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test2/source/blender/freestyle/intern/view_map/GridDensityProvider.h

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License Headers: Set copyright to "Blender Authors", add AUTHORS Listing the "Blender Foundation" as copyright holder implied the Blender Foundation holds copyright to files which may include work from many developers. While keeping copyright on headers makes sense for isolated libraries, Blender's own code may be refactored or moved between files in a way that makes the per file copyright holders less meaningful. Copyright references to the "Blender Foundation" have been replaced with "Blender Authors", with the exception of `./extern/` since these this contains libraries which are more isolated, any changed to license headers there can be handled on a case-by-case basis. Some directories in `./intern/` have also been excluded: - `./intern/cycles/` it's own `AUTHORS` file is planned. - `./intern/opensubdiv/`. An "AUTHORS" file has been added, using the chromium projects authors file as a template. Design task: #110784 Ref !110783.
2023-08-16 00:20:26 +10:00
/* SPDX-FileCopyrightText: 2023 Blender Authors
Cleanup: Add a copyright notice to files and use SPDX format A lot of files were missing copyright field in the header and the Blender Foundation contributed to them in a sense of bug fixing and general maintenance. This change makes it explicit that those files are at least partially copyrighted by the Blender Foundation. Note that this does not make it so the Blender Foundation is the only holder of the copyright in those files, and developers who do not have a signed contract with the foundation still hold the copyright as well. Another aspect of this change is using SPDX format for the header. We already used it for the license specification, and now we state it for the copyright as well, following the FAQ: https://reuse.software/faq/
2023-05-31 16:19:06 +02:00
*
* SPDX-License-Identifier: GPL-2.0-or-later */
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
#pragma once
doxygen: add newline after \file While \file doesn't need an argument, it can't have another doxy command after it.
2019-02-18 08:08:12 +11:00
/** \file
* \ingroup freestyle
* \brief Class to define a cell grid surrounding the projected image of a scene
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
*/
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
Woo Hoo. First git commit. Changes for VC2013 Now, I can build Blender with VC2013 with Cycles, Collada, OpenExr,OpenImageIO disabled. Also, you need VC2008 sp1 installed to make old libs compatible.
2013-11-29 14:50:59 -05:00
#include <algorithm>
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
#include <memory>
Fix clang-format differences between version 6 and 9 Version 6 does not appear to respect clang-format off for header sorting.
2020-04-21 12:39:12 +02:00
#include <stdexcept>
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
Initial compilation support with C++11 featureset enabled This commit makes some preliminary fixes and tweaks aimed to make blender compilable with C++11 feature set. This includes: - Build system attribute to enable C++11 featureset. It's for sure default OFF, but easy to enable to have a play around with it and make sure all the stuff is compilable before we go C++11 for real. - Changes in Compositor to use non-named cl_int structure fields. This is because __STRICT_ANSI__ is defined by default by GCC and OpenCL does not use named fields in this case. - Changes to TYPE_CHECK() related on lack of typeof() in C++11 This uses decltype() instead with some trickery to make sure returned type is not a reference. - Changes for auto_ptr in Freestyle This actually conditionally switches between auto_ptr and unique_ptr since auto_ptr is deprecated in C++11. Seems to be not strictly needed but still nice to be ready for such an update anyway/ This all based on changes form depsgraph_refactor branch apart from the weird changes which were made in order to support MinGW compilation. Those parts of change would need to be carefully reviewed again after official move to gcc49 in MinGW. Tested on Linux with GCC-4.7 and Clang-3.5, other platforms are not tested and likely needs some more tweaks. Reviewers: campbellbarton, juicyfruit, mont29, lukastoenne, psy-fi, kjym3 Differential Revision: https://developer.blender.org/D1089
2015-02-09 22:23:21 +05:00
#include "AutoPtrHelper.h"
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
#include "OccluderSource.h"
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
#include "../geometry/BBox.h"
Cleanup: Make `BKE_global.h` a Cpp header.
