metaforce/Runtime/Graphics/Shaders/CFluidPlaneShaderGLSL.cpp

708 lines
24 KiB
C++

#include "CFluidPlaneShader.hpp"
namespace urde
{
static const char* VS =
"#version 330\n"
BOO_GLSL_BINDING_HEAD
"layout(location=0) in vec4 posIn;\n"
"layout(location=1) in vec4 normalIn;\n"
"layout(location=2) in vec4 binormalIn;\n"
"layout(location=3) in vec4 tangentIn;\n"
"layout(location=4) in vec4 colorIn;\n"
"\n"
"UBINDING0 uniform FluidPlaneUniform\n"
"{\n"
" mat4 mv;\n"
" mat4 mvNorm;\n"
" mat4 proj;\n"
" mat4 texMtxs[6];\n"
"};\n"
"\n"
"struct VertToFrag\n"
"{\n"
" vec4 mvPos;\n"
" vec4 mvNorm;\n"
" vec4 mvBinorm;\n"
" vec4 mvTangent;\n"
" vec4 color;\n"
" vec2 uvs[7];\n"
"};\n"
"\n"
"SBINDING(0) out VertToFrag vtf;\n"
"void main()\n"
"{\n"
" vtf.mvPos = mv * vec4(posIn.xyz, 1.0);\n"
" gl_Position = proj * vtf.mvPos;\n"
" vtf.mvNorm = mvNorm * normalIn;\n"
" vtf.mvBinorm = mvNorm * binormalIn;\n"
" vtf.mvTangent = mvNorm * tangentIn;\n"
" vtf.color = colorIn;\n"
" vtf.uvs[0] = (texMtxs[0] * posIn).xy;\n"
" vtf.uvs[1] = (texMtxs[1] * posIn).xy;\n"
" vtf.uvs[2] = (texMtxs[2] * posIn).xy;\n"
"%s" // Additional TCGs here
"}\n";
static const char* FS =
"#version 330\n"
BOO_GLSL_BINDING_HEAD
"\n"
"struct Light\n"
"{\n"
" vec4 pos;\n"
" vec4 dir;\n"
" vec4 color;\n"
" vec4 linAtt;\n"
" vec4 angAtt;\n"
"};\n"
"struct Fog\n" // Reappropriated for indirect texture scaling
"{\n"
" vec4 color;\n"
" float indScale;\n"
" float start;\n"
"};\n"
"\n"
"UBINDING2 uniform LightingUniform\n"
"{\n"
" Light lights[" _XSTR(URDE_MAX_LIGHTS) "];\n"
" vec4 ambient;\n"
" vec4 kColor0;\n"
" vec4 kColor1;\n"
" vec4 kColor2;\n"
" vec4 kColor3;\n"
" Fog fog;\n"
"};\n"
"\n"
"vec4 LightingFunc(vec4 mvPosIn, vec4 mvNormIn)\n"
"{\n"
" vec4 ret = ambient;\n"
" \n"
" for (int i=0 ; i<" _XSTR(URDE_MAX_LIGHTS) " ; ++i)\n"
" {\n"
" vec3 delta = mvPosIn.xyz - lights[i].pos.xyz;\n"
" float dist = length(delta);\n"
" float angDot = clamp(dot(normalize(delta), lights[i].dir.xyz), 0.0, 1.0);\n"
" float att = 1.0 / (lights[i].linAtt[2] * dist * dist +\n"
" lights[i].linAtt[1] * dist +\n"
" lights[i].linAtt[0]);\n"
" float angAtt = lights[i].angAtt[2] * angDot * angDot +\n"
" lights[i].angAtt[1] * angDot +\n"
" lights[i].angAtt[0];\n"
" ret += lights[i].color * clamp(angAtt, 0.0, 1.0) * att * clamp(dot(normalize(-delta), mvNormIn.xyz), 0.0, 1.0);\n"
" }\n"
" \n"
" return clamp(ret, vec4(0.0,0.0,0.0,0.0), vec4(1.0,1.0,1.0,1.0));\n"
"}\n"
"\n"
"struct VertToFrag\n"
"{\n"
" vec4 mvPos;\n"
" vec4 mvNorm;\n"
" vec4 mvBinorm;\n"
" vec4 mvTangent;\n"
" vec4 color;\n"
" vec2 uvs[7];\n"
"};\n"
"\n"
"SBINDING(0) in VertToFrag vtf;\n"
"layout(location=0) out vec4 colorOut;\n"
"%s" // Textures here
"void main()\n"
"{\n"
" vec4 lighting = LightingFunc(vtf.mvPos, normalize(vtf.mvNorm));\n"
"%s" // Combiner expression here
"}\n";
