solvespace/src/draw.cpp

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//-----------------------------------------------------------------------------
// The root function to paint our graphics window, after setting up all the
// views and such appropriately. Also contains all the stuff to manage the
// selection.
//
// Copyright 2008-2013 Jonathan Westhues.
//-----------------------------------------------------------------------------
#include "solvespace.h"
bool GraphicsWindow::Selection::Equals(Selection *b) {
if(entity.v != b->entity.v) return false;
if(constraint.v != b->constraint.v) return false;
return true;
}
bool GraphicsWindow::Selection::IsEmpty() {
if(entity.v) return false;
if(constraint.v) return false;
return true;
}
bool GraphicsWindow::Selection::HasEndpoints() {
if(!entity.v) return false;
Entity *e = SK.GetEntity(entity);
return e->HasEndpoints();
}
void GraphicsWindow::Selection::Clear() {
entity.v = constraint.v = 0;
emphasized = false;
}
void GraphicsWindow::Selection::Draw() {
Vector refp[2];
refp[0] = refp[1] = Vector::From(0, 0, 0);
if(entity.v) {
Entity *e = SK.GetEntity(entity);
Allow rendering hidden solid edges using a distinct style. Before this change, the two buttons "Show/hide shaded model" (S) and "Show/hide hidden lines" (H) resulted in drawing the following elements in the following styles: Button | Non-occluded | Non-occluded | Occluded | Occluded state | solid edges | entities | solid edges | entities --------+--------------+--------------+-------------+-------------- !S !H | | | solid-edge | entity style --------+ | +-------------+-------------- S !H | | | invisible --------+ solid-edge | entity style +-------------+-------------- !S H | | | | --------+ | | solid-edge | entity style S H | | | | --------+--------------+--------------+-------------+-------------- After this change, they are drawn as follows: Button | Non-occluded | Non-occluded | Occluded | Occluded state | solid edges | entities | solid edges | entities --------+--------------+--------------+-------------+-------------- !S !H | | | solid-edge | entity style --------+ | +-------------+-------------- S !H | | | invisible --------+ solid-edge | entity style +-------------+-------------- !S H | | | | --------+ | | hidden-edge | stippled¹ S H | | | | --------+--------------+--------------+-------------+-------------- ¹ entity style, but the stipple parameters taken from hidden-edge In SolveSpace's true WYSIWYG tradition, the 2d view export follows the rendered view exactly. Also, it is now possible to edit the stipple parameters of built-in styles, so that by changing the hidden-edge style to non-stippled it is possible to regain the old behavior.
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e->Draw(/*drawAsHidden=*/false);
if(emphasized) {
refp[0] = refp[1] = e->GetReferencePos();
}
}
if(constraint.v) {
Constraint *c = SK.GetConstraint(constraint);
c->Draw();
if(emphasized) c->GetReferencePos(refp);
}
if(emphasized && (constraint.v || entity.v)) {
// We want to emphasize this constraint or entity, by drawing a thick
// line from the top left corner of the screen to the reference point(s)
// of that entity or constraint.
double s = 0.501/SS.GW.scale;
Vector topLeft = SS.GW.projRight.ScaledBy(-SS.GW.width*s);
topLeft = topLeft.Plus(SS.GW.projUp.ScaledBy(SS.GW.height*s));
topLeft = topLeft.Minus(SS.GW.offset);
ssglLineWidth(40);
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RgbaColor rgb = Style::Color(Style::HOVERED);
Replaced RGB-color integers with dedicated data structure RGB colors were represented using a uint32_t with the red, green and blue values stuffed into the lower three octets (i.e. 0x00BBGGRR), like Microsoft's COLORREF. This approach did not lend itself to type safety, however, so this change replaces it with an RgbColor class that provides the same infomation plus a handful of useful methods to work with it. (Note that sizeof(RgbColor) == sizeof(uint32_t), so this change should not lead to memory bloat.) Some of the new methods/fields replace what were previously macro calls; e.g. RED(c) is now c.red, REDf(c) is now c.redF(). The .Equals() method is now used instead of == to compare colors. RGB colors still need to be represented as packed integers in file I/O and preferences, so the methods .FromPackedInt() and .ToPackedInt() are provided. Also implemented are Cnf{Freeze,Thaw}Color(), type-safe wrappers around Cnf{Freeze,Thaw}Int() that facilitate I/O with preferences. (Cnf{Freeze,Thaw}Color() are defined outside of the system-dependent code to minimize the footprint of the latter; because the same can be done with Cnf{Freeze,Thaw}Bool(), those are also moved out of the system code with this commit.) Color integers were being OR'ed with 0x80000000 in some places for two distinct purposes: One, to indicate use of a default color in glxFillMesh(); this has been replaced by use of the .UseDefault() method. Two, to indicate to TextWindow::Printf() that the format argument of a "%Bp"/"%Fp" specifier is an RGB color rather than a color "code" from TextWindow::bgColors[] or TextWindow::fgColors[] (as the specifier can accept either); instead, we define a new flag "z" (as in "%Bz" or "%Fz") to indicate an RGBcolor pointer, leaving "%Bp"/"%Fp" to indicate a color code exclusively. (This also allows TextWindow::meta[][].bg to be a char instead of an int, partly compensating for the new .bgRgb field added immediately after.) In array declarations, RGB colors could previously be specified as 0 (often in a terminating element). As that no longer works, we define NULL_COLOR, which serves much the same purpose for RgbColor variables as NULL serves for pointers.
