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/*==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 plWaveSet7_inc
#define plWaveSet7_inc
#include "hsGeometry3.h"
#include "hsTemplates.h"
#include "plMath/plRandom.h"
#include "hsBounds.h"
#include "plFixedWaterState7.h"
#include "plWaveSetBase.h"
class hsStream;
class hsResMgr;
class plAccessVtxSpan;
class plMessage;
class hsGMaterial;
class plDrawableSpans;
class plRenderMsg;
class plArmatureUpdateMsg;
class plGenRefMsg;
class plAuxSpan;
class plDynaDecalMgr;
class plGBufferGroup;
class plBitmap;
class plMipmap;
class plLayer;
class plRenderRequest;
class plRenderRequestMsg;
class plRenderTarget;
class plShader;
class plPipeline;
class plRipVSConsts;
class plStatusLog;
class plGraphPlate;
class plWorldWaveData7
{
public:
hsPoint3 fDir;
hsScalar fLength;
hsScalar fFreq;
hsScalar fPhase;
hsScalar fAmplitude;
};
class plWorldWave7 : public plWorldWaveData7
{
public:
inline void Accumulate(hsPoint3& accumPos, hsVector3& accumNorm) const;
};
class plWaveSet7 : public plWaveSetBase
{
public:
// Props inc by 1 (bit shift in bitvector).
enum plDrawProperties {
kDisable = 0,
kNumProps // last in the list
};
// Flags, also in a bitvector, so far unused in the multimodifier
enum {
kHasRefObject = 16
};
enum {
kNumWaves = 4
};
enum {
kRefDynaDecalMgr,
kRefBuoy,
kRefBumpMat,
kRefBumpDraw,
kRefBumpVShader,
kRefBumpPShader,
kRefBiasVShader,
kRefBiasPShader,
kRefRipVShader,
kRefRipPShader,
kRefShoreVShader,
kRefShorePShader,
kRefFixedVShader,
kRefFixedPShader,
kRefGraphShoreTex,
kRefBubbleShoreTex,
kRefEdgeShoreTex,
kRefGraphShoreMat,
kRefGraphShoreDraw,
kRefGraphVShader,
kRefGraphPShader,
kRefGraphShoreRT,
kRefShore,
kRefDecal,
kRefDecVShader,
kRefDecPShader,
kRefEnvMap,
kRefCosineLUT,
kRefRefObj
};
enum {
kGraphShorePasses = 3
};
enum {
kNumWindDep = 5
};
enum {
kNumTexWaves = 16
};
enum {
kBumpPerPass = 4
};
enum {
kNumBumpShaders = kNumTexWaves / kBumpPerPass
};
enum {
kCompositeSize = 256
};
enum {
kUpdateWaveKs = 0x1,
kRemakeBubble = 0x2,
kRemakeEdge = 0x4,
kReRenderEnvMap = 0x8,
kReInitWaves = 0x10
};
protected:
double fCurrTime;
double fLastTime;
plStatusLog* fStatusLog;
plGraphPlate* fStatusGraph;
UInt32 fTrialUpdate;
plFixedWaterState7 fState;
hsScalar fScrunchLen;
hsScalar fScrunchScale;
hsVector3 fWindDir;
hsScalar fMinLen;
hsScalar fMaxLen;
hsScalar fFreqScale;
hsScalar fTransCountDown;
int fTransistor;
hsScalar fTransDel;
hsScalar fTexTransCountDown;
int fTexTrans;
hsScalar fTexTransDel;
hsScalar fTexWaveFade[kNumTexWaves];
plWorldWave7 fWorldWaves[kNumWaves];
hsScalar fFreqMod[kNumWaves];
plRandom fRand;
plKey fSceneNode;
hsTArray<plDynaDecalMgr*> fDecalMgrs;
hsTArray<plSceneObject*> fBuoys;
hsTArray<plSceneObject*> fShores;
hsTArray<plSceneObject*> fDecals;
plSceneObject* fRefObj;
hsTArray<hsBounds3Ext> fTargBnds;
plLayer* fBiasLayer[2];
plLayer* fBumpLayers[kNumTexWaves];
hsGMaterial* fBumpMat;
plDrawableSpans* fBumpDraw;
plRenderRequest* fBumpReq;