static const char* FSDoor =
"#version 330\n"
BOO_GLSL_BINDING_HEAD
"\n"
"struct Light\n"
"{\n"
" vec4 pos;\n"
" vec4 dir;\n"
" vec4 color;\n"
" vec4 linAtt;\n"
" vec4 angAtt;\n"
"};\n"
"struct Fog\n" // Reappropriated for indirect texture scaling
"{\n"
" vec4 color;\n"
" float indScale;\n"
" float start;\n"
"};\n"
"\n"
"UBINDING2 uniform LightingUniform\n"
"{\n"
" Light lights[" _XSTR(URDE_MAX_LIGHTS) "];\n"
" vec4 ambient;\n"
" vec4 kColor0;\n"
" vec4 kColor1;\n"
" vec4 kColor2;\n"
" vec4 kColor3;\n"
" Fog fog;\n"
"};\n"
"\n"
"struct VertToFrag\n"
"{\n"
" vec4 mvPos;\n"
" vec4 mvNorm;\n"
" vec4 mvBinorm;\n"
" vec4 mvTangent;\n"
" vec4 color;\n"
" vec2 uvs[7];\n"
"};\n"
"\n"
"SBINDING(0) in VertToFrag vtf;\n"
"layout(location=0) out vec4 colorOut;\n"
"%s" // Textures here
"void main()\n"
"{\n"
"%s" // Combiner expression here
"}\n";
static void _BuildShader(std::string& finalVS, std::string& finalFS, int& nextTex, const char* texNames[7],
const SFluidPlaneShaderInfo& info)
{
std::string additionalTCGs;
std::string textures;
std::string combiner;
int nextTCG = 3;
int nextMtx = 4;
int bumpMapUv, envBumpMapUv, envMapUv, lightmapUv;
if (info.m_hasPatternTex1)
{
texNames[nextTex] = "patternTex1";
textures += hecl::Format("TBINDING%d uniform sampler2D patternTex1;\n", nextTex++);
}
if (info.m_hasPatternTex2)
{
texNames[nextTex] = "patternTex2";
textures += hecl::Format("TBINDING%d uniform sampler2D patternTex2;\n", nextTex++);
}
if (info.m_hasColorTex)
{
texNames[nextTex] = "colorTex";
textures += hecl::Format("TBINDING%d uniform sampler2D colorTex;\n", nextTex++);
}
if (info.m_hasBumpMap)
{
texNames[nextTex] = "bumpMap";
textures += hecl::Format("TBINDING%d uniform sampler2D bumpMap;\n", nextTex++);
}
if (info.m_hasEnvMap)
{
texNames[nextTex] = "envMap";
textures += hecl::Format("TBINDING%d uniform sampler2D envMap;\n", nextTex++);
}
if (info.m_hasEnvBumpMap)
{
texNames[nextTex] = "envBumpMap";
textures += hecl::Format("TBINDING%d uniform sampler2D envBumpMap;\n", nextTex++);
}
if (info.m_hasLightmap)
{
texNames[nextTex] = "lightMap";
textures += hecl::Format("TBINDING%d uniform sampler2D lightMap;\n", nextTex++);
}
if (info.m_hasBumpMap)
{
bumpMapUv = nextTCG;
additionalTCGs += hecl::Format(" vtf.uvs[%d] = (texMtxs[0] * posIn).xy;\n", nextTCG++);
}
if (info.m_hasEnvBumpMap)
{
envBumpMapUv = nextTCG;
additionalTCGs += hecl::Format(" vtf.uvs[%d] = (texMtxs[3] * posIn).xy;\n", nextTCG++);
}
if (info.m_hasEnvMap)
{
envMapUv = nextTCG;
additionalTCGs += hecl::Format(" vtf.uvs[%d] = (texMtxs[%d] * posIn).xy;\n", nextTCG++, nextMtx++);
}
if (info.m_hasLightmap)
{
lightmapUv = nextTCG;
additionalTCGs += hecl::Format(" vtf.uvs[%d] = (texMtxs[%d] * posIn).xy;\n", nextTCG++, nextMtx++);
}
switch (info.m_type)
{
case CFluidPlane::EFluidType::NormalWater:
case CFluidPlane::EFluidType::PhazonFluid:
