CWE-ou-minkata/MOULOpenSourceClientPlugin/Plasma20/Sources/Plasma/PubUtilLib/plDrawable/plAccessGeometry.h

/*==LICENSE==*

CyanWorlds.com Engine - MMOG client, server and tools
Copyright (C) 2011  Cyan Worlds, Inc.

This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with this program.  If not, see <http://www.gnu.org/licenses/>.

You can contact Cyan Worlds, Inc. by email legal@cyan.com
 or by snail mail at:
      Cyan Worlds, Inc.
      14617 N Newport Hwy
      Mead, WA   99021

*==LICENSE==*/

#ifndef plAccessGeometry_inc
#define plAccessGeometry_inc

#include "hsTemplates.h"

class plDrawable;
class plDrawableSpans;
class plGeometrySpan;
class plDrawInterface;
class plAccessSpan;
class plSpan;
class plParticleSpan;
class plIcicle;
class plVertexSpan;

class plPipeline;

class plAccessGeometry : public hsRefCnt
{
protected:
	void					Nilify() { fPipe = nil; }

	friend class plAccessGeometry;

	plPipeline*						fPipe;

	static plAccessGeometry*		fInstance;
public:
	// You're welcome to make your own,
	// but this is normally just called by the global plAccessGeometry's Init() function.
	// You should normally just use the instance supplied by Instance();
	plAccessGeometry(plPipeline* pipe=nil);

	static plAccessGeometry*		Instance() { return fInstance; }

	// App will initialize, which will create the global instance.
	// DeInit will nil the global instance.
	static void Init(plPipeline* pipe);
	static void DeInit();

	// External DLL's will share the same plAccessGeometry. After the main App has
	// DeInited the AccessGeometry,
	// all calls to Instance()->Function() will return nil in one form or another (e.g.
	// empty triangle lists). The external DLL needs to either not try to use these
	// accessor functions after PythonInterface::WeAreInShutdown() (it won't do any good
	// anyway as any work done will be thrown away), or else be prepared for receiving
	// empty data where there was data before.
	static void SetTheIntance(plAccessGeometry* i);

	// You have 2 options in opening the data.
	// RO - Read Only. 
	//		If you specify useSnapShot=true, then for channels which have had a snapshot
	//		taken, you will get pointers to this constant original snapshot form. For
	//		channels which have no snapshot data, or if useSnapShot=false, you will get
	//		pointers to the current (possibly modified since load) data. See SnapShot functions
	//		below.
	// RW - Read/Write access to the source data. After closing, this modified source data
	//		will be used to update the buffer data used for rendering.
	// In the normal case of reading the original (disk image) data, performing some operation
	//		on it and updating the renderable data, you need to open the same data twice, once
	//		RO(useSnapShot=true) (to get the constant source data) and once RW (for destination data). Note that
	//		the memory returned by RO will may be the same as returned by RW if there has been no snapshot
	//		taken.
	// The RW permutation by itself is useful when performing a one-time operation on the data (e.g.
	//		loadtime), so the modified source data is, to everyone else, what was read from disk.
	//		The only way to retrieve the original source data is to read it from disk again,
	//		unless you've made a snapshot. Normally you would do a RW modify the original data,
	//		then take the snapshot if you are going to be performing more modifications.
	// In ALL MODIFICATION CASES, if the modified data is paged out, and the original paged back in, you will
	//		need to perform your operation again - your modifications aren't saved anywhere.
	void	OpenRO(plDrawable* drawable, UInt32 spanIdx, plAccessSpan& acc, hsBool useSnapShot=true) const;
	void	OpenRW(plDrawable* drawable, UInt32 spanIdx, plAccessSpan& acc, hsBool idxToo=false) const;

	// What do we need to close up here?
	void	Close(plAccessSpan& acc) const;

