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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/>.
Additional permissions under GNU GPL version 3 section 7
If you modify this Program, or any covered work, by linking or
combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK,
NVIDIA PhysX SDK, Microsoft DirectX SDK, OpenSSL library, Independent
JPEG Group JPEG library, Microsoft Windows Media SDK, or Apple QuickTime SDK
(or a modified version of those libraries),
containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA,
PhysX SDK EULA, DirectX SDK EULA, OpenSSL and SSLeay licenses, IJG
JPEG Library README, Windows Media SDK EULA, or QuickTime SDK EULA, the
licensors of this Program grant you additional
permission to convey the resulting work. Corresponding Source for a
non-source form of such a combination shall include the source code for
the parts of OpenSSL and IJG JPEG Library used as well as that of the covered
work.
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==*/
#include "hsTypes.h"
#include "hsFastMath.h"
#include "hsTimer.h"
#include "plWaveSet7.h"
#include "plWaveSetShaderConsts.h"
#include "plRipVSConsts.h"
#include "plAccessGeometry.h"
#include "plAccessSpan.h"
#include "plAccessVtxSpan.h"
#include "plAuxSpan.h"
#include "plDynaDecal.h"
#include "plDynaRippleVSMgr.h"
#include "../plMessage/plRenderMsg.h"
#include "../pnMessage/plTimeMsg.h"
#include "../pnMessage/plObjRefMsg.h"
#include "plgDispatch.h"
#include "plPipeline.h"
#include "hsResMgr.h"
#include "../pnSceneObject/plDrawInterface.h"
#include "plPhysical.h"
#include "../plMessage/plSimInfluenceMsg.h"
#include "../plSurface/hsGMaterial.h"
#include "../plDrawable/plDrawableSpans.h"
#include "../plDrawable/plDrawableGenerator.h"
#include "../plMessage/plAvatarMsg.h"
#include "../plAvatar/plArmatureMod.h"
#include "../plGImage/plMipmap.h"
#include "../plGImage/plCubicEnvironmap.h"
#include "../plSurface/plLayer.h"
#include "../plMessage/plLayRefMsg.h"
#include "../plSurface/plShader.h"
#include "../plPipeline/plRenderTarget.h"
#include "../plScene/plRenderRequest.h"
#include "../plMessage/plRenderRequestMsg.h"
#include "../plScene/plPageTreeMgr.h"
#include "../plPipeline/plDynamicEnvMap.h"
#include "../plGImage/plBumpMapGen.h"
#include "../plMessage/plMatRefMsg.h"
#include "../plMessage/plAgeLoadedMsg.h"
#include "plTweak.h"
#ifndef PLASMA_EXTERNAL_RELEASE
#include "../plStatusLog/plStatusLog.h"
#include "../plPipeline/plPlates.h"
#endif // PLASMA_EXTERNAL_RELEASE
using namespace plShaderID;
///////////////////////////////////////////////////////////////////////
#include "plProfile.h"
///////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////
#define TEST_ENVSPH
// #define TEST_UVWS
static const hsScalar kPiOverTwo = hsScalarPI * 0.5f;
static const hsScalar kGravConst = 30.f;
static const hsScalar kOOEightNsqPI = 1.f / (8.f * hsScalarPI * 4.f * 4.f);
static hsScalar currOOEightNsqPI = kOOEightNsqPI;
static inline hsScalar FreqToLen(hsScalar f) { return 2.f * hsScalarPI / f; }
static inline hsScalar LenToFreq(hsScalar l) { return 2.f * hsScalarPI / l; }
static inline hsScalar MPH2FPS(hsScalar f) { return f * 5280.f / 3600.f; }
static inline hsScalar FPS2MPH(hsScalar f) { return f / 5280.f * 3600.f; }
plCONST(hsScalar) kTimeClamp(0.3f);
inline void plWorldWave7::Accumulate(hsPoint3& accumPos, hsVector3& accumNorm) const
{
hsScalar dist = accumPos.fX * fDir.fX + accumPos.fY * fDir.fY;
dist *= fFreq;
dist += fPhase;
hsScalar s, c;
hsFastMath::SinCosAppr(dist, s, c);
// s += 1.f;
// Add scaled local Z instead? So decals can move up and down non-vertically?
// Thing is, for the height is still based on the unperterbed position, so when
// we move it laterally, the height is wrong. Maybe not too wrong, but still wrong.
// Same for normal.
accumPos.fZ += s * fAmplitude;
c *= -fFreq * fAmplitude;
accumNorm.fX += fDir.fX * c;
accumNorm.fY += fDir.fY * c;
}
#ifndef PLASMA_EXTERNAL_RELEASE
inline void plWaveSet7::GraphLen(hsScalar len) const
{
if( fStatusGraph )
{
hsScalar maxLen = TexState().fMaxLength * kCompositeSize / State().fRippleScale;
Int32 val = Int32(len / maxLen * 100.f);
fStatusGraph->AddData(val);
}
}
inline void plWaveSet7::IRestartGraph() const
{
if( fStatusGraph )
fStatusGraph->ClearData();
}
void plWaveSet7::StartGraph()
{
delete fStatusGraph;
plPlateManager::Instance().CreateGraphPlate(&fStatusGraph);
fStatusGraph->SetSize(0.25f, 0.25f);
fStatusGraph->SetDataRange(0, 100, kNumTexWaves);
fStatusGraph->SetVisible(true);
fStatusGraph->SetPosition(0.75f, -0.75f);
}
void plWaveSet7::StopGraph()
{
delete fStatusGraph;
fStatusGraph = nil;
}
inline void plWaveSet7::LogF(const char *format, ...) const
{
if( fStatusLog )
{
va_list args;
va_start(args,format);
fStatusLog->AddLineV(format, args);
va_end(args);
}
}
inline void plWaveSet7::LogF(UInt32 color, const char *format, ...) const
{
if( fStatusLog )
{
va_list args;
va_start(args,format);
fStatusLog->AddLineV(color, format, args);
va_end(args);
}
}
inline void plWaveSet7::IRestartLog() const
{
if( fStatusLog )
fStatusLog->Clear();
}
void plWaveSet7::StartLog()
{
delete fStatusLog;
fStatusLog = plStatusLogMgr::GetInstance().CreateStatusLog(kNumTexWaves, "TexWaves",
plStatusLog::kDontWriteFile | plStatusLog::kDeleteForMe | plStatusLog::kFilledBackground);
}
void plWaveSet7::StopLog()
{
delete fStatusLog;
fStatusLog = nil;
}
#else // PLASMA_EXTERNAL_RELEASE
inline void plWaveSet7::GraphLen(hsScalar len) const
{
}
inline void plWaveSet7::IRestartGraph() const
{
}
void plWaveSet7::StartGraph()
{
}
void plWaveSet7::StopGraph()
{
}
inline void plWaveSet7::LogF(const char *format, ...) const
{
}
inline void plWaveSet7::LogF(UInt32 color, const char *format, ...) const
{
}
inline void plWaveSet7::IRestartLog() const
{
}
void plWaveSet7::StartLog()
{
}
void plWaveSet7::StopLog()
{
}
#endif // PLASMA_EXTERNAL_RELEASE
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Enough of that, WaveSet (system manager) follows
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
plWaveSet7::plWaveSet7()
: fLastTime(0),
fCurrTime(0),
fScrunchLen(8.f),
fScrunchScale(2.f),
fFreqScale(1.f),
fRipVShader(nil),
fRipPShader(nil),
fShoreVShader(nil),
fShorePShader(nil),
fFixedVShader(nil),
fFixedPShader(nil),
fBiasVShader(nil),
fBiasPShader(nil),
fBumpMat(nil),
fBumpDraw(nil),
fBumpReq(nil),
fBumpReqMsg(nil),
fEnvMap(nil),
fRefObj(nil),
fCosineLUT(nil),
fGraphShoreTex(nil),
fBubbleShoreTex(nil),
fEdgeShoreTex(nil),
fMaxLen(0),
fTrialUpdate(0),
fTransistor(-1),
fTransCountDown(30.f),
fTransDel(0),
fTexTrans(0),
fTexTransCountDown(0),
fTexTransDel(0),
fStatusLog(nil),
fStatusGraph(nil)
{
IInitState();
IInitWaveConsts();
int i;
for( i = 0; i < kNumWaves; i++ )
{
fFreqMod[i] = 1.f;
IInitWave(i);
}
for( i = 0; i < 4; i++ )
{
fFixedLayers[i] = nil;
}
for( i = 0; i < kNumBumpShaders; i++ )
{
fBumpVShader[i] = nil;
fBumpPShader[i] = nil;
}
fBiasLayer[0] = nil;
fBiasLayer[1] = nil;
for( i = 0; i < kNumTexWaves; i++ )
{
fBumpLayers[i] = nil;
fTexWaveFade[i] = 1.f;
}
for( i = 0; i < kGraphShorePasses; i++ )
{
fGraphVShader[i] = nil;
fGraphPShader[i] = nil;
fGraphShoreMat[i] = nil;
fGraphShoreRT[i] = nil;
fGraphShoreDraw[i] = nil;
fGraphReq[i] = nil;
fGraphReqMsg[i] = nil;
}
for( i = 0; i < kNumDecalVShaders; i++ )
fDecalVShaders[i] = nil;
for( i = 0; i < kNumDecalPShaders; i++ )
fDecalPShaders[i] = nil;
}
plWaveSet7::~plWaveSet7()
{
delete fStatusLog;
delete fBumpReqMsg;
delete fBumpReq;
int i;
for( i = 0; i < kGraphShorePasses; i++ )
{
delete fGraphReqMsg[i];
delete fGraphReq[i];
}
}
void plWaveSet7::Read(hsStream* stream, hsResMgr* mgr)
{
plMultiModifier::Read(stream, mgr);
fMaxLen = stream->ReadSwapScalar();
fState.Read(stream);
IUpdateWindDir(0);
int n = stream->ReadSwap32();
int i;
for( i = 0; i < n; i++ )
{
mgr->ReadKeyNotifyMe(stream, TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnCreate, -1, kRefShore), plRefFlags::kPassiveRef);
}
n = stream->ReadSwap32();
for( i = 0; i < n; i++ )
{
mgr->ReadKeyNotifyMe(stream, TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnCreate, -1, kRefDecal), plRefFlags::kPassiveRef);
}
mgr->ReadKeyNotifyMe(stream, TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnCreate, -1, kRefEnvMap), plRefFlags::kActiveRef);
if( HasFlag(kHasRefObject) )
{
mgr->ReadKeyNotifyMe(stream, TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnCreate, -1, kRefRefObj), plRefFlags::kPassiveRef);
}
ISetupTextureWaves();
for( i = 0; i < kNumWaves; i++ )
{
fFreqMod[i] = 1.f;
IInitWave(i);
}
plgDispatch::Dispatch()->RegisterForExactType(plEvalMsg::Index(), GetKey());
plgDispatch::Dispatch()->RegisterForExactType(plRenderMsg::Index(), GetKey());
plgDispatch::Dispatch()->RegisterForExactType(plInitialAgeStateLoadedMsg::Index(), GetKey());
plgDispatch::Dispatch()->RegisterForExactType(plAgeLoadedMsg::Index(), GetKey());
}
void plWaveSet7::Write(hsStream* stream, hsResMgr* mgr)
{
plMultiModifier::Write(stream, mgr);
stream->WriteSwapScalar(fMaxLen);
fState.Write(stream);
stream->WriteSwap32(fShores.GetCount());
int i;
for( i = 0; i < fShores.GetCount(); i++ )
{
mgr->WriteKey(stream, fShores[i]);
}
stream->WriteSwap32(fDecals.GetCount());
for( i = 0; i < fDecals.GetCount(); i++ )
{
mgr->WriteKey(stream, fDecals[i]);
}
mgr->WriteKey(stream, fEnvMap);
if( HasFlag(kHasRefObject) )
{
mgr->WriteKey(stream, fRefObj);
}
}
hsBool plWaveSet7::MsgReceive(plMessage* msg)
{
plEvalMsg* update = plEvalMsg::ConvertNoRef(msg);
if( update )
{
if (fFixedVShader == nil)
{
ICheckTargetMaterials();
ICheckShoreMaterials();
ICheckDecalMaterials();
}
IRestartLog();
IRestartGraph();
plCONST(hsBool) reRender(false);
if( reRender || (fTrialUpdate & kReRenderEnvMap) )
{
plDynamicEnvMap* envMap = plDynamicEnvMap::ConvertNoRef(fEnvMap);
if( envMap )
{
envMap->ReRender();
fTrialUpdate &= ~kReRenderEnvMap;
}
}
hsScalar dt = update->DelSeconds();
if( dt > kTimeClamp )
dt = kTimeClamp;
IUpdateWindDir(dt);
IFloatBuoys(dt);
return true;
}
plRenderMsg* rend = plRenderMsg::ConvertNoRef(msg);
if( rend )
{
if( !IAnyBoundsVisible(rend->Pipeline()) )
return true;
fCurrTime = hsTimer::GetSysSeconds();
// Can't just use GetDelSysSeconds() or else we lose time if we skip a frame render because of high FPS.
hsScalar dt = fLastTime > 0 ? hsScalar(fCurrTime - fLastTime) : hsTimer::GetDelSysSeconds();
if( dt > kTimeClamp )
dt = kTimeClamp;
IUpdateRefObject();
IUpdateLayers(dt);
IUpdateWaves(dt);
hsMatrix44 l2w;
hsMatrix44 w2l;
IUpdateShaders(rend->Pipeline(), l2w, w2l);
IUpdateGraphShaders(rend->Pipeline(), dt);
fLastTime = fCurrTime;
return true;
}
plAgeLoadedMsg* ageLoaded = plAgeLoadedMsg::ConvertNoRef(msg);
if( (ageLoaded && ageLoaded->fLoaded) || plInitialAgeStateLoadedMsg::ConvertNoRef(msg) )
{
ICheckTargetMaterials();
ICheckShoreMaterials();
ICheckDecalMaterials();
return true;
}
plGenRefMsg* refMsg = plGenRefMsg::ConvertNoRef(msg);
if( refMsg )
{
if( refMsg->GetContext() & (plRefMsg::kOnCreate | plRefMsg::kOnRequest | plRefMsg::kOnReplace) )
{
IOnReceive(refMsg);
}
else
{
IOnRemove(refMsg);
}
return true;
}
return plMultiModifier::MsgReceive(msg);
}
hsBool plWaveSet7::IAnyBoundsVisible(plPipeline* pipe) const
{
int i;
for( i = 0; i < fTargBnds.GetCount(); i++ )
{
if( pipe->TestVisibleWorld(fTargBnds[i]) )
return true;
}
return false;
}
hsBool plWaveSet7::IOnReceive(plGenRefMsg* refMsg)
{
switch( refMsg->fType )
{
case kRefRefObj:
fRefObj = plSceneObject::ConvertNoRef(refMsg->GetRef());
return true;
case kRefCosineLUT:
fCosineLUT = plMipmap::ConvertNoRef(refMsg->GetRef());
return true;
case kRefEnvMap:
fEnvMap = plBitmap::ConvertNoRef(refMsg->GetRef());
return true;
case kRefShore:
fShores.Append(plSceneObject::ConvertNoRef(refMsg->GetRef()));
return true;
case kRefDecal:
fDecals.Append(plSceneObject::ConvertNoRef(refMsg->GetRef()));
return true;
case kRefDecVShader:
fDecalVShaders[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefDecPShader:
fDecalPShaders[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphShoreRT:
fGraphShoreRT[refMsg->fWhich] = plRenderTarget::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphVShader:
fGraphVShader[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphPShader:
fGraphPShader[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphShoreTex:
fGraphShoreTex = plMipmap::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBubbleShoreTex:
fBubbleShoreTex = plMipmap::ConvertNoRef(refMsg->GetRef());
return true;
case kRefEdgeShoreTex:
fEdgeShoreTex = plMipmap::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphShoreMat:
fGraphShoreMat[refMsg->fWhich] = hsGMaterial::ConvertNoRef(refMsg->GetRef());
return true;
case kRefGraphShoreDraw:
fGraphShoreDraw[refMsg->fWhich] = plDrawableSpans::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBiasVShader:
fBiasVShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBiasPShader:
fBiasPShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBumpVShader:
fBumpVShader[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBumpPShader:
fBumpPShader[refMsg->fWhich] = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefRipVShader:
fRipVShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefRipPShader:
fRipPShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefShoreVShader:
fShoreVShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefShorePShader:
fShorePShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefFixedVShader:
fFixedVShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefFixedPShader:
fFixedPShader = plShader::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBumpDraw:
fBumpDraw = plDrawableSpans::ConvertNoRef(refMsg->GetRef());
return true;
case kRefBumpMat:
fBumpMat = hsGMaterial::ConvertNoRef(refMsg->GetRef());
return true;
case kRefDynaDecalMgr:
{
plDynaDecalMgr* dyna = plDynaDecalMgr::ConvertNoRef(refMsg->GetRef());
if( fDecalMgrs.Find(dyna) == fDecalMgrs.kMissingIndex )
{
fDecalMgrs.Append(dyna);
}
}
return true;
case kRefBuoy:
{
plSceneObject* so = plSceneObject::ConvertNoRef(refMsg->GetRef());
if( fBuoys.Find(so) == fBuoys.kMissingIndex )
{
IShiftCenter(so);
fBuoys.Append(so);
}
}
return true;
}
return false;
}
hsBool plWaveSet7::IOnRemove(plGenRefMsg* refMsg)
{
switch( refMsg->fType )
{
case kRefRefObj:
fRefObj = nil;
return true;
case kRefCosineLUT:
fCosineLUT = nil;
return true;
case kRefEnvMap:
fEnvMap = nil;
return true;
case kRefShore:
{
plSceneObject* shore = (plSceneObject*)refMsg->GetRef();
int idx = fShores.Find(shore);
if( idx != fShores.kMissingIndex )
fShores.Remove(idx);
}
return true;
case kRefDecal:
{
plSceneObject* decal = (plSceneObject*)refMsg->GetRef();
int idx = fDecals.Find(decal);
if( idx != fDecals.kMissingIndex )
fDecals.Remove(idx);
}
return true;
case kRefDecVShader:
fDecalVShaders[refMsg->fWhich] = nil;
return true;
case kRefDecPShader:
fDecalPShaders[refMsg->fWhich] = nil;
return true;
case kRefGraphShoreRT:
fGraphShoreRT[refMsg->fWhich] = nil;
return true;
case kRefGraphVShader:
fGraphVShader[refMsg->fWhich] = nil;
return true;
case kRefGraphPShader:
fGraphPShader[refMsg->fWhich] = nil;
return true;
case kRefGraphShoreTex:
fGraphShoreTex = nil;
return true;
case kRefBubbleShoreTex:
fBubbleShoreTex = nil;
return true;
case kRefEdgeShoreTex:
fEdgeShoreTex = nil;
return true;
case kRefGraphShoreMat:
fGraphShoreMat[refMsg->fWhich] = nil;
return true;
case kRefGraphShoreDraw:
fGraphShoreDraw[refMsg->fWhich] = nil;
return true;
case kRefBiasVShader:
fBiasVShader = nil;
return true;
case kRefBiasPShader:
fBiasPShader = nil;
return true;
case kRefBumpVShader:
fBumpVShader[refMsg->fWhich] = nil;
return true;
case kRefBumpPShader:
fBumpPShader[refMsg->fWhich] = nil;
return true;
case kRefRipVShader:
fRipVShader = nil;
return true;
case kRefRipPShader:
fRipPShader = nil;
return true;
case kRefShoreVShader:
fShoreVShader = nil;
return true;
case kRefShorePShader:
fShorePShader = nil;
return true;
case kRefFixedVShader:
fFixedVShader = nil;
return true;
case kRefFixedPShader:
fFixedPShader = nil;
return true;
case kRefBumpDraw:
fBumpDraw = nil;
return true;
case kRefBumpMat:
fBumpMat = nil;
return true;
case kRefDynaDecalMgr:
{
plDynaDecalMgr* dyna = (plDynaDecalMgr*)refMsg->GetRef();
int idx = fDecalMgrs.Find(dyna);
if( fDecalMgrs.kMissingIndex != idx )
fDecalMgrs.Remove(idx);
}
return true;
case kRefBuoy:
{
plSceneObject* so = (plSceneObject*)refMsg->GetRef();
int idx = fBuoys.Find(so);
if( fBuoys.kMissingIndex != idx )
fBuoys.Remove(idx);
}
return true;
}
return false;
}
void plWaveSet7::SetState(const plFixedWaterState7& state, hsScalar dur)
{
fState.Set(state, dur);
if( fFixedLayers[0] )
{
plLayer* lay = plLayer::ConvertNoRef(fFixedLayers[0]->BottomOfStack());
lay->SetRuntimeColor(state.fWaterTint);
}
}
void plWaveSet7::IUpdateWaves(hsScalar dt)
{
ITransition(dt);
ITransTex(dt);
ICalcScale();
fScrunchLen = 1.e33f;
if( fTrialUpdate & kReInitWaves )
{
IReInitWaves();
ISetupTextureWaves();
ICreateBumpMipmapPS();
}
int i;
for( i = 0; i < kNumWaves; i++ )
{
IUpdateWave(dt, i);
}
}
// return true if we've finished this transition.
