CWE-ou-minkata/Sources/Plasma/PubUtilLib/plAvatar/plAvCallbackAction.cpp

/*==LICENSE==*

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

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

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

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

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

*==LICENSE==*/
#include "plAvCallbackAction.h"
#include "plMessage/plLOSHitMsg.h"

#include "plArmatureMod.h" // for LOS enum type
#include "plMatrixChannel.h"
#include "hsTimer.h"
#include "plPhysicalControllerCore.h"

// Generic geom utils.
hsBool LinearVelocity(hsVector3 &outputV, float elapsed, hsMatrix44 &prevMat, hsMatrix44 &curMat);
void AngularVelocity(hsScalar &outputV, float elapsed, hsMatrix44 &prevMat, hsMatrix44 &curMat);
float AngleRad2d (float x1, float y1, float x3, float y3);
inline hsVector3 GetYAxis(hsMatrix44 &mat)
{
    return hsVector3(mat.fMap[1][0], mat.fMap[1][1], mat.fMap[1][2]);
}

plAnimatedController::plAnimatedController(plSceneObject* rootObject, plAGApplicator* rootApp, plPhysicalControllerCore* controller)
    : fRootObject(rootObject)
    , fRootApp(rootApp)
    , fController(controller)
    , fTurnStr(0.f)
    , fAnimAngVel(0.f)
    , fAnimPosVel(0.f, 0.f, 0.f)
{
}   

void plAnimatedController::RecalcVelocity(double timeNow, double timePrev, hsBool useAnim /* = true */)
{
    if (useAnim)
    {
        // while you may think it would be correct to cache this,
        // what we're actually asking is "what would the animation's
        // position be at the previous time given its *current*
        // parameters (particularly blends)"
        hsMatrix44 prevMat = ((plMatrixChannel *)fRootApp->GetChannel())->Value(timePrev, true);        
        hsMatrix44 curMat = ((plMatrixChannel *)fRootApp->GetChannel())->Value(timeNow, true);
        
        // If we get a valid linear velocity (ie, we didn't wrap around in the anim),
        // use it.  Otherwise just reuse the previous frames velocity.
        hsVector3 linearVel;
        if (LinearVelocity(linearVel, (float)(timeNow - timePrev), prevMat, curMat))
            fAnimPosVel = linearVel;

        // Automatically sets fAnimAngVel
        AngularVelocity(fAnimAngVel, (float)(timeNow - timePrev), prevMat, curMat);
    }
    else
    {
        fAnimPosVel.Set(0.f, 0.f, 0.f);
        fAnimAngVel = 0.f;
    }

    if (fController)
        fController->SetVelocities(fAnimPosVel, fAnimAngVel + fTurnStr);
}

///////////////////////////////////////////////////////////////////////////

const hsScalar plWalkingController::kControlledFlightThreshold = 1.f; // seconds

plWalkingController::plWalkingController(plSceneObject* rootObject, plAGApplicator* rootApp, plPhysicalControllerCore* controller)
    : plAnimatedController(rootObject, rootApp, controller)
    , fHitGroundInThisAge(false)
    , fWaitingForGround(false)
    , fControlledFlightTime(0)
    , fControlledFlight(0)
    , fImpactTime(0.f)
    , fImpactVelocity(0.f, 0.f, 0.f)
    , fClearImpact(false)
    , fGroundLastFrame(false)
{
    if (fController)
    {
        fWalkingStrategy= TRACKED_NEW plWalkingStrategy(fController);
        fController->SetMovementSimulationInterface(fWalkingStrategy);
    }
    else
        fWalkingStrategy = nil;
}

void plWalkingController::RecalcVelocity(double timeNow, double timePrev, hsBool useAnim)
{
    if (!fHitGroundInThisAge && fController && fController->IsEnabled() && fWalkingStrategy->IsOnGround())
        fHitGroundInThisAge = true; // if we're not pinned and we're not in an age yet, we are now.