	// Second set. You have a SceneObject's DrawInterface. This can reference into
	// multiple drawables, and multiple spans within each drawable. You would rather
	// not deal with it. So you can open by passing in a DrawInterface, and get back
	// a list of geometry corresponding to that SceneObject/DrawInterface.
	// NOTE: the list is in no way suggested to be homogenous. In fact, it's guaranteed
	// not to be, because the reason the single object resolved into multiple geometry spans
	// (possibly across multiple drawables) is that the conceptual single object is composed 
	// of multiple types of data that can't be batched into a single drawprimitive call.
	// At the least, the different AccessSpans will have different materials. But it's just
	// as likely that they will have different underlying formats (number of UVs, etc.).
	// Again, if you are using the iterators supplied, you probably don't care, but sometimes
	// you will (like if you are messing with the UVs).
	void	OpenRO(const plDrawInterface* di, hsTArray<plAccessSpan>& accs, hsBool useSnapShot=true) const;
	void	OpenRW(const plDrawInterface* di, hsTArray<plAccessSpan>& accs, hsBool idxToo=false) const;

	void	Close(hsTArray<plAccessSpan>& accs) const;

	// SnapShot functions.
	// If you need to generate channel values based on the original values (e.g. normal perterbation)
	// you need to reserve a copy of the original data. Only the channels specified will be copied.
	// Only one snapshot is ever taken, and it is the union of all channels requested. For example,
	//		taking a snapshot of positions AFTER taking a snapshot of positions/normals is a no-op,
	//		but taking a snapshot of positions/normals AFTER a snapshot of just positions will result in
	//		a copy of positions from the old snapshot, then a copy of normals from the buffergroup
	//		into the new snapshot, then freeing of the old snapshot.
	// Still, you should only snapshot the minimum set of channels you will need to be reading in their
	//		original form later.
	// The snapshot data is refcounted. You need to match your TakeSnapShots with FreeSnapShots.
	// SnapShot data is stored interleaved for efficiency, but don't count on it. Use an iterator.
	// RestoreSnapShot will copy the stored channels back into the buffer group, resetting those channels to
	//		the state when the snapshot was taken. Note that channels not SnapShotted might have been modified
	//		via OpenRW.
	// 
	void	TakeSnapShot(plDrawable* drawable, UInt32 spanIdx, UInt32 channels) const;
	void	RestoreSnapShot(plDrawable* drawable, UInt32 spanIdx, UInt32 channels) const;
	void	ReleaseSnapShot(plDrawable* drawable, UInt32 spanIdx) const;

	void	TakeSnapShot(const plDrawInterface* di, UInt32 channels) const;
	void	RestoreSnapShot(const plDrawInterface* di, UInt32 channels) const;
	void	ReleaseSnapShot(const plDrawInterface* di) const;

	// We often have geometry spans just sitting around devoid of any DI's, drawables or sceneobjects.
	// They aren't too bad to access directly (not like diving through the drawable into buffergroups),
	// but this let's them be accessed in a manner consistent with other geometry manipulations.
	void	AccessSpanFromGeometrySpan(plAccessSpan& dst, const plGeometrySpan* src) const { IAccessSpanFromSourceSpan(dst, src); }

protected:
	void	IAccessSpanFromSourceSpan(plAccessSpan& dst, const plGeometrySpan* src) const;
	void	IAccessSpanFromSpan(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* span, hsBool useSnap, hsBool readOnly) const;
	void	IAccessSpanFromVertexSpan(plAccessSpan& dst, plDrawableSpans* drawable, const plVertexSpan* span, hsBool readOnly) const;
	void	IAccessConnectivity(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* src) const;
	void	IAccessSpanFromIcicle(plAccessSpan& dst, plDrawableSpans* drawable, const plIcicle* span, hsBool readOnly) const;
	void	IAccessSpanFromParticle(plAccessSpan& dst, plDrawableSpans* drawable, const plParticleSpan* span, hsBool readOnly) const;
	void	IAccessSpanFromSnap(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* src) const;

	void	IOpen(plDrawable* d, UInt32 spanIdx, plAccessSpan& acc, hsBool useSnap, hsBool readOnly, hsBool idxToo=true) const;
};

#endif // plAccessGeometry_inc
Initial Commit of CyanWorlds.com Engine Open Source Client/Plugin 14 years ago			`/==LICENSE==`

			`CyanWorlds.com Engine - MMOG client, server and tools`
			`Copyright (C) 2011 Cyan Worlds, Inc.`

			`This program is free software: you can redistribute it and/or modify`
			`it under the terms of the GNU General Public License as published by`
			`the Free Software Foundation, either version 3 of the License, or`
			`(at your option) any later version.`