hsBool plWaveSet7::ITransContinue(hsScalar dt)
{
hsScalar currFade = (fFreqMod[fTransistor] += fTransDel * dt);
if( currFade <= 0 )
{
// Done fading down, time to fade back up.
fTransDel = -fTransDel;
fFreqMod[fTransistor] = fTransDel * dt;
// Reinit the wave. This gives a chance to introduce more randomization,
// as well as react to changing weather conditions.
IInitWave(fTransistor);
return false;
}
if( currFade >= 1.f )
{
fFreqMod[fTransistor] = 1.f;
fTransDel = 0;
return true;
}
return false;
}
void plWaveSet7::IStartTransition(hsScalar dt)
{
// select the next wave for transitioning
if( ++fTransistor >= kNumWaves )
fTransistor = 0;
// set the transFade to be fading down.
plCONST(hsScalar) kTransDel(0.5f);
fTransDel = -kTransDel;
}
hsScalar plWaveSet7::ITransitionDelay() const
{
plCONST(hsScalar) kTransDelay(2.f);
return kTransDelay;
}
void plWaveSet7::ITransition(hsScalar dt)
{
// If we're in a transition, keep transitioning till it's done.
if( fTransDel != 0 )
{
if( ITransContinue(dt) )
fTransCountDown = ITransitionDelay();
}
// else if our transition countdown has gone to zero, start a new one.
else if( (fTransCountDown -= dt) <= 0 )
{
IStartTransition(dt);
}
}
hsBool plWaveSet7::ITransTexContinue(hsScalar dt)
{
hsScalar currFade = (fTexWaveFade[fTexTrans] += fTexTransDel * dt);
if( currFade <= 0 )
{
// Done fading down, time to fade back up.
fTexTransDel = -fTexTransDel;
fTexWaveFade[fTexTrans] = fTexTransDel * dt;
// ReInit the wave
IInitTexWave(fTexTrans);
return false;
}
if( currFade >= 1.f )
{
// This one is back to full on, time to pick on another one.
fTexWaveFade[fTexTrans] = 1.f;
fTexTransDel = 0;
return true;
}
return false;
}
void plWaveSet7::IStartTexTransition(hsScalar dt)
{
if( ++fTexTrans >= kNumTexWaves )
fTexTrans = 0;
plConst(hsScalar) kTexTransDel(4.f);
fTexTransDel = -kTexTransDel;
}
void plWaveSet7::ITransTex(hsScalar dt)
{
// If we're in a transition, keep with it.
if( fTexTransDel != 0 )
{
plConst(hsScalar) kTexTransDelay(0);
if( ITransTexContinue(dt) )
fTexTransCountDown = kTexTransDelay;
}
// else if it's time to start another...
else if( (fTexTransCountDown -= dt) <= 0 )
{
IStartTexTransition(dt);
}
}
void plWaveSet7::ICalcScale()
{
}
void plWaveSet7::IUpdateWave(hsScalar dt, int i)
{
plWorldWave7& wave = fWorldWaves[i];
hsScalar len = FreqToLen(wave.fFreq);
hsScalar speed = hsFastMath::InvSqrtAppr(len / (2.f * hsScalarPI * kGravConst));
static hsScalar speedHack = 1.f;
speed *= speedHack;
wave.fPhase += speed * dt;
// wave.fPhase = fmod( speed * t, 2.f * hsScalarPI);
hsScalar amp = GeoState().fAmpOverLen * len / hsScalar(kNumWaves);
amp *= fFreqMod[i] * fFreqScale;
wave.fAmplitude = amp;
}
void plWaveSet7::IReInitWaves()
{
int i;
for( i = 0; i < kNumWaves; i++ )
{
IInitWave(i);
}
fTransDel = 0;
fTransCountDown = ITransitionDelay();
fTrialUpdate &= ~kReInitWaves;
}
void plWaveSet7::IInitWave(int i)
{
plWorldWave7& wave = fWorldWaves[i];
wave.fLength = GeoState().fMinLength + fRand.RandZeroToOne() * (GeoState().fMaxLength - GeoState().fMinLength);
hsScalar len = wave.fLength;
wave.fFreq = LenToFreq(len);
wave.fPhase = 0;
wave.fAmplitude = 0;
// Figure out the direction based on wind direction.
// Even waves go in the wind direction,
// odd waves go opposite direction
plConst(hsScalar) kMinRotDeg(15.f);
plConst(hsScalar) kMaxRotDeg(180.f);
hsVector3 dir = fWindDir;
hsScalar rotBase = GeoState().fAngleDev;
hsScalar rads = rotBase * fRand.RandMinusOneToOne();
hsScalar rx = hsScalar(cosf(rads));
hsScalar ry = hsScalar(sinf(rads));
hsScalar x = dir.fX;
hsScalar y = dir.fY;
dir.fX = x * rx + y * ry;
dir.fY = x * -ry + y * rx;
wave.fDir.Set(dir.fX, dir.fY, 0);
}
inline void plWaveSet7::IScrunch(hsPoint3& pos, hsVector3& norm) const
{
pos.fX += -norm.fX * fScrunchLen;
pos.fY += -norm.fY * fScrunchLen;
norm.fX *= fScrunchScale;
norm.fY *= fScrunchScale;
hsFastMath::NormalizeAppr(norm);
}
hsScalar plWaveSet7::EvalPoint(hsPoint3& pos, hsVector3& norm)
{
hsPoint3 accumPos;
hsVector3 accumNorm;
accumPos.Set(pos.fX, pos.fY, State().fWaterHeight);
accumNorm.Set(0,0,0);
int i;
for( i = 0; i < kNumWaves; i++ )
fWorldWaves[i].Accumulate(accumPos, accumNorm);
accumNorm.fZ = 1.f;
hsFastMath::NormalizeAppr(accumNorm);
IScrunch(accumPos, accumNorm);
// Project original pos along Z onto the plane tangent at accumPos with norm accumNorm
hsScalar t = hsVector3(&accumPos, &pos).InnerProduct(accumNorm);
t /= accumNorm.fZ;
pos.fZ += t;
norm = accumNorm;
return pos.fZ;
}
void plWaveSet7::IUpdateWindDir(hsScalar dt)
{
fWindDir = -State().fWindDir;
hsFastMath::NormalizeAppr(fWindDir);
}
void plWaveSet7::IUpdateRefObject()
{
if( fRefObj )
{
hsMatrix44 l2w = fRefObj->GetLocalToWorld();
hsScalar h = l2w.fMap[2][3];
hsScalar x = -l2w.fMap[0][1];
hsScalar y = -l2w.fMap[1][1];
fState.fWaterHeight = h;
fState.fWindDir = hsVector3(x, y, 0.f);
}
}
void plWaveSet7::IFloatBuoy(hsScalar dt, plSceneObject* so)
{
// Compute force based on world bounds
hsBounds3Ext wBnd = so->GetDrawInterface()->GetWorldBounds();
hsBounds3Ext lBnd = so->GetDrawInterface()->GetLocalBounds();
hsPoint3 pos(wBnd.GetCenter());
hsPoint3 surfPos(pos);
hsVector3 surfNorm;
EvalPoint(surfPos, surfNorm);
// Direction of impulse is surfNorm. Magnitude is proportional to depth
// (in an approximation lazy hackish way).
hsPoint2 boxDepth;
wBnd.TestPlane(surfNorm, boxDepth);
hsScalar surfDepth = surfNorm.InnerProduct(surfPos);
hsScalar depth = surfDepth - boxDepth.fX;
if( depth < 0 )
return;
if( depth > wBnd.GetMaxs().fZ - wBnd.GetMins().fZ )
depth = wBnd.GetMaxs().fZ - wBnd.GetMins().fZ;
// We really want the cross section area as facing into the water,
// but life is full of little disappointments.
hsScalar area = (wBnd.GetMaxs().fX - wBnd.GetMins().fX) * (wBnd.GetMaxs().fY - wBnd.GetMins().fY);
hsScalar volume = area * depth;
plCONST(hsScalar) kWaterDensity(1.0f);
hsScalar forceMag = volume * kWaterDensity;
// surfNorm is now the impulse vector. But where to apply it.
// Don't currently have anything informative from the physical to use.
// So, let's fake something for the moment.
plKey physKey = so->GetSimulationInterface()->GetPhysical()->GetKey();
// plImpulseMsg* iMsg = TRACKED_NEW plImpulseMsg(GetKey(), physKey, hsVector3(0, 0, 1.f) * forceMag * dt);
// iMsg->Send();
#if 0
plCONST(hsScalar) kRotScale(1.f);
hsVector3 rotAx = hsVector3(0, 0, 1.f) % surfNorm;
rotAx *= kRotScale * dt * volume;
plAngularImpulseMsg* aMsg = TRACKED_NEW plAngularImpulseMsg(GetKey(), physKey, rotAx);
aMsg->Send();
#endif
plCONST(hsScalar) kDampener(0.1f);
plCONST(hsScalar) kBaseDamp(0.1f);
if( wBnd.GetMaxs().fZ > wBnd.GetMins().fZ )
{
// Remember, we've already limited depth to be <= Max.fZ - Min.fZ;
hsScalar damp = depth / (wBnd.GetMaxs().fZ - wBnd.GetMins().fZ);
damp *= kDampener;
damp += kBaseDamp;
// plDampMsg* dMsg = TRACKED_NEW plDampMsg(GetKey(), physKey, damp);
// dMsg->Send();
}
}
void plWaveSet7::IFloatBuoys(hsScalar dt)
{
int i;
for( i = 0; i < fBuoys.GetCount(); i++ )
{
if( fBuoys[i] && fBuoys[i]->GetSimulationInterface() && fBuoys[i]->GetSimulationInterface()->GetPhysical() && fBuoys[i]->GetDrawInterface() )
{
IFloatBuoy(dt, fBuoys[i]);
}
}
}
void plWaveSet7::IShiftCenter(plSceneObject* so) const
{
// HACKAGE
if( 0 && so->GetSimulationInterface() && so->GetSimulationInterface()->GetPhysical() && so->GetDrawInterface() )
{
hsPoint3 center = so->GetDrawInterface()->GetWorldBounds().GetCenter();
hsPoint3 pos = so->GetLocalToWorld().GetTranslate();
hsVector3 offset(&pos, &center);
// plShiftMassMsg* msg = TRACKED_NEW plShiftMassMsg(GetKey(), so->GetSimulationInterface()->GetPhysical()->GetKey(), offset);
// msg->Send();
}
}
void plWaveSet7::ICheckTargetMaterials()
{
hsBounds3Ext targBnd;
targBnd.MakeEmpty();
int i;
for( i = 0; i < GetNumTargets(); i++ )
{
plSceneObject* so = GetTarget(i);
if( !so )
continue;
const plDrawInterface* di = so->GetDrawInterface();
if( !di )
continue;
hsTArray<plAccessSpan> src;
plAccessGeometry::Instance()->OpenRO(di, src, false);
const int numUVWs = src.GetCount() && src[0].AccessVtx().HasUVWs() ? src[0].AccessVtx().NumUVWs() : 0;
int j;
for( j = 0; j < src.GetCount(); j++ )
{
hsAssert(src[j].AccessVtx().NumUVWs() == numUVWs, "Must have same number uvws on each water mesh");
ICreateFixedMat(src[j].GetMaterial(), numUVWs); // no-op if it's already setup.
targBnd.Union(&src[j].GetWorldBounds());
}
plAccessGeometry::Instance()->Close(src);
for( j = 0; j < di->GetNumDrawables(); j++ )
{
plDrawableSpans* dr = plDrawableSpans::ConvertNoRef(di->GetDrawable(j));
if( dr )
{
dr->SetNativeProperty(di->GetDrawableMeshIndex(j), plSpan::kPropRunTimeLight | plSpan::kPropSkipProjection | plSpan::kPropNoShadow | plSpan::kLiteVtxNonPreshaded | plSpan::kPropReverseSort, true);
}
}
}
if( targBnd.GetType() == kBoundsNormal )
{
if( !fTargBnds.GetCount() )
fTargBnds.SetCount(1);
plConst(hsScalar) kMaxWaveHeight(5.f);
hsPoint3 p;
p = targBnd.GetMins();
p.fZ = GetHeight() - kMaxWaveHeight;
fTargBnds[0].Reset(&p);
p = targBnd.GetMaxs();
p.fZ = GetHeight() + kMaxWaveHeight;
fTargBnds[0].Union(&p);
}
}
void plWaveSet7::IAddTarget(const plKey& key)
{
plObjRefMsg* refMsg = TRACKED_NEW plObjRefMsg(key, plRefMsg::kOnRequest, -1, plObjRefMsg::kModifier);
hsgResMgr::ResMgr()->AddViaNotify( GetKey(), refMsg, plRefFlags::kActiveRef);
}
void plWaveSet7::IRemoveTarget(const plKey& key)
{
plObjRefMsg* refMsg = TRACKED_NEW plObjRefMsg(key, plRefMsg::kOnRemove, -1, plObjRefMsg::kModifier);
refMsg->SetRef(this);
refMsg->Send();
}
void plWaveSet7::AddTarget(const plKey& key)
{
IAddTarget(key);
}
void plWaveSet7::RemoveTarget(const plKey& key)
{
IRemoveTarget(key);
}
void plWaveSet7::SetRefObject(plSceneObject* refObj)
{
fFlags.SetBit(kHasRefObject, refObj != nil);
plGenRefMsg* msg = TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefRefObj);
hsgResMgr::ResMgr()->SendRef(refObj, msg, plRefFlags::kPassiveRef);
}
void plWaveSet7::AddBuoy(plKey soKey)
{
plGenRefMsg* msg = TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefBuoy);
hsgResMgr::ResMgr()->AddViaNotify(soKey, msg, plRefFlags::kPassiveRef);
}
void plWaveSet7::RemoveBuoy(plKey soKey)
{
plGenRefMsg* msg = TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRemove, 0, kRefBuoy);
msg->SetRef(soKey->ObjectIsLoaded());
msg->Send();
}
/////////////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////////////
// This is very evil. I can't believe I'm doing this. Stop me, please.
class plFilterMask
{
protected:
int fExt;
hsScalar **fMask;
public:
plFilterMask( hsScalar sig );
virtual ~plFilterMask();
int Begin() const { return -fExt; }
int End() const { return fExt; }
hsScalar Mask( int i, int j ) const { return fMask[ i ][ j ]; }
};
// End evil.
void plWaveSet7::IInitState()
{
plConst(hsScalar) kWaterTable(-10.f);
plConst(hsScalar) kWaterOffset[3] = { 3.f, 3.f, 0.f };
plConst(hsScalar) kMaxAtten[3] = { 1.f, 1.f, 1.f };
plConst(hsScalar) kMinAtten[3] = { 0.f, 0.f, 0.f };
plConst(hsScalar) kDepthFalloff[3] = { 4.f, 4.f, 6.f };
plConst(hsScalar) kGeoMinLen(3.f);
plConst(hsScalar) kGeoMaxLen(8.f);
plConst(hsScalar) kGeoAmpOverLen(0.1f);
plConst(hsScalar) kGeoAngleDev(30.f * hsScalarPI / 180.f);
plConst(hsScalar) kGeoChop(1.f);
plConst(hsScalar) kTexMinLen(4.f);
plConst(hsScalar) kTexMaxLen(30.f);
plConst(hsScalar) kTexAmpOverLen(0.1f);
plConst(hsScalar) kTexAngleDev(30.f * hsScalarPI / 180.f);
plConst(hsScalar) kTexChop(1.f);
plFixedWaterState7 state;
state.fWindDir = hsVector3(0, 1.f, 0);
state.fGeoState.fMaxLength = kGeoMaxLen;
state.fGeoState.fMinLength = kGeoMinLen;
state.fGeoState.fAmpOverLen = kGeoAmpOverLen;
state.fGeoState.fChop = kGeoChop;
state.fGeoState.fAngleDev = kGeoAngleDev;
state.fTexState.fMaxLength = kTexMaxLen;
state.fTexState.fMinLength = kTexMinLen;
state.fTexState.fAmpOverLen = kTexAmpOverLen;
state.fTexState.fChop = kTexChop;
state.fTexState.fAngleDev = kTexAngleDev;
state.fRippleScale = 25.f;
plConst(hsScalar) kNoise(1.f);
plConst(hsScalar) kSpecStart(50.f);
plConst(hsScalar) kSpecEnd(10000.f);
hsVector3 spec;
spec[state.kNoise] = kNoise;
spec[state.kSpecStart] = kSpecStart;
spec[state.kSpecEnd] = kSpecEnd;
state.fSpecVec = spec;
state.fWaterHeight = kWaterTable;
state.fWaterOffset = hsVector3(kWaterOffset[0], kWaterOffset[1], kWaterOffset[2]);
state.fMaxAtten = hsVector3(kMaxAtten[0], kMaxAtten[1], kMaxAtten[2]);
state.fMinAtten = hsVector3(kMinAtten[0], kMinAtten[1], kMinAtten[2]);
state.fDepthFalloff = hsVector3(kDepthFalloff[0], kDepthFalloff[1], kDepthFalloff[2]);
state.fWispiness = 0;
state.fShoreTint = hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f);
state.fMaxColor = hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f);
state.fMinColor = hsColorRGBA().Set(0.2f, 0.4f, 0.4f, 0.6f);
state.fEdgeOpac = 1.f;
state.fEdgeRadius = 1.f;
state.fPeriod = 3.f;
state.fFingerLength = 1.f;
state.fWaterTint = hsColorRGBA().Set(0.1f, 0.2f, 0.2f, 1.f);
state.fSpecularTint = hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f);
state.fEnvCenter = hsPoint3(0,0,0);
state.fEnvRadius = 500.f;
state.fEnvRefresh = 0.f;
fState = state;
IUpdateWindDir(0);
}
void plWaveSet7::IInitWaveConsts()
{
// See header for what fS, fK and fD actually mean.
