You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 

1402 lines
34 KiB

/*==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 "plAnimEaseTypes.h"
#include "plAnimTimeConvert.h"
#include "../plAvatar/plAGAnim.h"
#include "hsTimer.h"
#include "hsStream.h"
#include "../pnMessage/plEventCallbackMsg.h"
#include "../plMessage/plAnimCmdMsg.h"
#include "../plAvatar/plAGMasterSDLModifier.h"
#include "../plAvatar/plAGMasterMod.h"
#include "../plModifier/plLayerSDLModifier.h"
#include "../plSurface/plLayerAnimation.h"
#include "hsResMgr.h"
#include "plgDispatch.h"
plAnimTimeConvert::plAnimTimeConvert()
: fCurrentAnimTime(0),
fLastEvalWorldTime(0),
fBegin(0),
fEnd(0),
fLoopEnd(0),
fLoopBegin(0),
fSpeed(1.f),
fFlags(0),
fOwner(nil),
fEaseInCurve(nil),
fEaseOutCurve(nil),
fSpeedEaseCurve(nil),
fCurrentEaseCurve(nil),
fInitialBegin(0),
fInitialEnd(0),
fWrapTime(0)
//fDirtyNotifier(nil)
{
}
plAnimTimeConvert::~plAnimTimeConvert()
{
int i;
for( i = 0; i < fCallbackMsgs.GetCount(); i++ )
hsRefCnt_SafeUnRef(fCallbackMsgs[i]);
delete fEaseInCurve;
delete fEaseOutCurve;
delete fSpeedEaseCurve;
//delete fDirtyNotifier;
IClearAllStates();
}
void plAnimTimeConvert::Init(plATCAnim *anim, plAGAnimInstance *instance, plAGMasterMod *master)
{
// Set up our eval callbacks
plAGInstanceCallbackMsg *instMsg;
instMsg = TRACKED_NEW plAGInstanceCallbackMsg(master->GetKey(), kStart);
instMsg->fInstance = instance;
AddCallback(instMsg);
hsRefCnt_SafeUnRef(instMsg);
instMsg = TRACKED_NEW plAGInstanceCallbackMsg(master->GetKey(), kStop);
instMsg->fInstance = instance;
AddCallback(instMsg);
hsRefCnt_SafeUnRef(instMsg);
instMsg = TRACKED_NEW plAGInstanceCallbackMsg(master->GetKey(), kSingleFrameAdjust);
instMsg->fInstance = instance;
AddCallback(instMsg);
hsRefCnt_SafeUnRef(instMsg);
SetOwner(master);
ClearFlags();
for (int i = 0; i < anim->NumStopPoints(); i++)
GetStopPoints().Append(anim->GetStopPoint(i));
SetBegin(anim->GetStart());
SetEnd(anim->GetEnd());
fInitialBegin = fBegin;
fInitialEnd = fEnd;
if (anim->GetInitial() != -1)
SetCurrentAnimTime(anim->GetInitial());
else
SetCurrentAnimTime(anim->GetStart());
SetLoopPoints(anim->GetLoopStart(), anim->GetLoopEnd());
Loop(anim->GetLoop());
SetSpeed(1.f);
SetEase(true, anim->GetEaseInType(), anim->GetEaseInMin(),
anim->GetEaseInMax(), anim->GetEaseInLength());
SetEase(false, anim->GetEaseOutType(), anim->GetEaseOutMin(),
anim->GetEaseOutMax(), anim->GetEaseOutLength());
// set up our time converter based on the animation's specs...
// ... after we've set all of its other state values.
if (anim->GetAutoStart())
{
plSynchEnabler ps(true); // enable dirty tracking so that autostart will send out a state update
Start();
}
else
InitStop();
}
//
// 0=nil, 1=easeIn, 2=easeOut, 3=speed
//
void plAnimTimeConvert::SetCurrentEaseCurve(int x)
{
switch(x)
{
default:
hsAssert(false, "invalid arg to SetCurrentEaseCurve");
break;
case kEaseNone:
fCurrentEaseCurve=nil;
break;
case kEaseIn:
fCurrentEaseCurve=fEaseInCurve;
break;
case kEaseOut:
fCurrentEaseCurve=fEaseOutCurve;
break;
case kEaseSpeed:
fCurrentEaseCurve=fSpeedEaseCurve;
break;
}
}
int plAnimTimeConvert::GetCurrentEaseCurve() const
{
if (fCurrentEaseCurve==nil)
return kEaseNone;
if (fCurrentEaseCurve==fEaseInCurve)
return kEaseIn;
if (fCurrentEaseCurve==fEaseOutCurve)
return kEaseOut;
if (fCurrentEaseCurve==fSpeedEaseCurve)
return kEaseSpeed;
hsAssert(false, "unknown ease curve");
return 0;
}
//
// set the number of ATCStates we have
//
void plAnimTimeConvert::ResizeStates(int cnt)
{
while (fStates.size() > cnt)
{
delete fStates.back();
fStates.pop_back();
}
while (cnt>fStates.size())
{
fStates.push_back(TRACKED_NEW plATCState);
}
hsAssert(fStates.size()==cnt, "state resize mismatch");
}
void plAnimTimeConvert::ResetWrap()
{
fBegin = fInitialBegin;
fEnd = fInitialEnd;
Forewards();
fFlags &= (~kWrap & ~kNeedsReset);
}
hsScalar plAnimTimeConvert::ICalcEaseTime(const plATCEaseCurve *curve, double start, double end)
{
start -= curve->fBeginWorldTime;
end -= curve->fBeginWorldTime;
// Clamp to the curve's range
if (start < 0)
start = 0;
if (end > curve->fLength)
end = curve->fLength;
hsScalar delSecs = 0;
if (start < curve->fLength)
{
// Redundant eval... but only when easing.
