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blender-archive/source/blender/freestyle/intern/blender_interface/BlenderStrokeRenderer.cpp
Brecht Van Lommel 0803119725 Cycles: merge of cycles-x branch, a major update to the renderer 
This includes much improved GPU rendering performance, viewport interactivity,
new shadow catcher, revamped sampling settings, subsurface scattering anisotropy,
new GPU volume sampling, improved PMJ sampling pattern, and more.

Some features have also been removed or changed, breaking backwards compatibility.
Including the removal of the OpenCL backend, for which alternatives are under
development.

Release notes and code docs:
https://wiki.blender.org/wiki/Reference/Release_Notes/3.0/Cycles
https://wiki.blender.org/wiki/Source/Render/Cycles

Credits:
* Sergey Sharybin
* Brecht Van Lommel
* Patrick Mours (OptiX backend)
* Christophe Hery (subsurface scattering anisotropy)
* William Leeson (PMJ sampling pattern)
* Alaska (various fixes and tweaks)
* Thomas Dinges (various fixes)

For the full commit history, see the cycles-x branch. This squashes together
all the changes since intermediate changes would often fail building or tests.

Ref T87839, T87837, T87836
Fixes T90734, T89353, T80267, T80267, T77185, T69800
2021-09-21 14:55:54 +02:00

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/*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
/** \file
* \ingroup freestyle
*/
#include "BlenderStrokeRenderer.h"
#include "../application/AppConfig.h"
#include "../stroke/Canvas.h"
#include "MEM_guardedalloc.h"
#include "RNA_access.h"
#include "RNA_types.h"
#include "DNA_camera_types.h"
#include "DNA_collection_types.h"
#include "DNA_linestyle_types.h"
#include "DNA_listBase.h"
#include "DNA_material_types.h"
#include "DNA_mesh_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_object_types.h"
#include "DNA_scene_types.h"
#include "DNA_screen_types.h"
#include "BKE_collection.h"
#include "BKE_customdata.h"
#include "BKE_global.h"
#include "BKE_idprop.h"
#include "BKE_layer.h"
#include "BKE_lib_id.h" /* free_libblock */
#include "BKE_material.h"
#include "BKE_mesh.h"
#include "BKE_node.h"
#include "BKE_object.h"
#include "BKE_scene.h"
#include "BLI_ghash.h"
#include "BLI_listbase.h"
#include "BLI_math_color.h"
#include "BLI_math_vector.h"
#include "BLI_utildefines.h"
#include "DEG_depsgraph.h"
#include "DEG_depsgraph_build.h"
#include "RE_pipeline.h"
#include "render_types.h"
#include <climits>
namespace Freestyle {
const char *BlenderStrokeRenderer::uvNames[] = {"along_stroke", "along_stroke_tips"};
BlenderStrokeRenderer::BlenderStrokeRenderer(Render *re, int render_count)
{
freestyle_bmain = BKE_main_new();
/* We use the same window manager for freestyle bmain as
* real bmain uses. This is needed because freestyle's
* bmain could be used to tag scenes for update, which
* implies call of ED_render_scene_update in some cases
* and that function requires proper window manager
* to present (sergey)
*/
freestyle_bmain->wm = re->main->wm;
// for stroke mesh generation
_width = re->winx;
_height = re->winy;
old_scene = re->scene;
char name[MAX_ID_NAME - 2];
BLI_snprintf(name, sizeof(name), "FRS%d_%s", render_count, re->scene->id.name + 2);
freestyle_scene = BKE_scene_add(freestyle_bmain, name);
freestyle_scene->r.cfra = old_scene->r.cfra;
freestyle_scene->r.mode = old_scene->r.mode & ~(R_EDGE_FRS | R_BORDER);
freestyle_scene->r.xsch = re->rectx; // old_scene->r.xsch
freestyle_scene->r.ysch = re->recty; // old_scene->r.ysch
freestyle_scene->r.xasp = 1.0f; // old_scene->r.xasp;
freestyle_scene->r.yasp = 1.0f; // old_scene->r.yasp;
freestyle_scene->r.size = 100; // old_scene->r.size
freestyle_scene->r.color_mgt_flag = 0; // old_scene->r.color_mgt_flag;
freestyle_scene->r.scemode = (old_scene->r.scemode &
~(R_SINGLE_LAYER | R_NO_FRAME_UPDATE | R_MULTIVIEW)) &
(re->r.scemode);
freestyle_scene->r.flag = old_scene->r.flag;
freestyle_scene->r.threads = old_scene->r.threads;
freestyle_scene->r.border.xmin = old_scene->r.border.xmin;
freestyle_scene->r.border.ymin = old_scene->r.border.ymin;
freestyle_scene->r.border.xmax = old_scene->r.border.xmax;
freestyle_scene->r.border.ymax = old_scene->r.border.ymax;
strcpy(freestyle_scene->r.pic, old_scene->r.pic);
freestyle_scene->r.dither_intensity = old_scene->r.dither_intensity;
STRNCPY(freestyle_scene->r.engine, old_scene->r.engine);
if (G.debug & G_DEBUG_FREESTYLE) {
cout << "Stroke rendering engine : " << freestyle_scene->r.engine << endl;
}
freestyle_scene->r.im_format.planes = R_IMF_PLANES_RGBA;
freestyle_scene->r.im_format.imtype = R_IMF_IMTYPE_PNG;
// Copy ID properties, including Cycles render properties
if (old_scene->id.properties) {
freestyle_scene->id.properties = IDP_CopyProperty_ex(old_scene->id.properties, 0);
}
// Copy eevee render settings.
