Rasagar/Library/PackageCache/com.unity.render-pipelines.core/ShaderLibrary/Packing.hlsl
2024-08-26 23:07:20 +03:00

629 lines
19 KiB
HLSL

#ifndef UNITY_PACKING_INCLUDED
#define UNITY_PACKING_INCLUDED
#if SHADER_API_MOBILE || SHADER_API_GLES3 || SHADER_API_SWITCH || defined(UNITY_UNIFIED_SHADER_PRECISION_MODEL)
#pragma warning (disable : 3205) // conversion of larger type to smaller
#endif
//-----------------------------------------------------------------------------
// Normal packing
//-----------------------------------------------------------------------------
real3 PackNormalMaxComponent(real3 n)
{
return (n / Max3(abs(n.x), abs(n.y), abs(n.z))) * 0.5 + 0.5;
}
real3 UnpackNormalMaxComponent(real3 n)
{
return normalize(n * 2.0 - 1.0);
}
// Ref: http://www.vis.uni-stuttgart.de/~engelhts/paper/vmvOctaMaps.pdf "Octahedron Environment Maps"
// Encode with Oct, this function work with any size of output
// return real between [-1, 1]
real2 PackNormalOctRectEncode(real3 n)
{
// Perform planar projection.
real3 p = n * rcp(dot(abs(n), 1.0));
real x = p.x, y = p.y, z = p.z;
// Unfold the octahedron.
// Also correct the aspect ratio from 2:1 to 1:1.
real r = saturate(0.5 - 0.5 * x + 0.5 * y);
real g = x + y;
// Negative hemisphere on the left, positive on the right.
return real2(CopySign(r, z), g);
}
real3 UnpackNormalOctRectEncode(real2 f)
{
real r = f.r, g = f.g;
// Solve for {x, y, z} given {r, g}.
real x = 0.5 + 0.5 * g - abs(r);
real y = g - x;
real z = max(1.0 - abs(x) - abs(y), REAL_EPS); // EPS is absolutely crucial for anisotropy
real3 p = real3(x, y, CopySign(z, r));
return normalize(p);
}
// Ref: http://jcgt.org/published/0003/02/01/paper.pdf "A Survey of Efficient Representations for Independent Unit Vectors"
// Encode with Oct, this function work with any size of output
// return float between [-1, 1]
float2 PackNormalOctQuadEncode(float3 n)
{
//float l1norm = dot(abs(n), 1.0);
//float2 res0 = n.xy * (1.0 / l1norm);
//float2 val = 1.0 - abs(res0.yx);
//return (n.zz < float2(0.0, 0.0) ? (res0 >= 0.0 ? val : -val) : res0);
// Optimized version of above code:
n *= rcp(max(dot(abs(n), 1.0), 1e-6));
float t = saturate(-n.z);
return n.xy + float2(n.x >= 0.0 ? t : -t, n.y >= 0.0 ? t : -t);
}
float3 UnpackNormalOctQuadEncode(float2 f)
{
// NOTE: Do NOT use abs() in this line. It causes miscompilations. (UUM-62216, UUM-70600)
float3 n = float3(f.x, f.y, 1.0 - (f.x < 0 ? -f.x : f.x) - (f.y < 0 ? -f.y : f.y));
//float2 val = 1.0 - abs(n.yx);
//n.xy = (n.zz < float2(0.0, 0.0) ? (n.xy >= 0.0 ? val : -val) : n.xy);
// Optimized version of above code:
float t = max(-n.z, 0.0);
n.xy += float2(n.x >= 0.0 ? -t : t, n.y >= 0.0 ? -t : t);
return normalize(n);
}
real2 PackNormalHemiOctEncode(real3 n)
{
real l1norm = dot(abs(n), 1.0);
real2 res = n.xy * (1.0 / l1norm);
return real2(res.x + res.y, res.x - res.y);
}
real3 UnpackNormalHemiOctEncode(real2 f)
{
real2 val = real2(f.x + f.y, f.x - f.y) * 0.5;
real3 n = real3(val, 1.0 - dot(abs(val), 1.0));
return normalize(n);
}
// Tetrahedral encoding - Looks like Tetra encoding 10:10 + 2 is similar to oct 11:11, as oct is cheaper prefer it
// To generate the basisNormal below we use these 4 vertex of a regular tetrahedron
// v0 = float3(1.0, 0.0, -1.0 / sqrt(2.0));
// v1 = float3(-1.0, 0.0, -1.0 / sqrt(2.0));
// v2 = float3(0.0, 1.0, 1.0 / sqrt(2.0));
// v3 = float3(0.0, -1.0, 1.0 / sqrt(2.0));
// Then we normalize the average of each face's vertices
// normalize(v0 + v1 + v2), etc...
