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/* Starshatter: The Open Source Project
Copyright (c) 2021-2022, Starshatter: The Open Source Project Contributors
Copyright (c) 2011-2012, Starshatter OpenSource Distribution Contributors
Copyright (c) 1997-2006, Destroyer Studios LLC.
AUTHOR: John DiCamillo
OVERVIEW
========
3D Projection Camera class
*/
#ifndef NOMINMAX
#define NOMINMAX
#endif
#include <algorithm>
#include "MemDebug.h"
#include "Projector.h"
// +--------------------------------------------------------------------+
static const float CLIP_PLANE_EPSILON = 0.0001f;
static const double Z_NEAR = 1.0;
void Print(const char* fmt, ...);
// +--------------------------------------------------------------------+
static Camera emergency_cam;
// +--------------------------------------------------------------------+
Projector::Projector(Window* window, Camera* cam)
: camera(cam), infinite(0), depth_scale(1.0f), orthogonal(false), field_of_view(2)
{
if (!camera)
camera = &emergency_cam;
UseWindow(window);
}
Projector::~Projector()
{ }
// +--------------------------------------------------------------------+
void
Projector::UseCamera(Camera* cam)
{
if (cam)
camera = cam;
else
camera = &emergency_cam;
}
void
Projector::UseWindow(Window* win)
{
Rect r = win->GetRect();
width = r.w;
height = r.h;
xcenter = (width / 2.0);
ycenter = (height / 2.0);
xclip0 = 0.0f;
xclip1 = (float) width-0.5f;
yclip0 = 0.0f;
yclip1 = (float) height-0.5f;
SetFieldOfView(field_of_view);
}
void
Projector::SetFieldOfView(double fov)
{
field_of_view = fov;
xscreenscale = width / fov;
yscreenscale = height / fov;
maxscale = std::max(xscreenscale, yscreenscale);
xangle = atan(2.0/fov * maxscale/xscreenscale);
yangle = atan(2.0/fov * maxscale/yscreenscale);
}
double
Projector::GetFieldOfView() const
{
return field_of_view;
}
void
Projector::SetDepthScale(float scale)
{
depth_scale = scale;
}
double
Projector::GetDepthScale() const
{
return depth_scale;
}
int
Projector::SetInfinite(int i)
{
int old = infinite;
infinite = i;
return old;
}
// +--------------------------------------------------------------------+
void
Projector::StartFrame()
{
SetUpFrustum();
SetWorldSpace();
}
// +--------------------------------------------------------------------+
// Transform a point from worldspace to viewspace.
// +--------------------------------------------------------------------+
void
Projector::Transform(Vec3& vec) const
{
Vec3 tvert = vec;
// Translate into a viewpoint-relative coordinate
if (!infinite)
tvert -= camera->Pos();
// old method:
vec.x = (tvert * camera->vrt());
vec.y = (tvert * camera->vup());
vec.z = (tvert * camera->vpn());
// Rotate into the view orientation
// vec = tvert * camera->Orientation();
}
// +--------------------------------------------------------------------+
// Transform a point from worldspace to viewspace.
// +--------------------------------------------------------------------+
void
Projector::Transform(Point& point) const
{
Point tvert = point;
// Translate into a viewpoint-relative coordinate
if (!infinite)
tvert -= camera->Pos();
// old method:
point.x = (tvert * camera->vrt());
point.y = (tvert * camera->vup());
point.z = (tvert * camera->vpn());
// Rotate into the view orientation
// point = tvert * camera->Orientation();
}
// +--------------------------------------------------------------------+
// APPARENT RADIUS OF PROJECTED OBJECT
// Project a viewspace point into screen coordinates.
// Use projected Z to determine apparent radius of object.
// +--------------------------------------------------------------------+
float
Projector::ProjectRadius(const Vec3& v, float radius) const
{
return (float) fabs((radius * maxscale) / v.z);
}
// +--------------------------------------------------------------------+
// IN PLACE PROJECTION OF POINT
// Project a viewspace point into screen coordinates.
// Note that the y axis goes up in worldspace and viewspace, but
// goes down in screenspace.