BKE_scene_copy_data_eevee(freestyle_scene, old_scene);
/* Render with transparent background. */
freestyle_scene->r.alphamode = R_ALPHAPREMUL;
if (G.debug & G_DEBUG_FREESTYLE) {
printf("%s: %d thread(s)\n", __func__, BKE_render_num_threads(&freestyle_scene->r));
}
BKE_scene_set_background(freestyle_bmain, freestyle_scene);
// Scene layer.
ViewLayer *view_layer = (ViewLayer *)freestyle_scene->view_layers.first;
view_layer->layflag = SCE_LAY_SOLID;
// Camera
Object *object_camera = BKE_object_add(freestyle_bmain, view_layer, OB_CAMERA, nullptr);
Camera *camera = (Camera *)object_camera->data;
camera->type = CAM_ORTHO;
camera->ortho_scale = max(re->rectx, re->recty);
camera->clip_start = 0.1f;
camera->clip_end = 100.0f;
_z_delta = 0.00001f;
_z = camera->clip_start + _z_delta;
object_camera->loc[0] = re->disprect.xmin + 0.5f * re->rectx;
object_camera->loc[1] = re->disprect.ymin + 0.5f * re->recty;
object_camera->loc[2] = 1.0f;
freestyle_scene->camera = object_camera;
// Reset serial mesh ID (used for BlenderStrokeRenderer::NewMesh())
_mesh_id = 0xffffffff;
// Create a bNodeTree-to-Material hash table
_nodetree_hash = BLI_ghash_ptr_new("BlenderStrokeRenderer::_nodetree_hash");
// Depsgraph
freestyle_depsgraph = DEG_graph_new(
freestyle_bmain, freestyle_scene, view_layer, DAG_EVAL_RENDER);
DEG_graph_id_tag_update(freestyle_bmain, freestyle_depsgraph, &freestyle_scene->id, 0);
DEG_graph_id_tag_update(freestyle_bmain, freestyle_depsgraph, &object_camera->id, 0);
DEG_graph_tag_relations_update(freestyle_depsgraph);
}
BlenderStrokeRenderer::~BlenderStrokeRenderer()
{
BLI_ghash_free(_nodetree_hash, nullptr, nullptr);
DEG_graph_free(freestyle_depsgraph);
FreeStrokeGroups();
/* detach the window manager from freestyle bmain (see comments
* in add_freestyle() for more detail)
*/
BLI_listbase_clear(&freestyle_bmain->wm);
BKE_main_free(freestyle_bmain);
}
float BlenderStrokeRenderer::get_stroke_vertex_z() const
{
float z = _z;
BlenderStrokeRenderer *self = const_cast<BlenderStrokeRenderer *>(this);
if (!(_z < _z_delta * 100000.0f)) {
self->_z_delta *= 10.0f;
}
self->_z += _z_delta;
return -z;
}
unsigned int BlenderStrokeRenderer::get_stroke_mesh_id() const
{
unsigned mesh_id = _mesh_id;
BlenderStrokeRenderer *self = const_cast<BlenderStrokeRenderer *>(this);
self->_mesh_id--;
return mesh_id;
}
Material *BlenderStrokeRenderer::GetStrokeShader(Main *bmain,
bNodeTree *iNodeTree,
bool do_id_user)
{
Material *ma = BKE_material_add(bmain, "stroke_shader");
bNodeTree *ntree;
bNode *output_linestyle = nullptr;
bNodeSocket *fromsock, *tosock;
PointerRNA fromptr, toptr;
NodeShaderAttribute *storage;
id_us_min(&ma->id);
if (iNodeTree) {
// make a copy of linestyle->nodetree
ntree = ntreeCopyTree_ex(iNodeTree, bmain, do_id_user);
// find the active Output Line Style node
for (bNode *node = (bNode *)ntree->nodes.first; node; node = node->next) {
if (node->type == SH_NODE_OUTPUT_LINESTYLE && (node->flag & NODE_DO_OUTPUT)) {
output_linestyle = node;
break;
}
}
}
else {
ntree = ntreeAddTree(nullptr, "stroke_shader", "ShaderNodeTree");
}
ma->nodetree = ntree;
ma->use_nodes = 1;
ma->blend_method = MA_BM_HASHED;
bNode *input_attr_color = nodeAddStaticNode(nullptr, ntree, SH_NODE_ATTRIBUTE);
input_attr_color->locx = 0.0f;
input_attr_color->locy = -200.0f;
storage = (NodeShaderAttribute *)input_attr_color->storage;
