metaforce/DataSpec/DNAMP3/CMDLMaterials.cpp

339 lines
13 KiB
C++

#include "CMDLMaterials.hpp"
#include "hecl/Blender/Connection.hpp"
using Stream = hecl::blender::PyOutStream;
namespace DataSpec::DNAMP3 {
using Material = MaterialSet::Material;
template <>
void MaterialSet::Material::SectionFactory::Enumerate<BigDNA::Read>(typename Read::StreamT& reader) {
DNAFourCC type;
type.read(reader);
switch (ISection::Type(type.toUint32())) {
case ISection::Type::PASS:
section.reset(new struct SectionPASS);
section->read(reader);
break;
case ISection::Type::CLR:
section.reset(new struct SectionCLR);
section->read(reader);
break;
case ISection::Type::INT:
section.reset(new struct SectionINT);
section->read(reader);
break;
default:
section.reset(nullptr);
break;
}
}
template <>
void MaterialSet::Material::SectionFactory::Enumerate<BigDNA::Write>(typename Write::StreamT& writer) {
if (!section)
return;
writer.writeUBytes((atUint8*)&section->m_type, 4);
section->write(writer);
}
template <>
void MaterialSet::Material::SectionFactory::Enumerate<BigDNA::BinarySize>(typename BinarySize::StreamT& s) {
s += 4;
section->binarySize(s);
}
template <>
void MaterialSet::Material::Enumerate<BigDNA::Read>(typename Read::StreamT& reader) {
header.read(reader);
sections.clear();
do {
sections.emplace_back();
sections.back().read(reader);
} while (sections.back().section);
sections.pop_back();
}
template <>
void MaterialSet::Material::Enumerate<BigDNA::Write>(typename Write::StreamT& writer) {
header.write(writer);
for (const SectionFactory& section : sections)
section.write(writer);
writer.writeUBytes((atUint8*)"END ", 4);
}
template <>
void MaterialSet::Material::Enumerate<BigDNA::BinarySize>(typename BinarySize::StreamT& s) {
header.binarySize(s);
for (const SectionFactory& section : sections)
section.binarySize(s);
s += 4;
}
void MaterialSet::RegisterMaterialProps(Stream& out) {
out << "bpy.types.Material.retro_alpha_test = bpy.props.BoolProperty(name='Retro: Punchthrough Alpha')\n"
"bpy.types.Material.retro_shadow_occluder = bpy.props.BoolProperty(name='Retro: Shadow Occluder')\n"
"bpy.types.Material.retro_lightmapped = bpy.props.BoolProperty(name='Retro: Lightmapped')\n"
"bpy.types.Material.retro_opac = bpy.props.IntProperty(name='Retro: OPAC')\n"
"bpy.types.Material.retro_blod = bpy.props.IntProperty(name='Retro: BLOD')\n"
"bpy.types.Material.retro_bloi = bpy.props.IntProperty(name='Retro: BLOI')\n"
"bpy.types.Material.retro_bnif = bpy.props.IntProperty(name='Retro: BNIF')\n"
"bpy.types.Material.retro_xrbr = bpy.props.IntProperty(name='Retro: XRBR')\n"
"\n";
}
void MaterialSet::ConstructMaterial(Stream& out, const PAKRouter<PAKBridge>& pakRouter, const PAK::Entry& entry,
const Material& material, unsigned groupIdx, unsigned matIdx) {
unsigned i;
out.format(
"new_material = bpy.data.materials.new('MAT_%u_%u')\n"
"new_material.use_shadows = True\n"
"new_material.use_transparent_shadows = True\n"
"new_material.diffuse_color = (1.0,1.0,1.0)\n"
"new_material.use_nodes = True\n"
"new_nodetree = new_material.node_tree\n"
"material_node = new_nodetree.nodes['Material']\n"
"final_node = new_nodetree.nodes['Output']\n"
"\n"
"gridder = hecl.Nodegrid(new_nodetree)\n"
"gridder.place_node(final_node, 3)\n"
"gridder.place_node(material_node, 0)\n"
"material_node.material = new_material\n"
"\n"
"texture_nodes = []\n"
"kcolor_nodes = []\n"
"color_combiner_nodes = []\n"
"alpha_combiner_nodes = []\n"
"tex_links = []\n"
"tev_reg_sockets = [None]*4\n"
"\n",
groupIdx, matIdx);
/* Material Flags */
out.format(
"new_material.retro_alpha_test = %s\n"
"new_material.retro_shadow_occluder = %s\n"
"new_material.diffuse_color = (1, 1, 1, %s)\n",
material.header.flags.alphaTest() ? "True" : "False",
material.header.flags.shadowOccluderMesh() ? "True" : "False",
material.header.flags.shadowOccluderMesh() ? "0" : "1");