static const real3 tetraBasisNormal[4] =
{
real3(0., 0.816497, -0.57735),
real3(-0.816497, 0., 0.57735),
real3(0.816497, 0., 0.57735),
real3(0., -0.816497, -0.57735)
};
// Then to get the local matrix (with z axis rotate to basisNormal) use GetLocalFrame(basisNormal[xxx])
static const real3x3 tetraBasisArray[4] =
{
real3x3(-1., 0., 0.,0., 0.57735, 0.816497,0., 0.816497, -0.57735),
real3x3(0., -1., 0.,0.57735, 0., 0.816497,-0.816497, 0., 0.57735),
real3x3(0., 1., 0.,-0.57735, 0., 0.816497,0.816497, 0., 0.57735),
real3x3(1., 0., 0.,0., -0.57735, 0.816497,0., -0.816497, -0.57735)
};
// Return [-1..1] vector2 oriented in plane of the faceIndex of a regular tetrahedron
real2 PackNormalTetraEncode(float3 n, out uint faceIndex)
{
// Retrieve the tetrahedra's face for the normal direction
// It is the one with the greatest dot value with face normal
real dot0 = dot(n, tetraBasisNormal[0]);
real dot1 = dot(n, tetraBasisNormal[1]);
real dot2 = dot(n, tetraBasisNormal[2]);
real dot3 = dot(n, tetraBasisNormal[3]);
real maxi0 = max(dot0, dot1);
real maxi1 = max(dot2, dot3);
real maxi = max(maxi0, maxi1);
// Get the index from the greatest dot
if (maxi == dot0)
faceIndex = 0;
else if (maxi == dot1)
faceIndex = 1;
else if (maxi == dot2)
faceIndex = 2;
else //(maxi == dot3)
faceIndex = 3;
// Rotate n into this local basis
n = mul(tetraBasisArray[faceIndex], n);
// Project n onto the local plane
return n.xy;
}
// Assume f [-1..1]
real3 UnpackNormalTetraEncode(real2 f, uint faceIndex)
{
// Recover n from local plane
real3 n = real3(f.xy, sqrt(1.0 - dot(f.xy, f.xy)));
// Inverse of transform PackNormalTetraEncode (just swap order in mul as we have a rotation)
return mul(n, tetraBasisArray[faceIndex]);
}
// Unpack from normal map
real3 UnpackNormalRGB(real4 packedNormal, real scale = 1.0)
{
real3 normal;
normal.xyz = packedNormal.rgb * 2.0 - 1.0;
normal.xy *= scale;
return normal;
}
real3 UnpackNormalRGBNoScale(real4 packedNormal)
{
return packedNormal.rgb * 2.0 - 1.0;
}
real3 UnpackNormalAG(real4 packedNormal, real scale = 1.0)
{
real3 normal;
normal.xy = packedNormal.ag * 2.0 - 1.0;
normal.z = max(1.0e-16, sqrt(1.0 - saturate(dot(normal.xy, normal.xy))));
// must scale after reconstruction of normal.z which also
// mirrors UnpackNormalRGB(). This does imply normal is not returned
// as a unit length vector but doesn't need it since it will get normalized after TBN transformation.