BLI_strncpy(storage->name, "Color", sizeof(storage->name));
bNode *mix_rgb_color = nodeAddStaticNode(nullptr, ntree, SH_NODE_MIX_RGB);
mix_rgb_color->custom1 = MA_RAMP_BLEND; // Mix
mix_rgb_color->locx = 200.0f;
mix_rgb_color->locy = -200.0f;
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_color->inputs, 0); // Fac
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
RNA_float_set(&toptr, "default_value", 0.0f);
bNode *input_attr_alpha = nodeAddStaticNode(nullptr, ntree, SH_NODE_ATTRIBUTE);
input_attr_alpha->locx = 400.0f;
input_attr_alpha->locy = 300.0f;
storage = (NodeShaderAttribute *)input_attr_alpha->storage;
BLI_strncpy(storage->name, "Alpha", sizeof(storage->name));
bNode *mix_rgb_alpha = nodeAddStaticNode(nullptr, ntree, SH_NODE_MIX_RGB);
mix_rgb_alpha->custom1 = MA_RAMP_BLEND; // Mix
mix_rgb_alpha->locx = 600.0f;
mix_rgb_alpha->locy = 300.0f;
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_alpha->inputs, 0); // Fac
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
RNA_float_set(&toptr, "default_value", 0.0f);
bNode *shader_emission = nodeAddStaticNode(nullptr, ntree, SH_NODE_EMISSION);
shader_emission->locx = 400.0f;
shader_emission->locy = -200.0f;
bNode *input_light_path = nodeAddStaticNode(nullptr, ntree, SH_NODE_LIGHT_PATH);
input_light_path->locx = 400.0f;
input_light_path->locy = 100.0f;
bNode *mix_shader_color = nodeAddStaticNode(nullptr, ntree, SH_NODE_MIX_SHADER);
mix_shader_color->locx = 600.0f;
mix_shader_color->locy = -100.0f;
bNode *shader_transparent = nodeAddStaticNode(nullptr, ntree, SH_NODE_BSDF_TRANSPARENT);
shader_transparent->locx = 600.0f;
shader_transparent->locy = 100.0f;
bNode *mix_shader_alpha = nodeAddStaticNode(nullptr, ntree, SH_NODE_MIX_SHADER);
mix_shader_alpha->locx = 800.0f;
mix_shader_alpha->locy = 100.0f;
bNode *output_material = nodeAddStaticNode(nullptr, ntree, SH_NODE_OUTPUT_MATERIAL);
output_material->locx = 1000.0f;
output_material->locy = 100.0f;
fromsock = (bNodeSocket *)BLI_findlink(&input_attr_color->outputs, 0); // Color
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_color->inputs, 1); // Color1
nodeAddLink(ntree, input_attr_color, fromsock, mix_rgb_color, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&mix_rgb_color->outputs, 0); // Color
tosock = (bNodeSocket *)BLI_findlink(&shader_emission->inputs, 0); // Color
nodeAddLink(ntree, mix_rgb_color, fromsock, shader_emission, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&shader_emission->outputs, 0); // Emission
tosock = (bNodeSocket *)BLI_findlink(&mix_shader_color->inputs, 2); // Shader (second)
nodeAddLink(ntree, shader_emission, fromsock, mix_shader_color, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&input_light_path->outputs, 0); // In Camera Ray
tosock = (bNodeSocket *)BLI_findlink(&mix_shader_color->inputs, 0); // Fac
nodeAddLink(ntree, input_light_path, fromsock, mix_shader_color, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&mix_rgb_alpha->outputs, 0); // Color
tosock = (bNodeSocket *)BLI_findlink(&mix_shader_alpha->inputs, 0); // Fac
nodeAddLink(ntree, mix_rgb_alpha, fromsock, mix_shader_alpha, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&input_attr_alpha->outputs, 0); // Color
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_alpha->inputs, 1); // Color1