2024-02-10 18:25:14 +01:00
#include "BKE_global.hh"
New command-line option --debug-freestyle to enable verbose debug messages on the console during Freestyle rendering. The debug prints are turned off by default now. Errors are still printed on the console. A patch set implementing this functionality was provided by Bastien Montagne. Many thanks! :)
2013-01-03 23:27:20 +00:00
Core: remove WITH_CXX_GUARDEDALLOC option This implements the proposal from #124512. For that it contains the following changes: * Remove the global override of `new`/`delete` when `WITH_CXX_GUARDEDALLOC` was enabled. * Always use `MEM_CXX_CLASS_ALLOC_FUNCS` where it is currently used. This used to be guarded by `WITH_CXX_GUARDEDALLOC` in some but not all cases. This means that a few classes which didn't use our guarded allocator by default before, are now using it. Pull Request: https://projects.blender.org/blender/blender/pulls/130181
2024-11-13 13:39:49 +01:00
#include "MEM_guardedalloc.h"
Added support for WITH_CXX_GUARDEDALLOC build option to the Freestyle module.
2013-05-13 22:58:27 +00:00
Attempt to fix a potential name conflict between Freestyle and the compositor. A crash in the Freestyle renderer was reported by Ton on IRC with a stack trace below. Note that #2 is in Freestyle, whereas #1 is in the compositor. The problem was observed in a debug build on OS X 10.7 (gcc 4.2, openmp disabled, no llvm). ---------------------------------------------------------------------- Program received signal EXC_BAD_ACCESS, Could not access memory. Reason: 13 at address: 0x0000000000000000 [Switching to process 72386 thread 0xf303] 0x0000000100c129f3 in NodeBase::~NodeBase (this=0x10e501c80) at COM_NodeBase.cpp:43 43 delete (this->m_outputsockets.back()); Current language: auto; currently c++ (gdb) where #0 0x0000000100c129f3 in NodeBase::~NodeBase (this=0x10e501c80) at COM_NodeBase.cpp:43 #1 0x0000000100c29066 in Node::~Node (this=0x10e501c80) at COM_Node.h:49 #2 0x000000010089c273 in NodeShape::~NodeShape (this=0x10e501c80) at NodeShape.cpp:43 #3 0x000000010089910b in NodeGroup::destroy (this=0x10e501da0) at NodeGroup.cpp:61 #4 0x00000001008990cd in NodeGroup::destroy (this=0x10e5014b0) at NodeGroup.cpp:59 #5 0x00000001008990cd in NodeGroup::destroy (this=0x114e18da0) at NodeGroup.cpp:59 #6 0x00000001007e6602 in Controller::ClearRootNode (this=0x114e19640) at Controller.cpp:329 #7 0x00000001007ea52e in Controller::LoadMesh (this=0x114e19640, re=0x10aba4638, srl=0x1140f5258) at Controller.cpp:302 #8 0x00000001008030ad in prepare (re=0x10aba4638, srl=0x1140f5258) at FRS_freestyle.cpp:302 #9 0x000000010080457a in FRS_do_stroke_rendering (re=0x10aba4638, srl=0x1140f5258) at FRS_freestyle.cpp:600 #10 0x00000001006aeb9d in add_freestyle (re=0x10aba4638) at pipeline.c:1584 #11 0x00000001006aceb7 in do_render_3d (re=0x10aba4638) at pipeline.c:1094 #12 0x00000001006ae061 in do_render_fields_blur_3d (re=0x10aba4638) at pipeline.c:1367 #13 0x00000001006afa16 in do_render_composite_fields_blur_3d (re=0x10aba4638) at pipeline.c:1815 #14 0x00000001006b04e4 in do_render_all_options (re=0x10aba4638) at pipeline.c:2021 ---------------------------------------------------------------------- Apparently a name conflict between the two Blender modules is taking place. The present commit hence intends to address it by putting all the Freestyle C++ classes in the namespace 'Freestyle'. This revision will also prevent potential name conflicts with other Blender modules in the future. Special thanks to Lukas Toenne for the help with C++ namespace.