plRenderRequestMsg* fBumpReqMsg;
plMipmap* fCosineLUT;
plShader* fBumpVShader[kNumBumpShaders];
plShader* fBumpPShader[kNumBumpShaders];
plShader* fBiasVShader;
plShader* fBiasPShader;
plBitmap* fEnvMap;
UInt32 fEnvSize;
hsScalar fEnvRefresh;
plLayer* fFixedLayers[4];
plShader* fRipVShader;
plShader* fRipPShader;
plShader* fShoreVShader;
plShader* fShorePShader;
plShader* fFixedVShader;
plShader* fFixedPShader;
enum DecalVType {
kDecalV1Lay,
kDecalV2Lay11,
kDecalV2Lay12,
kDecalVEnv,
kNumDecalVShaders
};
enum DecalPType {
kDecalPBB,
kDecalPaB,
kDecalPaM,
kDecalPaA,
kDecalPAB,
kDecalPAM,
kDecalPAA,
kDecalPMB,
kDecalPMM,
kDecalPMA,
kDecalPEnv,
kNumDecalPShaders
};
plShader* fDecalVShaders[kNumDecalVShaders];
plShader* fDecalPShaders[kNumDecalPShaders];
// Graph shore stuff
plMipmap* fGraphShoreTex;
plMipmap* fBubbleShoreTex;
plMipmap* fEdgeShoreTex;
hsGMaterial* fGraphShoreMat[kGraphShorePasses];
plDrawableSpans* fGraphShoreDraw[kGraphShorePasses];
plRenderTarget* fGraphShoreRT[kGraphShorePasses];
plRenderRequest* fGraphReq[kGraphShorePasses];
plRenderRequestMsg* fGraphReqMsg[kGraphShorePasses];
plShader* fGraphVShader[kGraphShorePasses];
plShader* fGraphPShader[kGraphShorePasses];
class GraphState
{
public:
float fAge;
float fInvLife;
float fUOff;
float fFreq[4];
float fPhase[4];
float fAmp[4];
};
GraphState fGraphState[kGraphShorePasses];
class WaveK
{
public:
// fK is the number of times the sine wave repeats across the texture. Must be an integer
// fS/fK is the base X component of the direction of the wave, with Y = 1.f - X. Note that X^2 + Y^2 != 1.
// fD allows the wave to get more off the Y direction
// So the X component will be Int(fS + fD*dispersion) / fK, because it must be an integer ratio to
// preserve tiling. Also, (fS + fD) must be <= fK (for the Y normalization).
// See the notes.
float fS;
float fK;
float fD;
};
WaveK fWaveKs[kNumTexWaves];
class TexWaveDesc
{
public:
hsScalar fPhase;
hsScalar fAmp;
hsScalar fLen;
hsScalar fFreq;
hsScalar fDirX;
hsScalar fDirY;
hsScalar fRotScale00;
hsScalar fRotScale01;
};
TexWaveDesc fTexWaves[kNumTexWaves];
class TexWaveWindDep
{
public:
hsScalar fWindSpeed;
hsScalar fHeight;
hsScalar fSpecular;
};
TexWaveWindDep fWindDeps[kNumWindDep];
void IInitWaveConsts();
void IInitState();
inline void IScrunch(hsPoint3& pos, hsVector3& norm) const;
void ICalcWindow(hsScalar dt);
void ICalcScale();
void IUpdateWaves(hsScalar dt);
void IUpdateWave(hsScalar dt, int i);
hsBool IAnyBoundsVisible(plPipeline* pipe) const;
void IInitWave(int i);
void IReInitWaves();
void IUpdateRefObject();
void IUpdateWindDir(hsScalar dt);
void IShiftCenter(plSceneObject* so) const;
void IFloatBuoys(hsScalar dt);
void IFloatBuoy(hsScalar dt, plSceneObject* so);
// Bookkeeping
void IAddTarget(const plKey& key);
void IRemoveTarget(const plKey& key);
void ISetWindSpeed(hsScalar s);
hsBool IOnReceive(plGenRefMsg* refMsg);
hsBool IOnRemove(plGenRefMsg* refMsg);
hsBool ITransContinue(hsScalar dt);