nodeAddLink(ntree, input_attr_alpha, fromsock, mix_rgb_alpha, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&shader_transparent->outputs, 0); // BSDF
tosock = (bNodeSocket *)BLI_findlink(&mix_shader_alpha->inputs, 1); // Shader (first)
nodeAddLink(ntree, shader_transparent, fromsock, mix_shader_alpha, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&mix_shader_color->outputs, 0); // Shader
tosock = (bNodeSocket *)BLI_findlink(&mix_shader_alpha->inputs, 2); // Shader (second)
nodeAddLink(ntree, mix_shader_color, fromsock, mix_shader_alpha, tosock);
fromsock = (bNodeSocket *)BLI_findlink(&mix_shader_alpha->outputs, 0); // Shader
tosock = (bNodeSocket *)BLI_findlink(&output_material->inputs, 0); // Surface
nodeAddLink(ntree, mix_shader_alpha, fromsock, output_material, tosock);
if (output_linestyle) {
bNodeSocket *outsock;
bNodeLink *link;
mix_rgb_color->custom1 = output_linestyle->custom1; // blend_type
mix_rgb_color->custom2 = output_linestyle->custom2; // use_clamp
outsock = (bNodeSocket *)BLI_findlink(&output_linestyle->inputs, 0); // Color
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_color->inputs, 2); // Color2
link = (bNodeLink *)BLI_findptr(&ntree->links, outsock, offsetof(bNodeLink, tosock));
if (link) {
nodeAddLink(ntree, link->fromnode, link->fromsock, mix_rgb_color, tosock);
}
else {
float color[4];
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, outsock, &fromptr);
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
RNA_float_get_array(&fromptr, "default_value", color);
RNA_float_set_array(&toptr, "default_value", color);
}
outsock = (bNodeSocket *)BLI_findlink(&output_linestyle->inputs, 1); // Color Fac
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_color->inputs, 0); // Fac
link = (bNodeLink *)BLI_findptr(&ntree->links, outsock, offsetof(bNodeLink, tosock));
if (link) {
nodeAddLink(ntree, link->fromnode, link->fromsock, mix_rgb_color, tosock);
}
else {
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, outsock, &fromptr);
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
RNA_float_set(&toptr, "default_value", RNA_float_get(&fromptr, "default_value"));
}
outsock = (bNodeSocket *)BLI_findlink(&output_linestyle->inputs, 2); // Alpha
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_alpha->inputs, 2); // Color2
link = (bNodeLink *)BLI_findptr(&ntree->links, outsock, offsetof(bNodeLink, tosock));
if (link) {
nodeAddLink(ntree, link->fromnode, link->fromsock, mix_rgb_alpha, tosock);
}
else {
float color[4];
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, outsock, &fromptr);
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
color[0] = color[1] = color[2] = RNA_float_get(&fromptr, "default_value");
color[3] = 1.0f;
RNA_float_set_array(&toptr, "default_value", color);
}
outsock = (bNodeSocket *)BLI_findlink(&output_linestyle->inputs, 3); // Alpha Fac
tosock = (bNodeSocket *)BLI_findlink(&mix_rgb_alpha->inputs, 0); // Fac
link = (bNodeLink *)BLI_findptr(&ntree->links, outsock, offsetof(bNodeLink, tosock));
if (link) {
nodeAddLink(ntree, link->fromnode, link->fromsock, mix_rgb_alpha, tosock);
}
else {
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, outsock, &fromptr);
RNA_pointer_create((ID *)ntree, &RNA_NodeSocket, tosock, &toptr);
RNA_float_set(&toptr, "default_value", RNA_float_get(&fromptr, "default_value"));
}
for (bNode *node = (bNode *)ntree->nodes.first; node; node = node->next) {