/* Blend factors */
if (material.header.flags.alphaBlending())
out << "new_material.blend_method = 'BLEND'\n";
else if (material.header.flags.additiveBlending())
out << "new_material.blend_method = 'ADD'\n";
/* Texmap list */
out << "tex_maps = []\n"
"pnode = None\n"
"anode = None\n"
"rflv_tex_node = None\n";
/* Add PASSes */
i = 0;
unsigned texMapIdx = 0;
unsigned texMtxIdx = 0;
unsigned kColorIdx = 0;
Material::ISection* prevSection = nullptr;
for (const Material::SectionFactory& factory : material.sections) {
factory.section->constructNode(out, pakRouter, entry, prevSection, i++, texMapIdx, texMtxIdx, kColorIdx);
Material::SectionPASS* pass = Material::SectionPASS::castTo(factory.section.get());
if (!pass ||
(pass && Material::SectionPASS::Subtype(pass->subtype.toUint32()) != Material::SectionPASS::Subtype::RFLV))
prevSection = factory.section.get();
}
/* Connect final PASS */
out << "if pnode:\n"
" new_nodetree.links.new(pnode.outputs['Next Color'], final_node.inputs['Color'])\n"
"else:\n"
" new_nodetree.links.new(kcolor_nodes[-1][0].outputs[0], final_node.inputs['Color'])\n"
"if anode:\n"
" new_nodetree.links.new(anode.outputs['Value'], final_node.inputs['Alpha'])\n"
"elif pnode:\n"
" new_nodetree.links.new(pnode.outputs['Next Alpha'], final_node.inputs['Alpha'])\n"
"else:\n"
" new_nodetree.links.new(kcolor_nodes[-1][1].outputs[0], final_node.inputs['Alpha'])\n";
}
void Material::SectionPASS::constructNode(hecl::blender::PyOutStream& out, const PAKRouter<PAKBridge>& pakRouter,
const PAK::Entry& entry, const Material::ISection* prevSection, unsigned idx,
unsigned& texMapIdx, unsigned& texMtxIdx, unsigned& kColorIdx) const {
/* Add Texture nodes */
if (txtrId) {
std::string texName = pakRouter.getBestEntryName(txtrId);
const nod::Node* node;
const PAK::Entry* texEntry = pakRouter.lookupEntry(txtrId, &node);
hecl::ProjectPath txtrPath = pakRouter.getWorking(texEntry);
if (txtrPath.isNone()) {
txtrPath.makeDirChain(false);
PAKEntryReadStream rs = texEntry->beginReadStream(*node);
TXTR::Extract(rs, txtrPath);
}
hecl::SystemString resPath = pakRouter.getResourceRelativePath(entry, txtrId);
hecl::SystemUTF8Conv resPathView(resPath);
out.format(
"if '%s' in bpy.data.textures:\n"
" image = bpy.data.images['%s']\n"
" texture = bpy.data.textures[image.name]\n"
"else:\n"
" image = bpy.data.images.load('''//%s''')\n"
" image.name = '%s'\n"
" texture = bpy.data.textures.new(image.name, 'IMAGE')\n"
" texture.image = image\n"
"tex_maps.append(texture)\n"
"\n",
texName.c_str(), texName.c_str(), resPathView.c_str(), texName.c_str());
if (uvAnim.size()) {
const UVAnimation& uva = uvAnim[0];
DNAMP1::MaterialSet::Material::AddTexture(out, GX::TexGenSrc(uva.unk1 + (uva.unk1 < 2 ? 0 : 2)), texMtxIdx,
texMapIdx++, false);
DNAMP1::MaterialSet::Material::AddTextureAnim(out, uva.anim.mode, texMtxIdx++, uva.anim.vals);
} else
DNAMP1::MaterialSet::Material::AddTexture(out, GX::TexGenSrc(uvSrc + 4), -1, texMapIdx++, false);
}
/* Special case for RFLV (environment UV mask) */
if (Subtype(subtype.toUint32()) == Subtype::RFLV) {
if (txtrId)
out << "rflv_tex_node = texture_nodes[-1]\n";
return;
}
/* Add PASS node */
bool linkRAS = false;
out << "prev_pnode = pnode\n"
"pnode = new_nodetree.nodes.new('ShaderNodeGroup')\n";
switch (Subtype(subtype.toUint32())) {
case Subtype::DIFF: {
out << "pnode.node_tree = bpy.data.node_groups['RetroPassDIFF']\n";
if (txtrId) {
out << "new_material.hecl_lightmap = texture.name\n"
<< "texture.image.use_fake_user = True\n";
}
linkRAS = true;
break;
}
case Subtype::RIML:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassRIML']\n";
if (idx == 0)
linkRAS = true;
break;
case Subtype::BLOL:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassBLOL']\n";
if (idx == 0)
linkRAS = true;
break;
case Subtype::BLOD:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassBLOD']\n";