// If we ever need to blend contributions with built-in shaders for URP
// then we should consider using UnpackDerivativeNormalAG() instead like
// HDRP does since derivatives do not use renormalization and unlike tangent space
// normals allow you to blend, accumulate and scale contributions correctly.
normal.xy *= scale;
return normal;
}
// Unpack normal as DXT5nm (1, y, 0, x) or BC5 (x, y, 0, 1)
real3 UnpackNormalmapRGorAG(real4 packedNormal, real scale = 1.0)
{
// Convert to (?, y, 0, x)
packedNormal.a *= packedNormal.r;
return UnpackNormalAG(packedNormal, scale);
}
#ifndef BUILTIN_TARGET_API
real3 UnpackNormal(real4 packedNormal)
{
#if defined(UNITY_ASTC_NORMALMAP_ENCODING)
return UnpackNormalAG(packedNormal, 1.0);
#elif defined(UNITY_NO_DXT5nm)
return UnpackNormalRGBNoScale(packedNormal);
#else
// Compiler will optimize the scale away
return UnpackNormalmapRGorAG(packedNormal, 1.0);
#endif
}
#endif
real3 UnpackNormalScale(real4 packedNormal, real bumpScale)
{
#if defined(UNITY_ASTC_NORMALMAP_ENCODING)
return UnpackNormalAG(packedNormal, bumpScale);
#elif defined(UNITY_NO_DXT5nm)
return UnpackNormalRGB(packedNormal, bumpScale);
#else
return UnpackNormalmapRGorAG(packedNormal, bumpScale);
#endif
}
//-----------------------------------------------------------------------------
// HDR packing
//-----------------------------------------------------------------------------
// Ref: http://realtimecollisiondetection.net/blog/?p=15
real4 PackToLogLuv(real3 vRGB)
{
// M matrix, for encoding
const real3x3 M = real3x3(
0.2209, 0.3390, 0.4184,
0.1138, 0.6780, 0.7319,
0.0102, 0.1130, 0.2969);
real4 vResult;
real3 Xp_Y_XYZp = mul(vRGB, M);
Xp_Y_XYZp = max(Xp_Y_XYZp, real3(1e-6, 1e-6, 1e-6));
vResult.xy = Xp_Y_XYZp.xy / Xp_Y_XYZp.z;
real Le = 2.0 * log2(Xp_Y_XYZp.y) + 127.0;
vResult.w = frac(Le);
vResult.z = (Le - (floor(vResult.w * 255.0)) / 255.0) / 255.0;
return vResult;
}
real3 UnpackFromLogLuv(real4 vLogLuv)
{
// Inverse M matrix, for decoding
const real3x3 InverseM = real3x3(
6.0014, -2.7008, -1.7996,
-1.3320, 3.1029, -5.7721,
0.3008, -1.0882, 5.6268);
real Le = vLogLuv.z * 255.0 + vLogLuv.w;
real3 Xp_Y_XYZp;
Xp_Y_XYZp.y = exp2((Le - 127.0) / 2.0);
Xp_Y_XYZp.z = Xp_Y_XYZp.y / vLogLuv.y;
Xp_Y_XYZp.x = vLogLuv.x * Xp_Y_XYZp.z;
real3 vRGB = mul(Xp_Y_XYZp, InverseM);
return max(vRGB, real3(0.0, 0.0, 0.0));
}
// The standard 32-bit HDR color format
uint PackToR11G11B10f(float3 rgb)
{
uint r = (f32tof16(rgb.x) << 17) & 0xFFE00000;
uint g = (f32tof16(rgb.y) << 6) & 0x001FFC00;
uint b = (f32tof16(rgb.z) >> 5) & 0x000003FF;
return r | g | b;
}
float3 UnpackFromR11G11B10f(uint rgb)
{
float r = f16tof32((rgb >> 17) & 0x7FF0);
float g = f16tof32((rgb >> 6) & 0x7FF0);
float b = f16tof32((rgb << 5) & 0x7FE0);
return float3(r, g, b);
}
//-----------------------------------------------------------------------------
// Quaternion packing
//-----------------------------------------------------------------------------