2013-04-09 00:46:49 +00:00
namespace Freestyle {
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
class GridDensityProvider {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
// Disallow copying and assignment
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
GridDensityProvider(const GridDensityProvider &other);
GridDensityProvider &operator=(const GridDensityProvider &other);
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
public:
Clang-Format: Allow empty functions to be single-line For example ``` OIIOOutputDriver::~OIIOOutputDriver() { } ``` becomes ``` OIIOOutputDriver::~OIIOOutputDriver() {} ``` Saves quite some vertical space, which is especially handy for constructors. Pull Request: https://projects.blender.org/blender/blender/pulls/105594
2023-03-29 16:50:54 +02:00
GridDensityProvider(OccluderSource &source) : source(source) {}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
virtual ~GridDensityProvider(){};
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
float cellSize()
{
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
return _cellSize;
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Cleanup: typedef uchar, ushort, uint & ulong in freestyle source/blender/freestyle wasn't fillowing Blender's own conventions for integer types. This had the down-side of making the code_clean.py utility attempt to replace `unsigned int` types which always failed. While this edit could have been manually ignored for all files in freestyle, add the typedef's to `FreestyleConfig.h` and follow Blender's convention instead.
2023-07-25 12:51:50 +10:00
uint cellsX()
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
{
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
return _cellsX;
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Cleanup: typedef uchar, ushort, uint & ulong in freestyle source/blender/freestyle wasn't fillowing Blender's own conventions for integer types. This had the down-side of making the code_clean.py utility attempt to replace `unsigned int` types which always failed. While this edit could have been manually ignored for all files in freestyle, add the typedef's to `FreestyleConfig.h` and follow Blender's convention instead.
2023-07-25 12:51:50 +10:00
uint cellsY()
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
{
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
return _cellsY;
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
float cellOrigin(int index)
{
if (index < 2) {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
return _cellOrigin[index];
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
}
else {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
throw new out_of_range("GridDensityProvider::cellOrigin can take only indexes of 0 or 1.");
}
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
static void calculateOptimalProscenium(OccluderSource &source, real proscenium[4])
{
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
source.begin();
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
if (source.isValid()) {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
const Vec3r &initialPoint = source.getGridSpacePolygon().getVertices()[0];
proscenium[0] = proscenium[1] = initialPoint[0];
proscenium[2] = proscenium[3] = initialPoint[1];
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
while (source.isValid()) {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
GridHelpers::expandProscenium(proscenium, source.getGridSpacePolygon());
source.next();
}
}
New command-line option --debug-freestyle to enable verbose debug messages on the console during Freestyle rendering. The debug prints are turned off by default now. Errors are still printed on the console. A patch set implementing this functionality was provided by Bastien Montagne. Many thanks! :)
2013-01-03 23:27:20 +00:00
if (G.debug & G_DEBUG_FREESTYLE) {
Another big code clean-up patch from Bastien Montagne, thanks again!
2013-03-11 06:56:51 +00:00
cout << "Proscenium: (" << proscenium[0] << ", " << proscenium[1] << ", " << proscenium[2]
<< ", " << proscenium[3] << ")" << endl;
New command-line option --debug-freestyle to enable verbose debug messages on the console during Freestyle rendering. The debug prints are turned off by default now. Errors are still printed on the console. A patch set implementing this functionality was provided by Bastien Montagne. Many thanks! :)
2013-01-03 23:27:20 +00:00
}
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
static void calculateQuickProscenium(const GridHelpers::Transform &transform,
const BBox<Vec3r> &bbox,
real proscenium[4])
{
Fix for [#35482] 2.67 freestyle line visibility computation bug. The reported line visibility issue was caused by a wrong calculation of a 2D bounding box (so-called "proscenium face" in Freestyle) in the case of a spherical grid data structure used for a perspective camera. The problem was resulting from the proscenium computation based on two corners (min and max) of the 3D bounding box of imported mesh data. Aware of the spherical coordinate transformation involving non-linear (arctangent) functions, now the proscenium is computed by taking in account all the eight corners of the 3D bounding box. Also added minor code changes to facilitate future debugging.
