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|
[require]
GLSL >= 4.00
[vertex shader]
#version 400
#define FORCE_EARLY_Z layout(early_fragment_tests) in
#extension GL_ARB_shading_language_420pack : enable
#define ATTRIBUTE_LOCATION(x)
#define FRAGMENT_OUTPUT_LOCATION(x)
#define FRAGMENT_OUTPUT_LOCATION_INDEXED(x, y)
#define UBO_BINDING(packing, x) layout(packing, binding = x)
#define SAMPLER_BINDING(x) layout(binding = x)
#define SSBO_BINDING(x) layout(binding = x)
#define VARYING_LOCATION(x)
#extension GL_ARB_shader_storage_buffer_object : enable
#extension GL_ARB_shader_image_load_store : enable
#define float2 vec2
#define float3 vec3
#define float4 vec4
#define uint2 uvec2
#define uint3 uvec3
#define uint4 uvec4
#define int2 ivec2
#define int3 ivec3
#define int4 ivec4
#define frac fract
#define lerp mix
// Vertex UberShader
struct Light {
int4 color;
float4 cosatt;
float4 distatt;
float4 pos;
float4 dir;
};
UBO_BINDING(std140, 2) uniform VSBlock {
uint components;
uint xfmem_dualTexInfo;
uint xfmem_numColorChans;
float4 cpnmtx[6];
float4 cproj[4];
int4 cmtrl[4];
Light clights[8];
float4 ctexmtx[24];
float4 ctrmtx[64];
float4 cnmtx[32];
float4 cpostmtx[64];
float4 cpixelcenter;
float2 cviewport;
uint4 xfmem_pack1[8];
#define xfmem_texMtxInfo(i) (xfmem_pack1[(i)].x)
#define xfmem_postMtxInfo(i) (xfmem_pack1[(i)].y)
#define xfmem_color(i) (xfmem_pack1[(i)].z)
#define xfmem_alpha(i) (xfmem_pack1[(i)].w)
};
struct VS_OUTPUT {
float4 pos;
float4 colors_0;
float4 colors_1;
float3 tex0;
float3 tex1;
float3 tex2;
float3 tex3;
float3 tex4;
float3 tex5;
float4 clipPos;
float clipDist0;
float clipDist1;
};
int4 CalculateLighting(uint index, uint attnfunc, uint diffusefunc, float3 pos, float3 normal) {
float3 ldir, h, cosAttn, distAttn;
float dist, dist2, attn;
switch (attnfunc) {
case 0u: // LIGNTATTN_NONE
case 2u: // LIGHTATTN_DIR
ldir = normalize(clights[index].pos.xyz - pos.xyz);
attn = 1.0;
if (length(ldir) == 0.0)
ldir = normal;
break;
case 1u: // LIGHTATTN_SPEC
ldir = normalize(clights[index].pos.xyz - pos.xyz);
attn = (dot(normal, ldir) >= 0.0) ? max(0.0, dot(normal, clights[index].dir.xyz)) : 0.0;
cosAttn = clights[index].cosatt.xyz;
if (diffusefunc == 0u) // LIGHTDIF_NONE
distAttn = clights[index].distatt.xyz;
else
distAttn = normalize(clights[index].distatt.xyz);
attn = max(0.0, dot(cosAttn, float3(1.0, attn, attn*attn))) / dot(distAttn, float3(1.0, attn, attn*attn));
break;
case 3u: // LIGHTATTN_SPOT
ldir = clights[index].pos.xyz - pos.xyz;
dist2 = dot(ldir, ldir);
dist = sqrt(dist2);
ldir = ldir / dist;
attn = max(0.0, dot(ldir, clights[index].dir.xyz));
attn = max(0.0, clights[index].cosatt.x + clights[index].cosatt.y * attn + clights[index].cosatt.z * attn * attn) / dot(clights[index].distatt.xyz, float3(1.0, dist, dist2));
break;
default:
attn = 1.0;
ldir = normal;
break;
}
switch (diffusefunc) {
case 0u: // LIGHTDIF_NONE
return int4(round(attn * float4(clights[index].color)));
case 1u: // LIGHTDIF_SIGN
return int4(round(attn * dot(ldir, normal) * float4(clights[index].color)));
case 2u: // LIGHTDIF_CLAMP
return int4(round(attn * max(0.0, dot(ldir, normal)) * float4(clights[index].color)));
default:
return int4(0, 0, 0, 0);
}
}
ATTRIBUTE_LOCATION(0) in float4 rawpos;
ATTRIBUTE_LOCATION(1) in uint4 posmtx;
ATTRIBUTE_LOCATION(2) in float3 rawnorm0;
ATTRIBUTE_LOCATION(3) in float3 rawnorm1;
ATTRIBUTE_LOCATION(4) in float3 rawnorm2;
ATTRIBUTE_LOCATION(5) in float4 rawcolor0;
ATTRIBUTE_LOCATION(6) in float4 rawcolor1;
ATTRIBUTE_LOCATION(8) in float3 rawtex0;
ATTRIBUTE_LOCATION(9) in float3 rawtex1;
ATTRIBUTE_LOCATION(10) in float3 rawtex2;
ATTRIBUTE_LOCATION(11) in float3 rawtex3;
ATTRIBUTE_LOCATION(12) in float3 rawtex4;
ATTRIBUTE_LOCATION(13) in float3 rawtex5;
ATTRIBUTE_LOCATION(14) in float3 rawtex6;
ATTRIBUTE_LOCATION(15) in float3 rawtex7;
VARYING_LOCATION(0) out VertexData {
float4 pos;
float4 colors_0;
float4 colors_1;
float3 tex0;
float3 tex1;
float3 tex2;
float3 tex3;
float3 tex4;
float3 tex5;
float4 clipPos;
float clipDist0;
float clipDist1;
} vs;
void main()
{
VS_OUTPUT o;
// Position matrix
float4 P0;
float4 P1;
float4 P2;
// Normal matrix
float3 N0;
float3 N1;
float3 N2;
if ((components & 2u) != 0u) {// VB_HAS_POSMTXIDX
// Vertex format has a per-vertex matrix
int posidx = int(posmtx.r);
P0 = ctrmtx[posidx];
P1 = ctrmtx[posidx+1];
P2 = ctrmtx[posidx+2];
int normidx = posidx >= 32 ? (posidx - 32) : posidx;
N0 = cnmtx[normidx].xyz;
N1 = cnmtx[normidx+1].xyz;
N2 = cnmtx[normidx+2].xyz;
} else {
// One shared matrix
P0 = cpnmtx[0];
P1 = cpnmtx[1];
P2 = cpnmtx[2];
N0 = cpnmtx[3].xyz;
N1 = cpnmtx[4].xyz;
N2 = cpnmtx[5].xyz;
}
float4 pos = float4(dot(P0, rawpos), dot(P1, rawpos), dot(P2, rawpos), 1.0);
o.pos = float4(dot(cproj[0], pos), dot(cproj[1], pos), dot(cproj[2], pos), dot(cproj[3], pos));
// Only the first normal gets normalized (TODO: why?)