delSecs = curve->PositionGivenTime((hsScalar)end) - curve->PositionGivenTime((hsScalar)start);
}
return delSecs;
}
void plAnimTimeConvert::IClearSpeedEase()
{
if (fCurrentEaseCurve == fSpeedEaseCurve)
fCurrentEaseCurve = nil;
delete fSpeedEaseCurve;
fSpeedEaseCurve = nil;
}
void plAnimTimeConvert::ICheckTimeCallbacks(hsScalar frameStart, hsScalar frameStop)
{
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kTime)
{
if( ITimeInFrame(fCallbackMsgs[i]->fEventTime, frameStart, frameStop) )
ISendCallback(i);
}
else if (fCallbackMsgs[i]->fEvent == kBegin && ITimeInFrame(fBegin, frameStart, frameStop) )
ISendCallback(i);
else if (fCallbackMsgs[i]->fEvent == kEnd && ITimeInFrame(fEnd, frameStart, frameStop) )
ISendCallback(i);
}
}
hsBool plAnimTimeConvert::ITimeInFrame(hsScalar secs, hsScalar start, hsScalar stop)
{
if (secs == start && secs == stop)
return true;
if( IsBackwards() )
{
if( start < stop )
{
// We've just wrapped. Careful to exclude markers outside current loop.
if( ((secs <= start) && (secs >= fLoopBegin))
|| ((secs >= stop) && (secs <= fLoopEnd)) )
return true;
}
else
{
if( (secs <= start) && (secs >= stop) )
return true;
}
}
else
{
if( start > stop )
{
// We've just wrapped. Careful to exclude markers outside current loop.
if( ((secs >= start) && (secs <= fLoopEnd))
|| ((secs <= stop) && (secs >= fLoopBegin)) )
return true;
}
else
{
if( (secs >= start) && (secs <= stop) )
return true;
}
}
return false;
}
void plAnimTimeConvert::ISendCallback(int i)
{
// Check if callbacks are disabled this frame (i.e. when we're loading in state)
if (fFlags & kNoCallbacks)
return;
// send callback if msg is local or if we are the local master
if (!fCallbackMsgs[i]->HasBCastFlag(plMessage::kNetPropagate) ||
!fOwner || fOwner->IsLocallyOwned()==plSynchedObject::kYes)
{
plEventCallbackMsg *temp = fCallbackMsgs[i];
fCallbackMsgs[i]->SetSender(fOwner ? fOwner->GetKey() : nil);
hsRefCnt_SafeRef(fCallbackMsgs[i]);
plgDispatch::MsgSend(fCallbackMsgs[i]);
// No more repeats, remove this callback from our list
if (fCallbackMsgs[i]->fRepeats == 0)
{
hsRefCnt_SafeUnRef(fCallbackMsgs[i]);
fCallbackMsgs.Remove(i);
}
// If this isn't infinite, decrement the number of repeats
else if (fCallbackMsgs[i]->fRepeats > 0)
fCallbackMsgs[i]->fRepeats--;
}
}
plAnimTimeConvert& plAnimTimeConvert::IStop(double time, hsScalar animTime)
{
if( IsStopped() )
return *this;
IClearSpeedEase(); // If we had one queued up, clear it. It will automatically take effect when we start
SetFlag(kEasingIn, false);
SetFlag(kStopped, true);
if (fFlags & kNeedsReset)
ResetWrap();
IProcessStateChange(time, animTime);
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kStop)
{
ISendCallback(i);
}
}
return *this;
}
plAnimTimeConvert& plAnimTimeConvert::IProcessStateChange(double worldTime, hsScalar animTime /* = -1 */)
{
if (fStates.size() > 0 && worldTime < fStates.front()->fStartWorldTime)
return *this; // Sorry... state saves only work in the forward direction
fLastStateChange = worldTime;
plATCState *state = TRACKED_NEW plATCState;
state->fStartWorldTime = fLastStateChange;
state->fStartAnimTime = (animTime < 0 ? WorldToAnimTimeNoUpdate(fLastStateChange) : animTime);
state->fFlags = (UInt8)fFlags;
state->fBegin = fBegin;
state->fEnd = fEnd;
state->fLoopBegin = fLoopBegin;
state->fLoopEnd = fLoopEnd;
state->fSpeed = fSpeed;
state->fWrapTime = fWrapTime;
