Initial commit

engines/hpl1/engine/impl/CollideShapeNewton.cpp

@@ -0,0 +1,296 @@
+/* ScummVM - Graphic Adventure Engine
+ *
+ * ScummVM is the legal property of its developers, whose names
+ * are too numerous to list here. Please refer to the COPYRIGHT
+ * file distributed with this source distribution.
+ *
+ * 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/>.
+ *
+ */
+
+/*
+ * Copyright (C) 2006-2010 - Frictional Games
+ *
+ * This file is part of HPL1 Engine.
+ */
+
+#include "hpl1/engine/impl/CollideShapeNewton.h"
+
+#include "hpl1/engine/physics/PhysicsWorld.h"
+#include "hpl1/engine/system/low_level_system.h"
+
+namespace hpl {
+
+//////////////////////////////////////////////////////////////////////////
+// CONSTRUCTORS
+//////////////////////////////////////////////////////////////////////////
+
+//-----------------------------------------------------------------------
+
+cCollideShapeNewton::cCollideShapeNewton(eCollideShapeType aType, const cVector3f &avSize,
+										 cMatrixf *apOffsetMtx, NewtonWorld *apNewtonWorld,
+										 iPhysicsWorld *apWorld)
+	: iCollideShape(apWorld) {
+	mpNewtonCollision = NULL;
+	mpNewtonWorld = apNewtonWorld;
+	mvSize = avSize;
+	mType = aType;
+
+	mfVolume = 0;
+
+	float *pMtx = NULL;
+	cMatrixf mtxTranspose;
+	if (apOffsetMtx) {
+		m_mtxOffset = *apOffsetMtx;
+		mtxTranspose = m_mtxOffset.GetTranspose();
+
+		pMtx = &(mtxTranspose.m[0][0]);
+	} else {
+		m_mtxOffset = cMatrixf::Identity;
+	}
+
+	////////////////////////////////////////////
+	// Create Newton collision
+
+	switch (aType) {
+	case eCollideShapeType_Null:
+		mpNewtonCollision = NewtonCreateNull(apNewtonWorld);
+		break;
+
+	case eCollideShapeType_Box:
+		mpNewtonCollision = NewtonCreateBox(apNewtonWorld,
+											mvSize.x, mvSize.y, mvSize.z,
+											0, pMtx);
+		break;
+
+	case eCollideShapeType_Sphere:
+		mpNewtonCollision = NewtonCreateSphere(apNewtonWorld,
+											   mvSize.x, mvSize.y, mvSize.z,
+											   0, pMtx);
+		break;
+
+	case eCollideShapeType_Cylinder:
+		mpNewtonCollision = NewtonCreateCylinder(apNewtonWorld,
+												 mvSize.x, mvSize.y,
+												 0, pMtx);
+		break;
+
+	case eCollideShapeType_Capsule:
+		mpNewtonCollision = NewtonCreateCapsule(apNewtonWorld,
+												mvSize.x, mvSize.y,
+												0, pMtx);
+		break;
+	default:
+		break;
+	}
+
+	////////////////////////////////////////////
+	// Calculate Bounding volume and volume.
+	if (mType == eCollideShapeType_Box) {
+		mBoundingVolume.SetSize(mvSize);
+
+		mfVolume = mvSize.x * mvSize.y * mvSize.z;
+	} else if (mType == eCollideShapeType_Sphere) {
+		mBoundingVolume.SetSize(mvSize * 2);
+
+		mfVolume = (4.0f / 3.0f) * kPif * (mvSize.x * mvSize.x * mvSize.x);
+	} else if (mType == eCollideShapeType_Cylinder ||
+			   mType == eCollideShapeType_Capsule) {
+		mBoundingVolume.SetSize(cVector3f(mvSize.y, mvSize.x * 2, mvSize.x * 2));
+
+		// Not gonna be correct for capsule...
+		if (mType == eCollideShapeType_Cylinder)
+			mfVolume = kPif * (mvSize.x * mvSize.x) * mvSize.y;
+		else {
+			// Height of the cylinder part.
