Offline::OfflineRenderDeviceCaps LoadPlatformConfig(std::string const & platform)
{
ResIdentifierPtr plat = ResLoader::Instance().Open("PlatConf/" + platform + ".plat");
KlayGE::XMLDocument doc;
XMLNodePtr root = doc.Parse(plat);
Offline::OfflineRenderDeviceCaps caps;
caps.platform = RetrieveAttrValue(root, "name", "");
caps.major_version = static_cast<uint8_t>(RetrieveAttrValue(root, "major_version", 0));
caps.minor_version = static_cast<uint8_t>(RetrieveAttrValue(root, "minor_version", 0));
caps.requires_flipping = RetrieveNodeValue(root, "requires_flipping", 0) ? true : false;
std::string const fourcc_str = RetrieveNodeValue(root, "native_shader_fourcc", "");
caps.native_shader_fourcc = (fourcc_str[0] << 0) + (fourcc_str[1] << 8) + (fourcc_str[2] << 16) + (fourcc_str[3] << 24);
caps.native_shader_version = RetrieveNodeValue(root, "native_shader_version", 0);
XMLNodePtr max_shader_model_node = root->FirstNode("max_shader_model");
caps.max_shader_model = ShaderModel(static_cast<uint8_t>(RetrieveAttrValue(max_shader_model_node, "major", 0)),
static_cast<uint8_t>(RetrieveAttrValue(max_shader_model_node, "minor", 0)));
caps.max_texture_depth = RetrieveNodeValue(root, "max_texture_depth", 0);
caps.max_texture_array_length = RetrieveNodeValue(root, "max_texture_array_length", 0);
caps.max_pixel_texture_units = static_cast<uint8_t>(RetrieveNodeValue(root, "max_pixel_texture_units", 0));
caps.max_simultaneous_rts = static_cast<uint8_t>(RetrieveNodeValue(root, "max_simultaneous_rts", 0));
caps.standard_derivatives_support = RetrieveNodeValue(root, "standard_derivatives_support", 0) ? true : false;
caps.shader_texture_lod_support = RetrieveNodeValue(root, "shader_texture_lod_support", 0) ? true : false;
caps.fp_color_support = RetrieveNodeValue(root, "fp_color_support", 0) ? true : false;
caps.pack_to_rgba_required = RetrieveNodeValue(root, "pack_to_rgba_required", 0) ? true : false;
caps.gs_support = RetrieveNodeValue(root, "gs_support", 0) ? true : false;
caps.cs_support = RetrieveNodeValue(root, "cs_support", 0) ? true : false;
caps.hs_support = RetrieveNodeValue(root, "hs_support", 0) ? true : false;
caps.ds_support = RetrieveNodeValue(root, "ds_support", 0) ? true : false;
caps.bc4_support = RetrieveNodeValue(root, "bc4_support", 0) ? true : false;
caps.bc5_support = RetrieveNodeValue(root, "bc5_support", 0) ? true : false;
caps.frag_depth_support = RetrieveNodeValue(root, "frag_depth_support", 0) ? true : false;
caps.ubo_support = RetrieveNodeValue(root, "ubo_support", 0) ? true : false;
return caps;
}
void PackJTML(std::string const & jtml_name)
{
Timer timer;
ResIdentifierPtr jtml = ResLoader::Instance().Open(jtml_name);
KlayGE::XMLDocument doc;
XMLNodePtr root = doc.Parse(jtml);
uint32_t n = root->AttribInt("num_tiles", 2048);
uint32_t num_tiles = 1;
while (num_tiles * 2 <= n)
{
num_tiles *= 2;
}
uint32_t tile_size = root->AttribInt("tile_size", 128);
std::string fmt_str = root->AttribString("format", "");
ElementFormat format = EF_ARGB8;
if ("ARGB8" == fmt_str)
{
format = EF_ARGB8;
}
else if ("ABGR8" == fmt_str)
{
format = EF_ABGR8;
}
uint32_t pixel_size = NumFormatBytes(format);
JudaTexturePtr juda_tex = MakeSharedPtr<JudaTexture>(num_tiles, tile_size, format);
uint32_t level = juda_tex->TreeLevels() - 1;
RenderFactory& rf = Context::Instance().RenderFactoryInstance();
uint32_t attr = 0;
for (XMLNodePtr node = root->FirstNode("image"); node; node = node->NextSibling("image"), ++ attr)
{
timer.restart();