if (node->type == SH_NODE_UVALONGSTROKE) {
// UV output of the UV Along Stroke node
bNodeSocket *sock = (bNodeSocket *)BLI_findlink(&node->outputs, 0);
// add new UV Map node
bNode *input_uvmap = nodeAddStaticNode(nullptr, ntree, SH_NODE_UVMAP);
input_uvmap->locx = node->locx - 200.0f;
input_uvmap->locy = node->locy;
NodeShaderUVMap *storage = (NodeShaderUVMap *)input_uvmap->storage;
if (node->custom1 & 1) { // use_tips
BLI_strncpy(storage->uv_map, uvNames[1], sizeof(storage->uv_map));
}
else {
BLI_strncpy(storage->uv_map, uvNames[0], sizeof(storage->uv_map));
}
fromsock = (bNodeSocket *)BLI_findlink(&input_uvmap->outputs, 0); // UV
// replace links from the UV Along Stroke node by links from the UV Map node
for (bNodeLink *link = (bNodeLink *)ntree->links.first; link; link = link->next) {
if (link->fromnode == node && link->fromsock == sock) {
nodeAddLink(ntree, input_uvmap, fromsock, link->tonode, link->tosock);
}
}
nodeRemSocketLinks(ntree, sock);
}
}
}
nodeSetActive(ntree, output_material);
ntreeUpdateTree(bmain, ntree);
return ma;
}
void BlenderStrokeRenderer::RenderStrokeRep(StrokeRep *iStrokeRep) const
{
RenderStrokeRepBasic(iStrokeRep);
}
void BlenderStrokeRenderer::RenderStrokeRepBasic(StrokeRep *iStrokeRep) const
{
bNodeTree *nt = iStrokeRep->getNodeTree();
Material *ma = (Material *)BLI_ghash_lookup(_nodetree_hash, nt);
if (!ma) {
ma = BlenderStrokeRenderer::GetStrokeShader(freestyle_bmain, nt, false);
BLI_ghash_insert(_nodetree_hash, nt, ma);
}
iStrokeRep->setMaterial(ma);
const vector<Strip *> &strips = iStrokeRep->getStrips();
const bool hasTex = iStrokeRep->hasTex();
int totvert = 0, totedge = 0, totpoly = 0, totloop = 0;
int visible_faces, visible_segments;
for (vector<Strip *>::const_iterator s = strips.begin(), send = strips.end(); s != send; ++s) {
Strip::vertex_container &strip_vertices = (*s)->vertices();
// count visible faces and strip segments
test_strip_visibility(strip_vertices, &visible_faces, &visible_segments);
if (visible_faces == 0) {
continue;
}
totvert += visible_faces + visible_segments * 2;
totedge += visible_faces * 2 + visible_segments;
totpoly += visible_faces;
totloop += visible_faces * 3;
}
BlenderStrokeRenderer *self = const_cast<BlenderStrokeRenderer *>(this); // FIXME
vector<StrokeGroup *> *groups = hasTex ? &self->texturedStrokeGroups : &self->strokeGroups;
StrokeGroup *group;
if (groups->empty() || !(groups->back()->totvert + totvert < MESH_MAX_VERTS &&
groups->back()->materials.size() + 1 < MAXMAT)) {
group = new StrokeGroup;
groups->push_back(group);
}
else {
group = groups->back();
}
group->strokes.push_back(iStrokeRep);
group->totvert += totvert;
group->totedge += totedge;
group->totpoly += totpoly;
group->totloop += totloop;
if (!group->materials.contains(ma)) {
group->materials.add_new(ma, group->materials.size());
}
}
// Check if the triangle is visible (i.e., within the render image boundary)
bool BlenderStrokeRenderer::test_triangle_visibility(StrokeVertexRep *svRep[3]) const
{
int xl, xu, yl, yu;
Vec2r p;
xl = xu = yl = yu = 0;
for (int i = 0; i < 3; i++) {
p = svRep[i]->point2d();
if (p[0] < 0.0) {
xl++;
}
else if (p[0] > _width) {
xu++;
}
if (p[1] < 0.0) {
yl++;
}
else if (p[1] > _height) {
yu++;
}
}
return !(xl == 3 || xu == 3 || yl == 3 || yu == 3);
}
// Check the visibility of faces and strip segments.