float3 _norm0 = float3(0.0, 0.0, 0.0);
if ((components & 1024u) != 0u) // VB_HAS_NRM0
_norm0 = normalize(float3(dot(N0, rawnorm0), dot(N1, rawnorm0), dot(N2, rawnorm0)));
float3 _norm1 = float3(0.0, 0.0, 0.0);
if ((components & 2048u) != 0u) // VB_HAS_NRM1
_norm1 = float3(dot(N0, rawnorm1), dot(N1, rawnorm1), dot(N2, rawnorm1));
float3 _norm2 = float3(0.0, 0.0, 0.0);
if ((components & 4096u) != 0u) // VB_HAS_NRM2
_norm2 = float3(dot(N0, rawnorm2), dot(N1, rawnorm2), dot(N2, rawnorm2));
// Lighting
for (uint chan = 0u; chan < xfmem_numColorChans; chan++) {
uint colorreg = xfmem_color(chan);
uint alphareg = xfmem_alpha(chan);
int4 mat = cmtrl[chan + 2u];
int4 lacc = int4(255, 255, 255, 255);
if (bitfieldExtract(colorreg, 0, 1) != 0u) {
if ((components & (8192u << chan)) != 0u) // VB_HAS_COL0
mat.xyz = int3(round(((chan == 0u) ? rawcolor0.xyz : rawcolor1.xyz) * 255.0));
else if ((components & 8192u) != 0u) // VB_HAS_COLO0
mat.xyz = int3(round(rawcolor0.xyz * 255.0));
else
mat.xyz = int3(255, 255, 255);
}
if (bitfieldExtract(alphareg, 0, 1) != 0u) {
if ((components & (8192u << chan)) != 0u) // VB_HAS_COL0
mat.w = int(round(((chan == 0u) ? rawcolor0.w : rawcolor1.w) * 255.0));
else if ((components & 8192u) != 0u) // VB_HAS_COLO0
mat.w = int(round(rawcolor0.w * 255.0));
else
mat.w = 255;
} else {
mat.w = cmtrl [chan + 2u].w;
}
if (bitfieldExtract(colorreg, 1, 1) != 0u) {
if (bitfieldExtract(colorreg, 6, 1) != 0u) {
if ((components & (8192u << chan)) != 0u) // VB_HAS_COL0
lacc.xyz = int3(round(((chan == 0u) ? rawcolor0.xyz : rawcolor1.xyz) * 255.0));
else if ((components & 8192u) != 0u) // VB_HAS_COLO0
lacc.xyz = int3(round(rawcolor0.xyz * 255.0));
else
lacc.xyz = int3(255, 255, 255);
} else {
lacc.xyz = cmtrl [chan].xyz;
}
uint light_mask = bitfieldExtract(colorreg, 2, 4) | (bitfieldExtract(colorreg, 11, 4) << 4u);
uint attnfunc = bitfieldExtract(colorreg, 9, 2);
uint diffusefunc = bitfieldExtract(colorreg, 7, 2);
for (uint light_index = 0u; light_index < 8u; light_index++) {
if ((light_mask & (1u << light_index)) != 0u)
lacc.xyz += CalculateLighting(light_index, attnfunc, diffusefunc, pos.xyz, _norm0).xyz;
}
}
if (bitfieldExtract(alphareg, 1, 1) != 0u) {
if (bitfieldExtract(alphareg, 6, 1) != 0u) {
if ((components & (8192u << chan)) != 0u) // VB_HAS_COL0
lacc.w = int(round(((chan == 0u) ? rawcolor0.w : rawcolor1.w) * 255.0));
else if ((components & 8192u) != 0u) // VB_HAS_COLO0
lacc.w = int(round(rawcolor0.w * 255.0));
else
lacc.w = 255;
} else {
lacc.w = cmtrl [chan].w;
}
uint light_mask = bitfieldExtract(alphareg, 2, 4) | (bitfieldExtract(alphareg, 11, 4) << 4u);
uint attnfunc = bitfieldExtract(alphareg, 9, 2);
uint diffusefunc = bitfieldExtract(alphareg, 7, 2);
for (uint light_index = 0u; light_index < 8u; light_index++) {
if ((light_mask & (1u << light_index)) != 0u)
lacc.w += CalculateLighting(light_index, attnfunc, diffusefunc, pos.xyz, _norm0).w;
}
}
lacc = clamp(lacc, 0, 255);
// Hopefully GPUs that can support dynamic indexing will optimize this.