// +--------------------------------------------------------------------+
void
Projector::Project(Vec3& v, bool clamp) const
{
double zrecip;
if (orthogonal) {
double scale = field_of_view/2;
v.x = (float) (xcenter + scale * v.x);
v.y = (float) (height - (ycenter + scale * v.y));
v.z = (float) (0.0f);
}
else {
//zrecip = 2 * (1.0e5 / (1.0e5-1)) / v.z;
//zrecip = 2 * 0.97 / v.z; -- what the heck was this version used for?
zrecip = 2 / v.z;
v.x = (float) (xcenter + maxscale * v.x * zrecip);
v.y = (float) (height - (ycenter + maxscale * v.y * zrecip));
v.z = (float) (1 - zrecip);
}
// clamp the point to the viewport:
if (clamp) {
if (v.x < xclip0) v.x = xclip0;
if (v.x > xclip1) v.x = xclip1;
if (v.y < yclip0) v.y = yclip0;
if (v.y > yclip1) v.y = yclip1;
}
}
// +--------------------------------------------------------------------+
// IN PLACE PROJECTION OF POINT
// Project a viewspace point into screen coordinates.
// Note that the y axis goes up in worldspace and viewspace, but
// goes down in screenspace.
// +--------------------------------------------------------------------+
void
Projector::Project(Point& v, bool clamp) const
{
double zrecip;
if (orthogonal) {
double scale = field_of_view/2;
v.x = (xcenter + scale * v.x);
v.y = (height - (ycenter + scale * v.y));
v.z = 0;
}
else {
zrecip = 1 / v.z;
v.x = (xcenter + 2 * maxscale * v.x * zrecip);
v.y = (height - (ycenter + 2 * maxscale * v.y * zrecip));
v.z = (1 - zrecip);
}
// clamp the point to the viewport:
if (clamp) {
if (v.x < xclip0) v.x = xclip0;
if (v.x > xclip1) v.x = xclip1;
if (v.y < yclip0) v.y = yclip0;
if (v.y > yclip1) v.y = yclip1;
}
}
// +--------------------------------------------------------------------+
// IN PLACE UN-PROJECTION OF POINT
// Convert a point in screen coordinates back to viewspace.
// Note that the y axis goes up in worldspace and viewspace, but
// goes down in screenspace.
// +--------------------------------------------------------------------+
void
Projector::Unproject(Point& v) const
{
double zrecip = 1 / v.z;
/***
* forward projection:
v.x = (xcenter + maxscale * v.x * zrecip);
v.y = (height - (ycenter + maxscale * v.y * zrecip));
v.z = (1 - zrecip);
***/
v.x = ( v.x - xcenter) / (maxscale * zrecip);
v.y = (height - v.y - ycenter) / (maxscale * zrecip);
}
// +--------------------------------------------------------------------+
// IN PLACE PROJECTION OF RECTANGLE (FOR SPRITES)
// Project a viewspace point into screen coordinates.
// Note that the y axis goes up in worldspace and viewspace, but
// goes down in screenspace.
// +--------------------------------------------------------------------+
void
Projector::ProjectRect(Point& v, double& w, double& h) const
{
double zrecip;
if (orthogonal) {
double scale = field_of_view/2;
v.x = (xcenter + scale * v.x);
v.y = (height - (ycenter + scale * v.y));
v.z = 0;
}
else {
zrecip = 1 / v.z;
v.x = (xcenter + 2 * maxscale * v.x * zrecip);
v.y = (height - (ycenter + 2 * maxscale * v.y * zrecip));
v.z = (1 - Z_NEAR*zrecip);
w *= maxscale * zrecip;
h *= maxscale * zrecip;
}
}
// +--------------------------------------------------------------------+
// Set up a clip plane with the specified normal.
// +--------------------------------------------------------------------+
void
Projector::SetWorldspaceClipPlane(Vec3& normal, Plane& plane)
{
// Rotate the plane normal into worldspace
ViewToWorld(normal, plane.normal);
plane.distance = (float) (camera->Pos() * plane.normal + CLIP_PLANE_EPSILON);
}
// +--------------------------------------------------------------------+
// Set up the planes of the frustum, in worldspace coordinates.