case CFluidPlane::EFluidType::Four:
if (info.m_hasLightmap)
{
combiner += hecl::Format(" vec4 lightMapTexel = texture(lightMap, vtf.uvs[%d]);\n", lightmapUv);
// 0: Tex4TCG, Tex4, doubleLightmapBlend ? NULL : GX_COLOR1A1
// ZERO, TEX, KONST, doubleLightmapBlend ? ZERO : RAS
// Output reg 2
// KColor 2
if (info.m_doubleLightmapBlend)
{
// 1: Tex4TCG2, Tex4, GX_COLOR1A1
// C2, TEX, KONST, RAS
// Output reg 2
// KColor 3
// Tex * K2 + Lighting
combiner += " lighting += mix(lightMapTexel * kColor2, lightMapTexel, kColor3);\n";
}
else
{
// mix(Tex * K2, Tex, K3) + Lighting
combiner += " lighting += lightMapTexel * kColor2;\n";
}
}
// Next: Tex0TCG, Tex0, GX_COLOR1A1
// ZERO, TEX, KONST, RAS
// Output reg prev
// KColor 0
// Next: Tex1TCG, Tex1, GX_COLOR0A0
// ZERO, TEX, PREV, RAS
// Output reg prev
// Next: Tex2TCG, Tex2, GX_COLOR1A1
// ZERO, TEX, hasTex4 ? C2 : RAS, PREV
// Output reg prev
// (Tex0 * kColor0 + Lighting) * Tex1 + VertColor + Tex2 * Lighting
if (info.m_hasPatternTex2)
{
if (info.m_hasPatternTex1)
combiner += " colorOut = (texture(patternTex1, vtf.uvs[0]) * kColor0 + lighting) *\n"
" texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
else
combiner += " colorOut = lighting * texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
}
else
{
combiner += " colorOut = vtf.color;\n";
}
if (info.m_hasColorTex && !info.m_hasEnvMap && info.m_hasEnvBumpMap)
{
// Make previous stage indirect, mtx0
combiner += hecl::Format(" vec2 indUvs = (texture(envBumpMap, vtf.uvs[%d]).ra - vec2(0.5, 0.5)) *\n"
" vec2(fog.indScale, -fog.indScale);", envBumpMapUv);
combiner += " colorOut += texture(colorTex, indUvs + vtf.uvs[2]) * lighting;\n";
}
else if (info.m_hasEnvMap)
{
// Next: envTCG, envTex, NULL
// PREV, TEX, KONST, ZERO
// Output reg prev
// KColor 1
// Make previous stage indirect, mtx0
if (info.m_hasColorTex)
combiner += " colorOut += texture(colorTex, vtf.uvs[2]) * lighting;\n";
combiner += hecl::Format(" vec2 indUvs = (texture(envBumpMap, vtf.uvs[%d]).ra - vec2(0.5, 0.5)) *\n"
" vec2(fog.indScale, -fog.indScale);", envBumpMapUv);
combiner += hecl::Format(" colorOut = mix(colorOut, texture(envMap, indUvs + vtf.uvs[%d]), kColor1);\n",
envMapUv);
}
else if (info.m_hasColorTex)
{
combiner += " colorOut += texture(colorTex, vtf.uvs[2]) * lighting;\n";
}
break;
case CFluidPlane::EFluidType::PoisonWater:
if (info.m_hasLightmap)
{
combiner += hecl::Format(" vec4 lightMapTexel = texture(lightMap, vtf.uvs[%d]);\n", lightmapUv);
// 0: Tex4TCG, Tex4, doubleLightmapBlend ? NULL : GX_COLOR1A1
// ZERO, TEX, KONST, doubleLightmapBlend ? ZERO : RAS
// Output reg 2
// KColor 2
if (info.m_doubleLightmapBlend)
{
// 1: Tex4TCG2, Tex4, GX_COLOR1A1
// C2, TEX, KONST, RAS
// Output reg 2
// KColor 3
// Tex * K2 + Lighting
combiner += " lighting += mix(lightMapTexel * kColor2, lightMapTexel, kColor3);\n";