WaveK waveKs[] = {
// fS fK fD
{ 1.f, 5.f, 0.f },
{ 1.f, 10.f, 2.f },
{ -1.f, 20.f, -9.f },
{ 1.f, 30.f, 16.f }
};
int i;
for( i = 0; i < kNumTexWaves; i++ )
fWaveKs[i] = waveKs[i];
TexWaveWindDep windDeps[] = {
// WindSpeed, Height, Specular
{ 0.f, 0.01f, 1.f },
{ 5.f, 0.05f, 0.8f },
{ 10.f, 0.05f, 0.7f },
{ 15.f, 0.1f, 0.6f },
{ 20.f, 0.1f, 0.5f },
{ 25.f, 0.1f, 0.3f }
};
for( i = 0; i < kNumWindDep; i++ )
fWindDeps[i] = windDeps[i];
ISetupTextureWaves();
}
void plWaveSet7::ISetupTextureWaves()
{
// Fill in with sine waves.
// Start with 1/4 length of map = size / 4
// Go to 4 times length of pixel = 4
// Dir = U +- iLen/(numLen/2) * V
//
// For each mip level
// For each pixel
// For each wavelen
// Add height (sine) to alpha, normal (cosine) to color
// Scrunch
// For each wavelen
// // Half the wavelen to match higher mip level
// // If a wavelen falls below min (4), discard it and smaller lens
// len /= 2
// if( len < 4 )
// {
// numLen = iLen
// break;
// }
//
// Set up our table of amplitudes, wavelengths and wave directions
// our rotation/scale in our texture transform will be
// scale = waveKs.fK
// dir.x * scale, dir.y * scale
// -dir.y * scale, dir.x * scale
// So to tile, dir.x * scale and dir.y * scale must be integers.
// We select a randomized direction and a wavelength, then
// round the scaled direction components to be integral, then
// figure out what wavelength we actually came up with.
int i;
for( i = 0; i < kNumTexWaves; i++ )
{
IInitTexWave(i);
}
fTrialUpdate &= ~kReInitWaves;
return;
}
void plWaveSet7::IInitTexWave(int i)
{
hsScalar rads = fRand.RandMinusOneToOne() * TexState().fAngleDev;
hsScalar dx = sin(rads);
hsScalar dy = cos(rads);
hsScalar tx = dx;
dx = fWindDir.fY * dx - fWindDir.fX * dy;
dy = fWindDir.fX * tx + fWindDir.fY * dy;
hsScalar maxLen = TexState().fMaxLength * kCompositeSize / State().fRippleScale;
hsScalar minLen = TexState().fMinLength * kCompositeSize / State().fRippleScale;
hsScalar len = hsScalar(i) / hsScalar(kNumTexWaves-1) * (maxLen - minLen) + minLen;
hsScalar reps = hsScalar(kCompositeSize) / len;
dx *= reps;
dy *= reps;
dx = float(int(dx >= 0 ? dx + 0.5f : dx - 0.5f));
dy = float(int(dy >= 0 ? dy + 0.5f : dy - 0.5f));
fTexWaves[i].fRotScale00 = dx;
fTexWaves[i].fRotScale01 = dy;
hsScalar effK = hsFastMath::InvSqrt(dx*dx + dy*dy);
fTexWaves[i].fLen = hsScalar(kCompositeSize) * effK;
fTexWaves[i].fFreq = hsScalarPI * 2.f / fTexWaves[i].fLen;
fTexWaves[i].fAmp = fTexWaves[i].fLen * TexState().fAmpOverLen;
fTexWaves[i].fPhase = fRand.RandZeroToOne();
fTexWaves[i].fDirX = dx * effK;
fTexWaves[i].fDirY = dy * effK;
}
/////////////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////////////
void plWaveSet7::SetSceneNode(const plKey& key)
{
fSceneNode = key;
}
void plWaveSet7::AddDynaDecalMgr(plKey& key)
{
plGenRefMsg* msg = TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefDynaDecalMgr);
hsgResMgr::ResMgr()->AddViaNotify(key, msg, plRefFlags::kPassiveRef);
msg = TRACKED_NEW plGenRefMsg(key, plRefMsg::kOnRequest, 0, plDynaRippleVSMgr::kRefWaveSetBase);
hsgResMgr::ResMgr()->AddViaNotify(GetKey(), msg, plRefFlags::kPassiveRef);
}
void plWaveSet7::RemoveDynaDecalMgr(plKey& key)
{
plGenRefMsg* msg = TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRemove, 0, kRefDynaDecalMgr);
msg->SetRef(key->ObjectIsLoaded());
msg->Send();
msg = TRACKED_NEW plGenRefMsg(key, plRefMsg::kOnRemove, 0, plDynaRippleVSMgr::kRefWaveSetBase);
msg->SetRef(this);
msg->Send();
}
//////////////////////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////////////////////
void plWaveSet7::IUpdateLayers(hsScalar dt)
{
IUpdateBumpLayers(dt);
ISubmitRenderRequests();
}
void plWaveSet7::IUpdateBumpLayers(hsScalar dt)
{
plCONST(hsScalar) speedHack(1.f / 3.f);
int i;
for( i = 0; i < kNumTexWaves; i++ )
{
hsScalar speed = hsFastMath::InvSqrtAppr(fTexWaves[i].fLen / (2.f * hsScalarPI * kGravConst)) * speedHack;
fTexWaves[i].fPhase -= dt * speed;
fTexWaves[i].fPhase -= int(fTexWaves[i].fPhase);
if( fBumpLayers[i] )
{
hsMatrix44 xfm = fBumpLayers[i]->GetTransform();
xfm.fMap[0][0] = fTexWaves[i].fRotScale00;
xfm.fMap[0][1] = fTexWaves[i].fRotScale01;
xfm.fMap[1][0] = -fTexWaves[i].fRotScale01;
xfm.fMap[1][1] = fTexWaves[i].fRotScale00;
xfm.fMap[0][3] = fTexWaves[i].fPhase;
fBumpLayers[i]->SetTransform(xfm);
}
LogF("%.4d - L%8.4f R(%5.3f, %5.3f)", i, fTexWaves[i].fLen, fTexWaves[i].fRotScale00, fTexWaves[i].fRotScale01);
GraphLen(fTexWaves[i].fLen);
}
}
void plWaveSet7::ISubmitRenderRequests()
{
if( fBumpReqMsg )
fBumpReqMsg->SendAndKeep();
int i;
for( i = 0; i < kGraphShorePasses; i++ )
{
if( fGraphReqMsg[i] )
fGraphReqMsg[i]->SendAndKeep();
}
}
plMipmap* plWaveSet7::ICreateBumpBitmapFFP(hsScalar amp, hsScalar dx, hsScalar dy) const
{
return nil;
}
hsGMaterial* plWaveSet7::ICreateBumpLayersFFP()
{
// Create kNumTexWaves bitmaps, each containing a single cycle of values:
// mag = 0.25 * -Amplitude * cos(i/sz*2*Pi)
// r = mag * dx * 0.5 + 0.5
// g = mag * dy * 0.5 + 0.5
// b = 0.7 * 0.25 * 0.5 + 0.5
// a = 1.f
//
// Where:
// Amplitude == wave.amp * wave.freq * kNormHack(3.0)
// dx, dy == wave.fDir
//
// Create a blank material
// Create base layer
// Blend mode is none
// Transform scales to wave[0].freq
// No rotation, translation
// Add bitmap 0.
// For layers 1..kNumTexWaves
// Create blank layer
// Blend mode is ADDSIGNED
// Transform scales to wave[i].freq
// No rotation or translation.
// Add bitmap i;
// NOTE: if we use the fixed function pipeline to composite
// these into the CompositeMaterial, then they all need to
// be scaled down to avoid saturation on summation.
// Doing the composite with a pixel shader would allow the
// textures to be stored in full 256 range, and then scaled
// down during the summation, after interpolation. Would
// that be better? Not sure. Pixel shader registers only have
// a range of [-1..1], and it's hinted to be 8-bit fixed point.
// So we'd still have to scale down texture value (losing precision),
// then add it in.
//
// Also, for pixel shaded compositing, we can just store the cosine
// values in each layer, with no rotation in the bitmap values, just
// in the layer transform. No rotation would make for a cleaner
// interpolation (not interpolating diagonally across the waves).
// How much difference is that? Dunno. But it would also allow the
// bitmap to hold the full range [-1..1]=>[0..255] of cosine values,
// scaling them down with constants. The pixel shader would look like:
//
// tex t0;
// tex t1;
// tex t2;
// tex t3;
//
// mul r0, t0_bx2, c0;
// mad r0, t1_bx2, c1, r0;
// mad r0, t2_bx2, c2, r0;
// mad r0, t3_bx2, c3, r0;
// // Now bias it back into range [0..1] for output.
// mad r0, r0, c4, c5; // c4 = (0.5, 0.5, 0.5, 1), c5 = (0.5, 0.5, 0.5, 0)
// // or add_d2 r0, r0, c0.b; // except this is likely to saturate before the divide. Dunno.
//
// where the c[i] constants would be:
// c[i] = -wave[i].amp * wave[i].freq * kSomeNormHack * (wave[i].fDir.x, wave[i].fDir.y, 0, 1)
// except c[0].b = 0.7;
// In fact, we could cut it down to 2 textures using alpha replicate, except we need different
// transforms for each (for animation). So screw that.
//
// Note that the above won't run on a ps.1.0 pixel shader, because the combined number of tex and
// arith instructions is 9. Could make a version that was okay for ps.1.0 by doing:
//
// mad r0, t0_bias, c0, c4; // t0[-0.5..0.5]*c0 + 0.5, which is [0..1]
// mad r0, t1_bias, c1, r0; // + t1[-0.5..0.5]*c1
// mad r0, t2_bias, c2, r0; // + t2[-0.5..0.5]*c2
// mad r0, t3_bias, c3, r0; // + t3[-0.5..0.5]*c3
//
// which doesn't need a final bias instruction because it remains biased all the way through
// at the cost of 1 bit of precision.
// Whatever.
//
// return material;
return nil;
}
plMipmap* plWaveSet7::ICreateBiasNoiseMap()
{
const int size = kCompositeSize >> 2;
plMipmap* mipMap = TRACKED_NEW plMipmap(
size, size,
plMipmap::kARGB32Config,
1,
plMipmap::kUncompressed,
plMipmap::UncompressedInfo::kRGB8888);
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), "BiasBitPS");
hsgResMgr::ResMgr()->NewKey(buff, mipMap, GetKey()->GetUoid().GetLocation());
int i;
for( i = 0; i < size; i++ )
{
int j;
for( j = 0; j < size; j++ )
{
hsScalar x = fRand.RandMinusOneToOne();
hsScalar y = fRand.RandMinusOneToOne();
UInt8 r = UInt8((x * 0.5f + 0.5f) * 255.999f);
UInt8 g = UInt8((y * 0.5f + 0.5f) * 255.999f);
// r = g = 0xff; // SATURATE
UInt32* val = mipMap->GetAddr32(i, j);
*val = (0xff << 24)
| (r << 16)
| (g << 8)
| 0xff;
}
}
// For bonus points, modulate by a VERY coherent noise function.
return mipMap;
}
plMipmap* plWaveSet7::ICreateBumpMipmapPS()
{
// const int sizeV = kCompositeSize;
const int sizeV = 1;
const kNumLevels = 8; // must be log2(kCompositeSize)
hsAssert(kCompositeSize == (1 << kNumLevels), "Mismatch on size and num mip levels");
if( !fCosineLUT )
{
plMipmap* mipMap = TRACKED_NEW plMipmap(
kCompositeSize, sizeV,
plMipmap::kARGB32Config,
kNumLevels,
plMipmap::kUncompressed,
plMipmap::UncompressedInfo::kRGB8888);
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), "BumpBitPS");
hsgResMgr::ResMgr()->NewKey(buff, mipMap, GetKey()->GetUoid().GetLocation());
hsgResMgr::ResMgr()->SendRef(mipMap->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefCosineLUT), plRefFlags::kActiveRef);
}
hsAssert(fCosineLUT, "Failed to make cosine lookup table");
int k;
for( k = 0; k < kNumLevels; k++ )
{
fCosineLUT->SetCurrLevel(k);
const int sizeU = kCompositeSize >> k;
int i;
for( i = 0; i < sizeU; i++ )
{
hsScalar y = hsScalar(i);
hsScalar dist = hsScalar(i) / hsScalar(sizeU-1) * 2.f * hsScalarPI;
hsScalar c = cos(dist);
hsScalar s = sin(dist);
s *= 0.5f;
s += 0.5f;
s = hsScalar(pow(s, TexState().fChop));
c *= s;
UInt8 cosDist = UInt8((c * 0.5 + 0.5) * 255.999f);
int j;
for( j = 0; j < sizeV; j++ )
{
UInt32* val = fCosineLUT->GetAddr32(i, j);
*val = (0xff << 24)
| (cosDist << 16)
| (cosDist << 8)
| 0xff;
}
}
}
fCosineLUT->MakeDirty();
return fCosineLUT;
}
void plWaveSet7::IAddBumpBiasLayer(hsGMaterial* mat)
{
if( !fBiasLayer[0] )
{
plMipmap* mipMap = ICreateBiasNoiseMap();
int i;
for( i = 0; i < 2; i++ )
{
plLayer* layer = TRACKED_NEW plLayer;
char buff[256];
sprintf(buff, "%s_%s_%d", GetKey()->GetName(), "Bias", i);
hsgResMgr::ResMgr()->NewKey(buff, layer, GetKey()->GetUoid().GetLocation());
layer->SetBlendFlags(hsGMatState::kBlendAdd);
layer->SetZFlags(hsGMatState::kZNoZRead | hsGMatState::kZNoZWrite);
layer->SetShadeFlags(hsGMatState::kShadeReallyNoFog
| hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade);
layer->SetClampFlags(0);
layer->SetMiscFlags(0);
layer->SetMiscFlags(i ? 0 : hsGMatState::kMiscRestartPassHere);
layer->SetAmbientColor(hsColorRGBA().Set(0.25f, 0.25f, 0.f, 0.f));
layer->SetRuntimeColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 0.f));
layer->SetOpacity(0.f);
layer->SetUVWSrc(0);
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kTexture);
hsgResMgr::ResMgr()->SendRef(mipMap->GetKey(), refMsg, plRefFlags::kActiveRef);
IAddBumpBiasShaders(layer);
fBiasLayer[i] = layer; // SHOULD BE REFFED (SO SHOULD fBumpLayers)
}
}
mat->AddLayerViaNotify(fBiasLayer[0]);
mat->AddLayerViaNotify(fBiasLayer[1]);
}
plLayer* plWaveSet7::ICreateBumpLayerPS(plMipmap* mipMap, hsGMaterial* bumpMat, int which)
{
plLayer* layer = TRACKED_NEW plLayer;
char buff[256];
sprintf(buff, "%s_%s_%d", GetKey()->GetName(), "BumpLayerPS", which);
hsgResMgr::ResMgr()->NewKey(buff, layer, GetKey()->GetUoid().GetLocation());
layer->SetBlendFlags(which ? hsGMatState::kBlendAdd : 0);
layer->SetZFlags(hsGMatState::kZNoZRead | hsGMatState::kZNoZWrite);
layer->SetShadeFlags(hsGMatState::kShadeReallyNoFog
| hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
layer->SetClampFlags(0);
layer->SetMiscFlags(0);
if( (which / kBumpPerPass) * kBumpPerPass == which )
layer->SetMiscFlags(hsGMatState::kMiscRestartPassHere);
layer->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
layer->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
layer->SetOpacity(1.f);
layer->SetUVWSrc(0);
// Set up the transform.
