added Linux arm64 SDK

This commit is contained in:
Andrew Zambazos
2026-06-11 14:07:38 +12:00
parent c0395a49bd
commit cbf3f085d0
2160 changed files with 1 additions and 542 deletions
-587
View File
@@ -1,587 +0,0 @@
#include <string>
static const std::string shader_fill_frag1 = R"(
#version 150
// Program Uniforms
uniform vec4 State;
uniform mat4 Transform;
uniform vec4 Scalar4[2];
uniform vec4 Vector[8];
uniform uint ClipSize;
uniform mat4 Clip[8];
// Uniform Accessor Functions
float Scalar(uint i) { if (i < 4u) return Scalar4[0][i]; else return Scalar4[1][i - 4u]; }
// Texture Units
uniform sampler2D Texture1;
uniform sampler2D Texture2;
uniform sampler2D Texture3;
// Vertex Attributes
in vec4 ex_Color;
in vec2 ex_TexCoord;
in vec2 ex_ObjectCoord;
in vec2 ex_ScreenCoord;
in vec4 ex_Data0;
in vec4 ex_Data1;
in vec4 ex_Data2;
in vec4 ex_Data3;
in vec4 ex_Data4;
in vec4 ex_Data5;
in vec4 ex_Data6;
// Out Params
out vec4 out_Color;
uint FillType() { return uint(ex_Data0.x + 0.5); }
vec4 TileRectUV() { return Vector[0]; }
vec2 TileSize() { return Vector[1].zw; }
vec2 PatternTransformA() { return Vector[2].xy; }
vec2 PatternTransformB() { return Vector[2].zw; }
vec2 PatternTransformC() { return Vector[3].xy; }
uint Gradient_NumStops() { return uint(ex_Data0.y + 0.5); }
bool Gradient_IsRadial() { return bool(uint(ex_Data0.z + 0.5)); }
float Gradient_R0() { return ex_Data1.x; }
float Gradient_R1() { return ex_Data1.y; }
vec2 Gradient_P0() { return ex_Data1.xy; }
vec2 Gradient_P1() { return ex_Data1.zw; }
float SDFMaxDistance() { return ex_Data0.y; }
struct GradientStop { float percent; vec4 color; };
GradientStop GetGradientStop(uint offset) {
GradientStop result;
if (offset < 4u) {
result.percent = ex_Data2[offset];
if (offset == 0u)
result.color = ex_Data3;
else if (offset == 1u)
result.color = ex_Data4;
else if (offset == 2u)
result.color = ex_Data5;
else if (offset == 3u)
result.color = ex_Data6;
} else {
result.percent = Scalar(offset - 4u);
result.color = Vector[offset - 4u];
}
return result;
}
#define AA_WIDTH 0.354
float antialias(in float d, in float width, in float median) {
return smoothstep(median - width, median + width, d);
}
float sdRect(vec2 p, vec2 size) {
vec2 d = abs(p) - size;
return min(max(d.x,d.y),0.0) + length(max(d,0.0));
}
// The below function "sdEllipse" is MIT licensed with following text:
//
// The MIT License
// Copyright 2013 Inigo Quilez
// Permission is hereby granted, free of charge, to any person obtaining a
// copy of this software and associated documentation files (the "Software"),
// to deal in the Software without restriction, including without limitation
// the rights to use, copy, modify, merge, publish, distribute, sublicense,
// and/or sell copies of the Software, and to permit persons to whom the Software
// is furnished to do so, subject to the following conditions: The above copyright