			`This program is distributed in the hope that it will be useful,`
			`but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`GNU General Public License for more details.`

			`You should have received a copy of the GNU General Public License`
			`along with this program. If not, see <http://www.gnu.org/licenses/>.`

			`You can contact Cyan Worlds, Inc. by email legal@cyan.com`
			`or by snail mail at:`
			`Cyan Worlds, Inc.`
			`14617 N Newport Hwy`
			`Mead, WA 99021`

			`==LICENSE==/`

			`#ifndef plAccessGeometry_inc`
			`#define plAccessGeometry_inc`

			`#include "hsTemplates.h"`

			`class plDrawable;`
			`class plDrawableSpans;`
			`class plGeometrySpan;`
			`class plDrawInterface;`
			`class plAccessSpan;`
			`class plSpan;`
			`class plParticleSpan;`
			`class plIcicle;`
			`class plVertexSpan;`

			`class plPipeline;`

			`class plAccessGeometry : public hsRefCnt`
			`{`
			`protected:`
			`void Nilify() { fPipe = nil; }`

			`friend class plAccessGeometry;`

			`plPipeline* fPipe;`

			`static plAccessGeometry* fInstance;`
			`public:`
			`// You're welcome to make your own,`
			`// but this is normally just called by the global plAccessGeometry's Init() function.`
			`// You should normally just use the instance supplied by Instance();`
			`plAccessGeometry(plPipeline* pipe=nil);`

			`static plAccessGeometry* Instance() { return fInstance; }`

			`// App will initialize, which will create the global instance.`
			`// DeInit will nil the global instance.`
			`static void Init(plPipeline* pipe);`
			`static void DeInit();`

			`// External DLL's will share the same plAccessGeometry. After the main App has`
			`// DeInited the AccessGeometry,`
			`// all calls to Instance()->Function() will return nil in one form or another (e.g.`
			`// empty triangle lists). The external DLL needs to either not try to use these`
			`// accessor functions after PythonInterface::WeAreInShutdown() (it won't do any good`
			`// anyway as any work done will be thrown away), or else be prepared for receiving`
			`// empty data where there was data before.`
			`static void SetTheIntance(plAccessGeometry* i);`

			`// You have 2 options in opening the data.`
			`// RO - Read Only.`
			`// If you specify useSnapShot=true, then for channels which have had a snapshot`
			`// taken, you will get pointers to this constant original snapshot form. For`
			`// channels which have no snapshot data, or if useSnapShot=false, you will get`
			`// pointers to the current (possibly modified since load) data. See SnapShot functions`
			`// below.`
			`// RW - Read/Write access to the source data. After closing, this modified source data`
			`// will be used to update the buffer data used for rendering.`
			`// In the normal case of reading the original (disk image) data, performing some operation`
			`// on it and updating the renderable data, you need to open the same data twice, once`
			`// RO(useSnapShot=true) (to get the constant source data) and once RW (for destination data). Note that`
			`// the memory returned by RO will may be the same as returned by RW if there has been no snapshot`
			`// taken.`
			`// The RW permutation by itself is useful when performing a one-time operation on the data (e.g.`
			`// loadtime), so the modified source data is, to everyone else, what was read from disk.`
			`// The only way to retrieve the original source data is to read it from disk again,`
			`// unless you've made a snapshot. Normally you would do a RW modify the original data,`
			`// then take the snapshot if you are going to be performing more modifications.`
			`// In ALL MODIFICATION CASES, if the modified data is paged out, and the original paged back in, you will`
			`// need to perform your operation again - your modifications aren't saved anywhere.`
			`void OpenRO(plDrawable* drawable, UInt32 spanIdx, plAccessSpan& acc, hsBool useSnapShot=true) const;`
			`void OpenRW(plDrawable* drawable, UInt32 spanIdx, plAccessSpan& acc, hsBool idxToo=false) const;`