+			float fCylHeight = mvSize.y - (mvSize.x * 2);
+			mfVolume = 0;
+
+			// The volume of the cylinder part.
+			if (fCylHeight > 0)
+				mfVolume += kPif * (mvSize.x * mvSize.x) * fCylHeight;
+
+			// The volume of the sphere part.
+			mfVolume += (4.0f / 3.0f) * kPif * (mvSize.x * mvSize.x * mvSize.x);
+		}
+	}
+
+	mBoundingVolume.SetTransform(m_mtxOffset);
+}
+
+//-----------------------------------------------------------------------
+
+cCollideShapeNewton::~cCollideShapeNewton() {
+	// Release Newton Collision
+	if (mpNewtonCollision)
+		NewtonReleaseCollision(mpNewtonWorld, mpNewtonCollision);
+	// Release all subshapes (for compound objects)
+	for (int i = 0; i < (int)mvSubShapes.size(); i++) {
+		mpWorld->DestroyShape(mvSubShapes[i]);
+	}
+}
+
+//-----------------------------------------------------------------------
+
+//////////////////////////////////////////////////////////////////////////
+// PUBLIC METHODS
+//////////////////////////////////////////////////////////////////////////
+
+//-----------------------------------------------------------------------
+
+iCollideShape *cCollideShapeNewton::GetSubShape(int alIdx) {
+	if (mType == eCollideShapeType_Compound)
+		return mvSubShapes[alIdx];
+	else
+		return this;
+}
+
+int cCollideShapeNewton::GetSubShapeNum() {
+	if (mType == eCollideShapeType_Compound)
+		return (int)mvSubShapes.size();
+	else
+		return 1;
+}
+
+//-----------------------------------------------------------------------
+
+cVector3f cCollideShapeNewton::GetInertia(float afMass) {
+	cVector3f vInertia(1, 1, 1);
+
+	// Box
+	if (mType == eCollideShapeType_Box) {
+		float fInv = 1.0f / 12.0f;
+		vInertia = cVector3f(
+			afMass * (mvSize.y * mvSize.y + mvSize.z * mvSize.z) * fInv,
+			afMass * (mvSize.x * mvSize.x + mvSize.z * mvSize.z) * fInv,
+			afMass * (mvSize.x * mvSize.x + mvSize.y * mvSize.y) * fInv);
+	}
+	// Sphere
+	else if (mType == eCollideShapeType_Sphere) {
+		float fI = 0.4f * afMass * mvSize.x * mvSize.x;
+		vInertia = cVector3f(fI, fI, fI);
+	}
+	// Cylinder
+	else if (mType == eCollideShapeType_Cylinder) {
+		float fRadius = mvSize.x;
+		vInertia.x = afMass * (fRadius * fRadius) * (1.0f / 4.0f) + afMass * (mvSize.y * mvSize.y) * (1.0f / 12.0f);
+		vInertia.y = vInertia.x;
+		vInertia.z = afMass * (fRadius * fRadius) * (1.0f / 2.0f);
+	}
+	// Capsule
+	else if (mType == eCollideShapeType_Capsule) {
+		float fRadius = mvSize.x;
+		vInertia.x = afMass * (fRadius * fRadius) * (1.0f / 4.0f) + afMass * (mvSize.y * mvSize.y) * (1.0f / 12.0f);
+		vInertia.y = vInertia.x;
+		vInertia.z = afMass * (fRadius * fRadius) * (1.0f / 2.0f);
+	}
+	// Compound
+	// This is only a very bad approximation.