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glColor4d(rgb.redF(), rgb.greenF(), rgb.blueF(), 0.2);
for(int i = 0; i < (refp[0].Equals(refp[1]) ? 1 : 2); i++) {
glBegin(GL_LINES);
ssglVertex3v(topLeft);
ssglVertex3v(refp[i]);
glEnd();
}
ssglLineWidth(1);
}
}
void GraphicsWindow::ClearSelection() {
selection.Clear();
SS.ScheduleShowTW();
InvalidateGraphics();
}
void GraphicsWindow::ClearNonexistentSelectionItems() {
bool change = false;
Selection *s;
selection.ClearTags();
for(s = selection.First(); s; s = selection.NextAfter(s)) {
if(s->constraint.v && !(SK.constraint.FindByIdNoOops(s->constraint))) {
s->tag = 1;
change = true;
}
if(s->entity.v && !(SK.entity.FindByIdNoOops(s->entity))) {
s->tag = 1;
change = true;
}
}
selection.RemoveTagged();
if(change) InvalidateGraphics();
}
//-----------------------------------------------------------------------------
// Is this entity/constraint selected?
//-----------------------------------------------------------------------------
bool GraphicsWindow::IsSelected(hEntity he) {
Selection s = {};
s.entity = he;
return IsSelected(&s);
}
bool GraphicsWindow::IsSelected(Selection *st) {
Selection *s;
for(s = selection.First(); s; s = selection.NextAfter(s)) {
if(s->Equals(st)) {
return true;
}
}
return false;
}
//-----------------------------------------------------------------------------
// Unselect an item, if it is selected. We can either unselect just that item,
// or also unselect any coincident points. The latter is useful if the user
// somehow selects two coincident points (like with select all), because it
// would otherwise be impossible to de-select the lower of the two.
//-----------------------------------------------------------------------------
void GraphicsWindow::MakeUnselected(hEntity he, bool coincidentPointTrick) {
Selection stog = {};
stog.entity = he;
MakeUnselected(&stog, coincidentPointTrick);
}
void GraphicsWindow::MakeUnselected(Selection *stog, bool coincidentPointTrick){
if(stog->IsEmpty()) return;
Selection *s;
// If an item was selected, then we just un-select it.
selection.ClearTags();
for(s = selection.First(); s; s = selection.NextAfter(s)) {
if(s->Equals(stog)) {
s->tag = 1;
}
}
// If two points are coincident, then it's impossible to hover one of
// them. But make sure to deselect both, to avoid mysterious seeming
// inability to deselect if the bottom one did somehow get selected.
if(stog->entity.v && coincidentPointTrick) {
Entity *e = SK.GetEntity(stog->entity);
if(e->IsPoint()) {
Vector ep = e->PointGetNum();
for(s = selection.First(); s; s = selection.NextAfter(s)) {
if(!s->entity.v) continue;
if(s->entity.v == stog->entity.v) continue;
Entity *se = SK.GetEntity(s->entity);
if(!se->IsPoint()) continue;
if(ep.Equals(se->PointGetNum())) {
s->tag = 1;
}
}
}
}
selection.RemoveTagged();
}
//-----------------------------------------------------------------------------
// Select an item, if it isn't selected already.