void IStartTransition(hsScalar dt);
hsScalar ITransitionDelay() const;
void ITransition(hsScalar dt);
hsBool ITransTexContinue(hsScalar dt);
void IStartTexTransition(hsScalar dt);
void ITransTex(hsScalar dt);
void IInitTexWave(int i);
void ISetupTextureWaves();
void IUpdateLayers(hsScalar dt);
void IUpdateBumpLayers(hsScalar dt);
plRenderRequest* ICreateRenderRequest(plRenderTarget* rt, plDrawableSpans* draw, hsScalar pri);
void ISubmitRenderRequests();
plRenderTarget* ICreateTransferRenderTarget(const char* name, int size);
plDrawableSpans* ICreateClearDrawable(plDrawableSpans* drawable, hsGMaterial* mat);
void IAddBumpBiasShaders(plLayer* layer);
plMipmap* ICreateBiasNoiseMap();
void IAddBumpBiasLayer(hsGMaterial* mat);
plMipmap* ICreateBumpBitmapFFP(hsScalar amp, hsScalar dx, hsScalar dy) const;
hsGMaterial* ICreateBumpLayersFFP();
plMipmap* ICreateBumpMipmapPS();
plLayer* ICreateBumpLayerPS(plMipmap* mipMap, hsGMaterial* bumpMat, int which);
hsGMaterial* ICreateBumpLayersPS();
plDrawableSpans* ICreateBumpDrawable();
plLayer* ICreateTotalEnvLayer(plBitmap* envMap, hsGMaterial* mat, int which, const char* pref);
plLayer* ICreateTotalLayer(plBitmap* bm, hsGMaterial* mat, int which, const char* suff);
hsGMaterial* ICreateFixedMatPS(hsGMaterial* mat, const int numUVWs);
void ICreateFixedMat(hsGMaterial* mat, const int numUVWs);
void ICheckTargetMaterials();
plDrawableSpans* ICreateGraphDrawable(plDrawableSpans* drawable, hsGMaterial* mat, int nWid);
plDrawableSpans* ICreateEmptyGraphDrawable(const char* name, UInt32 ref, int wich);
hsGMaterial* ICreateEmptyMaterial(const char* name, UInt32 ref, int which);
plLayer* ICreateBlankLayer(const char* name, int suff);
plMipmap* ICreateBlankTex(const char* name, int width, int height, UInt32 ref);
plMipmap* ICreateGraphShoreTex(int width, int height);
plMipmap* ICreateBubbleShoreTex(int width, int height);
void IRefillBubbleShoreTex();
plMipmap* ICreateEdgeShoreTex(int width, int height);
void IRefillEdgeShoreTex();
void ISetAsTexture(plLayer* lay, plBitmap* tex);
void ICreateGraphShoreLayer(hsGMaterial* mat, int iPass);
void ICreateGraphBubbleLayer(hsGMaterial* mat, int iPass);
void ICreateGraphEdgeLayer(hsGMaterial* mat, int iPass);
void ICreateGraphShoreMaterials();
plRenderTarget* ISetupGraphShoreRenderReq(int which);
void IMakeShoreLayer(hsGMaterial* mat, int which);
void ISetupShoreLayers(hsGMaterial* mat);
void ISetupGraphShore(hsGMaterial* mat);
void ICheckShoreMaterial(plSceneObject* so);
void ICheckShoreMaterials();
void ICheckDecalMaterial(plSceneObject* so);
void ICheckDecalMaterials();
void ISetupDecal(hsGMaterial* mat);
void ICheckDecalEnvLayers(hsGMaterial* mat);
void IAddGraphPShader(hsGMaterial* mat, int iPass);
void IAddGraphVShader(hsGMaterial* mat, int iPass);
void IUpdateGraphShader(hsScalar dt, int iPass);
void IInitGraph(int iPass);
void IShuffleDownGraphs(int iPass);
// type is either plLayRefMsg::kVertexShader or plLayRefMsg::kPixelShader.
