void ObjectViewerView::Update()
{
if (Pi::KeyState(SDLK_EQUALS)) viewingDist *= 0.99;
if (Pi::KeyState(SDLK_MINUS)) viewingDist *= 1.01;
viewingDist = Clamp(viewingDist, 10.0f, 1e12f);
char buf[128];
Body *body = Pi::player->GetNavTarget();
if(body && (body != lastTarget)) {
// Reset view distance for new target.
viewingDist = body->GetBoundingRadius() * 2.0f;
lastTarget = body;
if (body->IsType(Object::PLANET)) {
Planet *planet = static_cast<Planet*>(body);
const SBody *sbody = planet->GetSBody();
m_sbodyVolatileGas->SetText(stringf("%0{f.3}", sbody->m_volatileGas.ToFloat()));
m_sbodyVolatileLiquid->SetText(stringf("%0{f.3}", sbody->m_volatileLiquid.ToFloat()));
m_sbodyVolatileIces->SetText(stringf("%0{f.3}", sbody->m_volatileIces.ToFloat()));
m_sbodyLife->SetText(stringf("%0{f.3}", sbody->m_life.ToFloat()));
m_sbodyVolcanicity->SetText(stringf("%0{f.3}", sbody->m_volcanicity.ToFloat()));
m_sbodyMetallicity->SetText(stringf("%0{f.3}", sbody->m_metallicity.ToFloat()));
m_sbodySeed->SetText(stringf("%0{d}", sbody->seed));
m_sbodyMass->SetText(stringf("%0{f}", sbody->mass.ToFloat()));
m_sbodyRadius->SetText(stringf("%0{f}", sbody->radius.ToFloat()));
}
}
snprintf(buf, sizeof(buf), "View dist: %s Object: %s", format_distance(viewingDist).c_str(), (body ? body->GetLabel().c_str() : "<none>"));
m_infoLabel->SetText(buf);
}
static Frame *MakeFrameFor(SBody *sbody, Body *b, Frame *f)
{
Frame *orbFrame, *rotFrame;
double frameRadius;
if (!sbody->parent) {
if (b) b->SetFrame(f);
f->m_sbody = sbody;
f->m_astroBody = b;
return f;
}
if (sbody->type == SBody::TYPE_GRAVPOINT) {
orbFrame = new Frame(f, sbody->name.c_str());
orbFrame->m_sbody = sbody;
orbFrame->m_astroBody = b;
orbFrame->SetRadius(sbody->GetMaxChildOrbitalDistance()*1.1);
return orbFrame;
}
SBody::BodySuperType supertype = sbody->GetSuperType();
if ((supertype == SBody::SUPERTYPE_GAS_GIANT) ||
(supertype == SBody::SUPERTYPE_ROCKY_PLANET)) {
// for planets we want an non-rotating frame for a few radii
// and a rotating frame in the same position but with maybe 1.05*radius,
// which actually contains the object.
frameRadius = std::max(4.0*sbody->GetRadius(), sbody->GetMaxChildOrbitalDistance()*1.05);
orbFrame = new Frame(f, sbody->name.c_str());
orbFrame->m_sbody = sbody;
orbFrame->SetRadius(frameRadius);
//printf("\t\t\t%s has frame size %.0fkm, body radius %.0fkm\n", sbody->name.c_str(),
// (frameRadius ? frameRadius : 10*sbody->GetRadius())*0.001f,
// sbody->GetRadius()*0.001f);
assert(sbody->rotationPeriod != 0);
rotFrame = new Frame(orbFrame, sbody->name.c_str());
// rotating frame has size of GeoSphere terrain bounding sphere
rotFrame->SetRadius(b->GetBoundingRadius());
rotFrame->SetAngVelocity(vector3d(0,2*M_PI/sbody->GetRotationPeriod(),0));
rotFrame->m_astroBody = b;
SetFrameOrientationFromSBodyAxialTilt(rotFrame, sbody);
b->SetFrame(rotFrame);
return orbFrame;
}
else if (supertype == SBody::SUPERTYPE_STAR) {
// stars want a single small non-rotating frame
orbFrame = new Frame(f, sbody->name.c_str());
orbFrame->m_sbody = sbody;
orbFrame->m_astroBody = b;
orbFrame->SetRadius(sbody->GetMaxChildOrbitalDistance()*1.1);
b->SetFrame(orbFrame);
return orbFrame;
}
else if (sbody->type == SBody::TYPE_STARPORT_ORBITAL) {
// space stations want non-rotating frame to some distance
// and a much closer rotating frame
frameRadius = 1000000.0; // XXX NFI!
orbFrame = new Frame(f, sbody->name.c_str());
orbFrame->m_sbody = sbody;
// orbFrame->SetRadius(10*sbody->GetRadius());
orbFrame->SetRadius(frameRadius);
assert(sbody->rotationPeriod != 0);
rotFrame = new Frame(orbFrame, sbody->name.c_str());
rotFrame->SetRadius(1000.0);
// rotFrame->SetRadius(1.1*sbody->GetRadius()); // enough for collisions?
rotFrame->SetAngVelocity(vector3d(0.0,double(static_cast<SpaceStation*>(b)->GetDesiredAngVel()),0.0));
rotFrame->m_astroBody = b; // hope this doesn't break anything
b->SetFrame(rotFrame);
return orbFrame;
} else if (sbody->type == SBody::TYPE_STARPORT_SURFACE) {
// just put body into rotating frame of planet, not in its own frame
// (because collisions only happen between objects in same frame,
// and we want collisions on starport and on planet itself)
Frame *frame = *f->m_children.begin();
b->SetFrame(frame);
assert(frame->m_astroBody->IsType(Object::PLANET));
Planet *planet = static_cast<Planet*>(frame->m_astroBody);
/* position on planet surface */
double height;
int tries;
matrix4x4d rot;
vector3d pos;
// first try suggested position
rot = sbody->orbit.rotMatrix;
pos = rot * vector3d(0,1,0);
if (planet->GetTerrainHeight(pos) - planet->GetSBody()->GetRadius() <= 0.0) {
MTRand r(sbody->seed);
// position is under water. try some random ones
for (tries=0; tries<100; tries++) {
// used for orientation on planet surface
double r2 = r.Double(); // function parameter evaluation order is implementation-dependent
double r1 = r.Double(); // can't put two rands in the same expression
rot = matrix4x4d::RotateZMatrix(2*M_PI*r1)
* matrix4x4d::RotateYMatrix(2*M_PI*r2);
pos = rot * vector3d(0,1,0);
height = planet->GetTerrainHeight(pos) - planet->GetSBody()->GetRadius();
// don't want to be under water
if (height > 0.0) break;
}
}
b->SetPosition(pos * planet->GetTerrainHeight(pos));
b->SetRotMatrix(rot);
return frame;
} else {
assert(0);
}
return NULL;
}