if (idx == 0)
linkRAS = true;
break;
case Subtype::CLR:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassCLR']\n";
if (idx == 0)
linkRAS = true;
break;
case Subtype::TRAN:
if (flags.TRANInvert())
out << "pnode.node_tree = bpy.data.node_groups['RetroPassTRANInv']\n";
else
out << "pnode.node_tree = bpy.data.node_groups['RetroPassTRAN']\n";
break;
case Subtype::INCA:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassINCA']\n";
break;
case Subtype::RFLV:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassRFLV']\n";
break;
case Subtype::RFLD:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassRFLD']\n"
"if rflv_tex_node:\n"
" new_nodetree.links.new(rflv_tex_node.outputs['Color'], pnode.inputs['Mask Color'])\n"
" new_nodetree.links.new(rflv_tex_node.outputs['Value'], pnode.inputs['Mask Alpha'])\n";
break;
case Subtype::LRLD:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassLRLD']\n";
break;
case Subtype::LURD:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassLURD']\n";
break;
case Subtype::BLOI:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassBLOI']\n";
break;
case Subtype::XRAY:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassXRAY']\n";
break;
case Subtype::TOON:
out << "pnode.node_tree = bpy.data.node_groups['RetroPassTOON']\n";
break;
default:
break;
}
out << "gridder.place_node(pnode, 2)\n";
if (txtrId) {
out << "new_nodetree.links.new(texture_nodes[-1].outputs['Color'], pnode.inputs['Tex Color'])\n"
"new_nodetree.links.new(texture_nodes[-1].outputs['Value'], pnode.inputs['Tex Alpha'])\n";
}
if (linkRAS)
out << "new_nodetree.links.new(material_node.outputs['Color'], pnode.inputs['Prev Color'])\n"
"new_nodetree.links.new(material_node.outputs['Alpha'], pnode.inputs['Prev Alpha'])\n";
else if (prevSection) {
if (prevSection->m_type == ISection::Type::PASS &&
Subtype(static_cast<const SectionPASS*>(prevSection)->subtype.toUint32()) != Subtype::RFLV)
out << "new_nodetree.links.new(prev_pnode.outputs['Next Color'], pnode.inputs['Prev Color'])\n"
"new_nodetree.links.new(prev_pnode.outputs['Next Alpha'], pnode.inputs['Prev Alpha'])\n";
else if (prevSection->m_type == ISection::Type::CLR)
out << "new_nodetree.links.new(kcolor_nodes[-1][0].outputs[0], pnode.inputs['Prev Color'])\n"
"new_nodetree.links.new(kcolor_nodes[-1][1].outputs[0], pnode.inputs['Prev Alpha'])\n";
}
/* Row Break in gridder */
out << "gridder.row_break(2)\n";
}
void Material::SectionCLR::constructNode(hecl::blender::PyOutStream& out, const PAKRouter<PAKBridge>& pakRouter,
const PAK::Entry& entry, const Material::ISection* prevSection, unsigned idx,
unsigned& texMapIdx, unsigned& texMtxIdx, unsigned& kColorIdx) const {
DNAMP1::MaterialSet::Material::AddKcolor(out, color, kColorIdx++);
switch (Subtype(subtype.toUint32())) {
case Subtype::DIFB:
out << "kc_node.label += ' DIFB'\n"
"ka_node.label += ' DIFB'\n";
break;
default:
break;
}
}
void Material::SectionINT::constructNode(hecl::blender::PyOutStream& out, const PAKRouter<PAKBridge>& pakRouter,
const PAK::Entry& entry, const Material::ISection* prevSection, unsigned idx,
unsigned& texMapIdx, unsigned& texMtxIdx, unsigned& kColorIdx) const {
switch (Subtype(subtype.toUint32())) {
case Subtype::OPAC: {
GX::Color clr(value);
out.format(
"anode = new_nodetree.nodes.new('ShaderNodeValue')\n"
"anode.outputs['Value'].default_value = %f\n",
float(clr[3]) / float(0xff));
out << "gridder.place_node(anode, 1)\n";
} break;
case Subtype::BLOD:
out.format("new_material.retro_blod = %d\n", value);
break;
case Subtype::BLOI:
out.format("new_material.retro_bloi = %d\n", value);
break;
case Subtype::BNIF:
out.format("new_material.retro_bnif = %d\n", value);
break;
case Subtype::XRBR:
out.format("new_material.retro_xrbr = %d\n", value);
break;
default:
break;
}
}
} // namespace DataSpec::DNAMP3