std::string name = node->AttribString("name", "");
int32_t x = node->AttribInt("x", 0);
int32_t y = node->AttribInt("y", 0);
std::string address_u_str = node->AttribString("address_u", "wrap");
std::string address_v_str = node->AttribString("address_v", "wrap");
Color border_clr;
border_clr.r() = node->AttribFloat("border_r", 0.0f);
border_clr.g() = node->AttribFloat("border_g", 0.0f);
border_clr.b() = node->AttribFloat("border_b", 0.0f);
border_clr.a() = node->AttribFloat("border_a", 0.0f);
uint32_t border_clr_u8;
switch (format)
{
case EF_ARGB8:
border_clr_u8 = border_clr.ARGB();
break;
case EF_ABGR8:
border_clr_u8 = border_clr.ABGR();
break;
default:
border_clr_u8 = 0;
break;
}
TexAddressingMode addr_u, addr_v;
std::shared_ptr<address_calculator> calc_u, calc_v;
if ("mirror" == address_u_str)
{
addr_u = TAM_Mirror;
calc_u = address_calculators[TAM_Mirror];
}
else if ("clamp" == address_u_str)
{
addr_u = TAM_Clamp;
calc_u = address_calculators[TAM_Clamp];
}
else if ("border" == address_u_str)
{
addr_u = TAM_Border;
calc_u = address_calculators[TAM_Border];
}
else
{
addr_u = TAM_Wrap;
calc_u = address_calculators[TAM_Wrap];
}
if ("mirror" == address_v_str)
{
addr_v = TAM_Mirror;
calc_v = address_calculators[TAM_Mirror];
}
else if ("clamp" == address_v_str)
{
addr_v = TAM_Clamp;
calc_v = address_calculators[TAM_Clamp];
}
else if ("border" == address_v_str)
{
addr_v = TAM_Border;
calc_v = address_calculators[TAM_Border];
}
else
{
addr_v = TAM_Wrap;
calc_v = address_calculators[TAM_Wrap];
}
cout << "Processing " << name << "... ";
TexturePtr src_texture = SyncLoadTexture(name, EAH_CPU_Read | EAH_CPU_Write);
if (src_texture->Type() != Texture::TT_2D)
{
cout << "Texture " << name << "is not 2D texture. Skipped." << endl;
continue;
}
uint32_t in_width = src_texture->Width(0);
uint32_t in_height = src_texture->Height(0);
TexturePtr texture = rf.MakeTexture2D(in_width, in_height, 1, 1, format, 1, 0, EAH_CPU_Read | EAH_CPU_Write);
src_texture->CopyToTexture(*texture);
Texture::Mapper mapper(*texture, 0, 0, TMA_Read_Only, 0, 0, in_width, in_height);
uint8_t const * in_data_p = mapper.Pointer<uint8_t>();
int32_t in_num_tiles_x = std::min((in_width + tile_size - 1) / tile_size, num_tiles);
int32_t in_num_tiles_y = std::min((in_height + tile_size - 1) / tile_size, num_tiles);
int32_t beg_tile_x = 0;
int32_t end_tile_x = std::min(static_cast<int32_t>(x + in_num_tiles_x), static_cast<int32_t>(num_tiles)) - x;
int32_t beg_tile_y = 0;
int32_t end_tile_y = std::min(static_cast<int32_t>(y + in_num_tiles_y), static_cast<int32_t>(num_tiles)) - y;
juda_tex->AddImageEntry(name, x, y, in_num_tiles_x, in_num_tiles_y, addr_u, addr_v, border_clr);
std::vector<std::vector<uint8_t>> tiles;
std::vector<uint32_t> tile_ids;
std::vector<uint32_t> tile_attrs;
for (int32_t by = beg_tile_y; by < end_tile_y; ++ by)
{
tiles.clear();
tile_ids.clear();
tile_attrs.clear();
for (int32_t bx = beg_tile_x; bx < end_tile_x; ++ bx)
{
uint32_t xindex = bx - beg_tile_x;
tiles.push_back(std::vector<uint8_t>(tile_size * tile_size * pixel_size, 0));
tile_ids.push_back(juda_tex->EncodeTileID(level, bx + x, by + y));
tile_attrs.push_back(attr);
for (size_t dy = 0; dy < tile_size; ++ dy)
{
int32_t tex_y = (*calc_v)(static_cast<int32_t>(by * tile_size + dy), in_height);
if (tex_y >= 0)
{
for (size_t dx = 0; dx < tile_size; ++ dx)
{
int32_t tex_x = (*calc_u)(static_cast<int32_t>(bx * tile_size + dx), in_width);
if (tex_x >= 0)
{
std::memcpy(&tiles[xindex][(dy * tile_size + dx) * pixel_size],