// notice and this permission notice shall be included in all copies or substantial
// portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF
// ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO
// EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR
// OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
// FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
float sdEllipse( vec2 p, in vec2 ab ) {
if (abs(ab.x - ab.y) < 0.1)
return length(p) - ab.x;
p = abs(p); if (p.x > p.y) { p=p.yx; ab=ab.yx; }
float l = ab.y*ab.y - ab.x*ab.x;
float m = ab.x*p.x/l;
float n = ab.y*p.y/l;
float m2 = m*m;
float n2 = n*n;
float c = (m2 + n2 - 1.0)/3.0;
float c3 = c*c*c;
float q = c3 + m2*n2*2.0;
float d = c3 + m2*n2;
float g = m + m*n2;
float co;
if (d < 0.0)
{
float p = acos(q/c3)/3.0;
float s = cos(p);
float t = sin(p)*sqrt(3.0);
float rx = sqrt( -c*(s + t + 2.0) + m2 );
float ry = sqrt( -c*(s - t + 2.0) + m2 );
co = ( ry + sign(l)*rx + abs(g)/(rx*ry) - m)/2.0;
} else {
float h = 2.0*m*n*sqrt( d );
float s = sign(q+h)*pow( abs(q+h), 1.0/3.0 );
float u = sign(q-h)*pow( abs(q-h), 1.0/3.0 );
float rx = -s - u - c*4.0 + 2.0*m2;
float ry = (s - u)*sqrt(3.0);
float rm = sqrt( rx*rx + ry*ry );
float p = ry/sqrt(rm-rx);
co = (p + 2.0*g/rm - m)/2.0;
}
float si = sqrt(1.0 - co*co);
vec2 r = vec2(ab.x*co, ab.y*si);
return length(r - p) * sign(p.y-r.y);
}
float sdRoundRect(vec2 p, vec2 size, vec4 rx, vec4 ry) {
size *= 0.5;
vec2 corner;
corner = vec2(-size.x+rx.x, -size.y+ry.x); // Top-Left
vec2 local = p - corner;
if (dot(rx.x, ry.x) > 0.0 && p.x < corner.x && p.y <= corner.y)
return sdEllipse(local, vec2(rx.x, ry.x));
corner = vec2(size.x-rx.y, -size.y+ry.y); // Top-Right
local = p - corner;
if (dot(rx.y, ry.y) > 0.0 && p.x >= corner.x && p.y <= corner.y)
return sdEllipse(local, vec2(rx.y, ry.y));
corner = vec2(size.x-rx.z, size.y-ry.z); // Bottom-Right
local = p - corner;
if (dot(rx.z, ry.z) > 0.0 && p.x >= corner.x && p.y >= corner.y)
return sdEllipse(local, vec2(rx.z, ry.z));
corner = vec2(-size.x+rx.w, size.y-ry.w); // Bottom-Left
local = p - corner;
if (dot(rx.w, ry.w) > 0.0 && p.x < corner.x && p.y > corner.y)
return sdEllipse(local, vec2(rx.w, ry.w));
return sdRect(p, size);
}
void fillSolid() {
out_Color = ex_Color;
}
void fillImage(vec2 uv) {
out_Color = texture(Texture1, uv) * ex_Color;
}
vec2 transformAffine(vec2 val, vec2 a, vec2 b, vec2 c) {
return val.x * a + val.y * b + c;
}
void fillPatternImage() {
vec4 tile_rect_uv = TileRectUV();
vec2 tile_size = TileSize();
vec2 p = ex_ObjectCoord;
// Apply the affine matrix
vec2 transformed_coords = transformAffine(p,
PatternTransformA(), PatternTransformB(), PatternTransformC());
// Convert back to uv coordinate space
transformed_coords /= tile_size;
// Wrap UVs to [0.0, 1.0] so texture repeats properly
vec2 uv = fract(transformed_coords);
// Clip to tile-rect UV
uv *= tile_rect_uv.zw - tile_rect_uv.xy;