state->fEaseCurve = (fCurrentEaseCurve == nil ? nil : fCurrentEaseCurve->Clone());
fStates.push_front(state);
IFlushOldStates();
const char* sdlName=nil;
if (plLayerAnimation::ConvertNoRef(fOwner))
sdlName=kSDLLayer;
else
if (plAGMasterMod::ConvertNoRef(fOwner))
sdlName=kSDLAGMaster;
else
{
hsAssert(false, "unknown sdl owner");
}
fOwner->DirtySynchState(sdlName, 0); // Send SDL state update to server
return *this;
}
// Remove any out-of-date plATCStates
// Where "out-of-date" means, "More than 1 frame old"
void plAnimTimeConvert::IFlushOldStates()
{
plATCState *state;
plATCStateList::const_iterator i = fStates.begin();
UInt32 count = 0;
for (i; i != fStates.end(); i++)
{
count++;
state = *i;
if (fLastEvalWorldTime - hsTimer::GetDelSysSeconds() >= state->fStartWorldTime)
break;
}
while (fStates.size() > count)
{
delete fStates.back();
fStates.pop_back();
}
}
void plAnimTimeConvert::IClearAllStates()
{
while (fStates.size() > 0)
{
delete fStates.back();
fStates.pop_back();
}
}
plATCState *plAnimTimeConvert::IGetState(double wSecs) const
{
plATCState *state;
plATCStateList::const_iterator i = fStates.begin();
for (i; i != fStates.end(); i++)
{
state = *i;
if (wSecs >= state->fStartWorldTime)
return state;
}
return nil;
}
plATCState *plAnimTimeConvert::IGetLatestState() const
{
return fStates.front();
}
void plAnimTimeConvert::SetOwner(plSynchedObject* o)
{
fOwner = o;
}
hsBool plAnimTimeConvert::IIsStoppedAt(const double &wSecs, const UInt32 &flags,
const plATCEaseCurve *curve) const
{
if (flags & kStopped)
return !(flags & kForcedMove); // If someone called SetCurrentAnimTime(), we need to say we moved.
return false;
}
hsBool plAnimTimeConvert::IsStoppedAt(double wSecs) const
{
if (wSecs > fLastStateChange)
return IIsStoppedAt(wSecs, fFlags, fCurrentEaseCurve);
plATCState *state = IGetState(wSecs);
if ( !state )
return true;
return IIsStoppedAt(wSecs, state->fFlags, state->fEaseCurve);
}
hsScalar plAnimTimeConvert::WorldToAnimTime(double wSecs)
{
//hsAssert(wSecs >= fLastEvalWorldTime, "Tried to eval a time that's earlier than the last eval time.");
double d = wSecs - fLastEvalWorldTime;
hsScalar f = fCurrentAnimTime;
if (wSecs < fLastStateChange)
{
fCurrentAnimTime = IWorldToAnimTimeBeforeState(wSecs);
fLastEvalWorldTime = wSecs;
return fCurrentAnimTime;
}
if (fLastEvalWorldTime <= fLastStateChange) // Crossing into the latest state
{
fLastEvalWorldTime = fLastStateChange;
fCurrentAnimTime = IGetLatestState()->fStartAnimTime;
}
if( (fFlags & kStopped) || (wSecs == fLastEvalWorldTime) )
{
if (fFlags & kForcedMove)
{
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kSingleFrameEval)
{
ISendCallback(i);
}
}
}
fFlags &= ~kForcedMove;
fLastEvalWorldTime = wSecs;
return fCurrentAnimTime;
}
hsScalar note = fCurrentAnimTime - f;
hsScalar secs = 0, delSecs = 0;
if (fCurrentEaseCurve != nil)
{
delSecs += ICalcEaseTime(fCurrentEaseCurve, fLastEvalWorldTime, wSecs);
if (wSecs > fCurrentEaseCurve->GetEndWorldTime())
{
if (fFlags & kEasingIn)
delSecs += hsScalar(wSecs - fCurrentEaseCurve->GetEndWorldTime()) * fSpeed;
IClearSpeedEase();
fCurrentEaseCurve = nil;
}
}
else
{
// The easy case... playing the animation at a constant speed.
delSecs = hsScalar(wSecs - fLastEvalWorldTime) * fSpeed;
}
if (fFlags & kBackwards)
delSecs = -delSecs;
secs = fCurrentAnimTime + delSecs;
// At this point, "secs" is the pre-wrapped (before looping) anim time.