&in_data_p[tex_y * mapper.RowPitch() + tex_x * pixel_size],
pixel_size);
}
else
{
std::memcpy(&tiles[xindex][(dy * tile_size + dx) * pixel_size],
&border_clr_u8,
pixel_size);
}
}
}
else
{
for (size_t dx = 0; dx < tile_size; ++ dx)
{
std::memcpy(&tiles[xindex][(dy * tile_size + dx) * pixel_size],
&border_clr_u8,
pixel_size);
}
}
}
}
juda_tex->CommitTiles(tiles, tile_ids, tile_attrs);
}
cout << "Takes " << timer.elapsed() << "s" << endl;
}
cout << "Total tiles: " << ((1UL << (juda_tex->TreeLevels() * 2)) - 1) / (4 - 1) << endl;
cout << "Non empty tiles: " << juda_tex->NumNonEmptyNodes() << endl;
cout << "Tree depth: " << juda_tex->TreeLevels() << endl;
std::string base_name = jtml_name.substr(0, jtml_name.find_last_of('.'));
cout << "Saving... ";
timer.restart();
SaveJudaTexture(juda_tex, base_name + ".jdt");
cout << "Takes " << timer.elapsed() << "s" << endl << endl;
}
void SaveRenderMaterial(RenderMaterialPtr const & mtl, std::string const & mtlml_name)
{
KlayGE::XMLDocument doc;
XMLNodePtr root = doc.AllocNode(XNT_Element, "material");
doc.RootNode(root);
{
XMLNodePtr albedo_node = doc.AllocNode(XNT_Element, "albedo");
std::string color_str = boost::lexical_cast<std::string>(mtl->albedo.x())
+ ' ' + boost::lexical_cast<std::string>(mtl->albedo.y())
+ ' ' + boost::lexical_cast<std::string>(mtl->albedo.z())
+ ' ' + boost::lexical_cast<std::string>(mtl->albedo.w());
albedo_node->AppendAttrib(doc.AllocAttribString("color", color_str));
if (!mtl->tex_names[RenderMaterial::TS_Albedo].empty())
{
albedo_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Albedo]));
}
root->AppendNode(albedo_node);
}
if ((mtl->metalness > 0) || !mtl->tex_names[RenderMaterial::TS_Metalness].empty())
{
XMLNodePtr metalness_node = doc.AllocNode(XNT_Element, "metalness");
if (mtl->metalness > 0)
{
metalness_node->AppendAttrib(doc.AllocAttribFloat("value", mtl->metalness));
}
if (!mtl->tex_names[RenderMaterial::TS_Metalness].empty())
{
metalness_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Metalness]));
}
root->AppendNode(metalness_node);
}
if ((mtl->glossiness > 0) || !mtl->tex_names[RenderMaterial::TS_Glossiness].empty())
{
XMLNodePtr glossiness_node = doc.AllocNode(XNT_Element, "glossiness");
if (mtl->glossiness > 0)
{
glossiness_node->AppendAttrib(doc.AllocAttribFloat("value", mtl->glossiness));
}
if (!mtl->tex_names[RenderMaterial::TS_Glossiness].empty())
{
glossiness_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Glossiness]));
}
root->AppendNode(glossiness_node);
}
if ((mtl->emissive.x() > 0) || (mtl->emissive.y() > 0) || (mtl->emissive.z() > 0)
|| (!mtl->tex_names[RenderMaterial::TS_Emissive].empty()))
{
XMLNodePtr emissive_node = doc.AllocNode(XNT_Element, "emissive");
if ((mtl->emissive.x() > 0) || (mtl->emissive.y() > 0) || (mtl->emissive.z() > 0))
{
std::string color_str = boost::lexical_cast<std::string>(mtl->emissive.x())
+ ' ' + boost::lexical_cast<std::string>(mtl->emissive.y())
+ ' ' + boost::lexical_cast<std::string>(mtl->emissive.z());
emissive_node->AppendAttrib(doc.AllocAttribString("color", color_str));
}
if (!mtl->tex_names[RenderMaterial::TS_Emissive].empty())
{
emissive_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Emissive]));
}
root->AppendNode(emissive_node);
}
if (!mtl->tex_names[RenderMaterial::TS_Normal].empty())
{
XMLNodePtr normal_node = doc.AllocNode(XNT_Element, "normal");
normal_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Normal]));
root->AppendNode(normal_node);
}