void BlenderStrokeRenderer::test_strip_visibility(Strip::vertex_container &strip_vertices,
int *visible_faces,
int *visible_segments) const
{
const int strip_vertex_count = strip_vertices.size();
Strip::vertex_container::iterator v[3];
StrokeVertexRep *svRep[3];
bool visible;
// iterate over all vertices and count visible faces and strip segments
// (note: a strip segment is a series of visible faces, while two strip
// segments are separated by one or more invisible faces)
v[0] = strip_vertices.begin();
v[1] = v[0] + 1;
v[2] = v[0] + 2;
*visible_faces = *visible_segments = 0;
visible = false;
for (int n = 2; n < strip_vertex_count; n++, v[0]++, v[1]++, v[2]++) {
svRep[0] = *(v[0]);
svRep[1] = *(v[1]);
svRep[2] = *(v[2]);
if (test_triangle_visibility(svRep)) {
(*visible_faces)++;
if (!visible) {
(*visible_segments)++;
}
visible = true;
}
else {
visible = false;
}
}
}
// Release allocated memory for stroke groups
void BlenderStrokeRenderer::FreeStrokeGroups()
{
vector<StrokeGroup *>::const_iterator it, itend;
for (it = strokeGroups.begin(), itend = strokeGroups.end(); it != itend; ++it) {
delete (*it);
}
for (it = texturedStrokeGroups.begin(), itend = texturedStrokeGroups.end(); it != itend; ++it) {
delete (*it);
}
}
// Build a scene populated by mesh objects representing stylized strokes
int BlenderStrokeRenderer::GenerateScene()
{
vector<StrokeGroup *>::const_iterator it, itend;
for (it = strokeGroups.begin(), itend = strokeGroups.end(); it != itend; ++it) {
GenerateStrokeMesh(*it, false);
}
for (it = texturedStrokeGroups.begin(), itend = texturedStrokeGroups.end(); it != itend; ++it) {
GenerateStrokeMesh(*it, true);
}
return get_stroke_count();
}
// Return the number of strokes
int BlenderStrokeRenderer::get_stroke_count() const
{
return strokeGroups.size() + texturedStrokeGroups.size();
}
// Build a mesh object representing a group of stylized strokes
void BlenderStrokeRenderer::GenerateStrokeMesh(StrokeGroup *group, bool hasTex)
{
#if 0
Object *object_mesh = BKE_object_add(
freestyle_bmain, (ViewLayer *)freestyle_scene->view_layers.first, OB_MESH);
DEG_relations_tag_update(freestyle_bmain);
#else
Object *object_mesh = NewMesh();
#endif
Mesh *mesh = (Mesh *)object_mesh->data;
mesh->totvert = group->totvert;
mesh->totedge = group->totedge;
mesh->totpoly = group->totpoly;
mesh->totloop = group->totloop;
mesh->totcol = group->materials.size();
mesh->mvert = (MVert *)CustomData_add_layer(
&mesh->vdata, CD_MVERT, CD_CALLOC, nullptr, mesh->totvert);
mesh->medge = (MEdge *)CustomData_add_layer(
&mesh->edata, CD_MEDGE, CD_CALLOC, nullptr, mesh->totedge);
mesh->mpoly = (MPoly *)CustomData_add_layer(
&mesh->pdata, CD_MPOLY, CD_CALLOC, nullptr, mesh->totpoly);
mesh->mloop = (MLoop *)CustomData_add_layer(
&mesh->ldata, CD_MLOOP, CD_CALLOC, nullptr, mesh->totloop);
MVert *vertices = mesh->mvert;
MEdge *edges = mesh->medge;
MPoly *polys = mesh->mpoly;
MLoop *loops = mesh->mloop;
MLoopUV *loopsuv[2] = {nullptr};
if (hasTex) {
// First UV layer
CustomData_add_layer_named(
&mesh->ldata, CD_MLOOPUV, CD_CALLOC, nullptr, mesh->totloop, uvNames[0]);
CustomData_set_layer_active(&mesh->ldata, CD_MLOOPUV, 0);
BKE_mesh_update_customdata_pointers(mesh, true);
loopsuv[0] = mesh->mloopuv;
// Second UV layer
CustomData_add_layer_named(
&mesh->ldata, CD_MLOOPUV, CD_CALLOC, nullptr, mesh->totloop, uvNames[1]);
CustomData_set_layer_active(&mesh->ldata, CD_MLOOPUV, 1);
BKE_mesh_update_customdata_pointers(mesh, true);
loopsuv[1] = mesh->mloopuv;
}