hsMatrix44 xfm;
xfm.Reset();
xfm.NotIdentity();
xfm.fMap[0][0] = fTexWaves[which].fRotScale00;
xfm.fMap[0][1] = fTexWaves[which].fRotScale01;
xfm.fMap[1][0] = -fTexWaves[which].fRotScale01;
xfm.fMap[1][1] = fTexWaves[which].fRotScale00;
layer->SetTransform(xfm);
bumpMat->AddLayerViaNotify(layer);
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kTexture);
hsgResMgr::ResMgr()->SendRef(mipMap->GetKey(), refMsg, plRefFlags::kActiveRef);
return layer;
}
hsGMaterial* plWaveSet7::ICreateBumpLayersPS()
{
if( fBumpMat )
return fBumpMat;
// Create four bitmaps, each containing a single cycle of values:
// mag = cos(i/sz*2*Pi)
// r = 0
// g = mag* 0.5 + 0.5
// b = 1.f
// a = 1.f
//
// Where:
// Amplitude == wave.amp * wave.freq * kNormHack(3.0)
//
// Create a blank material
hsGMaterial* bumpMat = TRACKED_NEW hsGMaterial;
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), "BumpMatPS");
hsgResMgr::ResMgr()->NewKey(buff, bumpMat, GetKey()->GetUoid().GetLocation());
plMipmap* mipMap = ICreateBumpMipmapPS();
// Create base layer
// Blend mode is none
// Transform scales to wave[0].freq
// No translation
// Rotation is by wave[0].fDir
// Add bitmap 0.
int i;
for( i = 0; i < kNumBumpShaders; i++ )
{
int nBegin = bumpMat->GetNumLayers();
int j;
for( j = 0; j < kBumpPerPass; j++ )
fBumpLayers[i*kBumpPerPass + j] = ICreateBumpLayerPS(mipMap, bumpMat, i*kBumpPerPass + j);
IAddBumpVertexShader(bumpMat, i, nBegin, nBegin + kBumpPerPass-1);
IAddBumpPixelShader(bumpMat, i, nBegin, nBegin + kBumpPerPass-1);
}
IAddBumpBiasLayer(bumpMat);
// Need to add this via notify to ourselves.
hsgResMgr::ResMgr()->SendRef(bumpMat->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefBumpMat), plRefFlags::kActiveRef);
ICreateBumpDrawable();
return fBumpMat = bumpMat;
}
void plWaveSet7::IAddBumpBiasShaders(plLayer* layer)
{
if( !fBiasVShader )
{
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_BiasVS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetNumConsts(plBiasVS::kNumConsts);
vShader->SetVector(plBiasVS::kTexU0,
1.f,
0.f,
0.f,
0.f);
vShader->SetVector(plBiasVS::kTexV0,
0.f,
1.f,
0.f,
0.f);
vShader->SetVector(plBiasVS::kTexU1,
1.f,
0.f,
0.f,
0.f);
vShader->SetVector(plBiasVS::kTexV1,
0.f,
1.f,
0.f,
0.f);
vShader->SetVector(plBiasVS::kNumbers,
0.f,
0.5f,
1.f,
2.f);
hsVector3 specVec = State().fSpecVec;
hsScalar biasScale = 0.5f * specVec[State().kNoise] / (hsScalar(kNumBumpShaders) + specVec[State().kNoise]);
vShader->SetVector(plBiasVS::kScaleBias,
biasScale,
biasScale,
0.f,
1.f);
vShader->SetInputFormat(1);
vShader->SetOutputFormat(0);
// static const plShaderDecl vDecl("sha/vs_BiasNormals.inl");
// vShader->SetDecl(&vDecl);
vShader->SetDecl(plShaderTable::Decl(vs_BiasNormals));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefBiasVShader), plRefFlags::kActiveRef);
fBiasVShader = vShader;
}
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kVertexShader);
hsgResMgr::ResMgr()->SendRef(fBiasVShader->GetKey(), refMsg, plRefFlags::kActiveRef);
if( !fBiasPShader )
{
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_BiasPS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
pShader->SetNumConsts(plBiasPS::kNumConsts);
pShader->SetInputFormat(0);
pShader->SetOutputFormat(0);
// static const plShaderDecl pDecl("sha/ps_BiasNormals.inl");
// pShader->SetDecl(&pDecl);
pShader->SetDecl(plShaderTable::Decl(ps_BiasNormals));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefBiasPShader), plRefFlags::kActiveRef);
fBiasPShader = pShader;
}
refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kPixelShader);
hsgResMgr::ResMgr()->SendRef(fBiasPShader->GetKey(), refMsg, plRefFlags::kActiveRef);
}
void plWaveSet7::IAddBumpVertexShader(hsGMaterial* mat, int iShader, int iFirst, int iLast)
{
if( !fBumpVShader[0] )
{
int iBase = 0;
while( iBase < kNumTexWaves )
{
int iShader = iBase / kBumpPerPass;
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_BumpVS_%d", GetKey()->GetName(), iShader);
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetNumConsts(plBumpVS::kNumConsts);
vShader->SetVector(plBumpVS::kNumbers,
0.f,
0.5f,
1.f,
2.f);
vShader->SetInputFormat(1);
vShader->SetOutputFormat(0);
vShader->SetNumPipeConsts(kBumpPerPass);
int i;
for( i = 0; i < kBumpPerPass; i++ )
{
vShader->SetPipeConst(i, static_cast<plPipeConst::Type>(plPipeConst::kTex1x4_0 + i), plBumpVS::kUXform0 + i);
}
vShader->SetDecl(plShaderTable::Decl(vs_CompCosines));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, iShader, kRefBumpVShader), plRefFlags::kActiveRef);
fBumpVShader[iShader] = vShader;
iBase += kBumpPerPass;
}
}
IAddShaderToLayers(mat, iFirst, iLast, plLayRefMsg::kVertexShader, fBumpVShader[iShader]);
}
void plWaveSet7::IAddBumpPixelShader(hsGMaterial* mat, int iShader, int iFirst, int iLast)
{
if( !fBumpPShader[0] )
{
int iBase = 0;
while( iBase < kNumTexWaves )
{
int iShader = iBase / kBumpPerPass;
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_BumpPS_%d", GetKey()->GetName(), iShader);
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
pShader->SetNumConsts(plBumpPS::kNumConsts);
int iLay;
for( iLay = 0; iLay < kBumpPerPass; iLay++ )
{
pShader->SetVector(plBumpPS::kWave0,
-fTexWaves[iBase + iLay].fDirX * (1.f / hsScalar(kBumpPerPass)),
-fTexWaves[iBase + iLay].fDirY * (1.f / hsScalar(kBumpPerPass)),
1.f,
1.f);
}
pShader->SetInputFormat(0);
pShader->SetOutputFormat(0);
// pShader->SetShaderFileName("sha/ps_CompCosines.inl");
// pShader->SetShaderFileName("sha/ps_TestPos.inl");
// static const plShaderDecl moreDecl("sha/ps_MoreCosines.inl");
// pShader->SetDecl(&moreDecl);
pShader->SetDecl(plShaderTable::Decl(ps_MoreCosines));
pShader->SetVector(plBumpPS::kHalfOne, 0.25f, 0.25f, 0.25f, 1.f);
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, iShader, kRefBumpPShader), plRefFlags::kActiveRef);
fBumpPShader[iShader] = pShader;
iBase += kBumpPerPass;
}
}
IAddShaderToLayers(mat, iFirst, iLast, plLayRefMsg::kPixelShader, fBumpPShader[iShader]);
}
plDrawableSpans* plWaveSet7::ICreateBumpDrawable()
{
fBumpDraw = TRACKED_NEW plDrawableSpans;
char buff[256];
sprintf(buff, "%s_BumpDraw", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, fBumpDraw, GetKey()->GetUoid().GetLocation());
ICreateClearDrawable(fBumpDraw, fBumpMat);
hsgResMgr::ResMgr()->SendRef(fBumpDraw->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefBumpDraw), plRefFlags::kActiveRef);
return fBumpDraw;
}
plDrawableSpans* plWaveSet7::ICreateClearDrawable(plDrawableSpans* drawable, hsGMaterial* mat)
{
// drawable->SetNativeProperty(plDrawable::kPropVolatile, true);
hsPoint3 pos[4];
hsVector3 norm[4];
hsPoint3 uvw[4];
pos[0].fX = -1.f;
pos[0].fY = -1.f;
pos[0].fZ = 0.5f;
norm[0].Set(0.f, 0.f, -1.f);
uvw[0].fX = 0.5f / kCompositeSize;
uvw[0].fY = 0.5f / kCompositeSize;
uvw[0].fZ = 0;
// P1
pos[1] = pos[0];
pos[1].fY += 2.f;
norm[1] = norm[0];
uvw[1] = uvw[0];
uvw[1].fY += 1.f;
// P2
pos[2] = pos[0];
pos[2].fX += 2.f;
pos[2].fY += 2.f;
norm[2] = norm[0];
uvw[2] = uvw[0];
uvw[2].fX += 1.f;
uvw[2].fY += 1.f;
// P3
pos[3] = pos[0];
pos[3].fX += 2.f;
norm[3] = norm[0];
uvw[3] = uvw[0];
uvw[3].fX += 1.f;
UInt16 idx[6];
idx[0] = 1;
idx[1] = 0;
idx[2] = 2;
idx[3] = 2;
idx[4] = 0;
idx[5] = 3;
plDrawableGenerator::GenerateDrawable( 4, pos, norm,
uvw, 1,
nil, false, nil,
6, idx,
mat,
hsMatrix44::IdentityMatrix(),
false,
nil,
drawable);
return drawable;
}
plRenderRequest* plWaveSet7::ICreateRenderRequest(plRenderTarget* rt, plDrawableSpans* draw, hsScalar pri)
{
plRenderRequest* req = TRACKED_NEW plRenderRequest;
static plPageTreeMgr emptyMgr;
req->SetPageTreeMgr(&emptyMgr);
req->SetClearDrawable(draw);
req->SetOrthogonal(true);
req->SetLocalTransform(hsMatrix44::IdentityMatrix(), hsMatrix44::IdentityMatrix());
req->SetCameraTransform(hsMatrix44::IdentityMatrix(), hsMatrix44::IdentityMatrix());
req->SetHither(0);
req->SetYon(2.f);
req->SetSizeX(2.f);
req->SetSizeY(2.f);
req->SetPriority(pri);
req->SetRenderTarget(rt);
return req;
}
plRenderTarget* plWaveSet7::ICreateTransferRenderTarget(const char* name, int size)
{
UInt16 flags = plRenderTarget::kIsTexture | plRenderTarget::kIsOrtho;
UInt8 bitDepth = 32;
UInt8 zDepth = 0;
UInt8 stencilDepth = 0;
plRenderTarget* rt = TRACKED_NEW plRenderTarget(flags, size, size, bitDepth, zDepth, stencilDepth);
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), name);
hsgResMgr::ResMgr()->NewKey(buff, rt, GetKey()->GetUoid().GetLocation());
return rt;
}
plLayer* plWaveSet7::ICreateTotalLayer(plBitmap* bm, hsGMaterial* mat, int which, const char* suff)
{
plLayer* layer = mat->GetNumLayers() > which ? plLayer::ConvertNoRef(mat->GetLayer(which)->BottomOfStack()) : nil;
if( !layer )
{
layer = TRACKED_NEW plLayer;
char buff[256];
sprintf(buff, "%s_%sLayerPS_%d", GetKey()->GetName(), suff, which);
hsgResMgr::ResMgr()->NewKey(buff, layer, GetKey()->GetUoid().GetLocation());
layer->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
layer->SetRuntimeColor(State().fWaterTint);
layer->SetOpacity(1.f);
mat->AddLayerViaNotify(layer);
}
layer->SetBlendFlags(which ? hsGMatState::kBlendAddSigned : hsGMatState::kBlendAlpha);
layer->SetZFlags(which ? hsGMatState::kZNoZWrite : 0);
layer->SetShadeFlags(hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade);
layer->SetClampFlags(0);
layer->SetMiscFlags(hsGMatState::kMiscTwoSided);
layer->SetUVWSrc(which);
// Set up the transform.
hsMatrix44 xfm;
xfm.Reset();
layer->SetTransform(xfm);
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kTexture);
hsgResMgr::ResMgr()->SendRef(bm->GetKey(), refMsg, plRefFlags::kActiveRef);
return layer;
}
plLayer* plWaveSet7::ICreateTotalEnvLayer(plBitmap* envMap, hsGMaterial* mat, int which, const char* pref)
{
plLayer* layer = TRACKED_NEW plLayer;
char buff[256];
sprintf(buff, "%s_%s_%s_%d", GetKey()->GetName(), pref, "EnvLayerPS", which);
hsgResMgr::ResMgr()->NewKey(buff, layer, GetKey()->GetUoid().GetLocation());
layer->SetBlendFlags(which ? hsGMatState::kBlendAddSigned : 0);
layer->SetZFlags(which ? hsGMatState::kZNoZWrite : 0);
layer->SetShadeFlags(hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade);
layer->SetClampFlags(0);
layer->SetMiscFlags(0);
layer->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
layer->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
layer->SetOpacity(1.f);
layer->SetUVWSrc(which);
// Set up the transform.
hsMatrix44 xfm;
xfm.Reset();
layer->SetTransform(xfm);
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, plLayRefMsg::kTexture);
hsgResMgr::ResMgr()->SendRef(envMap->GetKey(), refMsg, plRefFlags::kActiveRef);
mat->AddLayerViaNotify(layer);
return layer;
}
hsGMaterial* plWaveSet7::ICreateFixedMatPS(hsGMaterial* mat, const int numUVWs)
{
hsAssert(mat, "Nil mat should have been filtered out before calling this");
// Check if we've already done this one.
if( (mat->GetNumLayers() == 4)
&&(mat->GetLayer(3) == fFixedLayers[3]) )
return mat;
// First, strip off whatever's on there now.
// If this is the
int i;
for( i = mat->GetNumLayers()-1; i > 0; i-- )
{
plMatRefMsg* refMsg = TRACKED_NEW plMatRefMsg(mat->GetKey(), plRefMsg::kOnRemove, i, plMatRefMsg::kLayer);
hsgResMgr::ResMgr()->SendRef(mat->GetLayer(i)->GetKey(), refMsg, plRefFlags::kActiveRef);
}
plRenderTarget* rt = ICreateTransferRenderTarget("CompRT", kCompositeSize);
if( mat->GetNumLayers() && mat->GetLayer(0) )
{
fState.fWaterTint = mat->GetLayer(0)->GetRuntimeColor();
}
fFixedLayers[0] = ICreateTotalLayer(rt, mat, 0, "Fix");
fFixedLayers[1] = ICreateTotalLayer(rt, mat, 1, "Fix");
fFixedLayers[2] = ICreateTotalLayer(rt, mat, 2, "Fix");
fFixedLayers[3] = ICreateTotalEnvLayer(fEnvMap, mat, 3, "Fix");
fBumpReq = ICreateRenderRequest(rt, fBumpDraw, -100.f);
fBumpReqMsg = TRACKED_NEW plRenderRequestMsg(GetKey(), fBumpReq);
IAddFixedVertexShader(mat, numUVWs);
IAddFixedPixelShader(mat);
return mat;
}
void plWaveSet7::ICreateFixedMat(hsGMaterial* mat, const int numUVWs)
{
if( !mat )
return;
if( !fEnvMap )
{
plDynamicEnvMap* env = TRACKED_NEW plDynamicEnvMap((UInt16)fEnvSize, (UInt16)fEnvSize, 32);
hsgResMgr::ResMgr()->NewKey(GetKey()->GetName(), env, GetKey()->GetUoid().GetLocation());
fEnvMap = env;
env->SetPosition(hsPoint3(0, 0, 50.f));
env->SetPosition(State().fEnvCenter);
env->SetYon(10000.f);
env->SetRefreshRate(State().fEnvRefresh);
env->Init();
env->ReRender();
}
ICreateBumpLayersPS();
ICreateFixedMatPS(mat, numUVWs);
}
void plWaveSet7::IAddShoreVertexShader(hsGMaterial* mat)
{
if( !fShoreVShader )
{
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_ShoreVS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetNumConsts(plShoreVS::kNumConsts);
vShader->SetInputFormat(1); // This should really be one!!!
vShader->SetOutputFormat(0);
vShader->SetVector(plShoreVS::kSinConsts, 1.f, -1.f/6.f, 1.f/120.f, -1.f/5040.f);
vShader->SetVector(plShoreVS::kCosConsts, 1.f, -1.f/2.f, 1.f/24.f, -1.f/720.f);
vShader->SetVector(plShoreVS::kPiConsts, 1.f / (8.f*hsScalarPI*4.f*4.f), hsScalarPI/2.f, hsScalarPI, hsScalarPI*2.f);
vShader->SetVector(plShoreVS::kNumericConsts, 0, 0.5f, 1.f, 2.f);
plConst(hsScalar) kK1(0.5f);
plConst(hsScalar) kK2(1.5f);
hsScalar negK1OverK2Sq = -kK1 / (kK2 * kK2);
vShader->SetVector(plShoreVS::kIncline, negK1OverK2Sq, kK1, 0.f, 0.f);
vShader->SetNumPipeConsts(5);
vShader->SetPipeConst(0, plPipeConst::kWorldToNDC, plShoreVS::kWorldToNDC);
vShader->SetPipeConst(1, plPipeConst::kTex3x4_0, plShoreVS::kTex0Transform);
vShader->SetPipeConst(2, plPipeConst::kLocalToWorld, plShoreVS::kLocalToWorld);
vShader->SetPipeConst(3, plPipeConst::kLayRuntime, plShoreVS::kShoreTint);
vShader->SetPipeConst(4, plPipeConst::kFogSet, plShoreVS::kFogSet);
// vShader->SetShaderFileName("sha/vs_Shore.inl");
// vShader->SetShaderFileName("sha/vs_ShoreSteep.inl");
// vShader->SetShaderFileName("sha/vs_ShoreSucks.inl");
// vShader->SetShaderFileName("sha/vs_ShoreLeave.inl");
// vShader->SetShaderFileName("sha/vs_ShoreLeave6.inl");
// vShader->SetDecl(plShaderTable::Decl(vs_ShoreLeave6));
// static const plShaderDecl decl("sha/vs_ShoreLeave7.inl");
// vShader->SetDecl(&decl);
vShader->SetDecl(plShaderTable::Decl(vs_ShoreLeave7));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefShoreVShader), plRefFlags::kActiveRef);
fShoreVShader = vShader;
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kVertexShader, fShoreVShader);
}
void plWaveSet7::IAddShorePixelShader(hsGMaterial* mat)
{
if( !fShorePShader )
{
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_ShorePS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
// pShader->SetShaderFileName("sha/ps_ShoreSucks.inl");
// pShader->SetShaderFileName("sha/ps_ShoreLeave6.inl");
pShader->SetDecl(plShaderTable::Decl(ps_ShoreLeave6));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefShorePShader), plRefFlags::kActiveRef);
fShorePShader = pShader;
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kPixelShader, fShorePShader);
}
void plWaveSet7::IAddFixedVertexShader(hsGMaterial* mat, const int numUVWs)
{
if( !fFixedVShader )
{
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_FixedVS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetNumConsts(plFixedVS7::kNumConsts);
vShader->SetInputFormat(numUVWs);
vShader->SetOutputFormat(0);
vShader->SetVector(plFixedVS7::kSinConsts, 1.f, -1.f/6.f, 1.f/120.f, -1.f/5040.f);
vShader->SetVector(plFixedVS7::kCosConsts, 1.f, -1.f/2.f, 1.f/24.f, -1.f/720.f);
vShader->SetVector(plFixedVS7::kPiConsts, 1.f / (8.f*hsScalarPI*4.f*4.f), hsScalarPI/2.f, hsScalarPI, hsScalarPI*2.f);
vShader->SetVector(plFixedVS7::kNumericConsts, 0, 0.5f, 1.f, 2.f);
vShader->SetNumPipeConsts(5);
vShader->SetPipeConst(0, plPipeConst::kWorldToNDC, plFixedVS7::kWorldToNDC);
vShader->SetPipeConst(1, plPipeConst::kCamPosWorld, plFixedVS7::kCameraPos);
vShader->SetPipeConst(2, plPipeConst::kLocalToWorld, plFixedVS7::kLocalToWorld);
vShader->SetPipeConst(3, plPipeConst::kLayRuntime, plFixedVS7::kWaterTint);
vShader->SetPipeConst(4, plPipeConst::kFogSet, plFixedVS7::kFogSet);
// static const plShaderDecl decl("sha/vs_WaveFixedFin7.inl");
// vShader->SetDecl(&decl);
vShader->SetDecl(plShaderTable::Decl(vs_WaveFixedFin7));
// vShader->SetShaderFileName("sha/vs_WaveFixedFin6.inl");
// vShader->SetShaderFileName("sha/vs_WaveFixedFin.inl");
// vShader->SetShaderFileName("sha/vs_TestPos.inl");
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefFixedVShader), plRefFlags::kActiveRef);
fFixedVShader = vShader;
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kVertexShader, fFixedVShader);
}
// type is either plLayRefMsg::kVertexShader or plLayRefMsg::kPixelShader.