}
else
{
// mix(Tex * K2, Tex, K3) + Lighting
combiner += " lighting += lightMapTexel * kColor2;\n";
}
}
// Next: Tex0TCG, Tex0, GX_COLOR1A1
// ZERO, TEX, KONST, RAS
// Output reg prev
// KColor 0
// Next: Tex1TCG, Tex1, GX_COLOR0A0
// ZERO, TEX, PREV, RAS
// Output reg prev
// Next: Tex2TCG, Tex2, GX_COLOR1A1
// ZERO, TEX, hasTex4 ? C2 : RAS, PREV
// Output reg prev
// (Tex0 * kColor0 + Lighting) * Tex1 + VertColor + Tex2 * Lighting
if (info.m_hasPatternTex2)
{
if (info.m_hasPatternTex1)
combiner += " colorOut = (texture(patternTex1, vtf.uvs[0]) * kColor0 + lighting) *\n"
" texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
else
combiner += " colorOut = lighting * texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
}
else
{
combiner += " colorOut = vtf.color;\n";
}
if (info.m_hasColorTex)
{
if (info.m_hasEnvBumpMap)
{
// Make previous stage indirect, mtx0
combiner += hecl::Format(" vec2 indUvs = (texture(envBumpMap, vtf.uvs[%d]).ra - vec2(0.5, 0.5)) *\n"
" vec2(fog.indScale, -fog.indScale);", envBumpMapUv);
combiner += " colorOut += texture(colorTex, indUvs + vtf.uvs[2]) * lighting;\n";
}
else
{
combiner += " colorOut += texture(colorTex, vtf.uvs[2]) * lighting;\n";
}
}
break;
case CFluidPlane::EFluidType::Lava:
// 0: Tex0TCG, Tex0, GX_COLOR0A0
// ZERO, TEX, KONST, RAS
// Output reg prev
// KColor 0
// 1: Tex1TCG, Tex1, GX_COLOR0A0
// ZERO, TEX, PREV, RAS
// Output reg prev
// 2: Tex2TCG, Tex2, NULL
// ZERO, TEX, ONE, PREV
// Output reg prev
// (Tex0 * kColor0 + VertColor) * Tex1 + VertColor + Tex2
if (info.m_hasPatternTex2)
{
if (info.m_hasPatternTex1)
combiner += " colorOut = (texture(patternTex1, vtf.uvs[0]) * kColor0 + vtf.color) *\n"
" texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
else
combiner += " colorOut = vtf.color * texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
}
else
{
combiner += " colorOut = vtf.color;\n";
}
if (info.m_hasColorTex)
combiner += " colorOut += texture(colorTex, vtf.uvs[2]);\n";
if (info.m_hasBumpMap)
{
// 3: bumpMapTCG, bumpMap, NULL
// ZERO, TEX, ONE, HALF
// Output reg 0, no clamp, no bias
// 4: bumpMapTCG2, bumpMap, NULL
// ZERO, TEX, ONE, C0
// Output reg 0, subtract, clamp, no bias
combiner += " vec3 lightVec = lights[3].pos.xyz - vtf.mvPos.xyz;\n"
" float lx = dot(vtf.mvTangent, lightVec);\n"
" float ly = dot(vtf.mvBinorm, lightVec);\n";
combiner += hecl::Format(" vec4 emboss1 = texture(bumpMap, vtf.uvs[%d]) + vec4(0.5);\n"
" vec4 emboss2 = texture(bumpMap, vtf.uvs[%d] + vec2(lx, ly));\n",
bumpMapUv, bumpMapUv);
// 5: NULL, NULL, NULL
// ZERO, PREV, C0, ZERO
// Output reg prev, scale 2, clamp
// colorOut * clamp(emboss1 + 0.5 - emboss2, 0.0, 1.0) * 2.0
combiner += "colorOut *= clamp((emboss1 + vec4(0.5) - emboss2) * vec4(2.0), vec4(0.0), vec4(1.0));\n";
}
break;
case CFluidPlane::EFluidType::ThickLava:
