226 lines
10 KiB
C++
226 lines
10 KiB
C++
/**
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* PANDA 3D SOFTWARE
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* Copyright (c) Carnegie Mellon University. All rights reserved.
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*
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* All use of this software is subject to the terms of the revised BSD
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* license. You should have received a copy of this license along
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* with this source code in a file named "LICENSE."
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*
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* @file eggBinMaker.h
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* @author drose
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* @date 1999-01-21
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*/
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#ifndef EGGBINMAKER_H
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#define EGGBINMAKER_H
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/*
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* EggBinMaker This is a handy class for collecting related nodes together.
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* Its purpose is to make it easier to process egg files for converting to
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* another scene graph format. Egg is very general and allows nodes to be
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* parented willy-nilly anywhere you like, while many other scene graph
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* formats have requirements that certain kinds of nodes be grouped together.
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* Although EggBinMaker can be used to group any kinds of nodes together, one
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* of the most common examples is grouping polygons into polysets. Egg allows
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* individual polygons to be parented directly to any group node, while most
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* scene graph formats prefer to have polygons with similar attributes grouped
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* into some kind of a polyset node. Therefore, the following usage
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* discussion will use grouping polygons into polysets as an example.
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* EggBinMaker is actually an abstract class; it cannot be used directly. To
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* use it, you must create a subclass and redefine some or all of its virtual
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* functions to specify the precise behavior you require. You must define at
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* least the following function: virtual int get_bin_number(const EggNode
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* *node); This function identifies the kinds of nodes in the graph, for
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* instance EggPolygons, that are to be put into bins. It will be called once
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* for each node encountered, and it should return nonzero if the node is to
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* be binned, and zero otherwise. To group polygons into polysets, this
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* function might look like: virtual int get_bin_number(const EggNode *node) {
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* if (node->is_of_type(EggPolygon::get_class_type())) { return 1; } else {
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* return 0; } } This function may also return the bin number that a given
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* node should be dropped into. The bin number is completely arbitrary, and
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* it just serves to differentiate different bins. By default, all sibling
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* nodes will be dropped into the same bin; you can redefine this to sort
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* nodes further into categories. For instance, if you wanted to put textured
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* polygons into a different polyset than untextured polygons, you might
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* define this function as follows: virtual int get_bin_number(const EggNode
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* *node) { if (node->is_of_type(EggPolygon::get_class_type())) { EggPolygon
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* *poly = DCAST(EggPolygon, node); return (poly->has_texture()) ? 1 : 2; }
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* else { return 0; } } Of course, unrelated nodes--nodes that belong to
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* different parents--will never be placed into the same bin together,
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* regardless of the bin number. It is important to note that it is not
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* necessarily true that there is only one bin for each bin number. If you
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* redefine sorts_less(), below, you provide a finer-grained control that may
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* create multiple bins for a given bin number. This function may be called
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* several times for a given node, and it should return the same number each
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* time. You may also redefine any or all of the following functions: virtual
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* void prepare_node(EggNode *node); This method is called, once, on each node
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* in the egg hierarchy as it is visited the first time. It allows the
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* subclass a chance to analyze the node or do any other initial processing.
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* This is a fine opportunity to tag an EggUserData onto the node, for
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* instance. virtual bool sorts_less(int bin_number, const EggNode *a, const
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* EggNode *b); Sometimes a simple bin number alone is not enough. For
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* instance, suppose you needed to group together not just all textured
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* polygons, but all polygons that shared a particular texture map. Two
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* polygons that are each textured with a different texture map should go into
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* different polysets. To do this with bin numbers, you'd have to know ahead
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* of time all the texture maps that are in use, and assign a unique number to
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* each one. sorts_less() can make this unnecessary. It's a finer-grained
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* sorting than by bin numbers. Once two nodes have been grouped together
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* into the same bin number, sorts_less is called on them. If it returns
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* true, then node a should be placed into an earlier bin than node b, even
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* though they share the same bin number. If sorts_less(a, b) and
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* sorts_less(b, a) both return false, then nodes a and b are placed into the
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* same bin. To continue the example, and sort polygons into different bins
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* based on the texture map: virtual bool sorts_less(int bin_number, const
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* EggNode *a, const EggNode *b) { if (bin_number == 2) { bin 2, textured
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* geometry return (a->get_texture() < b->get_texture()); } else { bin 1,
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* untextured geometry return false; } } The actual comparison can be
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* arbitrary, as long as it is consistent. Its only purpose is to assign some
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* ordering among bins. In the example, for instance, the comparison is based
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* on the pointer to the texture maps--it doesn't matter which comes before
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* the other, as long as it's consistent. In particular, it should never be
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* true that sorts_less(a, b) and sorts_less(b, a) both return true--that is a
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* clear contradiction. Of course, if you're using sorts_less() anyway, you
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* could put *all* of the logic for binning into this function; there's no
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* need to use both get_bin_number() and sorts_less(), necessarily. In the
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* current example, here's another version of sorts_less() that accomplishes
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* the same thing as the combined effects of the above get_bin_number() and
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* sorts_less() working together: virtual bool sorts_less(int bin_number,
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* const EggNode *a, const EggNode *b) { if (a->has_texture() !=
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* b->has_texture()) { return ((int)a->has_texture() < (int)b->has_texture());
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* } if (a->has_texture()) { return (a->get_texture() < b->get_texture()); }
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* return false; } virtual bool collapse_group(const EggGroup *group, int
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* bin_number); After all the nodes have been assigned to bins and the
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* individual bins (polysets) have been created, it might turn out that some
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* groups have had all their children placed into the same bin. In this case,
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* the group node is now redundant, since it contains just the one child, the
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* new EggBin (polyset) node. It might be advantageous to remove the group
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* and collapse its properties into the new node. In this case (and this case
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* only), collapse_group() will be called, given the node and the bin number.
