#version 420
#extension GL_ARB_texture_gather : enable
#extension GL_ARB_separate_shader_objects : enable

// shader f14bb57cd5c9cb77 - dumped 1.15
// Used for: Removing/Restoring the native BotW World Anti-Aliasing implementation

const float resX = $width/1280;
const float resY = $height/720;

uniform ivec4 uf_remappedPS[4];
layout(binding = 0) uniform sampler2D textureUnitPS0;// Tex0 addr 0xf462d000 res 1280x720x1 dim 1 tm: 4 format 0019 compSel: 0 1 2 3 mipView: 0x0 (num 0x1) sliceView: 0x0 (num 0x1) Sampler0 ClampX/Y/Z: 2 2 2 border: 1
layout(binding = 1) uniform sampler2D textureUnitPS1;// Tex1 addr 0x37f40000 res 1280x720x1 dim 1 tm: 4 format 0001 compSel: 0 4 4 5 mipView: 0x0 (num 0x1) sliceView: 0x0 (num 0x1) Sampler1 ClampX/Y/Z: 2 2 2 border: 1
layout(location = 0) in vec4 passParameterSem2;
layout(location = 0) out vec4 passPixelColor0;
uniform vec2 uf_fragCoordScale;

int clampFI32(int v)
{
if( v == 0x7FFFFFFF )
	return floatBitsToInt(1.0);
else if( v == 0xFFFFFFFF )
	return floatBitsToInt(0.0);
return floatBitsToInt(clamp(intBitsToFloat(v), 0.0, 1.0));
}
float mul_nonIEEE(float a, float b){return mix(0.0, a*b, (a != 0.0) && (b != 0.0));}
void main()
{
vec4 R0f = vec4(0.0);
vec4 R1f = vec4(0.0); // Important variable
vec4 R2f = vec4(0.0);
vec4 R3f = vec4(0.0); // Important variable
vec4 R123f = vec4(0.0);
vec4 R126f = vec4(0.0);
vec4 R127f = vec4(0.0);
float backupReg0f, backupReg1f, backupReg2f, backupReg3f, backupReg4f;
vec4 PV0f = vec4(0.0), PV1f = vec4(0.0);
float PS0f = 0.0, PS1f = 0.0;
vec4 tempf = vec4(0.0);
float tempResultf;
int tempResulti;
ivec4 ARi = ivec4(0);
bool predResult = true;
bool activeMaskStack[2];
bool activeMaskStackC[3];
activeMaskStack[0] = false;
activeMaskStackC[0] = false;
activeMaskStackC[1] = false;
activeMaskStack[0] = true;
activeMaskStackC[0] = true;
activeMaskStackC[1] = true;
vec3 cubeMapSTM;
int cubeMapFaceId;
R0f = passParameterSem2;
if( activeMaskStackC[1] == true ) {
R1f.xyzw = (textureGather(textureUnitPS1, R0f.xy).wzxy);
R2f.xyzw = (texture(textureUnitPS0, R0f.xy).xyzw);
}
if( activeMaskStackC[1] == true ) {
activeMaskStack[1] = activeMaskStack[0];
activeMaskStackC[2] = activeMaskStackC[1];
// 0
PV0f.x = R1f.w + -(R1f.x); 
PV0f.y = R1f.z + -(R1f.y);
PV0f.z = mul_nonIEEE(R2f.x, intBitsToFloat(uf_remappedPS[0].x));
R127f.w = min(R1f.z, R1f.x);
R127f.x = min(R1f.w, R1f.y);
PS0f = R127f.x;
// 1
R123f.x = (mul_nonIEEE(R2f.y,intBitsToFloat(uf_remappedPS[0].y) * resX ) + PV0f.z); //Important line
PV1f.x = R123f.x;
PV1f.y = max(R1f.z, R1f.x);
R127f.z = PV0f.y + -(PV0f.x);
PV1f.z = R127f.z;
R126f.w = PV0f.y + PV0f.x;
PV1f.w = R126f.w;
PS1f = max(R1f.w, R1f.y);
// 2
PV0f.x = max(PV1f.z, -(PV1f.z));
PV0f.y = max(PV1f.w, -(PV1f.w));
R123f.z = (mul_nonIEEE(R2f.z,intBitsToFloat(uf_remappedPS[0].z)) + PV1f.x);