float4 lit_color = float4((mat * (lacc + (lacc >> 7))) >> 8) / 255.0;
switch (chan) {
case 0u: o.colors_0 = lit_color; break;
case 1u: o.colors_1 = lit_color; break;
}
}
if (xfmem_numColorChans < 2u && (components & 16384u) == 0u)
o.colors_1 = o.colors_0;
o.tex0 = float3(0.0, 0.0, 0.0);
o.tex1 = float3(0.0, 0.0, 0.0);
o.tex2 = float3(0.0, 0.0, 0.0);
o.tex3 = float3(0.0, 0.0, 0.0);
o.tex4 = float3(0.0, 0.0, 0.0);
o.tex5 = float3(0.0, 0.0, 0.0);
// Texture coordinate generation
for (uint texgen = 0u; texgen < 6u; texgen++) {
// Texcoord transforms
float4 coord = float4(0.0, 0.0, 1.0, 1.0);
uint texMtxInfo = xfmem_texMtxInfo(texgen);
switch (bitfieldExtract(texMtxInfo, 7, 5)) {
case 0u: // XF_SRCGEOM_INROW
coord.xyz = rawpos.xyz;
break;
case 1u: // XF_SRCNORMAL_INROW
coord.xyz = ((components & 1024u /* VB_HAS_NRM0 */) != 0u) ? rawnorm0.xyz : coord.xyz; break;
case 3u: // XF_SRCBINORMAL_T_INROW
coord.xyz = ((components & 2048u /* VB_HAS_NRM1 */) != 0u) ? rawnorm1.xyz : coord.xyz; break;
case 4u: // XF_SRCBINORMAL_B_INROW
coord.xyz = ((components & 4096u /* VB_HAS_NRM2 */) != 0u) ? rawnorm2.xyz : coord.xyz; break;
case 5u: // XF_SRCTEX0_INROW
coord = ((components & 32768u /* VB_HAS_UV0 */) != 0u) ? float4(rawtex0.x, rawtex0.y, 1.0, 1.0) : coord;
break;
case 6u: // XF_SRCTEX1_INROW
coord = ((components & 65536u /* VB_HAS_UV1 */) != 0u) ? float4(rawtex1.x, rawtex1.y, 1.0, 1.0) : coord;
break;
case 7u: // XF_SRCTEX2_INROW
coord = ((components & 131072u /* VB_HAS_UV2 */) != 0u) ? float4(rawtex2.x, rawtex2.y, 1.0, 1.0) : coord;
break;
case 8u: // XF_SRCTEX3_INROW
coord = ((components & 262144u /* VB_HAS_UV3 */) != 0u) ? float4(rawtex3.x, rawtex3.y, 1.0, 1.0) : coord;
break;
case 9u: // XF_SRCTEX4_INROW
coord = ((components & 524288u /* VB_HAS_UV4 */) != 0u) ? float4(rawtex4.x, rawtex4.y, 1.0, 1.0) : coord;
break;
case 10u: // XF_SRCTEX5_INROW
coord = ((components & 1048576u /* VB_HAS_UV5 */) != 0u) ? float4(rawtex5.x, rawtex5.y, 1.0, 1.0) : coord;
break;
case 11u: // XF_SRCTEX6_INROW
coord = ((components & 2097152u /* VB_HAS_UV6 */) != 0u) ? float4(rawtex6.x, rawtex6.y, 1.0, 1.0) : coord;
break;
case 12u: // XF_SRCTEX7_INROW
coord = ((components & 4194304u /* VB_HAS_UV7 */) != 0u) ? float4(rawtex7.x, rawtex7.y, 1.0, 1.0) : coord;
break;
}
// Input form of AB11 sets z element to 1.0
if (bitfieldExtract(texMtxInfo, 2, 1) == 0u) // inputform == XF_TEXINPUT_AB11
coord.z = 1.0f;
// first transformation
uint texgentype = bitfieldExtract(texMtxInfo, 4, 3);
float3 output_tex;
switch (texgentype)
{
case 1u: // XF_TEXGEN_EMBOSS_MAP
{
uint light = bitfieldExtract(texMtxInfo, 15, 3);
uint source = bitfieldExtract(texMtxInfo, 12, 3);
switch (source) {
case 0u: output_tex.xyz = o.tex0; break;
case 1u: output_tex.xyz = o.tex1; break;
case 2u: output_tex.xyz = o.tex2; break;
case 3u: output_tex.xyz = o.tex3; break;
case 4u: output_tex.xyz = o.tex4; break;
case 5u: output_tex.xyz = o.tex5; break;
default: output_tex.xyz = float3(0.0, 0.0, 0.0); break;
}
if ((components & 6144u) != 0u) { // VB_HAS_NRM1 | VB_HAS_NRM2
float3 ldir = normalize(clights[light].pos.xyz - pos.xyz);
output_tex.xyz += float3(dot(ldir, _norm1), dot(ldir, _norm2), 0.0);
}
}
break;
case 2u: // XF_TEXGEN_COLOR_STRGBC0
output_tex.xyz = float3(o.colors_0.x, o.colors_0.y, 1.0);
break;
case 3u: // XF_TEXGEN_COLOR_STRGBC1
output_tex.xyz = float3(o.colors_1.x, o.colors_1.y, 1.0);
break;
default: // Also XF_TEXGEN_REGULAR
{
if ((components & (4u /* VB_HAS_TEXMTXIDX0 */ << texgen)) != 0u) {
// This is messy, due to dynamic indexing of the input texture coordinates.
// Hopefully the compiler will unroll this whole loop anyway and the switch.
int tmp = 0;
switch (texgen) {
case 0u: tmp = int(rawtex0.z); break;
case 1u: tmp = int(rawtex1.z); break;
case 2u: tmp = int(rawtex2.z); break;
case 3u: tmp = int(rawtex3.z); break;
case 4u: tmp = int(rawtex4.z); break;
case 5u: tmp = int(rawtex5.z); break;
}
if (bitfieldExtract(texMtxInfo, 1, 1) == 1u) {
output_tex.xyz = float3(dot(coord, ctrmtx[tmp]),
dot(coord, ctrmtx[tmp + 1]),
dot(coord, ctrmtx[tmp + 2]));
} else {
output_tex.xyz = float3(dot(coord, ctrmtx[tmp]),
dot(coord, ctrmtx[tmp + 1]),
1.0);
}
} else {
if (bitfieldExtract(texMtxInfo, 1, 1) == 1u) {
output_tex.xyz = float3(dot(coord, ctexmtx[3u * texgen]),
dot(coord, ctexmtx[3u * texgen + 1u]),
dot(coord, ctexmtx[3u * texgen + 2u]));
} else {
output_tex.xyz = float3(dot(coord, ctexmtx[3u * texgen]),
dot(coord, ctexmtx[3u * texgen + 1u]),
1.0);
}
}
}
break;
}
if (xfmem_dualTexInfo != 0u) {
uint postMtxInfo = xfmem_postMtxInfo(texgen); uint base_index = bitfieldExtract(postMtxInfo, 0, 6);
float4 P0 = cpostmtx[base_index & 0x3fu];
float4 P1 = cpostmtx[(base_index + 1u) & 0x3fu];
float4 P2 = cpostmtx[(base_index + 2u) & 0x3fu];
if (bitfieldExtract(postMtxInfo, 8, 1) != 0u)
output_tex.xyz = normalize(output_tex.xyz);
// multiply by postmatrix
output_tex.xyz = float3(dot(P0.xyz, output_tex.xyz) + P0.w,
dot(P1.xyz, output_tex.xyz) + P1.w,
dot(P2.xyz, output_tex.xyz) + P2.w);
}
if (texgentype == 0u && output_tex.z == 0.0) // XF_TEXGEN_REGULAR
output_tex.xy = clamp(output_tex.xy / 2.0f, float2(-1.0f,-1.0f), float2(1.0f,1.0f));
// Hopefully GPUs that can support dynamic indexing will optimize this.