// "delSecs" is the change in anim time
// if our speed is < 0, then checking for the kBackwards flag isn't enough
// so we base our decision on the direction of the actual change we've computed.
hsBool forewards = delSecs >= 0;
if (fFlags & kLoop)
{
hsBool wrapped = false;
if (forewards)
{
if (IGetLatestState()->fStartAnimTime > fLoopEnd)
{
// Our animation started past the loop. Play to the end.
if (secs > fEnd)
{
secs = fEnd;
IStop(wSecs, secs);
}
}
else
{
if (secs > fLoopEnd)
{
secs = fmodf(secs - fLoopBegin, fLoopEnd - fLoopBegin) + fLoopBegin;
wrapped = true;
}
}
}
else
{
if (IGetLatestState()->fStartAnimTime < fLoopBegin)
{
if (secs < fBegin)
{
secs = fBegin;
IStop(wSecs, secs);
}
}
else
{
if (secs < fLoopBegin)
{
secs = fLoopEnd - fmodf(fLoopEnd - secs, fLoopEnd - fLoopBegin);
wrapped = true;
}
}
}
if (fFlags & kWrap)
{
// possible options, representing each line:
// 1. We wrapped around the the beginning of the anim, so stop at the wrap point if we're past it.
// 2. Same as #1, but in the backwards case.
// 3. We started before the wrap point, now we're after it. Stop.
// 4. Same as #3, backwards.
if ((wrapped && (forewards && secs >= fWrapTime) ||
(!forewards && secs <= fWrapTime)) ||
(forewards && fCurrentAnimTime < fWrapTime && secs >= fWrapTime) ||
(!forewards && fCurrentAnimTime > fWrapTime && secs <= fWrapTime))
{
secs = fWrapTime;
IStop(wSecs, secs);
}
}
}
else // Not looping
{
if ((secs < fBegin) || (secs > fEnd))
{
secs = forewards ? fEnd : fBegin;
IStop(wSecs, secs);
}
}
ICheckTimeCallbacks(fCurrentAnimTime, secs);
fLastEvalWorldTime = wSecs;
if (fEaseOutCurve != nil && !(fFlags & kEasingIn) && wSecs >= fEaseOutCurve->GetEndWorldTime())
IStop(wSecs, secs);
return fCurrentAnimTime = secs;
}
hsScalar plAnimTimeConvert::WorldToAnimTimeNoUpdate(double wSecs) const
{
return IWorldToAnimTimeNoUpdate(wSecs, IGetState(wSecs));
}
hsScalar plAnimTimeConvert::IWorldToAnimTimeNoUpdate(double wSecs, plATCState *state)
{
//hsAssert(wSecs >= fLastEvalWorldTime, "Tried to eval a time that's earlier than the last eval time.");
if (state == nil)
return 0;
if (state->fFlags & kStopped)
return state->fStartAnimTime;
hsScalar secs = 0, delSecs = 0;
if (state->fEaseCurve != nil)
{
delSecs += ICalcEaseTime(state->fEaseCurve, state->fStartWorldTime, wSecs);
if (wSecs > state->fEaseCurve->GetEndWorldTime())
{
if (state->fFlags & kEasingIn)
delSecs += hsScalar(wSecs - state->fEaseCurve->GetEndWorldTime()) * state->fSpeed;
}
}
else
{
// The easy case... playing the animation at a constant speed.
delSecs = hsScalar(wSecs - state->fStartWorldTime) * state->fSpeed;
}
if (state->fFlags & kBackwards)
delSecs = -delSecs;
secs = state->fStartAnimTime + delSecs;
// At this point, "secs" is the pre-wrapped (before looping) anim time.
// "delSecs" is the change in anim time
hsBool forewards = delSecs >= 0;
if (state->fFlags & kLoop)
{
hsBool wrapped = false;
if (forewards)
{
if (state->fStartAnimTime > state->fLoopEnd)
{
// Our animation started past the loop. Play to the end.
if (secs > state->fEnd)
{
secs = state->fEnd;
}
}
else
{
if (secs > state->fLoopEnd)
{
secs = fmodf(secs - state->fLoopBegin, state->fLoopEnd - state->fLoopBegin) + state->fLoopBegin;
wrapped = true;
}
}
}
else
{
if (state->fStartAnimTime < state->fLoopBegin)
{
if (secs < state->fBegin)
{
secs = state->fBegin;
}
}
else
{
if (secs < state->fLoopBegin)
{
secs = state->fLoopEnd - fmodf(state->fLoopEnd - secs, state->fLoopEnd - state->fLoopBegin);
wrapped = true;
}
}
}
if (state->fFlags & kWrap)
{
if ((wrapped && (forewards && secs >= state->fWrapTime) ||
(!forewards && secs <= state->fWrapTime)) ||
(forewards && state->fStartAnimTime < state->fWrapTime && secs >= state->fWrapTime) ||
(!forewards && state->fStartAnimTime > state->fWrapTime && secs <= state->fWrapTime))
{
secs = state->fWrapTime;
}
}
}
else
{
if ((secs < state->fBegin) || (secs > state->fEnd))
{
secs = forewards ? state->fEnd : state->fBegin;
}
}
return secs;
}
hsScalar plAnimTimeConvert::IWorldToAnimTimeBeforeState(double wSecs) const
{
return IWorldToAnimTimeNoUpdate(wSecs, IGetState(wSecs));
}
void plAnimTimeConvert::SetCurrentAnimTime(hsScalar s, hsBool jump /* = false */)
{
// We're setting the anim value for whenever we last evaluated.