// 0: Tex0TCG, Tex0, GX_COLOR0A0
// ZERO, TEX, KONST, RAS
// Output reg prev
// KColor 0
// 1: Tex1TCG, Tex1, GX_COLOR0A0
// ZERO, TEX, PREV, RAS
// Output reg prev
// 2: Tex2TCG, Tex2, NULL
// ZERO, TEX, ONE, PREV
// Output reg prev
// (Tex0 * kColor0 + VertColor) * Tex1 + VertColor + Tex2
if (info.m_hasPatternTex2)
{
if (info.m_hasPatternTex1)
combiner += " colorOut = (texture(patternTex1, vtf.uvs[0]) * kColor0 + vtf.color) *\n"
" texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
else
combiner += " colorOut = vtf.color * texture(patternTex2, vtf.uvs[1]) + vtf.color;\n";
}
else
{
combiner += " colorOut = vtf.color;\n";
}
if (info.m_hasColorTex)
combiner += " colorOut += texture(colorTex, vtf.uvs[2]);\n";
if (info.m_hasBumpMap)
{
// 3: bumpMapTCG, bumpMap, NULL
// ZERO, TEX, PREV, ZERO
// Output reg prev, scale 2
combiner += hecl::Format(" vec4 emboss1 = texture(bumpMap, vtf.uvs[%d]) + vec4(0.5);\n", bumpMapUv);
combiner += "colorOut *= emboss1 * vec4(2.0);\n";
}
break;
}
combiner += " colorOut.a = kColor0.a;\n";
char *finalVSs, *finalFSs;
asprintf(&finalVSs, VS, additionalTCGs.c_str());
asprintf(&finalFSs, FS, textures.c_str(), combiner.c_str());
finalVS = finalVSs;
finalFS = finalFSs;
free(finalVSs);
free(finalFSs);
}
static void _BuildShader(std::string& finalVS, std::string& finalFS, int& nextTex, const char* texNames[3],
const SFluidPlaneDoorShaderInfo& info)
{
std::string additionalTCGs;
std::string textures;
std::string combiner;
if (info.m_hasPatternTex1)
{
texNames[nextTex] = "patternTex1";
textures += hecl::Format("TBINDING%d uniform sampler2D patternTex1;\n", nextTex++);
}
if (info.m_hasPatternTex2)
{
texNames[nextTex] = "patternTex2";
textures += hecl::Format("TBINDING%d uniform sampler2D patternTex2;\n", nextTex++);
}
if (info.m_hasColorTex)
{
texNames[nextTex] = "colorTex";
textures += hecl::Format("TBINDING%d uniform sampler2D colorTex;\n", nextTex++);
}
// Tex0 * kColor0 * Tex1 + Tex2
if (info.m_hasPatternTex1 && info.m_hasPatternTex2)
{
combiner += " colorOut = texture(patternTex1, vtf.uvs[0]) * kColor0 *\n"
" texture(patternTex2, vtf.uvs[1]);\n";
}
else
{
combiner += " colorOut = vec4(0.0);\n";
}
if (info.m_hasColorTex)
{
combiner += " colorOut += texture(colorTex, vtf.uvs[2]);\n";
}
combiner += " colorOut.a = kColor0.a;\n";
char *finalVSs, *finalFSs;
asprintf(&finalVSs, VS, additionalTCGs.c_str());
asprintf(&finalFSs, FSDoor, textures.c_str(), combiner.c_str());
finalVS = finalVSs;
finalFS = finalFSs;
free(finalVSs);
free(finalFSs);
}
boo::ObjToken<boo::IShaderPipeline>
CFluidPlaneShader::BuildShader(boo::GLDataFactory::Context& ctx, const SFluidPlaneShaderInfo& info)
{
int nextTex = 0;
const char* texNames[7] = {};
std::string finalVS, finalFS;
_BuildShader(finalVS, finalFS, nextTex, texNames, info);