switch (texgen) {
case 0u: o.tex0 = output_tex; break;
case 1u: o.tex1 = output_tex; break;
case 2u: o.tex2 = output_tex; break;
case 3u: o.tex3 = output_tex; break;
case 4u: o.tex4 = output_tex; break;
case 5u: o.tex5 = output_tex; break;
}
}
o.clipPos = o.pos;
float clipDepth = o.pos.z * (1.0 - 1e-7);
o.clipDist0 = clipDepth + o.pos.w;
o.clipDist1 = -clipDepth;
o.pos.z = o.pos.w * cpixelcenter.w - o.pos.z * cpixelcenter.z;
o.pos.xy *= sign(cpixelcenter.xy * float2(1.0, -1.0));
o.pos.xy = o.pos.xy - o.pos.w * cpixelcenter.xy;
vs.pos = o.pos;
vs.colors_0 = o.colors_0;
vs.colors_1 = o.colors_1;
vs.tex0 = o.tex0;
vs.tex1 = o.tex1;
vs.tex2 = o.tex2;
vs.tex3 = o.tex3;
vs.tex4 = o.tex4;
vs.tex5 = o.tex5;
vs.clipPos = o.clipPos;
vs.clipDist0 = o.clipDist0;
vs.clipDist1 = o.clipDist1;
gl_ClipDistance[0] = o.clipDist0;
gl_ClipDistance[1] = o.clipDist1;
gl_Position = o.pos;
}
[fragment shader]
#version 400
#define FORCE_EARLY_Z layout(early_fragment_tests) in
#extension GL_ARB_shading_language_420pack : enable
#define ATTRIBUTE_LOCATION(x)
#define FRAGMENT_OUTPUT_LOCATION(x)
#define FRAGMENT_OUTPUT_LOCATION_INDEXED(x, y)
#define UBO_BINDING(packing, x) layout(packing, binding = x)
#define SAMPLER_BINDING(x) layout(binding = x)
#define SSBO_BINDING(x) layout(binding = x)
#define VARYING_LOCATION(x)
#extension GL_ARB_shader_storage_buffer_object : enable
#extension GL_ARB_shader_image_load_store : enable
#define float2 vec2
#define float3 vec3
#define float4 vec4
#define uint2 uvec2
#define uint3 uvec3
#define uint4 uvec4
#define int2 ivec2
#define int3 ivec3
#define int4 ivec4
#define frac fract
#define lerp mix
// Pixel UberShader for 6 texgens
int idot(int3 x, int3 y)
{
int3 tmp = x * y;
return tmp.x + tmp.y + tmp.z;
}
int idot(int4 x, int4 y)
{
int4 tmp = x * y;
return tmp.x + tmp.y + tmp.z + tmp.w;
}
int iround(float x) { return int (round(x)); }
int2 iround(float2 x) { return int2(round(x)); }
int3 iround(float3 x) { return int3(round(x)); }
int4 iround(float4 x) { return int4(round(x)); }
SAMPLER_BINDING(0) uniform sampler2DArray samp[8];
UBO_BINDING(std140, 1) uniform PSBlock {
int4 color[4];
int4 k[4];
int4 alphaRef;
float4 texdim[8];
int4 czbias[2];
int4 cindscale[2];
int4 cindmtx[6];
int4 cfogcolor;
int4 cfogi;
float4 cfogf[2];
float4 czslope;
float2 cefbscale;
uint bpmem_genmode;
uint bpmem_alphaTest;
uint bpmem_fogParam3;
uint bpmem_fogRangeBase;
uint bpmem_dstalpha;
uint bpmem_ztex_op;
bool bpmem_late_ztest;
bool bpmem_rgba6_format;
bool bpmem_dither;
bool bpmem_bounding_box;
uint4 bpmem_pack1[16];
uint4 bpmem_pack2[8];
int4 konstLookup[32];
};
#define bpmem_combiners(i) (bpmem_pack1[(i)].xy)
#define bpmem_tevind(i) (bpmem_pack1[(i)].z)
#define bpmem_iref(i) (bpmem_pack1[(i)].w)
#define bpmem_tevorder(i) (bpmem_pack2[(i)].x)
#define bpmem_tevksel(i) (bpmem_pack2[(i)].y)
struct VS_OUTPUT {
float4 pos;
float4 colors_0;
float4 colors_1;
float3 tex0;
float3 tex1;
float3 tex2;
float3 tex3;
float3 tex4;
float3 tex5;
float4 clipPos;
float clipDist0;
float clipDist1;
};
FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 0) out vec4 ocol0;
FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 1) out vec4 ocol1;
VARYING_LOCATION(0) in VertexData {
float4 pos;
float4 colors_0;
float4 colors_1;
float3 tex0;
float3 tex1;
float3 tex2;
float3 tex3;
float3 tex4;
float3 tex5;
float4 clipPos;
float clipDist0;
float clipDist1;
};
float3 selectTexCoord(uint index) {
switch (index) {
case 0u:
return tex0;
case 1u:
return tex1;
case 2u:
return tex2;
case 3u:
return tex3;
case 4u:
return tex4;
case 5u:
return tex5;
default:
return float3(0.0, 0.0, 0.0);
}
}
int4 sampleTexture(uint sampler_num, float2 uv) {
return iround(texture(samp[sampler_num], float3(uv, 0.0)) * 255.0);
}
int4 Swizzle(uint s, int4 color) {
// AKA: Color Channel Swapping
int4 ret;
ret.r = color[bitfieldExtract(bpmem_tevksel(s * 2u), 0, 2)];
ret.g = color[bitfieldExtract(bpmem_tevksel(s * 2u), 2, 2)];
ret.b = color[bitfieldExtract(bpmem_tevksel(s * 2u + 1u), 0, 2)];
ret.a = color[bitfieldExtract(bpmem_tevksel(s * 2u + 1u), 2, 2)];
return ret;
}
int Wrap(int coord, uint mode) {
if (mode == 0u) // ITW_OFF
return coord;
else if (mode < 6u) // ITW_256 to ITW_16
return coord & (0xfffe >> mode);
else // ITW_0
return 0;
}
// TEV's Linear Interpolate, plus bias, add/subtract and scale
int tevLerp(int A, int B, int C, int D, uint bias, bool op, bool alpha, uint shift) {