//-----------------------------------------------------------------------------
void GraphicsWindow::MakeSelected(hEntity he) {
Selection stog = {};
stog.entity = he;
MakeSelected(&stog);
}
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void GraphicsWindow::MakeSelected(hConstraint hc) {
Selection stog = {};
stog.constraint = hc;
MakeSelected(&stog);
}
void GraphicsWindow::MakeSelected(Selection *stog) {
if(stog->IsEmpty()) return;
if(IsSelected(stog)) return;
if(stog->entity.v != 0 && SK.GetEntity(stog->entity)->IsFace()) {
// In the interest of speed for the triangle drawing code,
// only two faces may be selected at a time.
int c = 0;
Selection *s;
selection.ClearTags();
for(s = selection.First(); s; s = selection.NextAfter(s)) {
hEntity he = s->entity;
if(he.v != 0 && SK.GetEntity(he)->IsFace()) {
c++;
if(c >= 2) s->tag = 1;
}
}
selection.RemoveTagged();
}
selection.Add(stog);
}
//-----------------------------------------------------------------------------
// Select everything that lies within the marquee view-aligned rectangle.
//-----------------------------------------------------------------------------
void GraphicsWindow::SelectByMarquee() {
Point2d marqueePoint = ProjectPoint(orig.marqueePoint);
BBox marqueeBBox = BBox::From(Vector::From(marqueePoint.x, marqueePoint.y, -1),
Vector::From(orig.mouse.x, orig.mouse.y, 1));
Entity *e;
for(e = SK.entity.First(); e; e = SK.entity.NextAfter(e)) {
if(e->group.v != SS.GW.activeGroup.v) continue;
if(e->IsFace() || e->IsDistance()) continue;
if(!e->IsVisible()) continue;
bool entityHasBBox;
BBox entityBBox = e->GetOrGenerateScreenBBox(&entityHasBBox);
if(entityHasBBox && entityBBox.Overlaps(marqueeBBox)) {
MakeSelected(e->h);
}
}
}
//-----------------------------------------------------------------------------
// Sort the selection according to various critieria: the entities and
// constraints separately, counts of certain types of entities (circles,
// lines, etc.), and so on.
//-----------------------------------------------------------------------------
void GraphicsWindow::GroupSelection() {
gs = {};
int i;
for(i = 0; i < selection.n && i < MAX_SELECTED; i++) {
Selection *s = &(selection.elem[i]);
if(s->entity.v) {
(gs.n)++;
Entity *e = SK.entity.FindById(s->entity);
if(e->IsStylable()) gs.stylables++;
// A list of points, and a list of all entities that aren't points.
if(e->IsPoint()) {
gs.point[(gs.points)++] = s->entity;
} else {
gs.entity[(gs.entities)++] = s->entity;
}
// And an auxiliary list of normals, including normals from
// workplanes.
if(e->IsNormal()) {
gs.anyNormal[(gs.anyNormals)++] = s->entity;
} else if(e->IsWorkplane()) {
gs.anyNormal[(gs.anyNormals)++] = e->Normal()->h;
}
// And of vectors (i.e., stuff with a direction to constrain)
if(e->HasVector()) {
gs.vector[(gs.vectors)++] = s->entity;
}
// Faces (which are special, associated/drawn with triangles)
if(e->IsFace()) {
gs.face[(gs.faces)++] = s->entity;
}
if(e->HasEndpoints()) {
(gs.withEndpoints)++;
}
// And some aux counts too
switch(e->type) {
Convert all enumerations to use `enum class`. Specifically, take the old code that looks like this: class Foo { enum { X = 1, Y = 2 }; int kind; } ... foo.kind = Foo::X; ... and convert it to this: class Foo { enum class Kind : uint32_t { X = 1, Y = 2 }; Kind kind; } ... foo.kind = Foo::Kind::X; (In some cases the enumeration would not be in the class namespace, such as when it is generally useful.) The benefits are as follows: * The type of the field gives a clear indication of intent, both to humans and tools (such as binding generators). * The compiler is able to automatically warn when a switch is not exhaustive; but this is currently suppressed by the default: ssassert(false, ...) idiom. * Integers and plain enums are weakly type checked: they implicitly convert into each other. This can hide bugs where type conversion is performed but not intended. Enum classes are strongly type checked. * Plain enums pollute parent namespaces; enum classes do not. Almost every defined enum we have already has a kind of ad-hoc namespacing via `NAMESPACE_`, which is now explicit. * Plain enums do not have a well-defined ABI size, which is important for bindings. Enum classes can have it, if specified. We specify the base type for all enums as uint32_t, which is a safe choice and allows us to not change the numeric values of any variants. This commit introduces absolutely no functional change to the code, just renaming and change of types. It handles almost all cases, except GraphicsWindow::pending.operation, which needs minor functional change.