uv += tile_rect_uv.xy;
fillImage(uv);
}
// Gradient noise from Jorge Jimenez's presentation:
// http://www.iryoku.com/next-generation-post-processing-in-call-of-duty-advanced-warfare
float gradientNoise(in vec2 uv)
{
const vec3 magic = vec3(0.06711056, 0.00583715, 52.9829189);
return fract(magic.z * fract(dot(uv, magic.xy)));
}
float ramp(in float inMin, in float inMax, in float val)
{
return clamp((val - inMin) / (inMax - inMin), 0.0, 1.0);
}
void fillPatternGradient() {
int num_stops = int(Gradient_NumStops());
bool is_radial = Gradient_IsRadial();
vec2 p0 = Gradient_P0();
vec2 p1 = Gradient_P1();
float t = 0.0;
if (is_radial) {
float r0 = p1.x;
float r1 = p1.y;
t = distance(ex_TexCoord, p0);
float rDelta = r1 - r0;
t = clamp((t / rDelta) - (r0 / rDelta), 0.0, 1.0);
} else {
vec2 V = p1 - p0;
t = clamp(dot(ex_TexCoord - p0, V) / dot(V, V), 0.0, 1.0);
}
GradientStop stop0 = GetGradientStop(0u);
GradientStop stop1 = GetGradientStop(1u);
out_Color = mix(stop0.color, stop1.color, ramp(stop0.percent, stop1.percent, t));
if (num_stops > 2) {
GradientStop stop2 = GetGradientStop(2u);
out_Color = mix(out_Color, stop2.color, ramp(stop1.percent, stop2.percent, t));
if (num_stops > 3) {
GradientStop stop3 = GetGradientStop(3u);
out_Color = mix(out_Color, stop3.color, ramp(stop2.percent, stop3.percent, t));
if (num_stops > 4) {
GradientStop stop4 = GetGradientStop(4u);
out_Color = mix(out_Color, stop4.color, ramp(stop3.percent, stop4.percent, t));
if (num_stops > 5) {
GradientStop stop5 = GetGradientStop(5u);
out_Color = mix(out_Color, stop5.color, ramp(stop4.percent, stop5.percent, t));
if (num_stops > 6) {
GradientStop stop6 = GetGradientStop(6u);
out_Color = mix(out_Color, stop6.color, ramp(stop5.percent, stop6.percent, t));
}
}
}
}
}
// Add gradient noise to reduce banding (+4/-4 gradations)
//out_Color += (8.0/255.0) * gradientNoise(gl_FragCoord.xy) - (4.0/255.0);
}
void Unpack(vec4 x, out vec4 a, out vec4 b) {
const float s = 65536.0;
a = floor(x / s);
b = floor(x - a * s);
}
const float epsilon = AA_WIDTH;
float antialias2 (float d) {
return smoothstep (-epsilon, +epsilon, d);
}
// Returns two values:
// [0] = distance of p to line segment.
// [1] = closest t on line segment, clamped to [0, 1]
vec2 sdSegment(in vec2 p, in vec2 a, in vec2 b)
{
vec2 pa = p - a, ba = b - a;
float t = dot(pa, ba) / dot(ba, ba);
return vec2(length(pa - ba * t), t);
}
float testCross(vec2 a, vec2 b, vec2 p) {
return (b.y - a.y) * (p.x - a.x) - (b.x - a.x) * (p.y - a.y);
}
float sdLine(in vec2 a, in vec2 b, in vec2 p)
{
vec2 pa = p - a, ba = b - a;
float t = dot(pa, ba) / dot(ba, ba);
return length(pa - ba*t) * sign(testCross(a, b, p));
}
vec4 blend(vec4 src, vec4 dest) {
vec4 result;
result.rgb = src.rgb + dest.rgb * (1.0 - src.a);
result.a = src.a + dest.a * (1.0 - src.a);
return result;
}
)";
static const std::string shader_fill_frag2 = R"(