// Ref: https://cedec.cesa.or.jp/2015/session/ENG/14698.html The Rendering Materials of Far Cry 4
/*
// This is GCN intrinsic
uint FindBiggestComponent(real4 q)
{
uint xyzIndex = CubeMapFaceID(q.x, q.y, q.z) * 0.5f;
uint wIndex = 3;
bool wBiggest = abs(q.w) > max3(abs(q.x), qbs(q.y), qbs(q.z));
return wBiggest ? wIndex : xyzIndex;
}
// Pack a quaternion into a 10:10:10:2
real4 PackQuat(real4 quat)
{
uint index = FindBiggestComponent(quat);
if (index == 0) quat = quat.yzwx;
if (index == 1) quat = quat.xzwy;
if (index == 2) quat = quat.xywz;
real4 packedQuat;
packedQuat.xyz = quat.xyz * FastSign(quat.w) * sqrt(0.5) + 0.5;
packedQuat.w = index / 3.0;
return packedQuat;
}
*/
// Unpack a quaternion from a 10:10:10:2
real4 UnpackQuat(real4 packedQuat)
{
uint index = (uint)(packedQuat.w * 3.0);
real4 quat;
quat.xyz = packedQuat.xyz * sqrt(2.0) - (1.0 / sqrt(2.0));
quat.w = sqrt(1.0 - saturate(dot(quat.xyz, quat.xyz)));
if (index == 0) quat = quat.wxyz;
if (index == 1) quat = quat.xwyz;
if (index == 2) quat = quat.xywz;
return quat;
}
//-----------------------------------------------------------------------------
// Integer packing
//-----------------------------------------------------------------------------
// Packs an integer stored using at most 'numBits' into a [0..1] real.
real PackInt(uint i, uint numBits)
{
uint maxInt = (1u << numBits) - 1u;
return saturate(i * rcp(maxInt));
}
// Unpacks a [0..1] real into an integer of size 'numBits'.
uint UnpackInt(real f, uint numBits)
{
uint maxInt = (1u << numBits) - 1u;
return (uint)(f * maxInt + 0.5); // Round instead of truncating
}
// Packs a [0..255] integer into a [0..1] real.
real PackByte(uint i)
{
return PackInt(i, 8);
}
// Unpacks a [0..1] real into a [0..255] integer.
uint UnpackByte(real f)
{
return UnpackInt(f, 8);
}
// Packs a [0..65535] integer into a [0..1] real.
real PackShort(uint i)
{
return PackInt(i, 16);
}
// Unpacks a [0..1] real into a [0..65535] integer.
uint UnpackShort(real f)
{
return UnpackInt(f, 16);
}
// Packs 8 lowermost bits of a [0..65535] integer into a [0..1] real.
real PackShortLo(uint i)
{
uint lo = BitFieldExtract(i, 0u, 8u);
return PackInt(lo, 8);
}
// Packs 8 uppermost bits of a [0..65535] integer into a [0..1] real.
real PackShortHi(uint i)
{
uint hi = BitFieldExtract(i, 8u, 8u);
return PackInt(hi, 8);
}
real Pack2Byte(real2 inputs)
{
real2 temp = inputs * real2(255.0, 255.0);
temp.x *= 256.0;
temp = round(temp);
real combined = temp.x + temp.y;
return combined * (1.0 / 65535.0);
}
real2 Unpack2Byte(real inputs)
{
real temp = round(inputs * 65535.0);
real ipart;
real fpart = modf(temp / 256.0, ipart);
real2 result = real2(ipart, round(256.0 * fpart));
return result * (1.0 / real2(255.0, 255.0));
}
// Encode a real in [0..1] and an int in [0..maxi - 1] as a real [0..1] to be store in log2(precision) bit
// maxi must be a power of two and define the number of bit dedicated 0..1 to the int part (log2(maxi))
// Example: precision is 256.0, maxi is 2, i is [0..1] encode on 1 bit. f is [0..1] encode on 7 bit.