fFlags |= kForcedMove;
if (!jump)
ICheckTimeCallbacks(fCurrentAnimTime, s);
fCurrentAnimTime = s;
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kSingleFrameAdjust)
{
ISendCallback(i);
}
}
IProcessStateChange(hsTimer::GetSysSeconds(), fCurrentAnimTime);
}
void plAnimTimeConvert::SetEase(hsBool easeIn, UInt8 type, hsScalar minLength, hsScalar maxLength, hsScalar normLength)
{
if (easeIn)
{
delete fEaseInCurve;
fEaseInCurve = plATCEaseCurve::CreateEaseCurve(type, minLength, maxLength, normLength, 0, fSpeed);
}
else
{
delete fEaseOutCurve;
fEaseOutCurve = plATCEaseCurve::CreateEaseCurve(type, minLength, maxLength, normLength, fSpeed, 0);
}
}
hsScalar plAnimTimeConvert::GetBestStopDist(hsScalar min, hsScalar max, hsScalar norm, hsScalar time) const
{
hsScalar bestTime = -1;
hsScalar bestDist = -1;
if (fStopPoints.GetCount() == 0)
return norm;
hsScalar curTime;
hsScalar curDist;
int i;
for (i = 0; i < fStopPoints.GetCount(); i++)
{
hsScalar stop = fStopPoints.Get(i);
if (IsLooped())
{
hsScalar loopDist;
if (IsBackwards())
{
if ((time >= fLoopBegin && stop < fLoopBegin) ||
(time < fLoopBegin && stop > fLoopBegin))
continue;
loopDist = -(fLoopEnd - fLoopBegin);
}
else
{
if ((time <= fLoopEnd && stop > fLoopEnd) ||
(time > fLoopEnd && stop < fLoopEnd))
continue; // we'll never reach it.
loopDist = fLoopEnd - fLoopBegin;
}
if (stop <= fLoopEnd && stop >= fLoopBegin)
{
while (true)
{
curTime = stop - time;
if (IsBackwards())
curTime = -curTime;
if (curTime > max)
break;
curDist = curTime - norm;
if (curDist < 0)
curDist = -curDist;
if (curTime >= min && curTime <= max && (bestDist == -1 || bestDist > curDist))
{
bestDist = curDist;
bestTime = curTime;
}
stop += loopDist;
}
continue;
}
}
curTime = stop - time;
if (IsBackwards())
curTime = -curTime;
curDist = curTime - norm;
if (curDist < 0)
curDist = -curDist;
if (curTime >= min && curTime <= max && (bestDist == -1 || bestDist > curDist))
{
bestDist = curDist;
bestTime = curTime;
}
}
hsStatusMessageF("found stop point %f\n", bestTime);
if (bestTime == -1)
bestTime = norm;
return bestTime;
}
// Passing in a rate of zero specifies an immediate change.
void plAnimTimeConvert::SetSpeed(hsScalar goal, hsScalar rate /* = 0 */)
{
hsScalar curSpeed = fSpeed;
fSpeed = goal;
if (rate == 0)
{
IClearSpeedEase();
fCurrentEaseCurve = nil;
}
// Skip if we're either stopped or stopping. We'll take the new speed into account next time we start up.
else if ((fFlags & kEasingIn))
{
double curTime = hsTimer::GetSysSeconds();
if (fCurrentEaseCurve != nil)
{
double easeTime = curTime - fCurrentEaseCurve->fBeginWorldTime;
curSpeed = fCurrentEaseCurve->VelocityGivenTime((hsScalar)easeTime);
}
if (fSpeedEaseCurve != nil)
{
fSpeedEaseCurve->RecalcToSpeed(curSpeed, goal);
fSpeedEaseCurve->SetLengthOnRate(rate);
}
else
{
hsScalar length;
length = (goal - curSpeed) / rate;
if (length < 0)
length = -length;
fSpeedEaseCurve = plATCEaseCurve::CreateEaseCurve(plAnimEaseTypes::kConstAccel, length, length, length,
curSpeed, goal);
}
fSpeedEaseCurve->fBeginWorldTime = curTime;
fCurrentEaseCurve = fSpeedEaseCurve;
}
IProcessStateChange(hsTimer::GetSysSeconds());
}
void plAnimTimeConvert::Read(hsStream* s, hsResMgr* mgr)
{
plCreatable::Read(s, mgr);
fFlags = (UInt16)(s->ReadSwap32());
fBegin = fInitialBegin = s->ReadSwapScalar();
fEnd = fInitialEnd = s->ReadSwapScalar();
fLoopEnd = s->ReadSwapScalar();
fLoopBegin = s->ReadSwapScalar();
fSpeed = s->ReadSwapScalar();
fEaseInCurve = plATCEaseCurve::ConvertNoRef(mgr->ReadCreatable(s));