void plWaveSet7::IAddShaderToLayers(hsGMaterial* mat, int iFirst, int iLast, UInt8 type, plShader* shader)
{
if( iFirst < 0 )
iFirst = 0;
if( UInt32(iLast) >= mat->GetNumLayers() )
iLast = mat->GetNumLayers()-1;
int i;
for( i = iFirst; i <= iLast; i++ )
{
plLayer* layer = plLayer::ConvertNoRef(mat->GetLayer(i)->BottomOfStack());
if( layer
&& (layer->GetVertexShader() != shader)
&& (layer->GetPixelShader() != shader) )
{
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(layer->GetKey(), plRefMsg::kOnCreate, 0, type);
hsgResMgr::ResMgr()->SendRef(shader->GetKey(), refMsg, plRefFlags::kActiveRef);
// layer->SetShadeFlags(layer->GetShadeFlags() | hsGMatState::kShadeReallyNoFog);
}
}
}
void plWaveSet7::IAddFixedPixelShader(hsGMaterial* mat)
{
if( !fFixedPShader )
{
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_FixedPS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
// pShader->SetNumConsts(plFixedPS::kNumConsts);
pShader->SetNumConsts(0);
pShader->SetInputFormat(0);
pShader->SetOutputFormat(0);
// pShader->SetShaderFileName("sha/ps_WaveFixed.inl");
// pShader->SetShaderFileName("sha/ps_TestPos.inl");
pShader->SetDecl(plShaderTable::Decl(ps_WaveFixed));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefFixedPShader), plRefFlags::kActiveRef);
fFixedPShader = pShader;
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kPixelShader, fFixedPShader);
}
void plWaveSet7::IAddRipVertexShader(hsGMaterial* mat, const plRipVSConsts& ripConsts)
{
if( !fRipVShader )
{
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_RipVS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetInputFormat(1); // This should really be one!!!
vShader->SetOutputFormat(0);
vShader->SetNumConsts(plRipVS::kNumConsts);
vShader->SetVector(plRipVS::kSinConsts, 1.f, -1.f/6.f, 1.f/120.f, -1.f/5040.f);
vShader->SetVector(plRipVS::kCosConsts, 1.f, -1.f/2.f, 1.f/24.f, -1.f/720.f);
vShader->SetVector(plRipVS::kPiConsts, 1.f / (8.f*hsScalarPI*4.f*4.f), hsScalarPI/2.f, hsScalarPI, hsScalarPI*2.f);
vShader->SetVector(plRipVS::kNumericConsts, 0, 0.5f, 1.f, 2.f);
hsVector3 waterOffset = State().fWaterOffset;
vShader->SetVector(plRipVS::kWaterLevel,
State().fWaterHeight + waterOffset.fX,
State().fWaterHeight + waterOffset.fY,
State().fWaterHeight + waterOffset.fZ,
State().fWaterHeight);
hsVector3 maxAtten = State().fMaxAtten;
hsVector3 minAtten = State().fMinAtten;
hsVector3 depthFalloff = State().fDepthFalloff;
vShader->SetVector(plRipVS::kDepthFalloff,
(maxAtten.fX - minAtten.fX) / depthFalloff.fX,
(maxAtten.fY - minAtten.fY) / depthFalloff.fY,
(maxAtten.fZ - minAtten.fZ) / depthFalloff.fZ,
1.f
);
vShader->SetVector(plRipVS::kMinAtten,
minAtten.fX,
minAtten.fY,
minAtten.fZ,
0.f
);
// Set up the ones passed in from the dynarippleVSmgr.
vShader->SetVector(plRipVS::kTexConsts,
ripConsts.fC1U,
ripConsts.fC2U,
ripConsts.fC1V,
ripConsts.fC2V);
vShader->SetVector(plRipVS::kLifeConsts,
ripConsts.fInitAtten,
0, // current time, we'll fill that in later
ripConsts.fLife,
1.f / (ripConsts.fLife - ripConsts.fDecay));
plConst(hsScalar) kRipBias(0.1);
vShader->SetVector(plRipVS::kRampBias,
ripConsts.fRamp,
1.f / ripConsts.fRamp,
kRipBias,
0); // Last one still unused.
vShader->SetNumPipeConsts(4);
vShader->SetPipeConst(0, plPipeConst::kWorldToNDC, plRipVS::kWorldToNDC);
vShader->SetPipeConst(1, plPipeConst::kCamPosWorld, plRipVS::kCameraPos);
vShader->SetPipeConst(2, plPipeConst::kLocalToWorld, plRipVS::kLocalToWorld);
vShader->SetPipeConst(3, plPipeConst::kFogSet, plRipVS::kFogSet);
// vShader->SetShaderFileName("sha/vs_WaveRip.inl");
// vShader->SetDecl(plShaderTable::Decl(vs_WaveRip));
// static const plShaderDecl decl("sha/vs_WaveRip7.inl");
// vShader->SetDecl(&decl);
vShader->SetDecl(plShaderTable::Decl(vs_WaveRip7));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefRipVShader), plRefFlags::kActiveRef);
hsAssert(vShader == fRipVShader, "Should have been set by SendRef");
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kVertexShader, fRipVShader);
}
void plWaveSet7::IAddRipPixelShader(hsGMaterial* mat, const plRipVSConsts& ripConsts)
{
if( !fRipPShader )
{
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_RipPS", GetKey()->GetName());
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
pShader->SetNumConsts(0);
pShader->SetInputFormat(0);
pShader->SetOutputFormat(0);
// pShader->SetShaderFileName("sha/ps_WaveRip.inl");
pShader->SetDecl(plShaderTable::Decl(ps_WaveRip));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, kRefRipPShader), plRefFlags::kActiveRef);
hsAssert(pShader == fRipPShader, "Should have been set by SendRef");
}
IAddShaderToLayers(mat, 0, mat->GetNumLayers()-1, plLayRefMsg::kPixelShader, fRipPShader);
}
plShader* plWaveSet7::ICreateDecalVShader(DecalVType t)
{
if( !fDecalVShaders[t] )
{
static const char* fname[kNumDecalVShaders] = {
"vs_WaveDec1Lay_7",
"vs_WaveDec2Lay11_7",
"vs_WaveDec2Lay12_7",
"vs_WaveDecEnv_7"
};
static const plShaderDecl shaderDecls[kNumDecalVShaders] = {
plShaderDecl("sha/vs_WaveDec1Lay_7.inl"),
plShaderDecl("sha/vs_WaveDec2Lay11_7.inl"),
plShaderDecl("sha/vs_WaveDec2Lay12_7.inl"),
plShaderDecl("sha/vs_WaveDecEnv_7.inl")
};
static const plShaderID::ID shaderIDs[kNumDecalVShaders] = {
vs_WaveDec1Lay_7,
vs_WaveDec2Lay11_7,
vs_WaveDec2Lay12_7,
vs_WaveDecEnv_7
};
static const int numUVWs[kNumDecalVShaders] = {
1,
1,
2,
3
};
static const int numLayXfms[kNumDecalVShaders] = {
1,
2,
2,
1
};
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), fname[t]);
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetInputFormat(numUVWs[t]); // This should really be one!!!
vShader->SetOutputFormat(0);
vShader->SetNumConsts(plWaveDecVS::kNumConsts);
vShader->SetVector(plWaveDecVS::kSinConsts, 1.f, -1.f/6.f, 1.f/120.f, -1.f/5040.f);
vShader->SetVector(plWaveDecVS::kCosConsts, 1.f, -1.f/2.f, 1.f/24.f, -1.f/720.f);
vShader->SetVector(plWaveDecVS::kPiConsts, 1.f / (8.f*hsScalarPI*4.f*4.f), hsScalarPI/2.f, hsScalarPI, hsScalarPI*2.f);
vShader->SetVector(plWaveDecVS::kNumericConsts, 0, 0.5f, 1.f, 2.f);
hsVector3 waterOffset = State().fWaterOffset;
vShader->SetVector(plWaveDecVS::kWaterLevel,
State().fWaterHeight + waterOffset.fX,
State().fWaterHeight + waterOffset.fY,
State().fWaterHeight + waterOffset.fZ,
State().fWaterHeight);
hsVector3 maxAtten = State().fMaxAtten;
hsVector3 minAtten = State().fMinAtten;
hsVector3 depthFalloff = State().fDepthFalloff;
vShader->SetVector(plWaveDecVS::kDepthFalloff,
(maxAtten.fX - minAtten.fX) / depthFalloff.fX,
(maxAtten.fY - minAtten.fY) / depthFalloff.fY,
(maxAtten.fZ - minAtten.fZ) / depthFalloff.fZ,
1.f
);
vShader->SetVector(plWaveDecVS::kMinAtten,
minAtten.fX,
minAtten.fY,
minAtten.fZ,
0.f
);
plConst(hsScalar) kBias(0.1);
vShader->SetVector(plWaveDecVS::kBias,
kBias,
0,
0,
0); // Last one still unused.
const int kNumPipe = 5;
vShader->SetNumPipeConsts(kNumPipe + numLayXfms[t]);
vShader->SetPipeConst(0, plPipeConst::kWorldToNDC, plWaveDecVS::kWorldToNDC);
vShader->SetPipeConst(1, plPipeConst::kLocalToWorld, plWaveDecVS::kLocalToWorld);
vShader->SetPipeConst(2, plPipeConst::kLayRuntime, plWaveDecVS::kMatColor);
vShader->SetPipeConst(3, plPipeConst::kCamPosWorld, plWaveDecVS::kCameraPos);
vShader->SetPipeConst(4, plPipeConst::kFogSet, plWaveDecVS::kFogSet);
int i;
for( i = 0; i < numLayXfms[t]; i++ )
{
vShader->SetPipeConst(kNumPipe + i, plPipeConst::Type(plPipeConst::kTex2x4_0+i), plWaveDecVS::kTex0Transform + i);
}
// vShader->SetDecl(&shaderDecls[t]);
vShader->SetDecl(plShaderTable::Decl(shaderIDs[t]));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, t, kRefDecVShader), plRefFlags::kActiveRef);
hsAssert(vShader == fDecalVShaders[t], "Should have been set by SendRef");
}
return fDecalVShaders[t];
}
plShader* plWaveSet7::IGetDecalVShader(hsGMaterial* mat)
{
if( mat->GetLayer(0)->GetShadeFlags() & hsGMatState::kShadeEnvironMap )
return ICreateDecalVShader(kDecalVEnv);
switch( mat->GetNumLayers() )
{
case 1:
return ICreateDecalVShader(kDecalV1Lay);
case 2:
hsAssert(mat->GetLayer(0)->GetUVWSrc() == 0, "First layer must use uvw channel 1");
hsAssert(mat->GetLayer(1)->GetUVWSrc() < 2, "Second layer must use uvw channel 1 or 2");
switch( mat->GetLayer(1)->GetUVWSrc() )
{
case 0:
return ICreateDecalVShader(kDecalV2Lay11);
case 1:
return ICreateDecalVShader(kDecalV2Lay12);
default:
return nil;
}
break;
default:
hsAssert(false, "Only 1 or 2 layers currently supported");
}
return nil;
}
plShader* plWaveSet7::ICreateDecalPShader(DecalPType t)
{
if( !fDecalPShaders[t] )
{
static const char* fname[kNumDecalPShaders] = {
"ps_CbaseAbase",
"ps_CalphaAbase",
"ps_CalphaAMult",
"ps_CalphaAadd",
"ps_CaddAbase",
"ps_CaddAMult",
"ps_CaddAAdd",
"ps_CmultAbase",
"ps_CmultAMult",
"ps_CmultAAdd",
"ps_WaveDecEnv"
};
static const plShaderID::ID shaderIDs[kNumDecalPShaders] = {
ps_CbaseAbase,
ps_CalphaAbase,
ps_CalphaAMult,
ps_CalphaAadd,
ps_CaddAbase,
ps_CaddAMult,
ps_CaddAAdd,
ps_CmultAbase,
ps_CmultAMult,
ps_CmultAAdd,
ps_WaveDecEnv
};
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), fname[t]);
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
// sprintf(buff, "sha/%s.inl", fname[t]);
// pShader->SetShaderFileName(buff);
pShader->SetDecl(plShaderTable::Decl(shaderIDs[t]));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, t, kRefDecPShader), plRefFlags::kActiveRef);
hsAssert(fDecalPShaders[t] == pShader, "Should have been set by SendRef");
}
return fDecalPShaders[t];
}
plShader* plWaveSet7::IGetDecalPShader(hsGMaterial* mat)
{
if( mat->GetLayer(0)->GetShadeFlags() & hsGMatState::kShadeEnvironMap )
return ICreateDecalPShader(kDecalPEnv);
hsAssert(mat->GetNumLayers() < 3, "Only 2 layers supported on water decal");
if( mat->GetNumLayers() >= 3 )
return nil;
if( mat->GetNumLayers() == 1 )
return ICreateDecalPShader(kDecalPBB);
DecalPType t = kNumDecalPShaders; // Initialize to illegal value.
switch( mat->GetLayer(1)->GetBlendFlags() & (hsGMatState::kBlendMask | hsGMatState::kBlendAlphaMult | hsGMatState::kBlendAlphaAdd) )
{
case 0:
case hsGMatState::kBlendTest:
case hsGMatState::kBlendAlpha:
t = kDecalPaB;
break;
case hsGMatState::kBlendAdd:
t = kDecalPAB;
break;
case hsGMatState::kBlendMult:
t = kDecalPMB;
break;
case hsGMatState::kBlendAlpha | hsGMatState::kBlendAlphaAdd:
t = kDecalPaA;
break;
case hsGMatState::kBlendAdd | hsGMatState::kBlendAlphaAdd:
t = kDecalPAA;
break;
case hsGMatState::kBlendMult | hsGMatState::kBlendAlphaAdd:
t = kDecalPMA;
break;
case hsGMatState::kBlendAlpha | hsGMatState::kBlendAlphaMult:
t = kDecalPaM;
break;
case hsGMatState::kBlendAdd | hsGMatState::kBlendAlphaMult:
t = kDecalPAM;
break;
case hsGMatState::kBlendMult | hsGMatState::kBlendAlphaMult:
t = kDecalPMM;
break;
default:
hsAssert(false, "Unsupported layer blend mode");
return nil;
}
return ICreateDecalPShader(t);
}
void plWaveSet7::IUpdateShaders(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
IUpdateBiasVShader();
IUpdateBumpVShader(pipe, l2w, w2l);
IUpdateBumpPShader(pipe, l2w, w2l);
IUpdateRipPShader(pipe, l2w, w2l);
IUpdateRipVShader(pipe, l2w, w2l);
IUpdateShoreVShader(pipe, l2w, w2l);
IUpdateFixedVShader(pipe, l2w, w2l);
IUpdateFixedPShader(pipe, l2w, w2l);
IUpdateDecVShaders(pipe, l2w, w2l);
}
void plWaveSet7::IUpdateBumpPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
plCONST(Int32) skip(0);
int i;
for( i = 0; i < kNumBumpShaders; i++ )
{
int j;
for( j = 0; j < kBumpPerPass; j++ )
{
int iTex = i*kBumpPerPass + j;
hsVector3 specVec = State().fSpecVec;
hsScalar scale = 1.f / (hsScalar(kNumBumpShaders) + specVec[State().kNoise]);
hsScalar maxLen = TexState().fMaxLength * kCompositeSize / State().fRippleScale;
hsScalar rescale = fTexWaves[iTex].fLen / maxLen;
hsScalar bias = 0.5f * scale;
fBumpPShader[i]->SetVector(plBumpPS::kHalfOne, scale, scale, 1.f, 1.f);
fBumpPShader[i]->SetVector(plBumpPS::kBias, bias, bias, 1.f, 1.f);
hsScalar layScale = skip & (1 << iTex) ? 0.f : (1.f / hsScalar(kBumpPerPass));
layScale *= fTexWaveFade[iTex];
fBumpPShader[i]->SetVector(plBumpPS::kWave0 + j,
-fTexWaves[iTex].fDirX * layScale,
-fTexWaves[iTex].fDirY * layScale,
1.f,
1.f);
}
}
}
void plWaveSet7::IUpdateBumpVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
}
static inline hsScalar IRound(hsScalar f)
{
return hsScalar(int(f + (f > 0 ? 0.5f : -0.5f)));
}
void plWaveSet7::IUpdateBiasVShader()
{
if( fBiasVShader )
{
// Can't just use GetDelSysSeconds() or else we lose time if we skip a frame render because of high FPS.