// Scale C from 0..255 to 0..256
C += C >> 7;
// Add bias to D
if (bias == 1u) D += 128;
else if (bias == 2u) D -= 128;
int lerp = (A << 8) + (B - A)*C;
if (shift != 3u) {
lerp = lerp << shift;
D = D << shift;
}
if ((shift == 3u) == alpha)
lerp = lerp + (op ? 127 : 128);
int result = lerp >> 8;
// Add/Subtract D
if(op) // Subtract
result = D - result;
else // Add
result = D + result;
// Most of the Shift was moved inside the lerp for improved percision
// But we still do the divide by 2 here
if (shift == 3u)
result = result >> 1;
return result;
}
// TEV's Linear Interpolate, plus bias, add/subtract and scale
int3 tevLerp3(int3 A, int3 B, int3 C, int3 D, uint bias, bool op, bool alpha, uint shift) {
// Scale C from 0..255 to 0..256
C += C >> 7;
// Add bias to D
if (bias == 1u) D += 128;
else if (bias == 2u) D -= 128;
int3 lerp = (A << 8) + (B - A)*C;
if (shift != 3u) {
lerp = lerp << shift;
D = D << shift;
}
if ((shift == 3u) == alpha)
lerp = lerp + (op ? 127 : 128);
int3 result = lerp >> 8;
// Add/Subtract D
if(op) // Subtract
result = D - result;
else // Add
result = D + result;
// Most of the Shift was moved inside the lerp for improved percision
// But we still do the divide by 2 here
if (shift == 3u)
result = result >> 1;
return result;
}
// Implements operations 0-5 of tev's compare mode,
// which are common to both color and alpha channels
bool tevCompare(uint op, int3 color_A, int3 color_B) {
switch (op) {
case 0u: // TEVCMP_R8_GT
return (color_A.r > color_B.r);
case 1u: // TEVCMP_R8_EQ
return (color_A.r == color_B.r);
case 2u: // TEVCMP_GR16_GT
int A_16 = (color_A.r | (color_A.g << 8));
int B_16 = (color_B.r | (color_B.g << 8));
return A_16 > B_16;
case 3u: // TEVCMP_GR16_EQ
return (color_A.r == color_B.r && color_A.g == color_B.g);
case 4u: // TEVCMP_BGR24_GT
int A_24 = (color_A.r | (color_A.g << 8) | (color_A.b << 16));
int B_24 = (color_B.r | (color_B.g << 8) | (color_B.b << 16));
return A_24 > B_24;
case 5u: // TEVCMP_BGR24_EQ
return (color_A.r == color_B.r && color_A.g == color_B.g && color_A.b == color_B.b);
default:
return false;
}
}
// Helper function for Alpha Test
bool alphaCompare(int a, int b, uint compare) {
switch (compare) {
case 0u: // NEVER
return false;
case 1u: // LESS
return a < b;
case 2u: // EQUAL
return a == b;
case 3u: // LEQUAL
return a <= b;
case 4u: // GREATER
return a > b;
case 5u: // NEQUAL;
return a != b;
case 6u: // GEQUAL
return a >= b;
case 7u: // ALWAYS
return true;
}
}
struct State {
int4 Reg[4];
int4 TexColor;
int AlphaBump;
};
struct StageState {
uint stage;
uint order;
uint cc;
uint ac;
};
int4 getRasColor(State s, StageState ss, float4 colors_0, float4 colors_1);
int4 getKonstColor(State s, StageState ss);
int3 selectColorInput(State s, StageState ss, float4 colors_0, float4 colors_1, uint index) {
switch (index) {
case 0u: // prev.rgb
return s.Reg[0].rgb;
case 1u: // prev.aaa
return s.Reg[0].aaa;
case 2u: // c0.rgb
return s.Reg[1].rgb;
case 3u: // c0.aaa
return s.Reg[1].aaa;
case 4u: // c1.rgb
return s.Reg[2].rgb;
case 5u: // c1.aaa
return s.Reg[2].aaa;
case 6u: // c2.rgb
return s.Reg[3].rgb;
case 7u: // c2.aaa
return s.Reg[3].aaa;
case 8u:
return s.TexColor.rgb;
case 9u:
return s.TexColor.aaa;
case 10u:
return getRasColor(s, ss, colors_0, colors_1).rgb;
case 11u:
return getRasColor(s, ss, colors_0, colors_1).aaa;
case 12u: // One
return int3(255, 255, 255);
case 13u: // Half
return int3(128, 128, 128);
case 14u:
return getKonstColor(s, ss).rgb;
case 15u: // Zero
return int3(0, 0, 0);
}
}
int selectAlphaInput(State s, StageState ss, float4 colors_0, float4 colors_1, uint index) {
switch (index) {
case 0u: // prev.a
return s.Reg[0].a;
case 1u: // c0.a
return s.Reg[1].a;
case 2u: // c1.a
return s.Reg[2].a;
case 3u: // c2.a
return s.Reg[3].a;
case 4u:
return s.TexColor.a;
case 5u:
return getRasColor(s, ss, colors_0, colors_1).a;
case 6u:
return getKonstColor(s, ss).a;
case 7u: // Zero
return 0;
}
}
int4 getTevReg(in State s, uint index) {
switch (index) {
case 0u: // prev
return s.Reg[0];
case 1u: // c0
return s.Reg[1];
case 2u: // c1
return s.Reg[2];
case 3u: // c2
return s.Reg[3];
default: // prev
return s.Reg[0];
}
}
void setRegColor(inout State s, uint index, int3 color) {
switch (index) {
case 0u: // prev
s.Reg[0].rgb = color;
break;
case 1u: // c0
s.Reg[1].rgb = color;
break;
case 2u: // c1
s.Reg[2].rgb = color;
break;
case 3u: // c2
s.Reg[3].rgb = color;
break;
}
}
void setRegAlpha(inout State s, uint index, int alpha) {
