gl.GenTextures(1, &imguiInfo.TexID)
gl.GenTextures(1, imguiInfo.TexID)
// Upload font to gpu
gl.BindTexture(gl.TEXTURE_2D, imguiInfo.TexID)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, *imguiInfo.TexID)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.LINEAR)
gl.TexParameteri(gl.TEXTURE_2D, gl.TEXTURE_MAG_FILTER, gl.LINEAR)
gl.PixelStorei(gl.UNPACK_ROW_LENGTH, 0)
@ -209,7 +237,7 @@ func NewImGui() ImguiInfo {
gl.TexImage2D(gl.TEXTURE_2D, 0, gl.RED, int32(width), int32(height), 0, gl.RED, gl.UNSIGNED_BYTE, pixels)
// Store our identifier
io.Fonts().SetTexID(imgui.TextureID(uintptr(imguiInfo.TexID)))
io.Fonts().SetTexID(imgui.TextureID(imguiInfo.TexID))
//Shader attributes
imguiInfo.Mat.Bind()