2013-07-13 19:33:25 +00:00
// Transform the coordinates of the 8 corners of the 3D bounding box
real xm = bbox.getMin()[0], xM = bbox.getMax()[0];
real ym = bbox.getMin()[1], yM = bbox.getMax()[1];
real zm = bbox.getMin()[2], zM = bbox.getMax()[2];
Vec3r p1 = transform(Vec3r(xm, ym, zm));
Vec3r p2 = transform(Vec3r(xm, ym, zM));
Vec3r p3 = transform(Vec3r(xm, yM, zm));
Vec3r p4 = transform(Vec3r(xm, yM, zM));
Vec3r p5 = transform(Vec3r(xM, ym, zm));
Vec3r p6 = transform(Vec3r(xM, ym, zM));
Vec3r p7 = transform(Vec3r(xM, yM, zm));
Vec3r p8 = transform(Vec3r(xM, yM, zM));
Cleanup: comments (long lines) in freestyle
2019-04-30 17:50:57 +10:00
// Determine the proscenium face according to the min and max values of the transformed x and y
// coordinates
Fix for [#35482] 2.67 freestyle line visibility computation bug. The reported line visibility issue was caused by a wrong calculation of a 2D bounding box (so-called "proscenium face" in Freestyle) in the case of a spherical grid data structure used for a perspective camera. The problem was resulting from the proscenium computation based on two corners (min and max) of the 3D bounding box of imported mesh data. Aware of the spherical coordinate transformation involving non-linear (arctangent) functions, now the proscenium is computed by taking in account all the eight corners of the 3D bounding box. Also added minor code changes to facilitate future debugging.
2013-07-13 19:33:25 +00:00
proscenium[0] = std::min(std::min(std::min(p1.x(), p2.x()), std::min(p3.x(), p4.x())),
std::min(std::min(p5.x(), p6.x()), std::min(p7.x(), p8.x())));
proscenium[1] = std::max(std::max(std::max(p1.x(), p2.x()), std::max(p3.x(), p4.x())),
std::max(std::max(p5.x(), p6.x()), std::max(p7.x(), p8.x())));
proscenium[2] = std::min(std::min(std::min(p1.y(), p2.y()), std::min(p3.y(), p4.y())),
std::min(std::min(p5.y(), p6.y()), std::min(p7.y(), p8.y())));
proscenium[3] = std::max(std::max(std::max(p1.y(), p2.y()), std::max(p3.y(), p4.y())),
std::max(std::max(p5.y(), p6.y()), std::max(p7.y(), p8.y())));
New command-line option --debug-freestyle to enable verbose debug messages on the console during Freestyle rendering. The debug prints are turned off by default now. Errors are still printed on the console. A patch set implementing this functionality was provided by Bastien Montagne. Many thanks! :)
2013-01-03 23:27:20 +00:00
if (G.debug & G_DEBUG_FREESTYLE) {
Fix for [#35482] 2.67 freestyle line visibility computation bug. The reported line visibility issue was caused by a wrong calculation of a 2D bounding box (so-called "proscenium face" in Freestyle) in the case of a spherical grid data structure used for a perspective camera. The problem was resulting from the proscenium computation based on two corners (min and max) of the 3D bounding box of imported mesh data. Aware of the spherical coordinate transformation involving non-linear (arctangent) functions, now the proscenium is computed by taking in account all the eight corners of the 3D bounding box. Also added minor code changes to facilitate future debugging.
2013-07-13 19:33:25 +00:00
cout << "Proscenium: " << proscenium[0] << ", " << proscenium[1] << ", " << proscenium[2]
Another big code clean-up patch from Bastien Montagne, thanks again!