switch (index) {
case 0u: // prev
s.Reg[0].a = alpha;
break;
case 1u: // c0
s.Reg[1].a = alpha;
break;
case 2u: // c1
s.Reg[2].a = alpha;
break;
case 3u: // c2
s.Reg[3].a = alpha;
break;
}
}
#define getTexCoord(index) selectTexCoord((index))
void main()
{
float4 rawpos = gl_FragCoord;
int3 tevcoord = int3(0, 0, 0);
State s;
s.TexColor = int4(0, 0, 0, 0);
s.AlphaBump = 0;
s.Reg[0] = color[0];
s.Reg[1] = color[1];
s.Reg[2] = color[2];
s.Reg[3] = color[3];
uint num_stages = bitfieldExtract(bpmem_genmode, 10, 4);
// Main tev loop
for(uint stage = 0u; stage <= num_stages; stage++)
{
StageState ss;
ss.stage = stage;
ss.cc = bpmem_combiners(stage).x;
ss.ac = bpmem_combiners(stage).y;
ss.order = bpmem_tevorder(stage>>1);
if ((stage & 1u) == 1u)
ss.order = ss.order >> 12;
uint tex_coord = bitfieldExtract(ss.order, 3, 3);
float3 uv = getTexCoord(tex_coord);
int2 fixedPoint_uv = int2((uv.z == 0.0 ? uv.xy : (uv.xy / uv.z)) * texdim[tex_coord].zw);
bool texture_enabled = (ss.order & 64u) != 0u;
// Indirect textures
uint tevind = bpmem_tevind(stage);
if (tevind != 0u)
{
uint bs = bitfieldExtract(tevind, 7, 2);
uint fmt = bitfieldExtract(tevind, 2, 2);
uint bias = bitfieldExtract(tevind, 4, 3);
uint bt = bitfieldExtract(tevind, 0, 2);
uint mid = bitfieldExtract(tevind, 9, 4);
int3 indcoord;
{
uint iref = bpmem_iref(bt);
if ( iref != 0u)
{
uint texcoord = bitfieldExtract(iref, 0, 3);
uint texmap = bitfieldExtract(iref, 8, 3);
float3 uv = getTexCoord(texcoord);
int2 fixedPoint_uv = int2((uv.z == 0.0 ? uv.xy : (uv.xy / uv.z)) * texdim[texcoord].zw);
if ((bt & 1u) == 0u)
fixedPoint_uv = fixedPoint_uv >> cindscale[bt >> 1].xy;
else
fixedPoint_uv = fixedPoint_uv >> cindscale[bt >> 1].zw;
indcoord = sampleTexture(texmap, float2(fixedPoint_uv) * texdim[texmap].xy).abg;
}
else
{
indcoord = int3(0, 0, 0);
}
}
if (bs != 0u)
s.AlphaBump = indcoord[bs - 1u];
switch(fmt)
{
case 0u:
indcoord.x = indcoord.x + ((bias & 1u) != 0u ? -128 : 0);
indcoord.y = indcoord.y + ((bias & 2u) != 0u ? -128 : 0);
indcoord.z = indcoord.z + ((bias & 4u) != 0u ? -128 : 0);
s.AlphaBump = s.AlphaBump & 0xf8;
break;
case 1u:
indcoord.x = (indcoord.x & 0x1f) + ((bias & 1u) != 0u ? 1 : 0);
indcoord.y = (indcoord.y & 0x1f) + ((bias & 2u) != 0u ? 1 : 0);
indcoord.z = (indcoord.z & 0x1f) + ((bias & 4u) != 0u ? 1 : 0);
s.AlphaBump = s.AlphaBump & 0xe0;
break;
case 2u:
indcoord.x = (indcoord.x & 0x0f) + ((bias & 1u) != 0u ? 1 : 0);
indcoord.y = (indcoord.y & 0x0f) + ((bias & 2u) != 0u ? 1 : 0);
indcoord.z = (indcoord.z & 0x0f) + ((bias & 4u) != 0u ? 1 : 0);
s.AlphaBump = s.AlphaBump & 0xf0;
break;
case 3u:
indcoord.x = (indcoord.x & 0x07) + ((bias & 1u) != 0u ? 1 : 0);
indcoord.y = (indcoord.y & 0x07) + ((bias & 2u) != 0u ? 1 : 0);
indcoord.z = (indcoord.z & 0x07) + ((bias & 4u) != 0u ? 1 : 0);
s.AlphaBump = s.AlphaBump & 0xf8;
break;
}
// Matrix multiply
int2 indtevtrans = int2(0, 0);
if ((mid & 3u) != 0u)
{
uint mtxidx = 2u * ((mid & 3u) - 1u);
int shift = cindmtx[mtxidx].w;
switch (mid >> 2)
{
case 0u: // 3x2 S0.10 matrix
indtevtrans = int2(idot(cindmtx[mtxidx].xyz, indcoord), idot(cindmtx[mtxidx + 1u].xyz, indcoord)) >> 3;
break;
case 1u: // S matrix, S17.7 format
indtevtrans = (fixedPoint_uv * indcoord.xx) >> 8;
break;
case 2u: // T matrix, S17.7 format
indtevtrans = (fixedPoint_uv * indcoord.yy) >> 8;
break;
}
if (shift >= 0)
indtevtrans = indtevtrans >> shift;
else
indtevtrans = indtevtrans << ((-shift) & 31);
}
// Wrapping
uint sw = bitfieldExtract(tevind, 13, 3);
uint tw = bitfieldExtract(tevind, 16, 3);
int2 wrapped_coord = int2(Wrap(fixedPoint_uv.x, sw), Wrap(fixedPoint_uv.y, tw));
if ((tevind & 1048576u) != 0u) // add previous tevcoord
tevcoord.xy += wrapped_coord + indtevtrans;
else
tevcoord.xy = wrapped_coord + indtevtrans;
// Emulate s24 overflows
tevcoord.xy = (tevcoord.xy << 8) >> 8;
}
else if (texture_enabled)
{
tevcoord.xy = fixedPoint_uv;
}
// Sample texture for stage
if(texture_enabled) {
uint sampler_num = bitfieldExtract(ss.order, 0, 3);
float2 uv = (float2(tevcoord.xy)) * texdim[sampler_num].xy;
int4 color = sampleTexture(sampler_num, uv);
uint swap = bitfieldExtract(ss.ac, 2, 2);
s.TexColor = Swizzle(swap, color);
} else {
// Texture is disabled
s.TexColor = int4(255, 255, 255, 255);
}
// This is the Meat of TEV
{
// Color Combiner
uint color_a = bitfieldExtract(ss.cc, 12, 4);
uint color_b = bitfieldExtract(ss.cc, 8, 4);