void IAddShaderToLayers(hsGMaterial* mat, int iFirst, int iLast, UInt8 type, plShader* shader);
void IAddBumpPixelShader(hsGMaterial* mat, int iShader, int iFirst, int iLast);
void IAddBumpVertexShader(hsGMaterial* mat, int iShader, int iFirst, int iLast);
void IAddRipVertexShader(hsGMaterial* mat, const plRipVSConsts& ripConsts);
void IAddRipPixelShader(hsGMaterial* mat, const plRipVSConsts& ripConsts);
void IAddShoreVertexShader(hsGMaterial* mat);
void IAddShorePixelShader(hsGMaterial* mat);
void IAddFixedVertexShader(hsGMaterial* mat, const int numUVWs);
void IAddFixedPixelShader(hsGMaterial* mat);
plShader* IGetDecalPShader(hsGMaterial* mat);
plShader* ICreateDecalPShader(DecalPType t);
plShader* IGetDecalVShader(hsGMaterial* mat);
plShader* ICreateDecalVShader(DecalVType t);
void IUpdateShaders(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateBiasVShader();
void IUpdateBumpPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateBumpVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateRipPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateRipVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateShoreVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateFixedVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateFixedPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
void IUpdateGraphShaders(plPipeline* pipe, hsScalar dt);
void IUpdateDecVShader(int t, plPipeline* pipe);
void IUpdateDecVShaders(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l);
virtual int IShoreRef() const { return kRefShore; }
virtual int IDecalRef() const { return kRefDecal; }
inline void LogF(const char *format, ...) const;
inline void LogF(UInt32 color, const char *format, ...) const;
inline void IRestartLog() const;
inline void GraphLen(hsScalar len) const;
inline void IRestartGraph() const;
public:
plWaveSet7();
virtual ~plWaveSet7();
CLASSNAME_REGISTER( plWaveSet7 );
GETINTERFACE_ANY( plWaveSet7, plWaveSetBase );
virtual hsBool MsgReceive(plMessage* msg);
virtual hsBool IEval(double secs, hsScalar del, UInt32 dirty) { return false; }
Int32 GetNumProperties() const { return kNumProps; }
virtual void Read(hsStream* stream, hsResMgr* mgr);
virtual void Write(hsStream* stream, hsResMgr* mgr);
hsScalar EvalPoint(hsPoint3& pos, hsVector3& norm);
// Getters and Setters for Python twiddling
//
// First a way to set new values. The secs parameter says how long to take
// blending to the new value from the current value.
//
// Geometric wave parameters. These are all safe to twiddle at any time or speed.
// The new settings take effect as new waves are spawned.
void SetGeoMaxLength(hsScalar s, hsScalar secs=0) { fState.fGeoState.fMaxLength.Set(s, secs); }
void SetGeoMinLength(hsScalar s, hsScalar secs=0) { fState.fGeoState.fMinLength.Set(s, secs); }
void SetGeoAmpOverLen(hsScalar s, hsScalar secs=0) { fState.fGeoState.fAmpOverLen.Set(s, secs); }
void SetGeoChop(hsScalar s, hsScalar secs=0) { fState.fGeoState.fChop.Set(s, secs); }
void SetGeoAngleDev(hsScalar s, hsScalar secs=0) { fState.fGeoState.fAngleDev.Set(s, secs); }
// Texture wave parameters. Safe to twiddle any time or speed.
// The new settings take effect as new waves are spawned.
void SetTexMaxLength(hsScalar s, hsScalar secs=0) { fState.fTexState.fMaxLength.Set(s, secs); }
void SetTexMinLength(hsScalar s, hsScalar secs=0) { fState.fTexState.fMinLength.Set(s, secs); }
void SetTexAmpOverLen(hsScalar s, hsScalar secs=0) { fState.fTexState.fAmpOverLen.Set(s, secs); }
void SetTexChop(hsScalar s, hsScalar secs=0) { fState.fTexState.fChop.Set(s, secs); }
void SetTexAngleDev(hsScalar s, hsScalar secs=0) { fState.fTexState.fAngleDev.Set(s, secs); }
// The size in feet of one tile of the ripple texture. If you change this (I don't
// recommend it), you need to change it very slowly or it will look very stupid.
void SetRippleScale(hsScalar s, hsScalar secs=0) { fState.fRippleScale.Set(s, secs); }
// The direction the wind is blowing (waves will be more or less perpindicular to wind dir).