2013-03-11 06:56:51 +00:00
<< ", " << proscenium[3] << endl;
New command-line option --debug-freestyle to enable verbose debug messages on the console during Freestyle rendering. The debug prints are turned off by default now. Errors are still printed on the console. A patch set implementing this functionality was provided by Bastien Montagne. Many thanks! :)
2013-01-03 23:27:20 +00:00
}
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
}
ClangFormat: apply to source, most of intern Apply clang format as proposed in T53211. For details on usage and instructions for migrating branches without conflicts, see: https://wiki.blender.org/wiki/Tools/ClangFormat
2019-04-17 06:17:24 +02:00
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
protected:
OccluderSource &source;
Cleanup: typedef uchar, ushort, uint & ulong in freestyle source/blender/freestyle wasn't fillowing Blender's own conventions for integer types. This had the down-side of making the code_clean.py utility attempt to replace `unsigned int` types which always failed. While this edit could have been manually ignored for all files in freestyle, add the typedef's to `FreestyleConfig.h` and follow Blender's convention instead.
2023-07-25 12:51:50 +10:00
uint _cellsX, _cellsY;
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
float _cellSize;
float _cellOrigin[2];
Added support for WITH_CXX_GUARDEDALLOC build option to the Freestyle module.
2013-05-13 22:58:27 +00:00
MEM_CXX_CLASS_ALLOC_FUNCS("Freestyle:GridDensityProvider")
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
};
Yet another big style clean-up patch by Bastien Montagne, thanks a lot! Now the code style is acceptable for the merge now, according to Bastien. Thanks again Bastien for having this done! :)
2013-01-02 01:55:30 +00:00
class GridDensityProviderFactory {
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
// Disallow copying and assignment
Another big code clean-up patch from Bastien Montagne, thanks again!
2013-03-11 06:56:51 +00:00
GridDensityProviderFactory(const GridDensityProviderFactory &other);
GridDensityProviderFactory &operator=(const GridDensityProviderFactory &other);
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
public:
Clang-Format: Allow empty functions to be single-line For example ``` OIIOOutputDriver::~OIIOOutputDriver() { } ``` becomes ``` OIIOOutputDriver::~OIIOOutputDriver() {} ``` Saves quite some vertical space, which is especially handy for constructors. Pull Request: https://projects.blender.org/blender/blender/pulls/105594
2023-03-29 16:50:54 +02:00
GridDensityProviderFactory() {}
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
Initial compilation support with C++11 featureset enabled This commit makes some preliminary fixes and tweaks aimed to make blender compilable with C++11 feature set. This includes: - Build system attribute to enable C++11 featureset. It's for sure default OFF, but easy to enable to have a play around with it and make sure all the stuff is compilable before we go C++11 for real. - Changes in Compositor to use non-named cl_int structure fields. This is because __STRICT_ANSI__ is defined by default by GCC and OpenCL does not use named fields in this case. - Changes to TYPE_CHECK() related on lack of typeof() in C++11 This uses decltype() instead with some trickery to make sure returned type is not a reference. - Changes for auto_ptr in Freestyle This actually conditionally switches between auto_ptr and unique_ptr since auto_ptr is deprecated in C++11. Seems to be not strictly needed but still nice to be ready for such an update anyway/ This all based on changes form depsgraph_refactor branch apart from the weird changes which were made in order to support MinGW compilation. Those parts of change would need to be carefully reviewed again after official move to gcc49 in MinGW. Tested on Linux with GCC-4.7 and Clang-3.5, other platforms are not tested and likely needs some more tweaks. Reviewers: campbellbarton, juicyfruit, mont29, lukastoenne, psy-fi, kjym3 Differential Revision: https://developer.blender.org/D1089