fEaseOutCurve = plATCEaseCurve::ConvertNoRef(mgr->ReadCreatable(s));
fSpeedEaseCurve = plATCEaseCurve::ConvertNoRef(mgr->ReadCreatable(s));
fCurrentAnimTime = s->ReadSwapScalar();
fLastEvalWorldTime = s->ReadSwapDouble();
// load other non-synched data;
int count = s->ReadSwap32();
fCallbackMsgs.SetCountAndZero(count);
int i;
for (i = 0; i < count; i++)
{
plEventCallbackMsg* msg = plEventCallbackMsg::ConvertNoRef(mgr->ReadCreatable(s));
fCallbackMsgs[i] = msg;
}
count = s->ReadSwap32();
for (i = 0; i < count; i++)
{
fStopPoints.Append(s->ReadSwapScalar());
}
IProcessStateChange(0, fBegin);
}
void plAnimTimeConvert::Write(hsStream* s, hsResMgr* mgr)
{
plCreatable::Write(s, mgr);
s->WriteSwap32(fFlags);
s->WriteSwapScalar(fBegin);
s->WriteSwapScalar(fEnd);
s->WriteSwapScalar(fLoopEnd);
s->WriteSwapScalar(fLoopBegin);
s->WriteSwapScalar(fSpeed);
mgr->WriteCreatable(s, fEaseInCurve);
mgr->WriteCreatable(s, fEaseOutCurve);
mgr->WriteCreatable(s, fSpeedEaseCurve);
s->WriteSwapScalar(fCurrentAnimTime);
s->WriteSwapDouble(fLastEvalWorldTime);
// save out other non-synched important data
s->WriteSwap32(fCallbackMsgs.Count());
int i;
for (i = 0; i < fCallbackMsgs.Count(); i++)
mgr->WriteCreatable(s, fCallbackMsgs[i]);
s->WriteSwap32(fStopPoints.GetCount());
for (i = 0; i < fStopPoints.GetCount(); i++)
{
s->WriteSwapScalar(fStopPoints.Get(i));
}
}
plAnimTimeConvert& plAnimTimeConvert::InitStop()
{
return IStop(hsTimer::GetSysSeconds(), fCurrentAnimTime);
}
plAnimTimeConvert& plAnimTimeConvert::Stop(hsBool on)
{
if( on )
return Stop();
else
return Start();
}
plAnimTimeConvert& plAnimTimeConvert::Stop(double stopTime)
{
if( IsStopped() || (fEaseOutCurve != nil && !(fFlags & kEasingIn)) )
return *this;
if (stopTime < 0)
stopTime = hsTimer::GetSysSeconds();
hsScalar stopAnimTime = WorldToAnimTimeNoUpdate(stopTime);
SetFlag(kEasingIn, false);
if( fEaseOutCurve == nil )
{
return IStop(stopTime, fCurrentAnimTime);
}
hsScalar currSpeed;
if (fCurrentEaseCurve == nil || stopTime >= fCurrentEaseCurve->GetEndWorldTime())
currSpeed = fSpeed;
else
currSpeed = fCurrentEaseCurve->VelocityGivenTime((hsScalar)(stopTime - fCurrentEaseCurve->fBeginWorldTime));
fEaseOutCurve->RecalcToSpeed(currSpeed > fSpeed ? currSpeed : fSpeed, 0);
fEaseOutCurve->SetLengthOnDistance(GetBestStopDist(fEaseOutCurve->GetMinDistance(), fEaseOutCurve->GetMaxDistance(),
fEaseOutCurve->GetNormDistance(), stopAnimTime));
fEaseOutCurve->fBeginWorldTime = stopTime - fEaseOutCurve->TimeGivenVelocity(currSpeed);
fCurrentEaseCurve = fEaseOutCurve;
return IProcessStateChange(stopTime);
}
plAnimTimeConvert& plAnimTimeConvert::Start(double startTime)
{
// If start has not been called since the last stop, kEasingIn will not be set
if( (fFlags & kEasingIn) && (startTime == fLastStateChange) )
return *this;
SetFlag(kEasingIn, true);
if (startTime < 0)
startTime = hsTimer::GetSysSeconds();
if (fEaseInCurve != nil)
{
hsScalar currSpeed;
if (fCurrentEaseCurve == nil || startTime >= fCurrentEaseCurve->GetEndWorldTime())
currSpeed = 0;
else
currSpeed = fCurrentEaseCurve->VelocityGivenTime((hsScalar)(startTime - fCurrentEaseCurve->fBeginWorldTime));
if (currSpeed <= fSpeed)
{
fEaseInCurve->RecalcToSpeed(0, fSpeed);
fEaseInCurve->fBeginWorldTime = startTime - fEaseInCurve->TimeGivenVelocity(currSpeed);
fCurrentEaseCurve = fEaseInCurve;
}
else
{ // We eased out in the middle of a speed change, but were told to start again before slowing past
// the target speed, so the "ease in" is really a slow down.