if (!mtl->tex_names[RenderMaterial::TS_Height].empty())
{
XMLNodePtr height_node = doc.AllocNode(XNT_Element, "height");
height_node->AppendAttrib(doc.AllocAttribString("texture", mtl->tex_names[RenderMaterial::TS_Height]));
height_node->AppendAttrib(doc.AllocAttribFloat("offset", mtl->height_offset_scale.x()));
height_node->AppendAttrib(doc.AllocAttribFloat("scale", mtl->height_offset_scale.y()));
root->AppendNode(height_node);
}
if (mtl->detail_mode != RenderMaterial::SDM_Parallax)
{
XMLNodePtr detail_node = doc.AllocNode(XNT_Element, "detail");
std::string detail_mode_str;
switch (mtl->detail_mode)
{
case RenderMaterial::SDM_FlatTessellation:
detail_mode_str = "Flat Tessellation";
break;
case RenderMaterial::SDM_SmoothTessellation:
detail_mode_str = "Smooth Tessellation";
break;
default:
KFL_UNREACHABLE("Invalid surface detail mode");
}
detail_node->AppendAttrib(doc.AllocAttribString("mode", detail_mode_str));
{
XMLNodePtr tess_node = doc.AllocNode(XNT_Element, "tess");
tess_node->AppendAttrib(doc.AllocAttribFloat("edge_hint", mtl->tess_factors.x()));
tess_node->AppendAttrib(doc.AllocAttribFloat("inside_hint", mtl->tess_factors.y()));
tess_node->AppendAttrib(doc.AllocAttribFloat("min", mtl->tess_factors.z()));
tess_node->AppendAttrib(doc.AllocAttribFloat("max", mtl->tess_factors.w()));
detail_node->AppendNode(tess_node);
}
root->AppendNode(detail_node);
}
if (mtl->transparent)
{
XMLNodePtr transparent_node = doc.AllocNode(XNT_Element, "transparent");
transparent_node->AppendAttrib(doc.AllocAttribString("value", "1"));
root->AppendNode(transparent_node);
}
if (mtl->alpha_test > 0)
{
XMLNodePtr alpha_test_node = doc.AllocNode(XNT_Element, "alpha_test");
alpha_test_node->AppendAttrib(doc.AllocAttribFloat("value", mtl->alpha_test));
root->AppendNode(alpha_test_node);
}
if (mtl->sss)
{
XMLNodePtr sss_node = doc.AllocNode(XNT_Element, "sss");
sss_node->AppendAttrib(doc.AllocAttribString("value", "1"));
root->AppendNode(sss_node);
}
if (mtl->two_sided)
{
XMLNodePtr two_sided_node = doc.AllocNode(XNT_Element, "two_sided");
two_sided_node->AppendAttrib(doc.AllocAttribString("value", "1"));
root->AppendNode(two_sided_node);
}
std::ofstream ofs(mtlml_name.c_str());
if (!ofs)
{
ofs.open((ResLoader::Instance().LocalFolder() + mtlml_name).c_str());
}
doc.Print(ofs);
}
void SubThreadStage()
{
ResIdentifierPtr psmm_input = ResLoader::Instance().Open(ps_desc_.res_name);
KlayGE::XMLDocument doc;
XMLNodePtr root = doc.Parse(psmm_input);
{
XMLNodePtr particle_node = root->FirstNode("particle");
{
XMLNodePtr alpha_node = particle_node->FirstNode("alpha");
ps_desc_.ps_data->particle_alpha_from_tex = alpha_node->Attrib("from")->ValueString();
ps_desc_.ps_data->particle_alpha_to_tex = alpha_node->Attrib("to")->ValueString();
}
{
XMLNodePtr color_node = particle_node->FirstNode("color");
{
Color from;
XMLAttributePtr attr = color_node->Attrib("from");
if (attr)
{
std::vector<std::string> strs;
boost::algorithm::split(strs, attr->ValueString(), boost::is_any_of(" "));
for (size_t i = 0; i < 3; ++ i)
{
if (i < strs.size())
{
boost::algorithm::trim(strs[i]);
from[i] = static_cast<float>(atof(strs[i].c_str()));
}
else
{
from[i] = 0;
}
}
}
from.a() = 1;
ps_desc_.ps_data->particle_color_from = from;
Color to;
attr = color_node->Attrib("to");
if (attr)
{
std::vector<std::string> strs;
boost::algorithm::split(strs, attr->ValueString(), boost::is_any_of(" "));
for (size_t i = 0; i < 3; ++ i)
{
if (i < strs.size())
{
boost::algorithm::trim(strs[i]);