2015-02-09 22:23:21 +05:00
virtual AutoPtr<GridDensityProvider> newGridDensityProvider(OccluderSource &source,
const real proscenium[4]) = 0;
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
Initial compilation support with C++11 featureset enabled This commit makes some preliminary fixes and tweaks aimed to make blender compilable with C++11 feature set. This includes: - Build system attribute to enable C++11 featureset. It's for sure default OFF, but easy to enable to have a play around with it and make sure all the stuff is compilable before we go C++11 for real. - Changes in Compositor to use non-named cl_int structure fields. This is because __STRICT_ANSI__ is defined by default by GCC and OpenCL does not use named fields in this case. - Changes to TYPE_CHECK() related on lack of typeof() in C++11 This uses decltype() instead with some trickery to make sure returned type is not a reference. - Changes for auto_ptr in Freestyle This actually conditionally switches between auto_ptr and unique_ptr since auto_ptr is deprecated in C++11. Seems to be not strictly needed but still nice to be ready for such an update anyway/ This all based on changes form depsgraph_refactor branch apart from the weird changes which were made in order to support MinGW compilation. Those parts of change would need to be carefully reviewed again after official move to gcc49 in MinGW. Tested on Linux with GCC-4.7 and Clang-3.5, other platforms are not tested and likely needs some more tweaks. Reviewers: campbellbarton, juicyfruit, mont29, lukastoenne, psy-fi, kjym3 Differential Revision: https://developer.blender.org/D1089
2015-02-09 22:23:21 +05:00
virtual AutoPtr<GridDensityProvider> newGridDensityProvider(
OccluderSource &source,
const BBox<Vec3r> &bbox,
const GridHelpers::Transform &transform) = 0;
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
Initial compilation support with C++11 featureset enabled This commit makes some preliminary fixes and tweaks aimed to make blender compilable with C++11 feature set. This includes: - Build system attribute to enable C++11 featureset. It's for sure default OFF, but easy to enable to have a play around with it and make sure all the stuff is compilable before we go C++11 for real. - Changes in Compositor to use non-named cl_int structure fields. This is because __STRICT_ANSI__ is defined by default by GCC and OpenCL does not use named fields in this case. - Changes to TYPE_CHECK() related on lack of typeof() in C++11 This uses decltype() instead with some trickery to make sure returned type is not a reference. - Changes for auto_ptr in Freestyle This actually conditionally switches between auto_ptr and unique_ptr since auto_ptr is deprecated in C++11. Seems to be not strictly needed but still nice to be ready for such an update anyway/ This all based on changes form depsgraph_refactor branch apart from the weird changes which were made in order to support MinGW compilation. Those parts of change would need to be carefully reviewed again after official move to gcc49 in MinGW. Tested on Linux with GCC-4.7 and Clang-3.5, other platforms are not tested and likely needs some more tweaks. Reviewers: campbellbarton, juicyfruit, mont29, lukastoenne, psy-fi, kjym3 Differential Revision: https://developer.blender.org/D1089
2015-02-09 22:23:21 +05:00
virtual AutoPtr<GridDensityProvider> newGridDensityProvider(OccluderSource &source) = 0;
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
Clang-Format: Allow empty functions to be single-line For example ``` OIIOOutputDriver::~OIIOOutputDriver() { } ``` becomes ``` OIIOOutputDriver::~OIIOOutputDriver() {} ``` Saves quite some vertical space, which is especially handy for constructors. Pull Request: https://projects.blender.org/blender/blender/pulls/105594
2023-03-29 16:50:54 +02:00
virtual ~GridDensityProviderFactory() {}
Added support for WITH_CXX_GUARDEDALLOC build option to the Freestyle module.