float innerStroke(float stroke_width, float d) {
return min(antialias(-d, AA_WIDTH, 0.0), 1.0 - antialias(-d, AA_WIDTH, stroke_width));
}
void fillRoundedRect() {
vec2 p = ex_TexCoord;
vec2 size = ex_Data0.zw;
p = (p - 0.5) * size;
float d = sdRoundRect(p, size, ex_Data1, ex_Data2);
// Fill background
float alpha = antialias(-d, AA_WIDTH, 0.0);
out_Color = ex_Color * alpha;
// Draw stroke
float stroke_width = ex_Data3.x;
vec4 stroke_color = ex_Data4;
if (stroke_width > 0.0) {
alpha = innerStroke(stroke_width, d);
vec4 stroke = stroke_color * alpha;
out_Color = blend(stroke, out_Color);
}
}
void fillBoxShadow() {
vec2 p = ex_ObjectCoord;
bool inset = bool(uint(ex_Data0.y + 0.5));
float radius = ex_Data0.z;
vec2 origin = ex_Data1.xy;
vec2 size = ex_Data1.zw;
vec2 clip_origin = ex_Data4.xy;
vec2 clip_size = ex_Data4.zw;
float sdClip = sdRoundRect(p - clip_origin, clip_size, ex_Data5, ex_Data6);
float sdRect = sdRoundRect(p - origin, size, ex_Data2, ex_Data3);
float clip = inset ? -sdRect : sdClip;
float d = inset ? -sdClip : sdRect;
if (clip < 0.0) {
discard;
out_Color = vec4(0.0, 0.0, 0.0, 0.0);
return;
}
float alpha = radius >= 1.0? pow(antialias(-d, radius * 2 + 0.2, 0.0), 1.9) * 3.3 / pow(radius * 1.2, 0.15) :
antialias(-d, AA_WIDTH, inset ? -1.0 : 1.0);
alpha = clamp(alpha, 0.0, 1.0) * ex_Color.a;
out_Color = vec4(ex_Color.rgb * alpha, alpha);
return;
}
vec3 blendOverlay(vec3 src, vec3 dest) {
vec3 col;
for (int i = 0; i < 3; ++i)
col[i] = dest[i] < 0.5 ? (2.0 * dest[i] * src[i]) : (1.0 - 2.0 * (1.0 - dest[i]) * (1.0 - src[i]));
return col;
}
vec3 blendColorDodge(vec3 src, vec3 dest) {
vec3 col;
for (int i = 0; i < 3; ++i)
col[i] = (src[i] == 1.0) ? src[i] : min(dest[i] / (1.0 - src[i]), 1.0);
return col;
}
vec3 blendColorBurn(vec3 src, vec3 dest) {
vec3 col;
for (int i = 0; i < 3; ++i)
col[i] = (src[i] == 0.0) ? src[i] : max((1.0 - ((1.0 - dest[i]) / src[i])), 0.0);
return col;
}
vec3 blendHardLight(vec3 src, vec3 dest) {
vec3 col;
for (int i = 0; i < 3; ++i)
col[i] = dest[i] < 0.5 ? (2.0 * dest[i] * src[i]) : (1.0 - 2.0 * (1.0 - dest[i]) * (1.0 - src[i]));
return col;
}
vec3 blendSoftLight(vec3 src, vec3 dest) {
vec3 col;
for (int i = 0; i < 3; ++i)
col[i] = (src[i] < 0.5) ? (2.0 * dest[i] * src[i] + dest[i] * dest[i] * (1.0 - 2.0 * src[i])) : (sqrt(dest[i]) * (2.0 * src[i] - 1.0) + 2.0 * dest[i] * (1.0 - src[i]));
return col;
}
vec3 rgb2hsl( vec3 col )
{
const float eps = 0.0000001;
float minc = min( col.r, min(col.g, col.b) );
float maxc = max( col.r, max(col.g, col.b) );
vec3 mask = step(col.grr,col.rgb) * step(col.bbg,col.rgb);
vec3 h = mask * (vec3(0.0,2.0,4.0) + (col.gbr-col.brg)/(maxc-minc + eps)) / 6.0;
return vec3(fract(1.0 + h.x + h.y + h.z ), // H
(maxc-minc)/(1.0-abs(minc+maxc-1.0) + eps), // S
(minc+maxc)*0.5 ); // L
}
vec3 hsl2rgb( vec3 c )
{
vec3 rgb = clamp( abs(mod(c.x*6.0+vec3(0.0,4.0,2.0),6.0)-3.0)-1.0, 0.0, 1.0 );