    if (fClearImpact)
    {
        fImpactTime = 0.f;
        fImpactVelocity.Set(0.f, 0.f, 0.f);
    }

    if (fController && !fWalkingStrategy->IsOnGround())
    {
        fImpactTime = fWalkingStrategy->GetAirTime();
        fImpactVelocity = fController->GetLinearVelocity();
        fClearImpact = false;
    }
    else
        fClearImpact = true;
    
    if (IsControlledFlight())
    {
        if (fWalkingStrategy && fWalkingStrategy->IsOnGround())
            fControlledFlightTime = fWalkingStrategy->GetAirTime();
        if(fGroundLastFrame&&(fWalkingStrategy && !fWalkingStrategy->IsOnGround()))
        {
            //we have started to leave the ground tell the movement strategy in case it cares
            fWalkingStrategy->StartJump();
        }
        if (fControlledFlightTime > kControlledFlightThreshold)
            EnableControlledFlight(false);
    }
    if (fWalkingStrategy)
        fGroundLastFrame = fWalkingStrategy->IsOnGround();
    else
        fGroundLastFrame=false;
    plAnimatedController::RecalcVelocity(timeNow, timePrev, useAnim);
}

void plWalkingController::Reset(bool newAge)
{
    
    ActivateController();
    if (newAge)
    {
        if (fWalkingStrategy)
        fWalkingStrategy->ResetAirTime();
        fHitGroundInThisAge = false;
    }
}
 void plWalkingController::ActivateController()
{
    if (fWalkingStrategy)
    {
        fWalkingStrategy->RefreshConnectionToControllerCore();
    }
    else
    {   
        fWalkingStrategy= TRACKED_NEW plWalkingStrategy(fController);
        fWalkingStrategy->RefreshConnectionToControllerCore();

    }
}

bool plWalkingController::EnableControlledFlight(bool status)
{
    if (status)
    {
        if (fControlledFlight == 0)
            fControlledFlightTime = 0.f;

        ++fControlledFlight;
        fWaitingForGround = true;
    }
    else
        fControlledFlight = __max(--fControlledFlight, 0);

    return status;
}
plWalkingController::~plWalkingController()
{
    delete fWalkingStrategy;
    if (fController)
            fController->SetMovementSimulationInterface(nil);
}
#if 0
void plWalkingController::Update()
{
//  double elapsed = time.asDouble() - getRefresh().asDouble();
//  setRefresh(time);
//  
//  hsBool isPhysical = !fPhysical->GetProperty(plSimulationInterface::kPinned);
//  const Havok::Vector3 straightUp(0.0f, 0.0f, 1.0f);
//  hsBool alreadyInAge = fHitGroundInThisAge;
//  
//  int numContacts = fPhysical->GetNumContacts();
//  bool ground = false;
//  fPushingPhysical = nil;
//  int i, j;

/*  for(i = 0; i < numContacts; i++)
    {
        plHKPhysical *contactPhys = fPhysical->GetContactPhysical(i);
        if (!contactPhys)
            continue; // Physical no longer exists. Skip it.

        const Havok::ContactPoint *contact = fPhysical->GetContactPoint(i);
        hsScalar dotUp = straightUp.dot(contact->m_normal);
        if (dotUp > .5)
            ground = true;
        else if (contactPhys->GetProperty(plSimulationInterface::kAvAnimPushable))
        {
            hsPoint3 position;
            hsQuat rotation;
            fPhysical->GetPositionAndRotationSim(&position, &rotation);
        
            hsQuat inverseRotation = rotation.Inverse();
            hsVector3 normal(contact->m_normal.x, contact->m_normal.y, contact->m_normal.z);
            fFacingPushingPhysical = (inverseRotation.Rotate(&kAvatarForward).InnerProduct(normal) < 0 ? true : false);
        