			`// What do we need to close up here?`
			`void Close(plAccessSpan& acc) const;`

			`// Second set. You have a SceneObject's DrawInterface. This can reference into`
			`// multiple drawables, and multiple spans within each drawable. You would rather`
			`// not deal with it. So you can open by passing in a DrawInterface, and get back`
			`// a list of geometry corresponding to that SceneObject/DrawInterface.`
			`// NOTE: the list is in no way suggested to be homogenous. In fact, it's guaranteed`
			`// not to be, because the reason the single object resolved into multiple geometry spans`
			`// (possibly across multiple drawables) is that the conceptual single object is composed`
			`// of multiple types of data that can't be batched into a single drawprimitive call.`
			`// At the least, the different AccessSpans will have different materials. But it's just`
			`// as likely that they will have different underlying formats (number of UVs, etc.).`
			`// Again, if you are using the iterators supplied, you probably don't care, but sometimes`
			`// you will (like if you are messing with the UVs).`
			`void OpenRO(const plDrawInterface* di, hsTArray<plAccessSpan>& accs, hsBool useSnapShot=true) const;`
			`void OpenRW(const plDrawInterface* di, hsTArray<plAccessSpan>& accs, hsBool idxToo=false) const;`

			`void Close(hsTArray<plAccessSpan>& accs) const;`

			`// SnapShot functions.`
			`// If you need to generate channel values based on the original values (e.g. normal perterbation)`
			`// you need to reserve a copy of the original data. Only the channels specified will be copied.`
			`// Only one snapshot is ever taken, and it is the union of all channels requested. For example,`
			`// taking a snapshot of positions AFTER taking a snapshot of positions/normals is a no-op,`
			`// but taking a snapshot of positions/normals AFTER a snapshot of just positions will result in`
			`// a copy of positions from the old snapshot, then a copy of normals from the buffergroup`
			`// into the new snapshot, then freeing of the old snapshot.`
			`// Still, you should only snapshot the minimum set of channels you will need to be reading in their`
			`// original form later.`
			`// The snapshot data is refcounted. You need to match your TakeSnapShots with FreeSnapShots.`
			`// SnapShot data is stored interleaved for efficiency, but don't count on it. Use an iterator.`
			`// RestoreSnapShot will copy the stored channels back into the buffer group, resetting those channels to`
			`// the state when the snapshot was taken. Note that channels not SnapShotted might have been modified`
			`// via OpenRW.`
			`//`
			`void TakeSnapShot(plDrawable* drawable, UInt32 spanIdx, UInt32 channels) const;`
			`void RestoreSnapShot(plDrawable* drawable, UInt32 spanIdx, UInt32 channels) const;`
			`void ReleaseSnapShot(plDrawable* drawable, UInt32 spanIdx) const;`

			`void TakeSnapShot(const plDrawInterface* di, UInt32 channels) const;`
			`void RestoreSnapShot(const plDrawInterface* di, UInt32 channels) const;`
			`void ReleaseSnapShot(const plDrawInterface* di) const;`

			`// We often have geometry spans just sitting around devoid of any DI's, drawables or sceneobjects.`
			`// They aren't too bad to access directly (not like diving through the drawable into buffergroups),`
			`// but this let's them be accessed in a manner consistent with other geometry manipulations.`
			`void AccessSpanFromGeometrySpan(plAccessSpan& dst, const plGeometrySpan* src) const { IAccessSpanFromSourceSpan(dst, src); }`

			`protected:`
			`void IAccessSpanFromSourceSpan(plAccessSpan& dst, const plGeometrySpan* src) const;`
			`void IAccessSpanFromSpan(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* span, hsBool useSnap, hsBool readOnly) const;`
			`void IAccessSpanFromVertexSpan(plAccessSpan& dst, plDrawableSpans* drawable, const plVertexSpan* span, hsBool readOnly) const;`
			`void IAccessConnectivity(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* src) const;`
			`void IAccessSpanFromIcicle(plAccessSpan& dst, plDrawableSpans* drawable, const plIcicle* span, hsBool readOnly) const;`
			`void IAccessSpanFromParticle(plAccessSpan& dst, plDrawableSpans* drawable, const plParticleSpan* span, hsBool readOnly) const;`
			`void IAccessSpanFromSnap(plAccessSpan& dst, plDrawableSpans* drawable, const plSpan* src) const;`

			`void IOpen(plDrawable* d, UInt32 spanIdx, plAccessSpan& acc, hsBool useSnap, hsBool readOnly, hsBool idxToo=true) const;`
			`};`

			`#endif // plAccessGeometry_inc`