uint color_c = bitfieldExtract(ss.cc, 4, 4);
uint color_d = bitfieldExtract(ss.cc, 0, 4);
uint color_bias = bitfieldExtract(ss.cc, 16, 2);
bool color_op = bool(bitfieldExtract(ss.cc, 18, 1));
bool color_clamp = bool(bitfieldExtract(ss.cc, 19, 1));
uint color_shift = bitfieldExtract(ss.cc, 20, 2);
uint color_dest = bitfieldExtract(ss.cc, 22, 2);
uint color_compare_op = color_shift << 1 | uint(color_op);
int3 color_A = selectColorInput(s, ss, colors_0, colors_1, color_a) & int3(255, 255, 255);
int3 color_B = selectColorInput(s, ss, colors_0, colors_1, color_b) & int3(255, 255, 255);
int3 color_C = selectColorInput(s, ss, colors_0, colors_1, color_c) & int3(255, 255, 255);
int3 color_D = selectColorInput(s, ss, colors_0, colors_1, color_d); // 10 bits + sign
int3 color;
if(color_bias != 3u) { // Normal mode
color = tevLerp3(color_A, color_B, color_C, color_D, color_bias, color_op, false, color_shift);
} else { // Compare mode
// op 6 and 7 do a select per color channel
if (color_compare_op == 6u) {
// TEVCMP_RGB8_GT
color.r = (color_A.r > color_B.r) ? color_C.r : 0;
color.g = (color_A.g > color_B.g) ? color_C.g : 0;
color.b = (color_A.b > color_B.b) ? color_C.b : 0;
} else if (color_compare_op == 7u) {
// TEVCMP_RGB8_EQ
color.r = (color_A.r == color_B.r) ? color_C.r : 0;
color.g = (color_A.g == color_B.g) ? color_C.g : 0;
color.b = (color_A.b == color_B.b) ? color_C.b : 0;
} else {
// The remaining ops do one compare which selects all 3 channels
color = tevCompare(color_compare_op, color_A, color_B) ? color_C : int3(0, 0, 0);
}
color = color_D + color;
}
// Clamp result
if (color_clamp)
color = clamp(color, 0, 255);
else
color = clamp(color, -1024, 1023);
// Write result to the correct input register of the next stage
setRegColor(s, color_dest, color);
// Alpha Combiner
uint alpha_a = bitfieldExtract(ss.ac, 13, 3);
uint alpha_b = bitfieldExtract(ss.ac, 10, 3);
uint alpha_c = bitfieldExtract(ss.ac, 7, 3);
uint alpha_d = bitfieldExtract(ss.ac, 4, 3);
uint alpha_bias = bitfieldExtract(ss.ac, 16, 2);
bool alpha_op = bool(bitfieldExtract(ss.ac, 18, 1));
bool alpha_clamp = bool(bitfieldExtract(ss.ac, 19, 1));
uint alpha_shift = bitfieldExtract(ss.ac, 20, 2);
uint alpha_dest = bitfieldExtract(ss.ac, 22, 2);
uint alpha_compare_op = alpha_shift << 1 | uint(alpha_op);
int alpha_A;
int alpha_B;
if (alpha_bias != 3u || alpha_compare_op > 5u) {
// Small optimisation here: alpha_A and alpha_B are unused by compare ops 0-5
alpha_A = selectAlphaInput(s, ss, colors_0, colors_1, alpha_a) & 255;
alpha_B = selectAlphaInput(s, ss, colors_0, colors_1, alpha_b) & 255;
};
int alpha_C = selectAlphaInput(s, ss, colors_0, colors_1, alpha_c) & 255;
int alpha_D = selectAlphaInput(s, ss, colors_0, colors_1, alpha_d); // 10 bits + sign
int alpha;
if(alpha_bias != 3u) { // Normal mode
alpha = tevLerp(alpha_A, alpha_B, alpha_C, alpha_D, alpha_bias, alpha_op, true, alpha_shift);
} else { // Compare mode
if (alpha_compare_op == 6u) {
// TEVCMP_A8_GT
alpha = (alpha_A > alpha_B) ? alpha_C : 0;
} else if (alpha_compare_op == 7u) {
// TEVCMP_A8_EQ
alpha = (alpha_A == alpha_B) ? alpha_C : 0;
} else {
// All remaining alpha compare ops actually compare the color channels
alpha = tevCompare(alpha_compare_op, color_A, color_B) ? alpha_C : 0;
}
alpha = alpha_D + alpha;
}
// Clamp result
if (alpha_clamp)
alpha = clamp(alpha, 0, 255);
else
alpha = clamp(alpha, -1024, 1023);
// Write result to the correct input register of the next stage
setRegAlpha(s, alpha_dest, alpha);
}
} // Main tev loop
int4 TevResult;
TevResult.xyz = getTevReg(s, bitfieldExtract(bpmem_combiners(num_stages).x, 22, 2)).xyz;
TevResult.w = getTevReg(s, bitfieldExtract(bpmem_combiners(num_stages).y, 22, 2)).w;
TevResult &= 255;
int zCoord = int(rawpos.z * 16777216.0);
zCoord = clamp(zCoord, 0, 0xFFFFFF);
// Depth Texture
int early_zCoord = zCoord;
if (bpmem_ztex_op != 0u) {
int ztex = int(czbias[1].w); // fixed bias
// Whatever texture was in our last stage, it's now our depth texture
ztex += idot(s.TexColor.xyzw, czbias[0].xyzw);
ztex += (bpmem_ztex_op == 1u) ? zCoord : 0;
zCoord = ztex & 0xFFFFFF;
}
// Alpha Test
if (bpmem_alphaTest != 0u) {
bool comp0 = alphaCompare(TevResult.a, alphaRef.r, bitfieldExtract(bpmem_alphaTest, 16, 3));
bool comp1 = alphaCompare(TevResult.a, alphaRef.g, bitfieldExtract(bpmem_alphaTest, 19, 3));
// These if statements are written weirdly to work around intel and qualcom bugs with handling booleans.