// +--------------------------------------------------------------------+
void
Projector::SetUpFrustum()
{
double angle, s, c;
Vec3 normal;
angle = XAngle();
s = sin(angle);
c = cos(angle);
// Left clip plane
normal.x = (float) s;
normal.y = (float) 0;
normal.z = (float) c;
view_planes[0].normal = normal;
view_planes[0].distance = CLIP_PLANE_EPSILON;
SetWorldspaceClipPlane(normal, world_planes[0]);
// Right clip plane
normal.x = (float) -s;
view_planes[1].normal = normal;
view_planes[1].distance = CLIP_PLANE_EPSILON;
SetWorldspaceClipPlane(normal, world_planes[1]);
angle = YAngle();
s = sin(angle);
c = cos(angle);
// Bottom clip plane
normal.x = (float) 0;
normal.y = (float) s;
normal.z = (float) c;
view_planes[2].normal = normal;
view_planes[2].distance = CLIP_PLANE_EPSILON;
SetWorldspaceClipPlane(normal, world_planes[2]);
// Top clip plane
normal.y = (float) -s;
view_planes[3].normal = normal;
view_planes[3].distance = CLIP_PLANE_EPSILON;
SetWorldspaceClipPlane(normal, world_planes[3]);
}
// +--------------------------------------------------------------------+
// Clip the point against the frustum and return 1 if partially inside
// Return 2 if completely inside
// +--------------------------------------------------------------------+
int
Projector::IsVisible(const Vec3& v, float radius) const
{
int visible = 1;
int complete = 1;
Plane* plane = (Plane*) frustum_planes;
if (infinite) {
complete = 0;
for (int i = 0; visible && (i < NUM_FRUSTUM_PLANES); i++) {
visible = ((v * plane->normal) >= CLIP_PLANE_EPSILON);
plane++;
}
}
else {
for (int i = 0; visible && (i < NUM_FRUSTUM_PLANES); i++) {
float dot = v * plane->normal;
visible = ((dot + radius) >= plane->distance);
complete = complete && ((dot - radius) >= plane->distance);
plane++;
}
}
return visible + complete;
}
// +--------------------------------------------------------------------+
// Clip the bouding point against the frustum and return non zero
// if at least partially inside. This version is not terribly
// efficient as it checks all eight box corners rather than just
// the minimum two.
// +--------------------------------------------------------------------+
int
Projector::IsBoxVisible(const Point* p) const
{
int i, j, outside = 0;
// if all eight corners are outside of the same
// frustrum plane, then the box is not visible
Plane* plane = (Plane*) frustum_planes;
if (infinite) {
for (i = 0; !outside && (i < NUM_FRUSTUM_PLANES); i++) {
for (j = 0; j < 8; j++)
outside += (p[j] * plane->normal) < CLIP_PLANE_EPSILON;
if (outside < 8)
outside = 0;
plane++;
}
}
else {
for (i = 0; !outside && (i < NUM_FRUSTUM_PLANES); i++) {
for (j = 0; j < 8; j++)
outside += (p[j] * plane->normal) < plane->distance;
if (outside < 8)
outside = 0;
plane++;
}
}
// if not outside, then the box is visible
return !outside;
}
// +--------------------------------------------------------------------+
float
Projector::ApparentRadius(const Vec3& v, float radius) const
{
Vec3 vloc = v;
Transform(vloc); // transform in place
return ProjectRadius(vloc, radius);
}
// +--------------------------------------------------------------------+
// Rotate a vector from viewspace to worldspace.
// +--------------------------------------------------------------------+
void
Projector::ViewToWorld(Point& pin, Point& pout)
{
// Rotate into the world orientation
pout.x = pin.x * camera->vrt().x + pin.y * camera->vup().x + pin.z * camera->vpn().x;
pout.y = pin.x * camera->vrt().y + pin.y * camera->vup().y + pin.z * camera->vpn().y;
pout.z = pin.x * camera->vrt().z + pin.y * camera->vup().z + pin.z * camera->vpn().z;
}
void
Projector::ViewToWorld(Vec3& vin, Vec3& vout)
{
// Rotate into the world orientation
vout.x = (float) (vin.x * camera->vrt().x + vin.y * camera->vup().x + vin.z * camera->vpn().x);
vout.y = (float) (vin.x * camera->vrt().y + vin.y * camera->vup().y + vin.z * camera->vpn().y);
vout.z = (float) (vin.x * camera->vrt().z + vin.y * camera->vup().z + vin.z * camera->vpn().z);
}
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