            fPushingPhysical = contactPhys;
        }
    }

    // We need to check for the case where the avatar hasn't collided with "ground", but is colliding
    // with a few other objects so that he's not actually falling (wedged in between some slopes).
    // We do this by answering the following question (in 2d top-down space): "If you sort the contact 
    // normals by angle, is there a large enough gap between normals?"
    // 
    // If you think in terms of geometry, this means a collection of surfaces are all pushing on you.
    // If they're pushing from all sides, you have nowhere to go, and you won't fall. There needs to be
    // a gap, so that you're pushed out and have somewhere to fall. This is the same as finding a gap 
    // larger than 180 degrees between sorted normals.
    // 
    // The problem is that on top of that, the avatar needs enough force to shove him out that gap (he
    // has to overcome friction). I deal with that by making the threshold (360 - (180 - 60) = 240). I've
    // seen up to 220 reached in actual gameplay in a situation where we'd want this to take effect. 
    // This is the same running into 2 walls where the angle between them is 60.
    const hsScalar threshold = hsScalarDegToRad(240);
    if (!ground && numContacts >= 2)
    {
        // Can probably do a special case for exactly 2 contacts. Not sure if it's worth it...

        fCollisionAngles.SetCount(numContacts);
        for (i = 0; i < numContacts; i++)
        {
            const Havok::ContactPoint *contact = fPhysical->GetContactPoint(i);
            fCollisionAngles[i] = hsATan2(contact->m_normal.y, contact->m_normal.x);
        }

        // numContacts is rarely larger than 6, so let's do a simple bubble sort.
        for (i = 0; i < numContacts; i++)
        {
            for (j = i + 1; j < numContacts; j++)
            {
                if (fCollisionAngles[i] > fCollisionAngles[j])
                {
                    hsScalar tempAngle = fCollisionAngles[i];
                    fCollisionAngles[i] = fCollisionAngles[j];
                    fCollisionAngles[j] = tempAngle;
                }
            }
        }
        
        // sorted, now we check.
        for (i = 1; i < numContacts; i++)
        {
            if (fCollisionAngles[i] - fCollisionAngles[i - 1] >= threshold)
                break;
        }
        
        if (i == numContacts)
        {
            // We got to the end. Check the last with the first and make your decision.
            if (!(fCollisionAngles[0] - fCollisionAngles[numContacts - 1] >= (threshold - 2 * hsScalarPI)))
                ground = true;
        }
    }
*/

    bool ground = fController ? fController->GotGroundHit() : true;
    bool isPhysical = true;

    if (!fHitGroundInThisAge && isPhysical)
        fHitGroundInThisAge = true; // if we're not pinned and we're not in an age yet, we are now.
    
    if (IsControlledFlight())
        fControlledFlightTime += (hsScalar)elapsed;
    if (fControlledFlightTime > kControlledFlightThreshold && numContacts > 0)
        EnableControlledFlight(false);
    
    if (ground || !isPhysical)
    {
        if (!IsControlledFlight() && !IsOnGround())
        {
            // The first ground contact in an age doesn't count.
//          if (alreadyInAge)
//          {
//              hsVector3 vel;
//              fPhysical->GetLinearVelocitySim(vel);
//              fImpactVel = vel.fZ;
//              fTimeInAirPeak = (hsScalar)(fTimeInAir + elapsed);
//          }
            
            fWaitingForGround = false;              
        }           
        fTimeInAir = 0;
    }
    else if (elapsed < plSimulationMgr::GetInstance()->GetMaxDelta())
    {
        // If the simultation skipped a huge chunk of time, we didn't process the
        // collisions, which could trick us into thinking we've just gone a long
        // time without hitting ground. So we only count the time if this wasn't
        // the case.
        fTimeInAir += (hsScalar)elapsed;
    }
    
    
    // Tweakage so that we still fall under the right conditions.
    // If we're in controlled flight, or standing still with ground solidly under us (probe hit). We only use anim velocity.
//  if (!IsControlledFlight() && !(ground && fProbeHitGround && fAnimPosVel.fX == 0 && fAnimPosVel.fY == 0)) 
//  {
//      hsVector3 curV;
//      fPhysical->GetLinearVelocitySim(curV);
//      fAnimPosVel.fZ = curV.fZ;
// 
//      // Prevents us from going airborn from running up bumps/inclines.
//      if (IsOnGround() && fAnimPosVel.fZ > 0.f)
//          fAnimPosVel.fZ = 0.f;
//      
//      // Unless we're on the ground and moving, or standing still with a probe hit, we use the sim's other axes too.
//      if (!(IsOnGround() && (fProbeHitGround || fAnimPosVel.fX != 0 || fAnimPosVel.fY != 0)))
//      {
//          fAnimPosVel.fX = curV.fX;
//          fAnimPosVel.fY = curV.fY;
//      }
//  }
// 
//  fPhysical->SetLinearVelocitySim(fAnimPosVel);
//  fPhysical->SetSpin(fAnimAngVel + fTurnStr, hsVector3(0.0f, 0.0f, 1.0f));    
}
#endif