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* If it returns true, the node will indeed be collapsed into its bin;
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* otherwise, they will be left separate. The point is that there might be
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* some attributes in the group node (for instance, a matrix transform) that
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* cannot be represented in a polyset node in the new scene graph format, so
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* there may be some cases in which the group cannot be safely collapsed.
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* Since the egg library cannot know about which such cases cause problems, it
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* leaves it up to you. The default behavior is never to collapse nodes.
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* virtual string get_bin_name(int bin_number, EggNode *child); This function
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* is called as each new bin is created, to optionally define a name for the
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* new node. If it returns the empty string, the node name will be empty,
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* unless it was collapsed with its parent group, in which case it will
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* inherit its former parent's name. Once you have subclassed EggBinMaker and
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* defined the functions as you require, you use it by simply calling
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* make_bins() one or more times, passing it the pointer to the root of the
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* scene graph or of some subgraph. It will traverse the subgraph and create
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* a series of EggBin objects, as required, moving all the binned geometry
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* under the EggBin objects. The return value is the number of EggBins
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* created. Each EggBin stores its bin number, which may be retrieved via
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* get_bin_number().
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*/
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#include "pandabase.h"
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#include "eggObject.h"
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#include "pointerTo.h"
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#include "pnotify.h"
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#include "pset.h"
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#include "pmap.h"
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class EggNode;
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class EggGroup;
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class EggGroupNode;
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class EggBin;
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class EggBinMaker;
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/**
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* This is just an STL function object, used to sort nodes within EggBinMaker.
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* It's part of the private interface; ignore it.
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*/
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class EXPCL_PANDA_EGG EggBinMakerCompareNodes {
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public:
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EggBinMakerCompareNodes() {
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// We need to have a default constructor to compile, but it should never
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// be called.
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nassertv(false);
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}
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EggBinMakerCompareNodes(EggBinMaker *ebm) : _ebm(ebm) { }
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bool operator ()(const EggNode *a, const EggNode *b) const;
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EggBinMaker *_ebm;
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};
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/**
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* This is a handy class for collecting related nodes together. It is an
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* abstract class; to use it you must subclass off of it. See the somewhat
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* lengthy comment above.
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*/
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class EXPCL_PANDA_EGG EggBinMaker : public EggObject {
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PUBLISHED:
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EggBinMaker();
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~EggBinMaker();
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int make_bins(EggGroupNode *root_group);
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virtual void
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prepare_node(EggNode *node);
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virtual int
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get_bin_number(const EggNode *node)=0;
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virtual bool
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sorts_less(int bin_number, const EggNode *a, const EggNode *b);
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virtual bool
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collapse_group(const EggGroup *group, int bin_number);
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virtual std::string
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get_bin_name(int bin_number, const EggNode *child);
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virtual PT(EggBin)
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make_bin(int bin_number, const EggNode *child, EggGroup *collapse_from);
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private:
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// The logic is two-pass. First, we make a scene graph traversal and store
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// all the pointers into the GroupNodesSortedNodes structure, which groups
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// nodes by their parent group, and then sorted into bin order.
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typedef pmultiset<PT(EggNode), EggBinMakerCompareNodes> SortedNodes;
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typedef pmap<EggGroupNode *, SortedNodes> GroupNodes;
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// Then we walk through that list and create a BinsNodes structure for each
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// group, which separates out the nodes into the individual bins.
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typedef pvector< PT(EggNode) > Nodes;
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typedef pvector<Nodes> Bins;
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void collect_nodes(EggGroupNode *group);
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int get_bins_for_group(GroupNodes::const_iterator gi);
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void make_bins_for_group(EggGroupNode *group, const Bins &bins);
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void setup_bin(EggBin *bin, const Nodes &nodes);
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GroupNodes _group_nodes;
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public:
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static TypeHandle get_class_type() {
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return _type_handle;
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}
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static void init_type() {
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EggObject::init_type();
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register_type(_type_handle, "EggBinMaker",
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EggObject::get_class_type());
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}
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virtual TypeHandle get_type() const {
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return get_class_type();
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}
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virtual TypeHandle force_init_type() {init_type(); return get_class_type();}
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private:
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static TypeHandle _type_handle;
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};
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#endif
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