const char* uniNames[] = {"FluidPlaneUniform", "FluidPlaneUniform", "LightingUniform"};
return ctx.newShaderPipeline(finalVS.c_str(), finalFS.c_str(), size_t(nextTex), texNames, 3, uniNames,
info.m_additive ? boo::BlendFactor::One : boo::BlendFactor::SrcAlpha,
info.m_additive ? boo::BlendFactor::One : boo::BlendFactor::InvSrcAlpha,
boo::Primitive::TriStrips, boo::ZTest::LEqual, false, true, false,
boo::CullMode::None);
}
boo::ObjToken<boo::IShaderPipeline>
CFluidPlaneShader::BuildShader(boo::GLDataFactory::Context& ctx, const SFluidPlaneDoorShaderInfo& info)
{
int nextTex = 0;
const char* texNames[3] = {};
std::string finalVS, finalFS;
_BuildShader(finalVS, finalFS, nextTex, texNames, info);
const char* uniNames[] = {"FluidPlaneUniform"};
return ctx.newShaderPipeline(finalVS.c_str(), finalFS.c_str(), size_t(nextTex), texNames, 1, uniNames,
boo::BlendFactor::SrcAlpha, boo::BlendFactor::InvSrcAlpha,
boo::Primitive::TriStrips, boo::ZTest::LEqual, false, true, false,
boo::CullMode::None);
}
#if BOO_HAS_VULKAN
static boo::ObjToken<boo::IVertexFormat> s_vtxFmt;
boo::ObjToken<boo::IShaderPipeline>
CFluidPlaneShader::BuildShader(boo::VulkanDataFactory::Context& ctx, const SFluidPlaneShaderInfo& info)
{
if (!s_vtxFmt)
{
boo::VertexElementDescriptor elements[] =
{
{nullptr, nullptr, boo::VertexSemantic::Position4},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 0},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 1},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 2},
{nullptr, nullptr, boo::VertexSemantic::Color}
};
s_vtxFmt = ctx.newVertexFormat(5, elements);
}
int nextTex = 0;
const char* texNames[7] = {};
std::string finalVS, finalFS;
_BuildShader(finalVS, finalFS, nextTex, texNames, info);
return ctx.newShaderPipeline(finalVS.c_str(), finalFS.c_str(), s_vtxFmt,
info.m_additive ? boo::BlendFactor::One : boo::BlendFactor::SrcAlpha,
info.m_additive ? boo::BlendFactor::One : boo::BlendFactor::InvSrcAlpha,
boo::Primitive::TriStrips, boo::ZTest::LEqual, false, true, false,
boo::CullMode::None);
}
boo::ObjToken<boo::IShaderPipeline>
CFluidPlaneShader::BuildShader(boo::VulkanDataFactory::Context& ctx, const SFluidPlaneDoorShaderInfo& info)
{
if (!s_vtxFmt)
{
boo::VertexElementDescriptor elements[] =
{
{nullptr, nullptr, boo::VertexSemantic::Position4},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 0},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 1},
{nullptr, nullptr, boo::VertexSemantic::Normal4, 2},
{nullptr, nullptr, boo::VertexSemantic::Color}
};
s_vtxFmt = ctx.newVertexFormat(5, elements);
}
int nextTex = 0;
const char* texNames[3] = {};
std::string finalVS, finalFS;
_BuildShader(finalVS, finalFS, nextTex, texNames, info);
return ctx.newShaderPipeline(finalVS.c_str(), finalFS.c_str(), s_vtxFmt,
boo::BlendFactor::SrcAlpha, boo::BlendFactor::InvSrcAlpha,
boo::Primitive::TriStrips, boo::ZTest::LEqual, false, true, false,