// colors and transparency (the latter represented by grayscale colors)
MLoopCol *colors = (MLoopCol *)CustomData_add_layer_named(
&mesh->ldata, CD_MLOOPCOL, CD_CALLOC, nullptr, mesh->totloop, "Color");
MLoopCol *transp = (MLoopCol *)CustomData_add_layer_named(
&mesh->ldata, CD_MLOOPCOL, CD_CALLOC, nullptr, mesh->totloop, "Alpha");
mesh->mloopcol = colors;
mesh->mat = (Material **)MEM_mallocN(sizeof(Material *) * mesh->totcol, "MaterialList");
for (const auto item : group->materials.items()) {
Material *material = item.key;
const int matnr = item.value;
mesh->mat[matnr] = material;
if (material) {
id_us_plus(&material->id);
}
}
////////////////////
// Data copy
////////////////////
int vertex_index = 0, edge_index = 0, loop_index = 0;
int visible_faces, visible_segments;
bool visible;
Strip::vertex_container::iterator v[3];
StrokeVertexRep *svRep[3];
Vec2r p;
for (vector<StrokeRep *>::const_iterator it = group->strokes.begin(),
itend = group->strokes.end();
it != itend;
++it) {
const int matnr = group->materials.lookup_default((*it)->getMaterial(), 0);
vector<Strip *> &strips = (*it)->getStrips();
for (vector<Strip *>::const_iterator s = strips.begin(), send = strips.end(); s != send; ++s) {
Strip::vertex_container &strip_vertices = (*s)->vertices();
int strip_vertex_count = strip_vertices.size();
// count visible faces and strip segments
test_strip_visibility(strip_vertices, &visible_faces, &visible_segments);
if (visible_faces == 0) {
continue;
}
v[0] = strip_vertices.begin();
v[1] = v[0] + 1;
v[2] = v[0] + 2;
visible = false;
// NOTE: Mesh generation in the following loop assumes stroke strips
// to be triangle strips.
for (int n = 2; n < strip_vertex_count; n++, v[0]++, v[1]++, v[2]++) {
svRep[0] = *(v[0]);
svRep[1] = *(v[1]);
svRep[2] = *(v[2]);
if (!test_triangle_visibility(svRep)) {
visible = false;
}
else {
if (!visible) {
// first vertex
vertices->co[0] = svRep[0]->point2d()[0];
vertices->co[1] = svRep[0]->point2d()[1];
vertices->co[2] = get_stroke_vertex_z();
vertices->no[0] = 0;
vertices->no[1] = 0;
vertices->no[2] = SHRT_MAX;
++vertices;
++vertex_index;
// second vertex
vertices->co[0] = svRep[1]->point2d()[0];
vertices->co[1] = svRep[1]->point2d()[1];
vertices->co[2] = get_stroke_vertex_z();
vertices->no[0] = 0;
vertices->no[1] = 0;
vertices->no[2] = SHRT_MAX;
++vertices;
++vertex_index;
// first edge
edges->v1 = vertex_index - 2;
edges->v2 = vertex_index - 1;
++edges;
++edge_index;
}
visible = true;
// vertex
vertices->co[0] = svRep[2]->point2d()[0];
vertices->co[1] = svRep[2]->point2d()[1];
vertices->co[2] = get_stroke_vertex_z();
vertices->no[0] = 0;
vertices->no[1] = 0;
vertices->no[2] = SHRT_MAX;
++vertices;
++vertex_index;
// edges
edges->v1 = vertex_index - 1;
edges->v2 = vertex_index - 3;
++edges;
++edge_index;
edges->v1 = vertex_index - 1;
edges->v2 = vertex_index - 2;
++edges;
++edge_index;
// poly
polys->loopstart = loop_index;
polys->totloop = 3;
polys->mat_nr = matnr;
++polys;
// Even and odd loops connect triangles vertices differently
bool is_odd = n % 2;
// loops
if (is_odd) {
loops[0].v = vertex_index - 1;
loops[0].e = edge_index - 2;
loops[1].v = vertex_index - 3;
loops[1].e = edge_index - 3;
loops[2].v = vertex_index - 2;
loops[2].e = edge_index - 1;
}
else {
loops[0].v = vertex_index - 1;
loops[0].e = edge_index - 1;
loops[1].v = vertex_index - 2;
loops[1].e = edge_index - 3;
loops[2].v = vertex_index - 3;
loops[2].e = edge_index - 2;
}
loops += 3;
loop_index += 3;
// UV
if (hasTex) {
// First UV layer (loopsuv[0]) has no tips (texCoord(0)).