return c.z + c.y * (rgb-0.5)*(1.0-abs(2.0*c.z-1.0));
}
vec3 blendHue(vec3 src, vec3 dest) {
vec3 baseHSL = rgb2hsl(dest);
return hsl2rgb(vec3(rgb2hsl(src).r, baseHSL.g, baseHSL.b));
}
vec3 blendSaturation(vec3 src, vec3 dest) {
vec3 baseHSL = rgb2hsl(dest);
return hsl2rgb(vec3(baseHSL.r, rgb2hsl(src).g, baseHSL.b));
}
vec3 blendColor(vec3 src, vec3 dest) {
vec3 blendHSL = rgb2hsl(src);
return hsl2rgb(vec3(blendHSL.r, blendHSL.g, rgb2hsl(dest).b));
}
vec3 blendLuminosity(vec3 src, vec3 dest) {
vec3 baseHSL = rgb2hsl(dest);
return hsl2rgb(vec3(baseHSL.r, baseHSL.g, rgb2hsl(src).b));
}
vec4 saturate(vec4 val) {
return clamp(val, 0.0, 1.0);
}
vec4 calcBlend() {
const uint BlendOp_Clear = 0u;
const uint BlendOp_Source = 1u;
const uint BlendOp_Over = 2u;
const uint BlendOp_In = 3u;
const uint BlendOp_Out = 4u;
const uint BlendOp_Atop = 5u;
const uint BlendOp_DestOver = 6u;
const uint BlendOp_DestIn = 7u;
const uint BlendOp_DestOut = 8u;
const uint BlendOp_DestAtop = 9u;
const uint BlendOp_XOR = 10u;
const uint BlendOp_Darken = 11u;
const uint BlendOp_Add = 12u;
const uint BlendOp_Difference = 13u;
const uint BlendOp_Multiply = 14u;
const uint BlendOp_Screen = 15u;
const uint BlendOp_Overlay = 16u;
const uint BlendOp_Lighten = 17u;
const uint BlendOp_ColorDodge = 18u;
const uint BlendOp_ColorBurn = 19u;
const uint BlendOp_HardLight = 20u;
const uint BlendOp_SoftLight = 21u;
const uint BlendOp_Exclusion = 22u;
const uint BlendOp_Hue = 23u;
const uint BlendOp_Saturation = 24u;
const uint BlendOp_Color = 25u;
const uint BlendOp_Luminosity = 26u;
fillImage(ex_TexCoord);
vec4 src = out_Color;
vec4 dest = texture(Texture2, ex_ObjectCoord);
switch(uint(ex_Data0.y + 0.5))
{
case BlendOp_Clear: return vec4(0.0, 0.0, 0.0, 0.0);
case BlendOp_Source: return src;
case BlendOp_Over: return src + dest * (1.0 - src.a);
case BlendOp_In: return src * dest.a;
case BlendOp_Out: return src * (1.0 - dest.a);
case BlendOp_Atop: return src * dest.a + dest * (1.0 - src.a);
case BlendOp_DestOver: return src * (1.0 - dest.a) + dest;
case BlendOp_DestIn: return dest * src.a;
case BlendOp_DestOut: return dest * (1.0 - src.a);
case BlendOp_DestAtop: return src * (1.0 - dest.a) + dest * src.a;
case BlendOp_XOR: return saturate(src * (1.0 - dest.a) + dest * (1.0 - src.a));
case BlendOp_Darken: return vec4(min(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Add: return saturate(src + dest);
case BlendOp_Difference: return vec4(abs(dest.rgb - src.rgb) * src.a, dest.a * src.a);
case BlendOp_Multiply: return vec4(src.rgb * dest.rgb * src.a, dest.a * src.a);
case BlendOp_Screen: return vec4((1.0 - ((1.0 - dest.rgb) * (1.0 - src.rgb))) * src.a, dest.a * src.a);