+	else if (mType == eCollideShapeType_Compound) {
+		cVector3f vBoxSize = mBoundingVolume.GetSize();
+		float fBoxVolume = vBoxSize.x * vBoxSize.y * vBoxSize.z;
+
+		float fInv = 1.0f / 12.0f;
+		vInertia = cVector3f(
+			afMass * (vBoxSize.y * vBoxSize.y + vBoxSize.z * vBoxSize.z) * fInv,
+			afMass * (vBoxSize.x * vBoxSize.x + vBoxSize.z * vBoxSize.z) * fInv,
+			afMass * (vBoxSize.x * vBoxSize.x + vBoxSize.y * vBoxSize.y) * fInv);
+		// Scale of a bit of the inertia since the compound is not a 100% solid box
+		vInertia = vInertia * (1.0f - ((fBoxVolume / mfVolume) * 0.3f));
+	}
+
+	return vInertia;
+}
+
+//-----------------------------------------------------------------------
+
+void cCollideShapeNewton::CreateFromShapeVec(tCollideShapeVec &avShapes) {
+	Common::Array<NewtonCollision *> vNewtonColliders;
+
+	vNewtonColliders.reserve(avShapes.size());
+	mvSubShapes.reserve(avShapes.size());
+
+	mfVolume = 0;
+
+	for (size_t i = 0; i < avShapes.size(); i++) {
+		mvSubShapes.push_back(avShapes[i]);
+
+		cCollideShapeNewton *pNewtonShape = static_cast<cCollideShapeNewton *>(avShapes[i]);
+		vNewtonColliders.push_back(pNewtonShape->GetNewtonCollision());
+
+		mfVolume += pNewtonShape->GetVolume();
+	}
+
+	mpNewtonCollision = NewtonCreateCompoundCollision(mpNewtonWorld, (int)vNewtonColliders.size(),
+													  &vNewtonColliders[0], 0);
+
+	// Create bounding volume
+	cVector3f vFinalMax = avShapes[0]->GetBoundingVolume().GetMax();
+	cVector3f vFinalMin = avShapes[0]->GetBoundingVolume().GetMin();
+
+	for (size_t i = 1; i < avShapes.size(); i++) {
+		cVector3f vMax = avShapes[i]->GetBoundingVolume().GetMax();
+		cVector3f vMin = avShapes[i]->GetBoundingVolume().GetMin();
+
+		if (vFinalMax.x < vMax.x)
+			vFinalMax.x = vMax.x;
+		if (vFinalMin.x > vMin.x)
+			vFinalMin.x = vMin.x;
+
+		if (vFinalMax.y < vMax.y)
+			vFinalMax.y = vMax.y;
+		if (vFinalMin.y > vMin.y)
+			vFinalMin.y = vMin.y;
+
+		if (vFinalMax.z < vMax.z)
+			vFinalMax.z = vMax.z;
+		if (vFinalMin.z > vMin.z)
+			vFinalMin.z = vMin.z;
+	}
+
+	mBoundingVolume.SetLocalMinMax(vFinalMin, vFinalMax);
+}
+
+//-----------------------------------------------------------------------
+
+void cCollideShapeNewton::CreateFromVertices(const unsigned int *apIndexArray, int alIndexNum,
+											 const float *apVertexArray, int alVtxStride, int alVtxNum) {
+	float vTriVec[9];
+
+	mpNewtonCollision = NewtonCreateTreeCollision(mpNewtonWorld, 0);
+	// Log("-- Creating mesh collision.:\n");
+	NewtonTreeCollisionBeginBuild(mpNewtonCollision);
+	for (int tri = 0; tri < alIndexNum; tri += 3) {
+		// Log("tri: %d:\n", tri/3);
+		for (int idx = 0; idx < 3; idx++) {
+			int lVtx = apIndexArray[tri + 2 - idx] * alVtxStride;
+
+			vTriVec[idx * 3 + 0] = apVertexArray[lVtx + 0];
+			vTriVec[idx * 3 + 1] = apVertexArray[lVtx + 1];
+			vTriVec[idx * 3 + 2] = apVertexArray[lVtx + 2];
+		}
+
+		NewtonTreeCollisionAddFace(mpNewtonCollision, 3, vTriVec, sizeof(float) * 3, 1);
+	}
+
+	NewtonTreeCollisionEndBuild(mpNewtonCollision, false);
+
+	// Set bounding box size
+	mBoundingVolume.AddArrayPoints(apVertexArray, alVtxNum);
+	mBoundingVolume.CreateFromPoints(alVtxStride);
+}
+
+//-----------------------------------------------------------------------
+
+} // namespace hpl