// Change somewhat slowly, like over 30 seconds.
void SetWindDir(const hsVector3& s, hsScalar secs=0) { fState.fWindDir.Set(s, secs); }
// Change these gently, effect is immediate.
void SetSpecularNoise(hsScalar s, hsScalar secs=0) { hsVector3 spec = fState.fSpecVec; spec[plFixedWaterState7::kNoise] = s; fState.fSpecVec.Set(spec, secs); }
void SetSpecularStart(hsScalar s, hsScalar secs=0) { hsVector3 spec = fState.fSpecVec; spec[plFixedWaterState7::kSpecStart] = s; fState.fSpecVec.Set(spec, secs); }
void SetSpecularEnd(hsScalar s, hsScalar secs=0) { hsVector3 spec = fState.fSpecVec; spec[plFixedWaterState7::kSpecEnd] = s; fState.fSpecVec.Set(spec, secs); }
// Water Height is overriden if the ref object is animated.
void SetWaterHeight(hsScalar s, hsScalar secs=0) { fState.fWaterHeight.Set(s, secs); }
// Water Offset and DepthFalloff are complicated, and not immediately interesting to animate.
void SetWaterOffset(const hsVector3& s, hsScalar secs=0) { fState.fWaterOffset.Set(s, secs); }
void SetOpacOffset(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fWaterOffset; off.fX = s; fState.fWaterOffset.Set(off, secs); }
void SetReflOffset(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fWaterOffset; off.fY = s; fState.fWaterOffset.Set(off, secs); }
void SetWaveOffset(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fWaterOffset; off.fZ = s; fState.fWaterOffset.Set(off, secs); }
void SetDepthFalloff(const hsVector3& s, hsScalar secs=0) { fState.fDepthFalloff.Set(s, secs); }
void SetOpacFalloff(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fDepthFalloff; off.fX = s; fState.fDepthFalloff.Set(off, secs); }
void SetReflFalloff(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fDepthFalloff; off.fY = s; fState.fDepthFalloff.Set(off, secs); }
void SetWaveFalloff(hsScalar s, hsScalar secs=0) { hsVector3 off = fState.fDepthFalloff; off.fZ = s; fState.fDepthFalloff.Set(off, secs); }
// Max and Min Atten aren't very interesting, and will probably go away.
void SetMaxAtten(const hsVector3& s, hsScalar secs=0) { fState.fMaxAtten.Set(s, secs); }
void SetMinAtten(const hsVector3& s, hsScalar secs=0) { fState.fMinAtten.Set(s, secs); }
// Skipping the shore parameters, because they are never used.
// Water colors, adjust slowly, effect is immediate.
void SetWaterTint(const hsColorRGBA& s, hsScalar secs=0) { fState.fWaterTint.Set(s, secs); }
void SetWaterRGB(const hsVector3& col, hsScalar secs=0) { hsColorRGBA rgb; rgb.Set(col.fX, col.fY, col.fZ, GetWaterOpacity()); SetWaterTint(rgb, secs); }
void SetWaterOpacity(hsScalar s, hsScalar secs=0) { hsColorRGBA col = GetWaterTint(); col.a = s; SetWaterTint(col, secs); }
void SetSpecularTint(const hsColorRGBA& s, hsScalar secs=0) { fState.fSpecularTint.Set(s, secs); }
void SetSpecularRGB(const hsVector3& col, hsScalar secs=0) { hsColorRGBA rgb; rgb.Set(col.fX, col.fY, col.fZ, GetSpecularMute()); SetSpecularTint(rgb, secs); }
void SetSpecularMute(hsScalar s, hsScalar secs=0) { hsColorRGBA col = GetSpecularTint(); col.a = s; SetSpecularTint(col, secs); }
// The environment map is essentially projected onto a sphere. Moving the center of
// the sphere north will move the reflections north, changing the radius of the
// sphere effects parallax in the obvious way.
void SetEnvCenter(const hsPoint3& s, hsScalar secs=0) { fState.fEnvCenter.Set(s, secs); }
void SetEnvRadius(hsScalar s, hsScalar secs=0) { fState.fEnvRadius.Set(s, secs); }
// Now a way to get current values. See the accompanying Setter for notes on
// what the parameter means.