switch (bitfieldExtract(bpmem_alphaTest, 22, 2)) {
case 0u: // AND
if (comp0 && comp1) break; else discard; break;
case 1u: // OR
if (comp0 || comp1) break; else discard; break;
case 2u: // XOR
if (comp0 != comp1) break; else discard; break;
case 3u: // XNOR
if (comp0 == comp1) break; else discard; break;
}
}
if (bpmem_dither) {
// Flipper uses a standard 2x2 Bayer Matrix for 6 bit dithering
// Here the matrix is encoded into the two factor constants
int2 dither = int2(rawpos.xy) & 1;
TevResult.rgb = (TevResult.rgb - (TevResult.rgb >> 6)) + abs(dither.y * 3 - dither.x * 2);
}
// Fog
uint fog_function = bitfieldExtract(bpmem_fogParam3, 21, 3);
if (fog_function != 0u) {
// TODO: This all needs to be converted from float to fixed point
float ze;
if (bitfieldExtract(bpmem_fogParam3, 20, 1) == 0u) {
// perspective
// ze = A/(B - (Zs >> B_SHF)
ze = (cfogf[1].x * 16777216.0) / float(cfogi.y - (zCoord >> cfogi.w));
} else {
// orthographic
// ze = a*Zs (here, no B_SHF)
ze = cfogf[1].x * float(zCoord) / 16777216.0;
}
if (bool(bitfieldExtract(bpmem_fogRangeBase, 10, 1))) {
// x_adjust = sqrt((x-center)^2 + k^2)/k
// ze *= x_adjust
// TODO Instead of this theoretical calculation, we should use the
// coefficient table given in the fog range BP registers!
float x_adjust = (2.0 * (rawpos.x / cfogf[0].y)) - 1.0 - cfogf[0].x;
x_adjust = sqrt(x_adjust * x_adjust + cfogf[0].z * cfogf[0].z) / cfogf[0].z;
ze *= x_adjust;
}
float fog = clamp(ze - cfogf[1].z, 0.0, 1.0);
if (fog_function > 3u) {
switch (fog_function) {
case 4u:
fog = 1.0 - exp2(-8.0 * fog);
break;
case 5u:
fog = 1.0 - exp2(-8.0 * fog * fog);
break;
case 6u:
fog = exp2(-8.0 * (1.0 - fog));
break;
case 7u:
fog = 1.0 - fog;
fog = exp2(-8.0 * fog * fog);
break;
}
}
int ifog = iround(fog * 256.0);
TevResult.rgb = (TevResult.rgb * (256 - ifog) + cfogcolor.rgb * ifog) >> 8;
}
if (bpmem_rgba6_format)
ocol0.rgb = float3(TevResult.rgb >> 2) / 63.0;
else
ocol0.rgb = float3(TevResult.rgb) / 255.0;
if (bpmem_dstalpha != 0u)
ocol0.a = float(bitfieldExtract(bpmem_dstalpha, 0, 8) >> 2) / 63.0;
else
ocol0.a = float(TevResult.a >> 2) / 63.0;
// Dest alpha override (dual source blending)
// Colors will be blended against the alpha from ocol1 and
// the alpha from ocol0 will be written to the framebuffer.
ocol1 = float4(0.0, 0.0, 0.0, float(TevResult.a) / 255.0);
}
int4 getRasColor(State s, StageState ss, float4 colors_0, float4 colors_1) {
// Select Ras for stage
uint ras = bitfieldExtract(ss.order, 7, 3);
if (ras < 2u) { // Lighting Channel 0 or 1
int4 color = iround(((ras == 0u) ? colors_0 : colors_1) * 255.0);
uint swap = bitfieldExtract(ss.ac, 0, 2);
return Swizzle(swap, color);
} else if (ras == 5u) { // Alpha Bumb
return int4(s.AlphaBump, s.AlphaBump, s.AlphaBump, s.AlphaBump);
} else if (ras == 6u) { // Normalzied Alpha Bump
int normalized = s.AlphaBump | s.AlphaBump >> 5;
return int4(normalized, normalized, normalized, normalized);
} else {
return int4(0, 0, 0, 0);
}
}
int4 getKonstColor(State s, StageState ss) {
// Select Konst for stage
// TODO: a switch case might be better here than an dynamically // indexed uniform lookup
uint tevksel = bpmem_tevksel(ss.stage>>1);
if ((ss.stage & 1u) == 0u)
return int4(konstLookup[bitfieldExtract(tevksel, 4, 5)].rgb, konstLookup[bitfieldExtract(tevksel, 9, 5)].a);
else
return int4(konstLookup[bitfieldExtract(tevksel, 14, 5)].rgb, konstLookup[bitfieldExtract(tevksel, 19, 5)].a);
}
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