#if 0

/////////////////////////////////////////////////////////////////////////

plSimDefs::ActionType plHorizontalFreezeAction::GetType()
{
    return plSimDefs::kHorizontalFreeze;
}

void plHorizontalFreezeAction::apply(Havok::Subspace &s, Havok::hkTime time)
{
    double elapsed = time.asDouble() - getRefresh().asDouble();
    setRefresh(time);
    
    int numContacts = fPhysical->GetNumContacts();
    bool ground = false;
    const Havok::Vector3 straightUp(0.0f, 0.0f, 1.0f);  
    int i;
    for(i = 0; i < numContacts; i++)
    {
        const Havok::ContactPoint *contact = fPhysical->GetContactPoint(i);
        hsScalar dotUp = straightUp.dot(contact->m_normal);
        if (dotUp > .5)
            ground = true;
    }

    hsVector3 vel;
    fPhysical->GetLinearVelocitySim(vel);
    vel.fX = 0.0;
    vel.fY = 0.0;
    if (ground)
        vel.fZ = 0;
    fPhysical->SetLinearVelocitySim(vel);
    fPhysical->ClearContacts();
}
#endif
plSwimmingController::plSwimmingController(plSceneObject* rootObject, plAGApplicator* rootApp, plPhysicalControllerCore* controller)
:plAnimatedController(rootObject,rootApp,controller)
{
    if (controller)
        fSwimmingStrategy= TRACKED_NEW plSwimStrategy(controller);
    else
        fSwimmingStrategy = nil;
}
plSwimmingController::~plSwimmingController()
{
    delete fSwimmingStrategy;
}

plRidingAnimatedPhysicalController::plRidingAnimatedPhysicalController(plSceneObject* rootObject, plAGApplicator* rootApp, plPhysicalControllerCore* controller)
: plWalkingController(rootObject, rootApp, controller)
{
    if(controller)
        fWalkingStrategy = TRACKED_NEW plRidingAnimatedPhysicalStrategy(controller);
    else
        fWalkingStrategy = nil;
}
plRidingAnimatedPhysicalController::~plRidingAnimatedPhysicalController()
{
    delete fWalkingStrategy;
    fWalkingStrategy=nil;
}


//////////////////////////////////////////////////////////////////////////


/*
Purpose:

ANGLE_RAD_2D returns the angle in radians swept out between two rays in 2D.

Discussion:

Except for the zero angle case, it should be true that

ANGLE_RAD_2D(X1,Y1,X2,Y2,X3,Y3)
+ ANGLE_RAD_2D(X3,Y3,X2,Y2,X1,Y1) = 2 * PI

Modified:

19 April 1999

Author:

John Burkardt

Parameters:

Input, float X1, Y1, X2, Y2, X3, Y3, define the rays
( X1-X2, Y1-Y2 ) and ( X3-X2, Y3-Y2 ) which in turn define the
angle, counterclockwise from ( X1-X2, Y1-Y2 ).