//
hsScalar GetGeoMaxLength() const { return fState.fGeoState.fMaxLength; }
hsScalar GetGeoMinLength() const { return fState.fGeoState.fMinLength; }
hsScalar GetGeoAmpOverLen() const { return fState.fGeoState.fAmpOverLen; }
hsScalar GetGeoChop() const { return fState.fGeoState.fChop; }
hsScalar GetGeoAngleDev() const { return fState.fGeoState.fAngleDev; }
hsScalar GetTexMaxLength() const { return fState.fTexState.fMaxLength; }
hsScalar GetTexMinLength() const { return fState.fTexState.fMinLength; }
hsScalar GetTexAmpOverLen() const { return fState.fTexState.fAmpOverLen; }
hsScalar GetTexChop() const { return fState.fTexState.fChop; }
hsScalar GetTexAngleDev() const { return fState.fTexState.fAngleDev; }
hsScalar GetRippleScale() const { return fState.fRippleScale; }
hsVector3 GetWindDir() const { return fState.fWindDir; }
hsScalar GetSpecularNoise() const { hsVector3 spec = fState.fSpecVec; return spec[plFixedWaterState7::kNoise]; }
hsScalar GetSpecularStart() const { hsVector3 spec = fState.fSpecVec; return spec[plFixedWaterState7::kSpecStart]; }
hsScalar GetSpecularEnd() const { hsVector3 spec = fState.fSpecVec; return spec[plFixedWaterState7::kSpecEnd]; }
hsScalar GetWaterHeight() const { return fState.fWaterHeight; }
hsVector3 GetWaterOffset() const { return fState.fWaterOffset; }
hsScalar GetOpacOffset() const { hsVector3 off = fState.fWaterOffset; return off.fX; }
hsScalar GetReflOffset() const { hsVector3 off = fState.fWaterOffset; return off.fY; }
hsScalar GetWaveOffset() const { hsVector3 off = fState.fWaterOffset; return off.fZ; }
hsVector3 GetDepthFalloff() const { return fState.fDepthFalloff; }
hsScalar GetOpacFalloff() const { hsVector3 off = fState.fDepthFalloff; return off.fX; }
hsScalar GetReflFalloff() const { hsVector3 off = fState.fDepthFalloff; return off.fY; }
hsScalar GetWaveFalloff() const { hsVector3 off = fState.fDepthFalloff; return off.fZ; }
hsVector3 GetMaxAtten() const { return fState.fMaxAtten; }
hsVector3 GetMinAtten() const { return fState.fMinAtten; }
hsColorRGBA GetWaterTint() const { return fState.fWaterTint; }
hsVector3 GetWaterRGB() const { hsColorRGBA col = GetWaterTint(); return hsVector3(col.r, col.g, col.b); }
hsScalar GetWaterOpacity() const { return GetWaterTint().a; }
hsColorRGBA GetSpecularTint() const { return fState.fSpecularTint; }
hsVector3 GetSpecularRGB() const { hsColorRGBA col = GetSpecularTint(); return hsVector3(col.r, col.g, col.b); }
hsScalar GetSpecularMute() const { return GetSpecularTint().a; }
hsPoint3 GetEnvCenter() const { return fState.fEnvCenter; }
hsScalar GetEnvRadius() const { return fState.fEnvRadius; }
// Export/debugging functions. For runtime, use message interface (plGenRefMsg, plWaveMsg).
void AddTarget(const plKey& key);
void RemoveTarget(const plKey& key);
void AddShoreTest(plKey& key);
void SetRefObject(plSceneObject* refObj);
void SetSceneNode(const plKey& key);
plKey GetSceneNode() const { return fSceneNode; }
void AddDynaDecalMgr(plKey& key);
void RemoveDynaDecalMgr(plKey& key);
void AddBuoy(plKey soKey);
void RemoveBuoy(plKey soKey);
virtual hsBool SetupRippleMat(hsGMaterial* mat, const plRipVSConsts& ripConsts);
virtual hsScalar GetHeight() const { return State().fWaterHeight; }
const plFixedWaterState7::WaveState& GeoState() const { return State().fGeoState; }
const plFixedWaterState7::WaveState& TexState() const { return State().fTexState; }
const plFixedWaterState7& State() const { return fState; }
void SetState(const plFixedWaterState7& state, hsScalar dur);
void SetEnvSize(UInt32 s) { fEnvSize = s; }
UInt32 GetEnvSize() const { return fEnvSize; }
void StopLog();
void StartLog();
hsBool Logging() const { return fStatusLog != nil; }
void StartGraph();
void StopGraph();
hsBool Graphing() const { return fStatusGraph != nil; }
};
#endif // plWaveSet7_inc