PV0f.z = R123f.z;
PV0f.w = min(R127f.w, R127f.x);
PS0f = max(PV1f.y, PS1f);
// 3
PV1f.x = mul_nonIEEE(PS0f, intBitsToFloat(uf_remappedPS[1].x));
PV1f.y = max(PV0f.z, PS0f);
PV1f.z = min(PV0f.z, PV0f.w);
PV1f.w = min(PV0f.y, PV0f.x);
// 4
R1f.x = -(PV1f.z) + PV1f.y;
R0f.z = max(PV1f.x, intBitsToFloat(uf_remappedPS[1].y)); // Important - Divide looks blurrier/fuzzy and multiply looks sharper good
PS0f = 1.0 / PV1f.w; 									// Important line affects aliasing strongly, increasing it  is blurier and decreasing sharpens
// 5
PV1f.x = mul_nonIEEE(R127f.z, PS0f);
PV1f.y = mul_nonIEEE(R126f.w, PS0f);
// 6
PV0f.z = max(PV1f.x, -(intBitsToFloat(uf_remappedPS[2].y)));
PV0f.w = max(PV1f.y, -(intBitsToFloat(uf_remappedPS[2].y)));
// 7 - another way to do it other than the original implmentation
R3f.x = min(PV0f.w, intBitsToFloat(uf_remappedPS[2].y)); // Important - Divide looks sharper and better and multiply looks blurier fuzzy
R1f.y = min(PV0f.z, intBitsToFloat(uf_remappedPS[2].y)); // Important - Divide looks sharper and better and multiply looks blurier fuzzy
// 8
predResult = (R1f.x > R0f.z);
activeMaskStack[1] = predResult;
activeMaskStackC[2] = predResult == true && activeMaskStackC[1] == true;
}
else {
activeMaskStack[1] = false;
activeMaskStackC[2] = false;
}
if( activeMaskStackC[2] == true ) {
// 0
backupReg0f = R3f.x;
backupReg0f = R3f.x;
R3f.x = (mul_nonIEEE(backupReg0f,intBitsToFloat(uf_remappedPS[3].x) / resX) + R0f.x); // Original Implementation
R3f.y = (mul_nonIEEE(R1f.y,intBitsToFloat(uf_remappedPS[3].y) / resY) + R0f.y); // Original Implementation
R1f.x = (mul_nonIEEE(backupReg0f,-(intBitsToFloat(uf_remappedPS[3].x) / resX)) + R0f.x); // Original Implementation
PS0f = R1f.x;
// 1
backupReg0f = R1f.y;
R1f.y = (mul_nonIEEE(backupReg0f,-(intBitsToFloat(uf_remappedPS[3].y) / resY)) + R0f.y); // Original Implementation
}
if( activeMaskStackC[2] == true ) {
R0f.xyzw = (texture(textureUnitPS0, R3f.xy).xyzw);
R1f.xyzw = (texture(textureUnitPS0, R1f.xy).xyzw);
}
if( activeMaskStackC[2] == true ) {
// 0
R127f.x = R0f.w + R1f.w;
R127f.x /= 2.0;
PV0f.x = R127f.x;
R127f.y = R0f.z + R1f.z;
R127f.y /= 2.0;
PV0f.y = R127f.y;
R127f.z = R0f.y + R1f.y;
R127f.z /= 2.0;
PV0f.z = R127f.z;
R127f.w = R0f.x + R1f.x;
R127f.w /= 2.0;
PV0f.w = R127f.w;
// 1
PV1f.x = R2f.w + -(PV0f.x);
PV1f.y = R2f.z + -(PV0f.y);
PV1f.z = R2f.y + -(PV0f.z);
PV1f.w = R2f.x + -(PV0f.w);
// 2
R2f.x = (PV1f.w * intBitsToFloat(0x3eb33333) + R127f.w);
R2f.y = (PV1f.z * intBitsToFloat(0x3eb33333) + R127f.z);
R2f.z = (PV1f.y * intBitsToFloat(0x3eb33333) + R127f.y);
R2f.w = (PV1f.x * intBitsToFloat(0x3eb33333) + R127f.x);
}
activeMaskStackC[1] = activeMaskStack[0] == true && activeMaskStackC[0] == true;
// export
passPixelColor0 = vec4(R2f.x, R2f.y, R2f.z, R2f.w);
}