// Second UV layer (loopsuv[1]) has tips: (texCoord(1)).
for (int L = 0; L < 2; L++) {
if (is_odd) {
loopsuv[L][0].uv[0] = svRep[2]->texCoord(L).x();
loopsuv[L][0].uv[1] = svRep[2]->texCoord(L).y();
loopsuv[L][1].uv[0] = svRep[0]->texCoord(L).x();
loopsuv[L][1].uv[1] = svRep[0]->texCoord(L).y();
loopsuv[L][2].uv[0] = svRep[1]->texCoord(L).x();
loopsuv[L][2].uv[1] = svRep[1]->texCoord(L).y();
}
else {
loopsuv[L][0].uv[0] = svRep[2]->texCoord(L).x();
loopsuv[L][0].uv[1] = svRep[2]->texCoord(L).y();
loopsuv[L][1].uv[0] = svRep[1]->texCoord(L).x();
loopsuv[L][1].uv[1] = svRep[1]->texCoord(L).y();
loopsuv[L][2].uv[0] = svRep[0]->texCoord(L).x();
loopsuv[L][2].uv[1] = svRep[0]->texCoord(L).y();
}
loopsuv[L] += 3;
}
}
// colors and alpha transparency. vertex colors are in sRGB
// space by convention, so convert from linear
float rgba[3][4];
for (int i = 0; i < 3; i++) {
copy_v3fl_v3db(rgba[i], &svRep[i]->color()[0]);
rgba[i][3] = svRep[i]->alpha();
}
if (is_odd) {
linearrgb_to_srgb_uchar4(&colors[0].r, rgba[2]);
linearrgb_to_srgb_uchar4(&colors[1].r, rgba[0]);
linearrgb_to_srgb_uchar4(&colors[2].r, rgba[1]);
}
else {
linearrgb_to_srgb_uchar4(&colors[0].r, rgba[2]);
linearrgb_to_srgb_uchar4(&colors[1].r, rgba[1]);
linearrgb_to_srgb_uchar4(&colors[2].r, rgba[0]);
}
transp[0].r = transp[0].g = transp[0].b = colors[0].a;
transp[1].r = transp[1].g = transp[1].b = colors[1].a;
transp[2].r = transp[2].g = transp[2].b = colors[2].a;
colors += 3;
transp += 3;
}
} // loop over strip vertices
} // loop over strips
} // loop over strokes
BKE_object_materials_test(freestyle_bmain, object_mesh, (ID *)mesh);
#if 0 // XXX
BLI_assert(mesh->totvert == vertex_index);
BLI_assert(mesh->totedge == edge_index);
BLI_assert(mesh->totloop == loop_index);
BKE_mesh_validate(mesh, true, true);
#endif
}
// A replacement of BKE_object_add() for better performance.
Object *BlenderStrokeRenderer::NewMesh() const
{
Object *ob;
char name[MAX_ID_NAME];
unsigned int mesh_id = get_stroke_mesh_id();
BLI_snprintf(name, MAX_ID_NAME, "0%08xOB", mesh_id);
ob = BKE_object_add_only_object(freestyle_bmain, OB_MESH, name);
BLI_snprintf(name, MAX_ID_NAME, "0%08xME", mesh_id);
ob->data = BKE_mesh_add(freestyle_bmain, name);
Collection *collection_master = freestyle_scene->master_collection;
BKE_collection_object_add(freestyle_bmain, collection_master, ob);
DEG_graph_tag_relations_update(freestyle_depsgraph);
DEG_graph_id_tag_update(freestyle_bmain,
freestyle_depsgraph,
&ob->id,
ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY | ID_RECALC_ANIMATION);
return ob;
}
Render *BlenderStrokeRenderer::RenderScene(Render * /*re*/, bool render)
{
Camera *camera = (Camera *)freestyle_scene->camera->data;
if (camera->clip_end < _z) {
camera->clip_end = _z + _z_delta * 100.0f;
}
#if 0
if (G.debug & G_DEBUG_FREESTYLE) {
cout << "clip_start " << camera->clip_start << ", clip_end " << camera->clip_end << endl;
}
#endif
Render *freestyle_render = RE_NewSceneRender(freestyle_scene);
DEG_graph_relations_update(freestyle_depsgraph);
RE_RenderFreestyleStrokes(
freestyle_render, freestyle_bmain, freestyle_scene, render && get_stroke_count() > 0);
return freestyle_render;
}
} /* namespace Freestyle */
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