Output, float ANGLE_RAD_2D, the angle swept out by the rays, measured
in radians.  0 <= ANGLE_DEG_2D < 2 PI.  If either ray has zero length,
then ANGLE_RAD_2D is set to 0.
*/

static float AngleRad2d ( float x1, float y1, float x3, float y3 )
{
    float value;
    float x;
    float y;

    x = ( x1 ) * ( x3 ) + ( y1 ) * ( y3 );
    y = ( x1 ) * ( y3 ) - ( y1 ) * ( x3 );

    if ( x == 0.0 && y == 0.0 ) {
        value = 0.0;
    }
    else 
    {
        value = atan2 ( y, x );

        if ( value < 0.0 ) 
        {
            value = (float)(value + TWO_PI);
        }
    }
    return value;
}

static hsBool LinearVelocity(hsVector3 &outputV, float elapsed, hsMatrix44 &prevMat, hsMatrix44 &curMat)
{
    bool result = false;

    hsPoint3 startPos(0.0f, 0.0f, 0.0f);                    // default position (at start of anim)
    hsPoint3 prevPos = prevMat.GetTranslate();              // position previous frame
    hsPoint3 nowPos = curMat.GetTranslate();                // position current frame

    hsVector3 prev2Now = (hsVector3)(nowPos - prevPos);     // frame-to-frame delta

    if (fabs(prev2Now.fX) < 0.0001f && fabs(prev2Now.fY) < 0.0001f && fabs(prev2Now.fZ) < 0.0001f)
    {
        outputV.Set(0.f, 0.f, 0.f);
        result = true;
    } 
    else 
    {
        hsVector3 start2Now = (hsVector3)(nowPos - startPos);   // start-to-frame delta

        float prev2NowMagSqr = prev2Now.MagnitudeSquared();
        float start2NowMagSqr = start2Now.MagnitudeSquared();

        float dot = prev2Now.InnerProduct(start2Now);

        // HANDLING ANIMATION WRAPPING:
        // the vector from the animation origin to the current frame should point in roughly
        // the same direction as the vector from the previous animation position to the
        // current animation position.
        //
        // If they don't agree (dot < 0,) then we probably mpst wrapped around. 
        // The right answer would be to compare the current frame to the start of
        // the anim loop, but it's cheaper to cheat and return false,
        // telling the caller to use the previous frame's velocity.
        if (dot > 0.0f)
        {
            prev2Now /= elapsed;

            float xfabs = fabs(prev2Now.fX);
            float yfabs = fabs(prev2Now.fY);
            float zfabs = fabs(prev2Now.fZ);
            static const float maxVel = 20.0f;
            hsBool valid = xfabs < maxVel && yfabs < maxVel && zfabs < maxVel;

            if (valid)
            {
                outputV = prev2Now;
                result = true;
            }
        } 
    }

    return result;
}

static void AngularVelocity(hsScalar &outputV, float elapsed, hsMatrix44 &prevMat, hsMatrix44 &curMat)
{
    outputV = 0.f;
    hsScalar appliedVelocity = 0.0f;
    hsVector3 prevForward = GetYAxis(prevMat);
    hsVector3 curForward = GetYAxis(curMat);

    hsScalar angleSincePrev = AngleRad2d(curForward.fX, curForward.fY, prevForward.fX, prevForward.fY);
    hsBool sincePrevSign = angleSincePrev > 0.0f;
    if (angleSincePrev > hsScalarPI)
        angleSincePrev = angleSincePrev - TWO_PI;

    const hsVector3 startForward = hsVector3(0, -1.0, 0);   // the Y orientation of a "resting" armature....
    hsScalar angleSinceStart = AngleRad2d(curForward.fX, curForward.fY, startForward.fX, startForward.fY);
    hsBool sinceStartSign = angleSinceStart > 0.0f;
    if (angleSinceStart > hsScalarPI)
        angleSinceStart = angleSinceStart - TWO_PI;

    // HANDLING ANIMATION WRAPPING:
    // under normal conditions, the angle from rest to the current frame will have the same
    // sign as the angle from the previous frame to the current frame.
    // if it does not, we have (most likely) wrapped the motivating animation from frame n back
    // to frame zero, creating a large angle from the previous frame to the current one
    if (sincePrevSign == sinceStartSign)
    {
        // signs are the same; didn't wrap; use the frame-to-frame angle difference
        appliedVelocity = angleSincePrev / elapsed; // rotation / time
        if (fabs(appliedVelocity) < 3)
        {
            outputV = appliedVelocity;
        }
    }
}