// Example: precision is 256.0, maxi is 4, i is [0..3] encode on 2 bit. f is [0..1] encode on 6 bit.
// Example: precision is 256.0, maxi is 8, i is [0..7] encode on 3 bit. f is [0..1] encode on 5 bit.
// ...
// Example: precision is 1024.0, maxi is 8, i is [0..7] encode on 3 bit. f is [0..1] encode on 7 bit.
//...
real PackFloatInt(real f, uint i, real maxi, real precision)
{
// Constant
real precisionMinusOne = precision - 1.0;
real t1 = ((precision / maxi) - 1.0) / precisionMinusOne;
real t2 = (precision / maxi) / precisionMinusOne;
return t1 * f + t2 * real(i);
}
void UnpackFloatInt(real val, real maxi, real precision, out real f, out uint i)
{
// Constant
real precisionMinusOne = precision - 1.0;
real t1 = ((precision / maxi) - 1.0) / precisionMinusOne;
real t2 = (precision / maxi) / precisionMinusOne;
// extract integer part
i = int((val / t2) + rcp(precisionMinusOne)); // + rcp(precisionMinusOne) to deal with precision issue (can't use round() as val contain the floating number
// Now that we have i, solve formula in PackFloatInt for f
//f = (val - t2 * real(i)) / t1 => convert in mads form
f = saturate((-t2 * real(i) + val) / t1); // Saturate in case of precision issue
}
// Define various variante for ease of read
real PackFloatInt8bit(real f, uint i, real maxi)
{
return PackFloatInt(f, i, maxi, 256.0);
}
void UnpackFloatInt8bit(real val, real maxi, out real f, out uint i)
{
UnpackFloatInt(val, maxi, 256.0, f, i);
}
real PackFloatInt10bit(real f, uint i, real maxi)
{
return PackFloatInt(f, i, maxi, 1024.0);
}
void UnpackFloatInt10bit(real val, real maxi, out real f, out uint i)
{
UnpackFloatInt(val, maxi, 1024.0, f, i);
}
real PackFloatInt16bit(real f, uint i, real maxi)
{
return PackFloatInt(f, i, maxi, 65536.0);
}
void UnpackFloatInt16bit(real val, real maxi, out real f, out uint i)
{
UnpackFloatInt(val, maxi, 65536.0, f, i);
}
//-----------------------------------------------------------------------------
// Float packing
//-----------------------------------------------------------------------------
// src must be between 0.0 and 1.0
uint PackFloatToUInt(real src, uint offset, uint numBits)
{
return UnpackInt(src, numBits) << offset;
}
real UnpackUIntToFloat(uint src, uint offset, uint numBits)
{
uint maxInt = (1u << numBits) - 1u;
return real(BitFieldExtract(src, offset, numBits)) * rcp(maxInt);
}
uint PackToR10G10B10A2(real4 rgba)
{
return (PackFloatToUInt(rgba.x, 0, 10) |
PackFloatToUInt(rgba.y, 10, 10) |
PackFloatToUInt(rgba.z, 20, 10) |
PackFloatToUInt(rgba.w, 30, 2));
}
real4 UnpackFromR10G10B10A2(uint rgba)
{
real4 output;
output.x = UnpackUIntToFloat(rgba, 0, 10);
output.y = UnpackUIntToFloat(rgba, 10, 10);
output.z = UnpackUIntToFloat(rgba, 20, 10);
output.w = UnpackUIntToFloat(rgba, 30, 2);
return output;
}
// Both the input and the output are in the [0, 1] range.
real2 PackFloatToR8G8(real f)
{
uint i = UnpackShort(f);
return real2(PackShortLo(i), PackShortHi(i));
}
// Both the input and the output are in the [0, 1] range.