SetSpeed(fSpeed, fEaseInCurve->fSpeed / fEaseInCurve->fLength);
}
}
// check for a start callback
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kStart)
{
ISendCallback(i);
}
}
SetFlag(kStopped, false);
if (fFlags & kBackwards)
{
if (fCurrentAnimTime == fBegin)
return IProcessStateChange(startTime, fEnd);
}
else
{
if (fCurrentAnimTime == fEnd)
return IProcessStateChange(startTime, fBegin);
}
return IProcessStateChange(startTime);
}
plAnimTimeConvert& plAnimTimeConvert::Backwards(hsBool on)
{
return on ? Backwards() : Forewards();
}
plAnimTimeConvert& plAnimTimeConvert::Backwards()
{
if( IsBackwards() )
return *this;
// check for a reverse callback
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kReverse)
{
ISendCallback(i);
}
}
SetFlag(kBackwards, true);
// Record state changes
IProcessStateChange(hsTimer::GetSysSeconds(), fCurrentAnimTime);
return *this;
}
plAnimTimeConvert& plAnimTimeConvert::Forewards()
{
if( !IsBackwards() )
return *this;
// check for a reverse callback
int i;
for( i = fCallbackMsgs.GetCount()-1; i >= 0; --i )
{
if (fCallbackMsgs[i]->fEvent == kReverse)
{
ISendCallback(i);
}
}
SetFlag(kBackwards, false);
// Record state changes
IProcessStateChange(hsTimer::GetSysSeconds(), fCurrentAnimTime);
return *this;
}
plAnimTimeConvert& plAnimTimeConvert::Loop(hsBool on)
{
SetFlag(kLoop, on);
// Record state changes
IProcessStateChange(hsTimer::GetSysSeconds(), fCurrentAnimTime);
return *this;
}
plAnimTimeConvert& plAnimTimeConvert::PlayToTime(hsScalar time)
{
fFlags |= kNeedsReset;
if (fCurrentAnimTime > time)
{
if (fFlags & kLoop)
{
fWrapTime = time;
fFlags |= kWrap;
}
else
{
fBegin = time;
Backwards();
}
}
else
{
fEnd = time;
}
Start();
return *this;
}
plAnimTimeConvert& plAnimTimeConvert::PlayToPercentage(hsScalar percent)
{
return PlayToTime(fBegin + (fEnd - fBegin) * percent);
}
void plAnimTimeConvert::RemoveCallback(plEventCallbackMsg* pMsg)
{
int idx = fCallbackMsgs.Find(pMsg);
if( idx != fCallbackMsgs.kMissingIndex )
{
hsRefCnt_SafeUnRef(fCallbackMsgs[idx]);
fCallbackMsgs.Remove(idx);
}
}
hsBool plAnimTimeConvert::HandleCmd(plAnimCmdMsg* modMsg)
{
if (fFlags & kNeedsReset)
ResetWrap();
// The net msg screener is already checking for callbacks,
// I'm just being extra safe.
if (!modMsg->HasBCastFlag(plMessage::kNetCreatedRemotely))
{
if( modMsg->Cmd(plAnimCmdMsg::kAddCallbacks) )
{
int i;
for( i = 0; i < modMsg->GetNumCallbacks(); i++ )
{
AddCallback(plEventCallbackMsg::ConvertNoRef(modMsg->GetEventCallback(i)));
}
}
if( modMsg->Cmd(plAnimCmdMsg::kRemoveCallbacks) )
{
int i;
for( i = 0; i < modMsg->GetNumCallbacks(); i++ )
{
RemoveCallback(modMsg->GetEventCallback(i));
}
}
}
if( modMsg->Cmd(plAnimCmdMsg::kSetBackwards) )
{
Backwards();
}
if( modMsg->Cmd(plAnimCmdMsg::kSetForewards) )
{
Forewards();
}
if( modMsg->Cmd(plAnimCmdMsg::kStop) )
Stop();
if( modMsg->Cmd(plAnimCmdMsg::kSetLooping) )
Loop();
if( modMsg->Cmd(plAnimCmdMsg::kUnSetLooping) )
NoLoop();
if (modMsg->Cmd(plAnimCmdMsg::kSetBegin))
{
if (modMsg->fBegin >= fInitialBegin)
SetBegin(modMsg->fBegin);
else
SetBegin(fInitialBegin);
}
if (modMsg->Cmd(plAnimCmdMsg::kSetEnd))
{
if (modMsg->fEnd <= fInitialEnd)
SetEnd(modMsg->fEnd);
else
SetEnd(fInitialEnd);
}
if (fBegin > fEnd)
{
fBegin = fInitialBegin;
fEnd = fInitialEnd;
}
if( modMsg->Cmd(plAnimCmdMsg::kSetLoopEnd) )