to[i] = static_cast<float>(atof(strs[i].c_str()));
}
else
{
to[i] = 0;
}
}
}
to.a() = 1;
ps_desc_.ps_data->particle_color_to = to;
}
}
}
{
XMLNodePtr emitter_node = root->FirstNode("emitter");
XMLAttributePtr type_attr = emitter_node->Attrib("type");
if (type_attr)
{
ps_desc_.ps_data->emitter_type = type_attr->ValueString();
}
else
{
ps_desc_.ps_data->emitter_type = "point";
}
XMLNodePtr freq_node = emitter_node->FirstNode("frequency");
if (freq_node)
{
XMLAttributePtr attr = freq_node->Attrib("value");
ps_desc_.ps_data->frequency = attr->ValueFloat();
}
XMLNodePtr angle_node = emitter_node->FirstNode("angle");
if (angle_node)
{
XMLAttributePtr attr = angle_node->Attrib("value");
ps_desc_.ps_data->angle = attr->ValueInt() * DEG2RAD;
}
XMLNodePtr pos_node = emitter_node->FirstNode("pos");
if (pos_node)
{
float3 min_pos(0, 0, 0);
XMLAttributePtr attr = pos_node->Attrib("min");
if (attr)
{
std::vector<std::string> strs;
boost::algorithm::split(strs, attr->ValueString(), boost::is_any_of(" "));
for (size_t i = 0; i < 3; ++ i)
{
if (i < strs.size())
{
boost::algorithm::trim(strs[i]);
min_pos[i] = static_cast<float>(atof(strs[i].c_str()));
}
else
{
min_pos[i] = 0;
}
}
}
ps_desc_.ps_data->min_pos = min_pos;
float3 max_pos(0, 0, 0);
attr = pos_node->Attrib("max");
if (attr)
{
std::vector<std::string> strs;
boost::algorithm::split(strs, attr->ValueString(), boost::is_any_of(" "));
for (size_t i = 0; i < 3; ++ i)
{
if (i < strs.size())
{
boost::algorithm::trim(strs[i]);
max_pos[i] = static_cast<float>(atof(strs[i].c_str()));
}
else
{
max_pos[i] = 0;
}
}
}
ps_desc_.ps_data->max_pos = max_pos;
}
XMLNodePtr vel_node = emitter_node->FirstNode("vel");
if (vel_node)
{
XMLAttributePtr attr = vel_node->Attrib("min");
ps_desc_.ps_data->min_vel = attr->ValueFloat();
attr = vel_node->Attrib("max");
ps_desc_.ps_data->max_vel = attr->ValueFloat();
}
XMLNodePtr life_node = emitter_node->FirstNode("life");
if (life_node)
{
XMLAttributePtr attr = life_node->Attrib("min");
ps_desc_.ps_data->min_life = attr->ValueFloat();
attr = life_node->Attrib("max");
ps_desc_.ps_data->max_life = attr->ValueFloat();
}
}
{
XMLNodePtr updater_node = root->FirstNode("updater");
XMLAttributePtr type_attr = updater_node->Attrib("type");
if (type_attr)
{
ps_desc_.ps_data->updater_type = type_attr->ValueString();
}
else
{
ps_desc_.ps_data->updater_type = "polyline";
}
if ("polyline" == ps_desc_.ps_data->updater_type)
{
for (XMLNodePtr node = updater_node->FirstNode("curve"); node; node = node->NextSibling("curve"))
{
std::vector<float2> xys;
for (XMLNodePtr ctrl_point_node = node->FirstNode("ctrl_point"); ctrl_point_node; ctrl_point_node = ctrl_point_node->NextSibling("ctrl_point"))
{
XMLAttributePtr attr_x = ctrl_point_node->Attrib("x");
XMLAttributePtr attr_y = ctrl_point_node->Attrib("y");
xys.push_back(float2(attr_x->ValueFloat(), attr_y->ValueFloat()));
}
XMLAttributePtr attr = node->Attrib("name");
size_t const name_hash = RT_HASH(attr->ValueString().c_str());
if (CT_HASH("size_over_life") == name_hash)
{
ps_desc_.ps_data->size_over_life_ctrl_pts = xys;
}
else if (CT_HASH("mass_over_life") == name_hash)
{
ps_desc_.ps_data->mass_over_life_ctrl_pts = xys;
}
else if (CT_HASH("opacity_over_life") == name_hash)
{
ps_desc_.ps_data->opacity_over_life_ctrl_pts = xys;
}
}
}
}
RenderFactory& rf = Context::Instance().RenderFactoryInstance();
RenderDeviceCaps const & caps = rf.RenderEngineInstance().DeviceCaps();
if (caps.multithread_res_creating_support)
{
this->MainThreadStage();
}
}