real UnpackFloatFromR8G8(real2 f)
{
uint lo = UnpackByte(f.x);
uint hi = UnpackByte(f.y);
uint cb = (hi << 8) + lo;
return PackShort(cb);
}
// Pack float2 (each of 12 bit) in 888
uint3 PackFloat2To888UInt(float2 f)
{
uint2 i = (uint2)(f * 4095.5);
uint2 hi = i >> 8;
uint2 lo = i & 255;
// 8 bit in lo, 4 bit in hi
uint3 cb = uint3(lo, hi.x | (hi.y << 4));
return cb;
}
// Pack float2 (each of 12 bit) in 888
float3 PackFloat2To888(float2 f)
{
return PackFloat2To888UInt(f) / 255.0;
}
// Unpack 2 float of 12bit packed into a 888
float2 Unpack888UIntToFloat2(uint3 x)
{
// 8 bit in lo, 4 bit in hi
uint hi = x.z >> 4;
uint lo = x.z & 15;
uint2 cb = x.xy | uint2(lo << 8, hi << 8);
return cb / 4095.0;
}
// Unpack 2 float of 12bit packed into a 888
float2 Unpack888ToFloat2(float3 x)
{
uint3 i = (uint3)(x * 255.5); // +0.5 to fix precision error on iOS
return Unpack888UIntToFloat2(i);
}
// Pack 2 float values from the [0, 1] range, to an 8 bits float from the [0, 1] range
float PackFloat2To8(float2 f)
{
float2 i = floor(f * 15.0); // f.x & f.y encoded over 4 bits, can have 2^4 = 16 distinct values mapped to [0, 1, ..., 15]
float x_y_expanded = i.x * 16.0 + i.y; // f.x encoded over higher bits, f.y encoded over the lower bits - x_y values in range [0, 1, ..., 255]
return x_y_expanded / 255.0;
// above 4 lines equivalent to:
//return (16.0 * f.x + f.y) / 17.0;
}
// Unpack 2 float values from the [0, 1] range, packed in an 8 bits float from the [0, 1] range
float2 Unpack8ToFloat2(float f)
{
float x_y_expanded = 255.0 * f;
float x_expanded = floor(x_y_expanded / 16.0);
float y_expanded = x_y_expanded - 16.0 * x_expanded;
float x = x_expanded / 15.0;
float y = y_expanded / 15.0;
return float2(x, y);
}
//-----------------------------------------------------------------------------
// Color packing
//-----------------------------------------------------------------------------
float4 UnpackFromR8G8B8A8(uint rgba)
{
return float4(rgba & 255, (rgba >> 8) & 255, (rgba >> 16) & 255, (rgba >> 24) & 255) * (1.0 / 255);
}
float2 PackToR5G6B5(float3 rgb)
{
uint rgb16 = (PackFloatToUInt(rgb.x, 0, 5) |
PackFloatToUInt(rgb.y, 5, 6) |
PackFloatToUInt(rgb.z, 11, 5));
return float2(PackByte(rgb16 >> 8), PackByte(rgb16 & 0xFF));
}
float3 UnpackFromR5G6B5(float2 rgb)
{
uint rgb16 = (UnpackByte(rgb.x) << 8) | UnpackByte(rgb.y);
return float3(UnpackUIntToFloat(rgb16, 0, 5),
UnpackUIntToFloat(rgb16, 5, 6),
UnpackUIntToFloat(rgb16, 11, 5));
}
uint PackToR7G7B6(float3 rgb)
{
uint rgb20 = (PackFloatToUInt(rgb.x, 0, 7) |
PackFloatToUInt(rgb.y, 7, 7) |
PackFloatToUInt(rgb.z, 14, 6));
return rgb20;
}
float3 UnpackFromR7G7B6(uint rgb)
{
return float3(UnpackUIntToFloat(rgb, 0, 7),
UnpackUIntToFloat(rgb, 7, 7),
UnpackUIntToFloat(rgb, 14, 6));
}
#if SHADER_API_MOBILE || SHADER_API_GLES3 || SHADER_API_SWITCH
#pragma warning (enable : 3205) // conversion of larger type to smaller
#endif
#endif // UNITY_PACKING_INCLUDED