2013-05-13 22:58:27 +00:00
MEM_CXX_CLASS_ALLOC_FUNCS("Freestyle:GridDensityProviderFactory")
Optimized view map calculation by Alexander Beels. * View map calculation has been intensively optimized for speed by means of: 1) new spatial grid data structures (SphericalGrid for perspective cameras and BoxGrid for orthographic cameras; automatically switched based on the camera type); 2) a heuristic grid density calculation algorithm; and 3) new line visibility computation algorithms: A "traditional" algorithm for emulating old visibility algorithms, and a "cumulative" algorithm for improved, more consistent line visibility, both exploiting the new spatial grid data structures for fast ray casting. A new option "Raycasting Algorithm" was added to allow users to choose a ray casting (line visibility) algorithm. Available choices are: - Normal Ray Casting - Fast Ray Casting - Very Fast Ray Casting - Culled Traditional Visibility Detection - Unculled Traditional Visibility Detection - Culled Cumulative Visibility Detection - Unculled Cumulative Visibility Detection The first three algorithms are those available in the original Freestyle (the "normal" ray casting was used unconditionally, though). The "fast" and "very fast" ray casting algorithms achieve a faster calculation at the cost of less visibility accuracy. The last four are newly introduced optimized options. The culled versions of the new algorithms will exclude from visibility calculation those faces that lay outside the camera, which leads to a faster view map construction. The unculled counterparts will take all faces into account. The unculled visibility algorithms are useful when culling affects stroke chaining. The recommended options for users are the culled/unculled cumulative visibility algorithms. These options are meant to replace the old algorithms in the future. Performance improvements over the old algorithms depend on the scenes to be rendered. * Silhouette detection has also been considerably optimized for speed. Performance gains by this optimization do not depend on scenes. * Improper handling of error conditions in the view map construction was fixed.
2011-03-14 00:36:27 +00:00
};
Attempt to fix a potential name conflict between Freestyle and the compositor. A crash in the Freestyle renderer was reported by Ton on IRC with a stack trace below. Note that #2 is in Freestyle, whereas #1 is in the compositor. The problem was observed in a debug build on OS X 10.7 (gcc 4.2, openmp disabled, no llvm). ---------------------------------------------------------------------- Program received signal EXC_BAD_ACCESS, Could not access memory. Reason: 13 at address: 0x0000000000000000 [Switching to process 72386 thread 0xf303] 0x0000000100c129f3 in NodeBase::~NodeBase (this=0x10e501c80) at COM_NodeBase.cpp:43 43 delete (this->m_outputsockets.back()); Current language: auto; currently c++ (gdb) where #0 0x0000000100c129f3 in NodeBase::~NodeBase (this=0x10e501c80) at COM_NodeBase.cpp:43 #1 0x0000000100c29066 in Node::~Node (this=0x10e501c80) at COM_Node.h:49 #2 0x000000010089c273 in NodeShape::~NodeShape (this=0x10e501c80) at NodeShape.cpp:43 #3 0x000000010089910b in NodeGroup::destroy (this=0x10e501da0) at NodeGroup.cpp:61 #4 0x00000001008990cd in NodeGroup::destroy (this=0x10e5014b0) at NodeGroup.cpp:59 #5 0x00000001008990cd in NodeGroup::destroy (this=0x114e18da0) at NodeGroup.cpp:59 #6 0x00000001007e6602 in Controller::ClearRootNode (this=0x114e19640) at Controller.cpp:329 #7 0x00000001007ea52e in Controller::LoadMesh (this=0x114e19640, re=0x10aba4638, srl=0x1140f5258) at Controller.cpp:302 #8 0x00000001008030ad in prepare (re=0x10aba4638, srl=0x1140f5258) at FRS_freestyle.cpp:302 #9 0x000000010080457a in FRS_do_stroke_rendering (re=0x10aba4638, srl=0x1140f5258) at FRS_freestyle.cpp:600 #10 0x00000001006aeb9d in add_freestyle (re=0x10aba4638) at pipeline.c:1584 #11 0x00000001006aceb7 in do_render_3d (re=0x10aba4638) at pipeline.c:1094 #12 0x00000001006ae061 in do_render_fields_blur_3d (re=0x10aba4638) at pipeline.c:1367 #13 0x00000001006afa16 in do_render_composite_fields_blur_3d (re=0x10aba4638) at pipeline.c:1815 #14 0x00000001006b04e4 in do_render_all_options (re=0x10aba4638) at pipeline.c:2021 ---------------------------------------------------------------------- Apparently a name conflict between the two Blender modules is taking place. The present commit hence intends to address it by putting all the Freestyle C++ classes in the namespace 'Freestyle'. This revision will also prevent potential name conflicts with other Blender modules in the future. Special thanks to Lukas Toenne for the help with C++ namespace.
2013-04-09 00:46:49 +00:00
} /* namespace Freestyle */
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