hsScalar dt = fLastTime > 0 ? hsScalar(fCurrTime - fLastTime) : hsTimer::GetDelSysSeconds();
plConst(hsScalar) kRate(-0.1f);
hsScalar tx = kRate * dt;
hsScalar ty = kRate * dt;
plConst(hsScalar) kScaleU(4.f);
plConst(hsScalar) kScaleV(1.f);
tx += fBiasVShader->GetFloat(plBiasVS::kTexU0, 3);
tx -= hsScalar(int(tx));
ty += fBiasVShader->GetFloat(plBiasVS::kTexV0, 3);
ty -= hsScalar(int(ty));
hsScalar scale = 1.f + (4.f - 1.f) * TexState().fAngleDev/hsScalarPI;
hsScalar m00 = IRound(fWindDir.fY * scale);
hsScalar m01 = IRound(fWindDir.fX * scale);
hsScalar m10 = IRound(-fWindDir.fX * 4.f);
hsScalar m11 = IRound(fWindDir.fY * 4.f);
fBiasVShader->SetVector(plBiasVS::kTexU0,
m00,
m01,
0,
tx);
fBiasVShader->SetVector(plBiasVS::kTexV0,
m10,
m11,
0,
ty);
plConst(hsScalar) kUpperNoiseOffU(0.f);
plConst(hsScalar) kUpperNoiseOffV(0.3f);
fBiasVShader->SetVector(plBiasVS::kTexU1,
m00,
m01,
0,
-tx + kUpperNoiseOffU);
fBiasVShader->SetVector(plBiasVS::kTexV1,
m10,
m11,
0,
ty + kUpperNoiseOffV);
hsVector3 specVec = State().fSpecVec;
hsScalar biasScale = 0.5f * specVec[State().kNoise] / (hsScalar(kNumBumpShaders) + specVec[State().kNoise]);
fBiasVShader->SetVector(plBiasVS::kScaleBias,
biasScale,
biasScale,
0.f,
1.f);
}
}
void plWaveSet7::IUpdateFixedPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
}
void plWaveSet7::IUpdateRipPShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
// Nothing to do
}
void plWaveSet7::IUpdateRipVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
if( fRipVShader )
{
fRipVShader->SetVector(plRipVS::kFrequency,
fWorldWaves[0].fFreq,
fWorldWaves[1].fFreq,
fWorldWaves[2].fFreq,
fWorldWaves[3].fFreq);
fRipVShader->SetVector(plRipVS::kPhase,
fWorldWaves[0].fPhase,
fWorldWaves[1].fPhase,
fWorldWaves[2].fPhase,
fWorldWaves[3].fPhase);
fRipVShader->SetVector(plRipVS::kAmplitude,
fWorldWaves[0].fAmplitude,
fWorldWaves[1].fAmplitude,
fWorldWaves[2].fAmplitude,
fWorldWaves[3].fAmplitude);
fRipVShader->SetVector(plRipVS::kDirectionX,
fWorldWaves[0].fDir.fX,
fWorldWaves[1].fDir.fX,
fWorldWaves[2].fDir.fX,
fWorldWaves[3].fDir.fX);
fRipVShader->SetVector(plRipVS::kDirectionY,
fWorldWaves[0].fDir.fY,
fWorldWaves[1].fDir.fY,
fWorldWaves[2].fDir.fY,
fWorldWaves[3].fDir.fY);
fRipVShader->SetVector(plRipVS::kWindRot,
fWindDir.fY,
-fWindDir.fX,
fWindDir.fX,
0);
fRipVShader->SetVector(plRipVS::kLengths,
fWorldWaves[0].fLength,
fWorldWaves[1].fLength,
fWorldWaves[2].fLength,
fWorldWaves[3].fLength);
fRipVShader->SetFloat(plRipVS::kLifeConsts, 1, float(hsTimer::GetSysSeconds()));
float normQ[kNumWaves];
int i;
for( i = 0; i < kNumWaves; i++ )
{
normQ[i] = GeoState().fChop / (2.f*hsScalarPI * GeoState().fAmpOverLen * kNumWaves);
}
fRipVShader->SetVector(plRipVS::kQADirX,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fX * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fX * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fX * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fX * normQ[3]);
fRipVShader->SetVector(plRipVS::kQADirY,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fY * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fY * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fY * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fY * normQ[3]);
}
}
void plWaveSet7::IUpdateDecVShaders(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
int i;
for( i = 0; i < kNumDecalVShaders; i++ )
IUpdateDecVShader(i, pipe);
}
void plWaveSet7::IUpdateDecVShader(int t, plPipeline* pipe)
{
plShader* shader = fDecalVShaders[t];
if( shader )
{
shader->SetVector(plWaveDecVS::kFrequency,
fWorldWaves[0].fFreq,
fWorldWaves[1].fFreq,
fWorldWaves[2].fFreq,
fWorldWaves[3].fFreq);
shader->SetVector(plWaveDecVS::kPhase,
fWorldWaves[0].fPhase,
fWorldWaves[1].fPhase,
fWorldWaves[2].fPhase,
fWorldWaves[3].fPhase);
shader->SetVector(plWaveDecVS::kAmplitude,
fWorldWaves[0].fAmplitude,
fWorldWaves[1].fAmplitude,
fWorldWaves[2].fAmplitude,
fWorldWaves[3].fAmplitude);
shader->SetVector(plWaveDecVS::kDirectionX,
fWorldWaves[0].fDir.fX,
fWorldWaves[1].fDir.fX,
fWorldWaves[2].fDir.fX,
fWorldWaves[3].fDir.fX);
shader->SetVector(plWaveDecVS::kDirectionY,
fWorldWaves[0].fDir.fY,
fWorldWaves[1].fDir.fY,
fWorldWaves[2].fDir.fY,
fWorldWaves[3].fDir.fY);
shader->SetVector(plWaveDecVS::kLengths,
fWorldWaves[0].fLength,
fWorldWaves[1].fLength,
fWorldWaves[2].fLength,
fWorldWaves[3].fLength);
if( t == kDecalVEnv )
{
hsPoint3 worldCam = pipe->GetViewTransform().GetCameraToWorld().GetTranslate();
hsPoint3 envCenter(State().fEnvCenter);
hsScalar envRadius = State().fEnvRadius;
hsVector3 camToCen(&envCenter, &worldCam);
hsScalar G = camToCen.MagnitudeSquared() - envRadius * envRadius;
shader->SetVectorW(plWaveDecVS::kEnvAdjust, camToCen, G);
}
float normQ[kNumWaves];
int i;
for( i = 0; i < kNumWaves; i++ )
{
normQ[i] = GeoState().fChop / (2.f*hsScalarPI * GeoState().fAmpOverLen * kNumWaves);
}
shader->SetVector(plWaveDecVS::kQADirX,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fX * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fX * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fX * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fX * normQ[3]);
shader->SetVector(plWaveDecVS::kQADirY,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fY * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fY * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fY * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fY * normQ[3]);
shader->SetVector(plWaveDecVS::kDirXW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fFreq,
fWorldWaves[1].fDir.fX * fWorldWaves[1].fFreq,
fWorldWaves[2].fDir.fX * fWorldWaves[2].fFreq,
fWorldWaves[3].fDir.fX * fWorldWaves[3].fFreq);
shader->SetVector(plWaveDecVS::kDirYW,
fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq,
fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq,
fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq,
fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq);
shader->SetVector(plWaveDecVS::kWK,
normQ[0] * fWorldWaves[0].fFreq,
normQ[1] * fWorldWaves[1].fFreq,
normQ[2] * fWorldWaves[2].fFreq,
normQ[3] * fWorldWaves[3].fFreq);
shader->SetVector(plWaveDecVS::kDirXSqKW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fDir.fX * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fX * fWorldWaves[1].fDir.fX * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fX * fWorldWaves[2].fDir.fX * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fX * fWorldWaves[3].fDir.fX * fWorldWaves[3].fFreq * normQ[3]);
shader->SetVector(plWaveDecVS::kDirXDirYKW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fX * fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fX * fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fX * fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq * normQ[3]);
shader->SetVector(plWaveDecVS::kDirYSqKW,
fWorldWaves[0].fDir.fY * fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fY * fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fY * fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fY * fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq * normQ[3]);
}
}
void plWaveSet7::IUpdateShoreVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
if( fShoreVShader )
{
fShoreVShader->SetVector(plShoreVS::kFrequency,
fWorldWaves[0].fFreq,
fWorldWaves[1].fFreq,
fWorldWaves[2].fFreq,
fWorldWaves[3].fFreq);
fShoreVShader->SetVector(plShoreVS::kPhase,
fWorldWaves[0].fPhase,
fWorldWaves[1].fPhase,
fWorldWaves[2].fPhase,
fWorldWaves[3].fPhase);
fShoreVShader->SetVector(plShoreVS::kAmplitude,
fWorldWaves[0].fAmplitude,
fWorldWaves[1].fAmplitude,
fWorldWaves[2].fAmplitude,
fWorldWaves[3].fAmplitude);
fShoreVShader->SetVector(plShoreVS::kDirectionX,
fWorldWaves[0].fDir.fX,
fWorldWaves[1].fDir.fX,
fWorldWaves[2].fDir.fX,
fWorldWaves[3].fDir.fX);
fShoreVShader->SetVector(plShoreVS::kDirectionY,
fWorldWaves[0].fDir.fY,
fWorldWaves[1].fDir.fY,
fWorldWaves[2].fDir.fY,
fWorldWaves[3].fDir.fY);
hsVector3 waterOffset = State().fWaterOffset;
fShoreVShader->SetVector(plShoreVS::kWaterLevel,
State().fWaterHeight + waterOffset.fX,
State().fWaterHeight + waterOffset.fY,
State().fWaterHeight + waterOffset.fZ,
State().fWaterHeight);
hsVector3 maxAtten = State().fMaxAtten;
hsVector3 minAtten = State().fMinAtten;
hsVector3 depthFalloff = State().fDepthFalloff;
fShoreVShader->SetVector(plShoreVS::kDepthFalloff,
(maxAtten.fX - minAtten.fX) / depthFalloff.fX,
(maxAtten.fY - minAtten.fY) / depthFalloff.fY,
(maxAtten.fZ - minAtten.fZ) / depthFalloff.fZ,
1.f
);
fShoreVShader->SetVector(plShoreVS::kMinAtten,
minAtten.fX,
minAtten.fY,
minAtten.fZ,
0.f
);
fShoreVShader->SetVector(plShoreVS::kLengths,
fWorldWaves[0].fLength,
fWorldWaves[1].fLength,
fWorldWaves[2].fLength,
fWorldWaves[3].fLength);
plConst(hsScalar) kK1(2.f);
plConst(hsScalar) kK2(5.f);
hsScalar negK1OverK2Sq = -kK1 / (kK2 * kK2);
fShoreVShader->SetVector(plShoreVS::kIncline, negK1OverK2Sq, kK1, 0.f, 0.f);
float normQ[kNumWaves];
int i;
for( i = 0; i < kNumWaves; i++ )
{
normQ[i] = GeoState().fChop / (2.f*hsScalarPI * GeoState().fAmpOverLen * kNumWaves);
}
fShoreVShader->SetVector(plShoreVS::kQADirX,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fX * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fX * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fX * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fX * normQ[3]);
fShoreVShader->SetVector(plShoreVS::kQADirY,
fWorldWaves[0].fAmplitude * fWorldWaves[0].fDir.fY * normQ[0],
fWorldWaves[1].fAmplitude * fWorldWaves[1].fDir.fY * normQ[1],
fWorldWaves[2].fAmplitude * fWorldWaves[2].fDir.fY * normQ[2],
fWorldWaves[3].fAmplitude * fWorldWaves[3].fDir.fY * normQ[3]);
if( fTrialUpdate & kRemakeBubble )
IRefillBubbleShoreTex();
if( fTrialUpdate & kRemakeEdge )
IRefillEdgeShoreTex();
}
}
void plWaveSet7::IUpdateFixedVShader(plPipeline* pipe, const hsMatrix44& l2w, const hsMatrix44& w2l)
{
if( fFixedVShader )
{
fFixedVShader->SetVector(plFixedVS7::kFrequency,
fWorldWaves[0].fFreq,
fWorldWaves[1].fFreq,
fWorldWaves[2].fFreq,
fWorldWaves[3].fFreq);
fFixedVShader->SetVector(plFixedVS7::kPhase,
fWorldWaves[0].fPhase,
fWorldWaves[1].fPhase,
fWorldWaves[2].fPhase,
fWorldWaves[3].fPhase);
fFixedVShader->SetVector(plFixedVS7::kAmplitude,
fWorldWaves[0].fAmplitude,
fWorldWaves[1].fAmplitude,
fWorldWaves[2].fAmplitude,
fWorldWaves[3].fAmplitude);
fFixedVShader->SetVector(plFixedVS7::kDirectionX,
fWorldWaves[0].fDir.fX,
fWorldWaves[1].fDir.fX,
fWorldWaves[2].fDir.fX,
fWorldWaves[3].fDir.fX);
fFixedVShader->SetVector(plFixedVS7::kDirectionY,
fWorldWaves[0].fDir.fY,
fWorldWaves[1].fDir.fY,
fWorldWaves[2].fDir.fY,
fWorldWaves[3].fDir.fY);
plCONST(hsScalar) kEnvRadius(500.f);
hsScalar envRadius = State().fEnvRadius;
hsPoint3 worldCam = pipe->GetViewTransform().GetCameraToWorld().GetTranslate();
hsPoint3 envCenter(State().fEnvCenter);
hsVector3 camToCen(&envCenter, &worldCam);
hsScalar G = camToCen.MagnitudeSquared() - envRadius * envRadius;
fFixedVShader->SetVectorW(plFixedVS7::kEnvAdjust, camToCen, G);
hsScalar texScale = 1.f / State().fRippleScale;
fFixedVShader->SetVector(plFixedVS7::kUVScale,
texScale,
0,
0,
0);
hsScalar specAtten = State().fTexState.fAmpOverLen * hsScalarPI * 2.f;
plCONST(hsScalar) kScaleHack(0.1f);
hsScalar baseScale = kScaleHack;
// baseScale *= hsScalar(kBumpPerPass) * (hsScalar(kNumBumpShaders) + State().fSpecVec[State().kNoise]);
// Not sure what's right here. but we are currently scaling down by 1/(numBumpShaders + noise),
// so I guess we want to scale up by that amount here. Not sure we shouldn't figuring in bumpperpass
// on both, but at least now we're consistent.
hsVector3 specVec = State().fSpecVec;
baseScale *= (hsScalar(kNumBumpShaders) + specVec[State().kNoise]);
baseScale *= (TexState().fChop + 1.f);
hsScalar specStart = specVec[State().kSpecStart];
hsScalar specEnd = specVec[State().kSpecEnd];
if( specStart > specEnd )
specEnd = specStart + 1.f;
fFixedVShader->SetVector(plFixedVS7::kSpecAtten,
-specEnd,
1.f / (specStart - specEnd),
baseScale * specAtten,
0.f);
hsColorRGBA envTint = State().fSpecularTint;
if( fFixedLayers[0] && (fFixedLayers[0]->GetShadeFlags() & hsGMatState::kShadeSpecular) )
{
envTint *= fFixedLayers[0]->GetSpecularColor();
}
fFixedVShader->SetColor(plFixedVS::kEnvTint, envTint);
fFixedVShader->SetVector(plFixedVS7::kWindRot,
fWindDir.fY,
-fWindDir.fX,
fWindDir.fX,
0);
fFixedVShader->SetVector(plFixedVS7::kLengths,
fWorldWaves[0].fLength,
fWorldWaves[1].fLength,
fWorldWaves[2].fLength,
fWorldWaves[3].fLength);
// These don't change often, but they can change. We're going
// to be uploading them to the card anyway, might as well refresh
// the sysmem shader to be safe.