SetLoopEnd(modMsg->fLoopEnd);
if( modMsg->Cmd(plAnimCmdMsg::kSetLoopBegin) )
SetLoopBegin(modMsg->fLoopBegin);
if( modMsg->Cmd(plAnimCmdMsg::kSetSpeed) )
SetSpeed(modMsg->fSpeed, modMsg->fSpeedChangeRate);
if( modMsg->Cmd(plAnimCmdMsg::kGoToTime) )
{
if (modMsg->fTime < fBegin)
SetCurrentAnimTime(fBegin, true);
else if (modMsg->fTime > fEnd)
SetCurrentAnimTime(fEnd, true);
else
SetCurrentAnimTime(modMsg->fTime, true);
}
if ( modMsg->Cmd(plAnimCmdMsg::kGoToPercent) )
SetCurrentAnimTime(fBegin + (fEnd - fBegin) * modMsg->fTime);
if( modMsg->Cmd(plAnimCmdMsg::kGoToBegin) )
SetCurrentAnimTime(fBegin, true);
if( modMsg->Cmd(plAnimCmdMsg::kGoToEnd) )
SetCurrentAnimTime(fEnd, true);
if( modMsg->Cmd(plAnimCmdMsg::kGoToLoopBegin) )
SetCurrentAnimTime(fLoopBegin, true);
if( modMsg->Cmd(plAnimCmdMsg::kGoToLoopEnd) )
SetCurrentAnimTime(fLoopEnd, true);
if( modMsg->Cmd(plAnimCmdMsg::kToggleState) )
{
if( IsStopped() )
{
Start();
}
else
{
Stop();
}
}
if( modMsg->Cmd(plAnimCmdMsg::kContinue) )
{
Start();
}
if( modMsg->Cmd(plAnimCmdMsg::kIncrementForward) )
{
if (fCurrentAnimTime == fEnd)
return true;
double currTime = hsTimer::GetSysSeconds();
hsScalar newTime = fCurrentAnimTime + hsTimer::GetDelSysSeconds();
if (newTime > fEnd)
{
newTime = fEnd;
}
Forewards();
SetCurrentAnimTime(newTime);
}
if( modMsg->Cmd(plAnimCmdMsg::kIncrementBackward) )
{
if (fCurrentAnimTime == fBegin)
return true;
double currTime = hsTimer::GetSysSeconds();
hsScalar newTime = fCurrentAnimTime - hsTimer::GetDelSysSeconds();
if (newTime < fBegin)
{
newTime = fBegin;
}
Backwards();
SetCurrentAnimTime(newTime);
}
if (modMsg->Cmd(plAnimCmdMsg::kPlayToTime))
PlayToTime(modMsg->fTime);
if (modMsg->Cmd(plAnimCmdMsg::kPlayToPercentage))
PlayToPercentage(modMsg->fTime);
// Basically, simulate what would happen if we played the animation
if (modMsg->Cmd(plAnimCmdMsg::kFastForward))
{
if (IsForewards())
SetCurrentAnimTime(fEnd, true);
else
SetCurrentAnimTime(fBegin, true);
// but if it should continue to play, statr it.
if (IsLooped())
Start();
}
return true;
}
void plAnimTimeConvert::AddCallback(plEventCallbackMsg* pMsg)
{
hsRefCnt_SafeRef(pMsg);
fCallbackMsgs.Append(pMsg);
}
void plAnimTimeConvert::ClearCallbacks()
{
for (int i = 0; i<fCallbackMsgs.Count(); i++)
{
hsRefCnt_SafeUnRef(fCallbackMsgs[i]);
}
fCallbackMsgs.Reset();
}
void plAnimTimeConvert::EnableCallbacks(hsBool val)
{
SetFlag(kNoCallbacks, !val);
}
/////////////////////////////////////////////////////////////////////////////////////////////////
void plATCState::Read(hsStream *s, hsResMgr *mgr)
{
fStartWorldTime = s->ReadSwapDouble();
fStartAnimTime = s->ReadSwapScalar();
fFlags = (UInt8)(s->ReadSwap32());
fEnd = s->ReadSwapScalar();
fLoopBegin = s->ReadSwapScalar();
fLoopEnd = s->ReadSwapScalar();
fSpeed = s->ReadSwapScalar();
fWrapTime = s->ReadSwapScalar();
if (s->ReadBool())
fEaseCurve = plATCEaseCurve::ConvertNoRef(mgr->ReadCreatable(s));
}
void plATCState::Write(hsStream *s, hsResMgr *mgr)
{
s->WriteSwapDouble(fStartWorldTime);
s->WriteSwapScalar(fStartAnimTime);
s->WriteSwap32(fFlags);
s->WriteSwapScalar(fEnd);
s->WriteSwapScalar(fLoopBegin);
s->WriteSwapScalar(fLoopEnd);
s->WriteSwapScalar(fSpeed);
s->WriteSwapScalar(fWrapTime);
if (fEaseCurve != nil)
{
s->WriteBool(true);
mgr->WriteCreatable(s, fEaseCurve);
}
else
s->WriteBool(false);
}