case BlendOp_Overlay: return vec4(blendOverlay(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Lighten: return vec4(max(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_ColorDodge: return vec4(blendColorDodge(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_ColorBurn: return vec4(blendColorBurn(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_HardLight: return vec4(blendOverlay(dest.rgb, src.rgb) * src.a, dest.a * src.a);
case BlendOp_SoftLight: return vec4(blendSoftLight(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Exclusion: return vec4((dest.rgb + src.rgb - 2.0 * dest.rgb * src.rgb) * src.a, dest.a * src.a);
case BlendOp_Hue: return vec4(blendHue(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Saturation: return vec4(blendSaturation(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Color: return vec4(blendColor(src.rgb, dest.rgb) * src.a, dest.a * src.a);
case BlendOp_Luminosity: return vec4(blendLuminosity(src.rgb, dest.rgb) * src.a, dest.a * src.a);
}
return src;
}
void fillBlend() {
out_Color = calcBlend();
}
void fillMask() {
fillImage(ex_TexCoord);
float alpha = texture(Texture2, ex_ObjectCoord).a;
out_Color *= alpha;
}
void fillGlyph(vec2 uv) {
float alpha = texture(Texture1, uv).r * ex_Color.a;
alpha = clamp(alpha, 0.0, 1.0);
float fill_color_luma = ex_Data0.y;
float corrected_alpha = texture(Texture2, vec2(alpha, fill_color_luma)).r;
//float corrected_alpha = alpha;
out_Color = vec4(ex_Color.rgb * corrected_alpha, corrected_alpha);
}
void applyClip() {
for (uint i = 0u; i < ClipSize; i++) {
mat4 data = Clip[i];
vec2 origin = data[0].xy;
vec2 size = data[0].zw;
vec4 radii_x, radii_y;
Unpack(data[1], radii_x, radii_y);
bool inverse = bool(data[3].z);
vec2 p = ex_ObjectCoord;
p = transformAffine(p, data[2].xy, data[2].zw, data[3].xy);
p -= origin;
float d_clip = sdRoundRect(p, size, radii_x, radii_y) * (inverse? -1.0 : 1.0);
float alpha = antialias2(-d_clip);
out_Color = vec4(out_Color.rgb * alpha, out_Color.a * alpha);
//if (abs(d_clip) < 2.0)
// out_Color = vec4(0.9, 1.0, 0.0, 1.0);
}
}
void main(void) {
const uint FillType_Solid = 0u;
const uint FillType_Image = 1u;
const uint FillType_Pattern_Image = 2u;
const uint FillType_Pattern_Gradient = 3u;
const uint FillType_RESERVED_1 = 4u;
const uint FillType_RESERVED_2 = 5u;
const uint FillType_RESERVED_3 = 6u;
const uint FillType_Rounded_Rect = 7u;
const uint FillType_Box_Shadow = 8u;
const uint FillType_Blend = 9u;
const uint FillType_Mask = 10u;
const uint FillType_Glyph = 11u;
switch (FillType())
{
case FillType_Solid: fillSolid(); break;
case FillType_Image: fillImage(ex_TexCoord); break;
case FillType_Pattern_Image: fillPatternImage(); break;
case FillType_Pattern_Gradient: fillPatternGradient(); break;
case FillType_Rounded_Rect: fillRoundedRect(); break;
case FillType_Box_Shadow: fillBoxShadow(); break;
case FillType_Blend: fillBlend(); break;
case FillType_Mask: fillMask(); break;
case FillType_Glyph: fillGlyph(ex_TexCoord); break;
}
applyClip();
}
)";
static std::string shader_fill_frag() { return shader_fill_frag1 + shader_fill_frag2; }