hsVector3 waterOffset = State().fWaterOffset;
fFixedVShader->SetVector(plFixedVS7::kWaterLevel,
State().fWaterHeight + waterOffset.fX,
State().fWaterHeight + waterOffset.fY,
State().fWaterHeight + waterOffset.fZ,
State().fWaterHeight);
hsVector3 maxAtten = State().fMaxAtten;
hsVector3 minAtten = State().fMinAtten;
hsVector3 depthFalloff = State().fDepthFalloff;
fFixedVShader->SetVector(plFixedVS7::kDepthFalloff,
(maxAtten.fX - minAtten.fX) / depthFalloff.fX,
(maxAtten.fY - minAtten.fY) / depthFalloff.fY,
(maxAtten.fZ - minAtten.fZ) / depthFalloff.fZ,
1.f
);
fFixedVShader->SetVector(plFixedVS7::kMinAtten,
minAtten.fX,
minAtten.fY,
minAtten.fZ,
0.f
);
float normQ[kNumWaves];
int i;
for( i = 0; i < kNumWaves; i++ )
{
normQ[i] = GeoState().fChop / (2.f*hsScalarPI * GeoState().fAmpOverLen * kNumWaves);
}
fFixedVShader->SetVector(plFixedVS7::kDirXK,
fWorldWaves[0].fDir.fX * normQ[0],
fWorldWaves[1].fDir.fX * normQ[1],
fWorldWaves[2].fDir.fX * normQ[2],
fWorldWaves[3].fDir.fX * normQ[3]);
fFixedVShader->SetVector(plFixedVS7::kDirYK,
fWorldWaves[0].fDir.fY * normQ[0],
fWorldWaves[1].fDir.fY * normQ[1],
fWorldWaves[2].fDir.fY * normQ[2],
fWorldWaves[3].fDir.fY * normQ[3]);
fFixedVShader->SetVector(plFixedVS7::kDirXW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fFreq,
fWorldWaves[1].fDir.fX * fWorldWaves[1].fFreq,
fWorldWaves[2].fDir.fX * fWorldWaves[2].fFreq,
fWorldWaves[3].fDir.fX * fWorldWaves[3].fFreq);
fFixedVShader->SetVector(plFixedVS7::kDirYW,
fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq,
fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq,
fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq,
fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq);
fFixedVShader->SetVector(plFixedVS7::kWK,
normQ[0] * fWorldWaves[0].fFreq,
normQ[1] * fWorldWaves[1].fFreq,
normQ[2] * fWorldWaves[2].fFreq,
normQ[3] * fWorldWaves[3].fFreq);
fFixedVShader->SetVector(plFixedVS7::kDirXSqKW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fDir.fX * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fX * fWorldWaves[1].fDir.fX * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fX * fWorldWaves[2].fDir.fX * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fX * fWorldWaves[3].fDir.fX * fWorldWaves[3].fFreq * normQ[3]);
fFixedVShader->SetVector(plFixedVS7::kDirXDirYKW,
fWorldWaves[0].fDir.fX * fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fX * fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fX * fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fX * fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq * normQ[3]);
fFixedVShader->SetVector(plFixedVS7::kDirYSqKW,
fWorldWaves[0].fDir.fY * fWorldWaves[0].fDir.fY * fWorldWaves[0].fFreq * normQ[0],
fWorldWaves[1].fDir.fY * fWorldWaves[1].fDir.fY * fWorldWaves[1].fFreq * normQ[1],
fWorldWaves[2].fDir.fY * fWorldWaves[2].fDir.fY * fWorldWaves[2].fFreq * normQ[2],
fWorldWaves[3].fDir.fY * fWorldWaves[3].fDir.fY * fWorldWaves[3].fFreq * normQ[3]);
}
}
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
void plWaveSet7::ICheckShoreMaterials()
{
int i;
for( i = 0; i < fShores.GetCount(); i++ )
ICheckShoreMaterial(fShores[i]);
}
void plWaveSet7::ICheckShoreMaterial(plSceneObject* so)
{
if( !so )
return;
const plDrawInterface* di = so->GetDrawInterface();
if( !di )
return;
hsTArray<plAccessSpan> src;
plAccessGeometry::Instance()->OpenRO(di, src);
if( !src.GetCount() )
return;
int i;
for( i = 0; i < src.GetCount(); i++ )
{
ISetupGraphShore(src[i].GetMaterial());
}
plAccessGeometry::Instance()->Close(src);
}
void plWaveSet7::ICheckDecalMaterials()
{
int i;
for( i = 0; i < fDecals.GetCount(); i++ )
ICheckDecalMaterial(fDecals[i]);
}
void plWaveSet7::ICheckDecalMaterial(plSceneObject* so)
{
if( !so )
return;
const plDrawInterface* di = so->GetDrawInterface();
if( !di )
return;
hsTArray<plAccessSpan> src;
plAccessGeometry::Instance()->OpenRO(di, src);
if( !src.GetCount() )
return;
int i;
for( i = 0; i < src.GetCount(); i++ )
{
ISetupDecal(src[i].GetMaterial());
}
plAccessGeometry::Instance()->Close(src);
}
void plWaveSet7::ICheckDecalEnvLayers(hsGMaterial* mat)
{
// Mat needs to be set up as:
// Lay0 = bumpmap - uv is lookup into bumpmap
// Lay1 = bumpmap - uv is col0 of tangent2local
// Lay2 = bumpmap - uv is col1 of tangent2local
// Lay3 = fEnvMap - uv is col2 of tangent2local, except we'll ignore it and use the normal instead
// Note we'll have to transpose that as part of creating tangent2world
// Easiest way to check whether we've done this one already is checking whether
// Lay3 == fEnvMap.
// If we haven't done this already
if( !fDecalVShaders[kDecalVEnv] || (mat->GetLayer(0)->GetVertexShader() != fDecalVShaders[kDecalVEnv]) )
{
plLayer* lay3 = nil;
plMatRefMsg* refMsg;
const int numLayers = mat->GetNumLayers();
int i;
for( i = numLayers-1; i >= 0; i-- )
{
plLayer* lay0 = plLayer::ConvertNoRef(mat->GetLayer(i)->BottomOfStack());
lay0->SetBlendFlags(hsGMatState::kBlendAddColorTimesAlpha);
// lay0->SetBlendFlags(hsGMatState::kBlendAlpha);
lay0->SetMiscFlags(lay0->GetMiscFlags() | hsGMatState::kMiscRestartPassHere);
// Repeat lay3 as i+1, i+2 and i+3
// set base blend to timealphaadd
// If we are just creating lay3, then by creating it we've added (appended) it to mat.
// Otherwise, we need to add it as i+1.
if( !lay3 )
{
lay3 = ICreateTotalEnvLayer(fEnvMap, mat, 3, "Dec");
lay3->SetBlendFlags(hsGMatState::kBlendAlpha);
}
else
{
refMsg = TRACKED_NEW plMatRefMsg(mat->GetKey(), plRefMsg::kOnRequest, i+1, plMatRefMsg::kLayer | plMatRefMsg::kInsert);
hsgResMgr::ResMgr()->SendRef(lay3->GetKey(), refMsg, plRefFlags::kActiveRef);
}
refMsg = TRACKED_NEW plMatRefMsg(mat->GetKey(), plRefMsg::kOnRequest, i+2, plMatRefMsg::kLayer | plMatRefMsg::kInsert);
hsgResMgr::ResMgr()->SendRef(lay3->GetKey(), refMsg, plRefFlags::kActiveRef);
refMsg = TRACKED_NEW plMatRefMsg(mat->GetKey(), plRefMsg::kOnRequest, i+3, plMatRefMsg::kLayer | plMatRefMsg::kInsert);
hsgResMgr::ResMgr()->SendRef(lay3->GetKey(), refMsg, plRefFlags::kActiveRef);
}
}
}
void plWaveSet7::ISetupDecal(hsGMaterial* mat)
{
if( mat->GetLayer(0)->GetShadeFlags() & hsGMatState::kShadeEnvironMap )
{
ICheckDecalEnvLayers(mat);
}
plShader* vShader = IGetDecalVShader(mat);
if( mat->GetLayer(0)->GetVertexShader() != vShader )
IAddShaderToLayers(mat, 0, -1, plLayRefMsg::kVertexShader, vShader);
int i;
for( i = 0; i < mat->GetNumLayers(); i++ )
{
plLayer* lay = plLayer::ConvertNoRef(mat->GetLayer(i)->BottomOfStack());
if( lay )
lay->SetZFlags(lay->GetZFlags() | hsGMatState::kZNoZWrite | hsGMatState::kZIncLayer);
}
// The FFP is actually quite adequate for the required blends,
// but may not stay that way (if we allow fancier blends and what not).
// So we can either use the Pixel Shaders or FFP, depending on this define.
// #define MF_USE_FFP
#ifndef MF_USE_FFP
plShader* pShader = IGetDecalPShader(mat);
if( mat->GetLayer(0)->GetPixelShader() != pShader )
IAddShaderToLayers(mat, 0, -1, plLayRefMsg::kPixelShader, pShader);
#endif // MF_USE_FFP
}
void plWaveSet7::AddShoreTest(plKey& key)
{
hsgResMgr::ResMgr()->SendRef(key, TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnCreate, -1, kRefShore), plRefFlags::kPassiveRef);
plSceneObject* so = plSceneObject::ConvertNoRef(key->ObjectIsLoaded());
ICheckShoreMaterial(so);
}
//////////////////////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////////////////////
hsBool plWaveSet7::SetupRippleMat(hsGMaterial* mat, const plRipVSConsts& ripConsts)
{
// We'll assume that if we set the vertexshader, we set the pixelshader too.
if( fRipVShader && (mat->GetLayer(0)->GetVertexShader() == fRipVShader) )
return true;
int i;
for( i = 0; i < mat->GetNumLayers(); i++ )
{
plLayer* lay = plLayer::ConvertNoRef(mat->GetLayer(i)->BottomOfStack());
if( lay )
lay->SetZFlags(lay->GetZFlags() | hsGMatState::kZNoZWrite | hsGMatState::kZIncLayer);
}
IAddRipVertexShader(mat, ripConsts);
IAddRipPixelShader(mat, ripConsts);
return true;
}
//////////////////////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////////////////////
plDrawableSpans* plWaveSet7::ICreateGraphDrawable(plDrawableSpans* drawable, hsGMaterial* mat, int nWid)
{
// drawable->SetNativeProperty(plDrawable::kPropVolatile, true);
const int nVerts = nWid * 2;
hsTArray<hsPoint3> pos;
hsTArray<hsVector3> norm;
pos.SetCount(nVerts);
norm.SetCount(nVerts);
#ifdef TEST_UVWS
hsTArray<hsPoint3> uvw; // Are we actually ever going to use these uvws?
uvw.SetCount(nVerts);
#endif // TEST_UVWS
int i;
for( i = 0; i < nWid; i++ )
{
int iDn = i << 1;
int iUp = iDn + 1;
hsScalar delX = hsScalar(i) / hsScalar(nWid-1);
pos[iDn].fX = delX * 2.f - 1.f;
pos[iDn].fY = -1.f;
pos[iDn].fZ = 0.5f;
norm[iDn].Set(0.f, 0.f, 1.f);
#ifdef TEST_UVWS
uvw[iDn].fX = delX;
uvw[iDn].fY = 0.f;
uvw[iDn].fZ = 0.f;
#endif // TEST_UVWS
pos[iUp].fX = delX * 2.f - 1.f;
pos[iUp].fY = 1.f;
pos[iUp].fZ = 0.5f;
norm[iUp].Set(1.f, 0.f, 1.f);
#ifdef TEST_UVWS
uvw[iUp].fX = delX;
uvw[iUp].fY = 1.f;
uvw[iUp].fZ = 0.f;
#endif // TEST_UVWS
}
const int nTris = (nWid-1) * 2;
hsTArray<UInt16> idxArr;
idxArr.SetCount(nTris * 3);
UInt16* idx = idxArr.AcquireArray();
int iBase = 0;
for( i = 0; i < nTris; i += 2 )
{
*idx++ = i;
*idx++ = i + 2;
*idx++ = i + 1;
*idx++ = i + 1;
*idx++ = i + 2;
*idx++ = i + 3;
}
plDrawableGenerator::GenerateDrawable( nVerts, pos.AcquireArray(), norm.AcquireArray(),
#ifndef TEST_UVWS
nil, 0,
#else // TEST_UVWS
uvw.AcquireArray(), 1,
#endif // TEST_UVWS
nil, false, nil,
nTris * 3, idxArr.AcquireArray(),
mat,
hsMatrix44::IdentityMatrix(),
false,
nil,
drawable);
return drawable;
}
plDrawableSpans* plWaveSet7::ICreateEmptyGraphDrawable(const char* name, UInt32 ref, int which)
{
plDrawableSpans* drawable = TRACKED_NEW plDrawableSpans;
char buff[256];
sprintf(buff, "%s_%s_%d", GetKey()->GetName(), name, which);
hsgResMgr::ResMgr()->NewKey(buff, drawable, GetKey()->GetUoid().GetLocation());
hsgResMgr::ResMgr()->SendRef(drawable->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, which, (Int8)ref), plRefFlags::kActiveRef);
return drawable;
}
hsGMaterial* plWaveSet7::ICreateEmptyMaterial(const char* name, UInt32 ref, int which)
{
hsGMaterial* mat = TRACKED_NEW hsGMaterial;
char buff[256];
sprintf(buff, "%s_%s_%d", GetKey()->GetName(), name, which);
hsgResMgr::ResMgr()->NewKey(buff, mat, GetKey()->GetUoid().GetLocation());
hsgResMgr::ResMgr()->SendRef(mat->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, which, (Int8)ref), plRefFlags::kActiveRef);
return mat;
}
plLayer* plWaveSet7::ICreateBlankLayer(const char* name, int suff)
{
plLayer* lay = TRACKED_NEW plLayer;
char buff[256];
sprintf(buff, "%s_%s_%d", GetKey()->GetName(), name, suff);
hsgResMgr::ResMgr()->NewKey(buff, lay, GetKey()->GetUoid().GetLocation());
return lay;
}
plMipmap* plWaveSet7::ICreateBlankTex(const char* name, int width, int height, UInt32 ref)
{
plMipmap* mipMap = TRACKED_NEW plMipmap(
width, height,
plMipmap::kARGB32Config,
1,
plMipmap::kUncompressed,
plMipmap::UncompressedInfo::kRGB8888);
char buff[256];
sprintf(buff, "%s_%s", GetKey()->GetName(), name);
hsgResMgr::ResMgr()->NewKey(buff, mipMap, GetKey()->GetUoid().GetLocation());
hsgResMgr::ResMgr()->SendRef(mipMap->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, 0, (Int8)ref), plRefFlags::kActiveRef);
return mipMap;
}
plMipmap* plWaveSet7::ICreateGraphShoreTex(int width, int height)
{
// GraphShoreLayer has a texture with white color (possibly noised),
// and a solid alpha.
// Alpha is constant along U (width).
// Alpha is 0 at base,
// ramps up to opaque
// then drops off sharply to transparent just before the top.
// If we haven't already made one...
if( !fGraphShoreTex )
{
plMipmap* mipMap = ICreateBlankTex("Graph", width, height, kRefGraphShoreTex);
plConst(hsScalar) kRampFrac(0.4f);
plConst(hsScalar) kTruncFrac(0.8f);
const int rampEnd = int(kRampFrac * height + 0.5f);
int truncEnd = int(kTruncFrac * height);
if( truncEnd >= (height-1) )
truncEnd = height-2;
int j;
for( j = 0; j < height; j++ )
{
UInt32 alpha = 255;
plConst(int) kRampStart(4);
if( j <= kRampStart )
{
alpha = 0;
}
else
if( j - kRampStart < rampEnd )
{
alpha = ((j-kRampStart) * 255) / rampEnd;
}
else if( j > truncEnd )
{
alpha = 0;
}
UInt32 color = (alpha << 24)
| (0xff << 16)
| (0xff << 8)
| 0xff;
int i;
for( i = 0; i < width; i++ )
{
UInt32* val = mipMap->GetAddr32(i, j);
*val = color;
}
}
}
return fGraphShoreTex;
}
void plWaveSet7::IRefillBubbleShoreTex()
{
plMipmap* mipMap = fBubbleShoreTex;
hsAssert(mipMap, "Refilling a non-existent bubble texture");
const int width = mipMap->GetWidth();
const int height = mipMap->GetHeight();
// Initialize to white opaque.
memset(mipMap->GetAddr32(0,0), 0xff, width*height*sizeof(UInt32));
plConst(int) kMinNumBub(1024);
plConst(int) kMaxNumBub(6000);
const int kNumBub = (int)(kMinNumBub + State().fWispiness * (kMaxNumBub - kMinNumBub));
int k;
for( k = 0; k < kNumBub; k++ )
{
// Select a random location.
int iLoc = (int)(fRand.RandZeroToOne() * width);
int jLoc = (int)(fRand.RandZeroToOne() * height);
// Select a random radius
plConst(hsScalar) kMinRad(2.f);
plConst(hsScalar) kMaxRad(5.0f);
int radius = int(kMinRad + fRand.RandZeroToOne() * (kMaxRad - kMinRad));
hsScalar invRadiusSq = 1.f / hsScalar(radius*radius);
// Carve out a hole.
int j;
for( j = -radius; j < radius; j++ )
{
int jj = jLoc + j;
if( jj < 0 )
jj += height;
else if( jj >= height )
jj -= height;
int i;
for( i = -radius; i < radius; i++ )
{
int ii = iLoc + i;
if( ii < 0 )
ii += width;
else if( ii >= width )
ii -= width;
hsScalar f = hsScalar(i*i + j*j) * invRadiusSq;
if( f > 1.f )
f = 1.f;
plConst(hsScalar) kMinAlpha(0.8f);
plConst(hsScalar) kMaxAlpha(1.f);
f *= (kMaxAlpha - kMinAlpha);
f += kMinAlpha;
UInt32* val = mipMap->GetAddr32(ii, jj);
UInt32 alpha = (*val) >> 24;
alpha = UInt32(hsScalar(alpha) * f);
*val &= 0x00ffffff;
*val |= (alpha << 24);
}
}
}
const hsColorRGBA maxColor = State().fMaxColor;
const hsColorRGBA minColor = State().fMinColor;
int j;
for( j = 0; j < height; j++ )
{
int i;
for( i = 0; i < width; i++ )
{
UInt32* val = mipMap->GetAddr32(i, j);
hsColorRGBA col;
col.FromARGB32(*val);
hsScalar alpha = col.a;
col = maxColor - minColor;
col *= alpha;
col += minColor;
*val = col.ToARGB32();
}
}
mipMap->MakeDirty();
fTrialUpdate &= ~kRemakeBubble;
}
plMipmap* plWaveSet7::ICreateBubbleShoreTex(int width, int height)
{
// Bubble layer is white in color (or noised).
// Alpha is just, well, random bubbles.
// Tile in U and V
// If we haven't already made one...
if( !fBubbleShoreTex )
{
plMipmap* mipMap = ICreateBlankTex("Bubble", width, height, kRefBubbleShoreTex);
IRefillBubbleShoreTex();
}
return fBubbleShoreTex;
}
void plWaveSet7::IRefillEdgeShoreTex()
{
plMipmap* mipMap = fEdgeShoreTex;
const int width = mipMap->GetWidth();
const int height = mipMap->GetHeight();
plConst(hsScalar) kCenter(0.8f);
plConst(hsScalar) kRadius(0.025f);
const int center = int(kCenter * height);
const int radius = int(kRadius * height * State().fEdgeRadius);
const int top = center + radius;
const int bot = center - radius;
const hsScalar invRadiusSq = 1.f / hsScalar(radius*radius);
hsAssert(top < height-1, "Center too high or radius too big");
const hsScalar maxAlpha = State().fEdgeOpac * 255.9f;
int j;
for( j = 0; j < height; j++ )
{
UInt32 alpha = 0;
if( (j > bot)&&(j < top) )
{
#if 0 // like x^2
hsScalar a = hsScalar(j-center);
a *= a;
a *= invRadiusSq;
a = 1.f - a;
#elif 1 // like 1/x^2
hsScalar a = hsScalar(j-center);
if( a < 0 )
a = -a;
a /= hsScalar(radius);
a = 1.f - a;
a *= a;
#else // like cos
hsScalar a = hsScalar(j - center);
a /= hsScalar(radius);
a *= hsScalarPI;
a = hsFastMath::CosInRange(a);
a += 1.f;
a *= 0.5f;
#endif
alpha = UInt32(a * maxAlpha);
}
int i;
for( i = 0; i < width; i++ )
{
UInt32* val = mipMap->GetAddr32(i, j);
*val = (alpha << 24)
| (alpha << 16)
| (alpha << 8)
| (alpha << 0);
}
}
mipMap->MakeDirty();
fTrialUpdate &= ~kRemakeEdge;
}
plMipmap* plWaveSet7::ICreateEdgeShoreTex(int width, int height)
{
// Edge layer is solid white color.