boo::CullMode::None);
}
#endif
boo::ObjToken<boo::IShaderDataBinding>
CFluidPlaneShader::BuildBinding(boo::GLDataFactory::Context& ctx,
const boo::ObjToken<boo::IShaderPipeline>& pipeline, bool door)
{
boo::VertexElementDescriptor elements[] =
{
{m_vbo.get(), nullptr, boo::VertexSemantic::Position4},
{m_vbo.get(), nullptr, boo::VertexSemantic::Normal4, 0},
{m_vbo.get(), nullptr, boo::VertexSemantic::Normal4, 1},
{m_vbo.get(), nullptr, boo::VertexSemantic::Normal4, 2},
{m_vbo.get(), nullptr, boo::VertexSemantic::Color}
};
boo::ObjToken<boo::IVertexFormat> vtxFmt = ctx.newVertexFormat(5, elements);
boo::ObjToken<boo::IGraphicsBuffer> ubufs[] = { m_uniBuf.get(), m_uniBuf.get(), m_uniBuf.get() };
boo::PipelineStage ubufStages[] = { boo::PipelineStage::Vertex, boo::PipelineStage::Vertex,
boo::PipelineStage::Fragment };
size_t ubufOffs[] = {0, 0, 768};
size_t ubufSizes[] = {768, 768, 256};
size_t texCount = 0;
boo::ObjToken<boo::ITexture> texs[7];
if (m_patternTex1)
texs[texCount++] = (*m_patternTex1)->GetBooTexture();
if (m_patternTex2)
texs[texCount++] = (*m_patternTex2)->GetBooTexture();
if (m_colorTex)
texs[texCount++] = (*m_colorTex)->GetBooTexture();
if (m_bumpMap)
texs[texCount++] = (*m_bumpMap)->GetBooTexture();
if (m_envMap)
texs[texCount++] = (*m_envMap)->GetBooTexture();
if (m_envBumpMap)
texs[texCount++] = (*m_envBumpMap)->GetBooTexture();
if (m_lightmap)
texs[texCount++] = (*m_lightmap)->GetBooTexture();
return ctx.newShaderDataBinding(pipeline, vtxFmt, m_vbo.get(), nullptr, nullptr, 3,
ubufs, ubufStages, ubufOffs, ubufSizes, texCount, texs, nullptr, nullptr);
}
#if BOO_HAS_VULKAN
boo::ObjToken<boo::IShaderDataBinding>
CFluidPlaneShader::BuildBinding(boo::VulkanDataFactory::Context& ctx,
const boo::ObjToken<boo::IShaderPipeline>& pipeline, bool door)
{
boo::ObjToken<boo::IGraphicsBuffer> ubufs[] = { m_uniBuf.get(), m_uniBuf.get(), m_uniBuf.get() };
boo::PipelineStage ubufStages[] = { boo::PipelineStage::Vertex, boo::PipelineStage::Vertex,
boo::PipelineStage::Fragment };
size_t ubufOffs[] = {0, 0, 768};
size_t ubufSizes[] = {768, 768, 256};
size_t texCount = 0;
boo::ObjToken<boo::ITexture> texs[7] = {};
if (m_patternTex1)
texs[texCount++] = (*m_patternTex1)->GetBooTexture();
if (m_patternTex2)
texs[texCount++] = (*m_patternTex2)->GetBooTexture();
if (m_colorTex)
texs[texCount++] = (*m_colorTex)->GetBooTexture();
if (m_bumpMap)
texs[texCount++] = (*m_bumpMap)->GetBooTexture();
if (m_envMap)
texs[texCount++] = (*m_envMap)->GetBooTexture();
if (m_envBumpMap)
texs[texCount++] = (*m_envBumpMap)->GetBooTexture();
if (m_lightmap)
texs[texCount++] = (*m_lightmap)->GetBooTexture();
return ctx.newShaderDataBinding(pipeline, s_vtxFmt, m_vbo.get(), nullptr, nullptr, 3,
ubufs, ubufStages, ubufOffs, ubufSizes, texCount, texs, nullptr, nullptr);
}
#endif
}