// Alpha is 0 from base almost up to where graph shore texture drops off
// sharply. There, alpha ramps up and back down. Probably get a better look
// from sqrt(k - d^2) (elliptical) than a linear ramp up and down.
// Tile in U, clamp in V.
// If we haven't already made one...
if( !fEdgeShoreTex )
{
plMipmap* mipMap = ICreateBlankTex("Edge", width, height, kRefEdgeShoreTex);
IRefillEdgeShoreTex();
}
return fEdgeShoreTex;
}
void plWaveSet7::ISetAsTexture(plLayer* lay, plBitmap* tex)
{
hsAssert(lay && tex, "Trying to set nil texture or nil layer");
plLayRefMsg* refMsg = TRACKED_NEW plLayRefMsg(lay->GetKey(), plRefMsg::kOnRequest, 0, plLayRefMsg::kTexture);
hsgResMgr::ResMgr()->SendRef(tex->GetKey(), refMsg, plRefFlags::kActiveRef);
}
void plWaveSet7::ICreateGraphShoreLayer(hsGMaterial* mat, int iPass)
{
// GraphShoreLayer has a texture with white color (possibly noised),
// and a solid alpha.
// Alpha is constant along U (width).
// Alpha is 0 at base,
// ramps up to opaque
// then drops off sharply to transparent just before the top.
// Might as well make it pretty much 1 dimensional.
//
// Tile in U, clamp in V
plLayer* lay = ICreateBlankLayer("Graph", iPass);
// Set up it's state.
// First pass just overwrites, from then on alpha blend onto.
lay->SetBlendFlags(0);
lay->SetZFlags(hsGMatState::kZNoZRead | hsGMatState::kZNoZWrite);
lay->SetShadeFlags(hsGMatState::kShadeReallyNoFog
| hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetClampFlags(hsGMatState::kClampTextureV);
lay->SetMiscFlags(hsGMatState::kMiscRestartPassHere);
lay->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
lay->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
lay->SetOpacity(1.f);
lay->SetUVWSrc(0);
// Now set the texture.
plConst(int) kGraphWidth(1);
plConst(int) kGraphHeight(512);
plMipmap* tex = ICreateGraphShoreTex(kGraphWidth, kGraphHeight);
ISetAsTexture(lay, tex);
mat->AddLayerViaNotify(lay);
}
// Second layer is the bubbles
void plWaveSet7::ICreateGraphBubbleLayer(hsGMaterial* mat, int iPass)
{
// Bubble layer is white in color (or noised).
// Alpha is just, well, random bubbles.
// Tile in U and V
plLayer* lay = ICreateBlankLayer("Bubble", iPass);
// Set up it's state.
lay->SetBlendFlags(hsGMatState::kBlendAlpha);
lay->SetZFlags(hsGMatState::kZNoZRead | hsGMatState::kZNoZWrite);
lay->SetShadeFlags(hsGMatState::kShadeReallyNoFog
| hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetClampFlags(0);
lay->SetMiscFlags(0);
lay->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
lay->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
lay->SetOpacity(1.f);
lay->SetUVWSrc(0);
// Now set the texture
plConst(int) kBubWidth(128);
plConst(int) kBubHeight(128);
plMipmap* tex = ICreateBubbleShoreTex(kBubWidth, kBubHeight);
ISetAsTexture(lay, tex);
mat->AddLayerViaNotify(lay);
}
// Third layer is the alpha leading edge
void plWaveSet7::ICreateGraphEdgeLayer(hsGMaterial* mat, int iPass)
{
// Edge layer is solid white color.
// Alpha is 0 from base almost up to where graph shore texture drops off
// sharply. There, alpha ramps up and back down. Probably get a better look
// from sqrt(k - d^2) (elliptical) than a linear ramp up and down.
// Tile in U, clamp in V.
plLayer* lay = ICreateBlankLayer("Edge", iPass);
// Set up it's state.
lay->SetBlendFlags(hsGMatState::kBlendAlpha);
lay->SetZFlags(hsGMatState::kZNoZRead | hsGMatState::kZNoZWrite);
lay->SetShadeFlags(hsGMatState::kShadeReallyNoFog
| hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetClampFlags(hsGMatState::kClampTextureV);
lay->SetMiscFlags(0);
lay->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
lay->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
lay->SetOpacity(1.f);
lay->SetUVWSrc(0);
// Now set the texture.
plConst(int) kEdgeWidth(1);
plConst(int) kEdgeHeight(512);
plMipmap* tex = ICreateEdgeShoreTex(kEdgeWidth, kEdgeHeight);
ISetAsTexture(lay, tex);
mat->AddLayerViaNotify(lay);
}
void plWaveSet7::ICreateGraphShoreMaterials()
{
int i;
for( i = 0; i < kGraphShorePasses; i++ )
{
// Create our material
// and send ourselves a ref.
hsGMaterial* mat = ICreateEmptyMaterial("GraphShoreMat", kRefGraphShoreMat, i);
// GraphShoreMat's are the materials used to generate the shore texture layers
// which are then used on rendering the shore to the screen.
// Create 3 layers
// First layer is the graph shore
ICreateGraphShoreLayer(mat, i);
// Second layer is the bubbles
ICreateGraphBubbleLayer(mat, i);
// Third layer is the alpha leading edge
ICreateGraphEdgeLayer(mat, i);
IAddGraphVShader(mat, i);
IAddGraphPShader(mat, i);
IInitGraph(i);
hsAssert(fGraphShoreMat[i] == mat, "Should have been processed in ICreateEmptyMaterial()");
}
}
void plWaveSet7::IAddGraphVShader(hsGMaterial* mat, int iPass)
{
if( !fGraphVShader[iPass] )
{
plShader* vShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_GraphVS_%d", GetKey()->GetName(), iPass);
hsgResMgr::ResMgr()->NewKey(buff, vShader, GetKey()->GetUoid().GetLocation());
vShader->SetIsPixelShader(false);
vShader->SetNumConsts(plGraphVS::kNumConsts);
vShader->SetVector(plGraphVS::kNumericConsts, 0, 0.5f, 1.f, 2.f);
vShader->SetVector(plGraphVS::kPiConsts, 1.f / (2.f*hsScalarPI), hsScalarPI/2.f, hsScalarPI, hsScalarPI*2.f);
vShader->SetVector(plGraphVS::kCosConsts, 1.f, -1.f/2.f, 1.f/24.f, -1.f/720.f);
#ifndef TEST_UVWS
vShader->SetInputFormat(0);
#else // TEST_UVWS
vShader->SetInputFormat(1);
#endif // TEST_UVWS
vShader->SetOutputFormat(0);
// vShader->SetShaderFileName("sha/vs_WaveGraph.inl");
// vShader->SetShaderFileName("sha/vs_WaveGraph2.inl");
vShader->SetDecl(plShaderTable::Decl(vs_WaveGraph2));
hsgResMgr::ResMgr()->SendRef(vShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, iPass, kRefGraphVShader), plRefFlags::kActiveRef);
hsAssert(fGraphVShader[iPass] == vShader, "SendRef should have set shader");
}
IAddShaderToLayers(mat, 0, 2, plLayRefMsg::kVertexShader, fGraphVShader[iPass]);
}
void plWaveSet7::IAddGraphPShader(hsGMaterial* mat, int iPass)
{
if( !fGraphPShader[iPass] )
{
plShader* pShader = TRACKED_NEW plShader;
char buff[256];
sprintf(buff, "%s_GraphPS_%d", GetKey()->GetName(), iPass);
hsgResMgr::ResMgr()->NewKey(buff, pShader, GetKey()->GetUoid().GetLocation());
pShader->SetIsPixelShader(true);
pShader->SetNumConsts(plGraphPS::kNumConsts);
pShader->SetInputFormat(0);
pShader->SetOutputFormat(0);
// pShader->SetShaderFileName("sha/ps_WaveGraph.inl");
pShader->SetDecl(plShaderTable::Decl(ps_WaveGraph));
hsgResMgr::ResMgr()->SendRef(pShader->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, iPass, kRefGraphPShader), plRefFlags::kActiveRef);
hsAssert(fGraphPShader[iPass] == pShader, "SendRef should have set shader");
}
IAddShaderToLayers(mat, 0, 2, plLayRefMsg::kPixelShader, fGraphPShader[iPass]);
}
plRenderTarget* plWaveSet7::ISetupGraphShoreRenderReq(int which)
{
plConst(int) kGraphSize(256);
char name[256];
sprintf(name, "Graph_%d", which);
plRenderTarget* rt = ICreateTransferRenderTarget(name, kGraphSize);
hsgResMgr::ResMgr()->SendRef(rt->GetKey(), TRACKED_NEW plGenRefMsg(GetKey(), plRefMsg::kOnRequest, which, kRefGraphShoreRT), plRefFlags::kActiveRef);
fGraphReq[which] = ICreateRenderRequest(rt, fGraphShoreDraw[which], -100.f);
fGraphReqMsg[which] = TRACKED_NEW plRenderRequestMsg(GetKey(), fGraphReq[which]);
return rt;
}
void plWaveSet7::ISetupGraphShore(hsGMaterial* mat)
{
if( !fGraphShoreRT[0] )
{
// Create the material
ICreateGraphShoreMaterials();
int i;
for( i = 0; i < kGraphShorePasses; i++ )
{
// Create the mesh
plDrawableSpans* drawable = ICreateEmptyGraphDrawable("GraphShore", kRefGraphShoreDraw, i);
plConst(int) kGraphWidth(256);
fGraphShoreDraw[i] = ICreateGraphDrawable(drawable, fGraphShoreMat[i], kGraphWidth);
// Setup render requests
// Return value is the texture we want to use for the shore line.
fGraphShoreRT[i] = ISetupGraphShoreRenderReq(i);
}
}
// If we've already done this material, we're done (it may be shared
// with another shore mesh).
if( fShoreVShader && mat->GetLayer(0) && (fShoreVShader == mat->GetLayer(0)->GetVertexShader()) )
return;
// We now have all our render target textures. Set them up as
// our kGraphShorePasses layers on this material.
ISetupShoreLayers(mat);
}
void plWaveSet7::IMakeShoreLayer(hsGMaterial* mat, int which)
{
char name[512];
if( which >= mat->GetNumLayers() )
{
plLayer* lay = TRACKED_NEW plLayer;
sprintf(name, "%s_lay_%d", mat->GetKey()->GetName(), which);
hsgResMgr::ResMgr()->NewKey(name, lay, GetKey()->GetUoid().GetLocation());
lay->SetAmbientColor(hsColorRGBA().Set(0.f, 0.f, 0.f, 1.f));
lay->SetRuntimeColor(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
lay->SetOpacity(1.f);
mat->AddLayerViaNotify(lay);
}
}
void plWaveSet7::ISetupShoreLayers(hsGMaterial* mat)
{
// Make sure we have exactly kGraphShorePasses layers on this mat.
IMakeShoreLayer(mat, 0);
IMakeShoreLayer(mat, 1);
IMakeShoreLayer(mat, 2);
// Make sure the state is correct for each layer.
// And set the textures up to point at the render targets
plLayer* lay = plLayer::ConvertNoRef(mat->GetLayer(0)->BottomOfStack());
hsAssert(lay, "Bad first layer on material %s. Animated?");
// lay->SetBlendFlags(hsGMatState::kBlendAlpha | hsGMatState::kBlendInvertFinalAlpha | hsGMatState::kBlendAlphaAlways);
lay->SetBlendFlags(hsGMatState::kBlendAlpha);
lay->SetClampFlags(hsGMatState::kClampTextureV);
lay->SetShadeFlags(hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetZFlags(hsGMatState::kZNoZWrite | hsGMatState::kZIncLayer);
lay->SetMiscFlags(hsGMatState::kMiscTwoSided);
ISetAsTexture(lay, fGraphShoreRT[0]);
lay->SetUVWSrc(0);
lay = plLayer::ConvertNoRef(mat->GetLayer(1));
hsAssert(lay, "Bad second layer on material %s. Animated?");
lay->SetBlendFlags(hsGMatState::kBlendAlpha);
lay->SetClampFlags(hsGMatState::kClampTextureV);
lay->SetShadeFlags(hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetZFlags(hsGMatState::kZNoZWrite);
lay->SetMiscFlags(hsGMatState::kMiscTwoSided);
ISetAsTexture(lay, fGraphShoreRT[1]);
lay->SetUVWSrc(1);
lay = plLayer::ConvertNoRef(mat->GetLayer(2));
hsAssert(lay, "Bad third layer on material %s. Animated?");
lay->SetBlendFlags(hsGMatState::kBlendAlpha);
lay->SetClampFlags(hsGMatState::kClampTextureV);
lay->SetShadeFlags(hsGMatState::kShadeNoProjectors
| hsGMatState::kShadeNoShade
| hsGMatState::kShadeWhite);
lay->SetZFlags(hsGMatState::kZNoZWrite);
lay->SetMiscFlags(hsGMatState::kMiscTwoSided);
ISetAsTexture(lay, fGraphShoreRT[2]);
lay->SetUVWSrc(2);
// Add the vertex and pixel shaders.
IAddShoreVertexShader(mat);
IAddShorePixelShader(mat);
}
void plWaveSet7::IInitGraph(int iPass)
{
GraphState& gs = fGraphState[iPass];
plShader* shader = fGraphVShader[iPass];
// First the easy stuff.
// Age starts off 0.
gs.fAge = 0;
static int lastOne = 0;
plConst(hsScalar) kBasePeriod(3.f);
hsScalar life = State().fPeriod * kBasePeriod * (1.f + fRand.RandZeroToOne());
gs.fInvLife = (1.f + hsScalar(lastOne)/hsScalar(kGraphShorePasses-1)) / life;
lastOne = !lastOne;
gs.fUOff = fRand.RandZeroToOne();
// Now the rest we have to think about a little, and
// think about four times.
int i;
for( i = 0; i < 4; i++ )
{
// Okay, phase we don't have to think too hard about,
// it doesn't matter as long as it's random.
gs.fPhase[i] = fRand.RandZeroToOne() * 2.f * hsScalarPI;
// Next up is frequency, but frequency is the hard one.
// Remember frequency has to preserve tiling, so freq = k * 2 * PI.
// We'd like to keep at least one big one around all the time,
// so we'll always put a big one in first, and then a bunch of
// smaller ones to noise it up nice.
int k;
if( !i )
{
k = fRand.RandZeroToOne() > 0.5 ? 1 : 2;
}
else
{
plConst(int) kMinFreq(3);
plConst(int) kMaxFreq(10);
k = kMinFreq + int((kMaxFreq-kMinFreq) * fRand.RandZeroToOne());
}
// Input will be in range [0..2], so we'll omit the customary 2*PI here.
gs.fFreq[i] = k * hsScalarPI;
// Amplitude depends on freqency, or roughly inversely proportional
// to frequency (randomized about linear on period).
// Divide by 4 because that's how many oscillators we have, and they
// are summed.
hsScalar period = 1.f / hsScalar(k);
plConst(hsScalar) kAmpScale(1.f / 4.f / 2.f);
plConst(hsScalar) kMinPeriodFrac(1.f);
plConst(hsScalar) kMaxPeriodFrac(2.f);
period *= kMinPeriodFrac + fRand.RandZeroToOne() * (kMaxPeriodFrac - kMinPeriodFrac);
period *= kAmpScale;
gs.fAmp[i] = period;
}
// Go ahead and set the ones on the shader that won't be updated.
shader->SetVector(plGraphVS::kPhase,
gs.fPhase[0],
gs.fPhase[1],
gs.fPhase[2],
gs.fPhase[3]);
shader->SetVector(plGraphVS::kFrequency,
gs.fFreq[0],
gs.fFreq[1],
gs.fFreq[2],
gs.fFreq[3]);
// Propagate all this to the shader.
IUpdateGraphShader(0, iPass);
}
void plWaveSet7::IShuffleDownGraphs(int iPass)
{
int i;
for( i = iPass+1; i < kGraphShorePasses; i++ )
{
fGraphState[i-1] = fGraphState[i];
fGraphVShader[i-1]->CopyConsts(fGraphVShader[i]);
}
IInitGraph(kGraphShorePasses-1);
}
void plWaveSet7::IUpdateGraphShader(hsScalar dt, int iPass)
{
if( fGraphShoreDraw[iPass] )
{
GraphState& gs = fGraphState[iPass];
plShader* shader = fGraphVShader[iPass];
gs.fAge += dt;
hsScalar rads = gs.fAge * gs.fInvLife;
if( rads >= hsScalarPI )
{
// Recycle this one and restart the upper.
IShuffleDownGraphs(iPass);
}
else
{
hsScalar sinAge = hsFastMath::SinInRange(rads);
shader->SetVector(plGraphVS::kAmplitude,
gs.fAmp[0] * sinAge,
gs.fAmp[1] * sinAge,
gs.fAmp[2] * sinAge,
gs.fAmp[3] * sinAge);
// Might want to tint this sometime.
plConst(hsColorRGBA) kTint(hsColorRGBA().Set(1.f, 1.f, 1.f, 1.f));
hsColorRGBA tint = kTint;
tint.a *= sinAge;
shader->SetColor(plGraphVS::kColor, tint);
plConst(hsScalar) kCMax(1.f);
plConst(hsScalar) kCMin(3.f);
hsScalar cMin = kCMax + (kCMin - kCMax) * State().fFingerLength;
plConst(hsScalar) k2ndLayerScale(2.f);
plConst(hsScalar) k2ndLayerVoff(1.5f);
shader->SetVector(plGraphVS::kUVWConsts,
(kCMax - cMin) * sinAge + cMin,
gs.fUOff,
k2ndLayerVoff,
k2ndLayerScale);
}
}
}
void plWaveSet7::IUpdateGraphShaders(plPipeline* pipe, hsScalar dt)
{
if( fGraphShoreDraw[0] )
{
int i;
for( i = kGraphShorePasses-1; i >= 0; i-- )
{
IUpdateGraphShader(dt, i);
}
}
}