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case Entity::Type::WORKPLANE: (gs.workplanes)++; break;
case Entity::Type::LINE_SEGMENT: (gs.lineSegments)++; break;
case Entity::Type::CUBIC: (gs.cubics)++; break;
case Entity::Type::CUBIC_PERIODIC: (gs.periodicCubics)++; break;
Convert all enumerations to use `enum class`. Specifically, take the old code that looks like this: class Foo { enum { X = 1, Y = 2 }; int kind; } ... foo.kind = Foo::X; ... and convert it to this: class Foo { enum class Kind : uint32_t { X = 1, Y = 2 }; Kind kind; } ... foo.kind = Foo::Kind::X; (In some cases the enumeration would not be in the class namespace, such as when it is generally useful.) The benefits are as follows: * The type of the field gives a clear indication of intent, both to humans and tools (such as binding generators). * The compiler is able to automatically warn when a switch is not exhaustive; but this is currently suppressed by the default: ssassert(false, ...) idiom. * Integers and plain enums are weakly type checked: they implicitly convert into each other. This can hide bugs where type conversion is performed but not intended. Enum classes are strongly type checked. * Plain enums pollute parent namespaces; enum classes do not. Almost every defined enum we have already has a kind of ad-hoc namespacing via `NAMESPACE_`, which is now explicit. * Plain enums do not have a well-defined ABI size, which is important for bindings. Enum classes can have it, if specified. We specify the base type for all enums as uint32_t, which is a safe choice and allows us to not change the numeric values of any variants. This commit introduces absolutely no functional change to the code, just renaming and change of types. It handles almost all cases, except GraphicsWindow::pending.operation, which needs minor functional change.
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case Entity::Type::ARC_OF_CIRCLE:
(gs.circlesOrArcs)++;
(gs.arcs)++;
break;
Enable exhaustive switch coverage warnings as an error, and use them. Specifically, this enables -Wswitch=error on GCC/Clang and its MSVC equivalent; the exact way it is handled varies slightly, but what they all have in common is that in a switch statement over an enumeration, any enumerand that is not explicitly (via case:) or implicitly (via default:) handled in the switch triggers an error. Moreover, we also change the switch statements in three ways: * Switch statements that ought to be extended every time a new enumerand is added (e.g. Entity::DrawOrGetDistance(), are changed to explicitly list every single enumerand, and not have a default: branch. Note that the assertions are kept because it is legal for a enumeration to have a value unlike any of its defined enumerands, and we can e.g. read garbage from a file, or an uninitialized variable. This requires some rearranging if a default: branch is undesired. * Switch statements that ought to only ever see a few select enumerands, are changed to always assert in the default: branch. * Switch statements that do something meaningful for a few enumerands, and ignore everything else, are changed to do nothing in a default: branch, under the assumption that changing them every time an enumerand is added or removed would just result in noise and catch no bugs. This commit also removes the {Request,Entity,Constraint}::UNKNOWN and Entity::DATUM_POINT enumerands, as those were just fancy names for zeroes. They mess up switch exhaustiveness checks and most of the time were not the best way to implement what they did anyway.
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case Entity::Type::CIRCLE: (gs.circlesOrArcs)++; break;
default: break;
}
}
if(s->constraint.v) {
gs.constraint[(gs.constraints)++] = s->constraint;
Constraint *c = SK.GetConstraint(s->constraint);
if(c->IsStylable()) gs.stylables++;
if(c->HasLabel()) gs.constraintLabels++;
}
}
}
void GraphicsWindow::HitTestMakeSelection(Point2d mp) {
int i;
double d, dmin = 1e12;
Selection s = {};
// Did the view projection change? If so, invalidate bounding boxes.
if(!offset.EqualsExactly(cached.offset) ||
!projRight.EqualsExactly(cached.projRight) ||
!projUp.EqualsExactly(cached.projUp) ||
EXACT(scale != cached.scale)) {
cached.offset = offset;
cached.projRight = projRight;
cached.projUp = projUp;
cached.scale = scale;
for(Entity *e = SK.entity.First(); e; e = SK.entity.NextAfter(e)) {
e->screenBBoxValid = false;
}
}
// Always do the entities; we might be dragging something that should
// be auto-constrained, and we need the hover for that.
for(i = 0; i < SK.entity.n; i++) {
Entity *e = &(SK.entity.elem[i]);
// Don't hover whatever's being dragged.
if(e->h.request().v == pending.point.request().v) {
// The one exception is when we're creating a new cubic; we
// want to be able to hover the first point, because that's
// how we turn it into a periodic spline.
if(!e->IsPoint()) continue;
if(!e->h.isFromRequest()) continue;
Request *r = SK.GetRequest(e->h.request());
Convert all enumerations to use `enum class`. Specifically, take the old code that looks like this: class Foo { enum { X = 1, Y = 2 }; int kind; } ... foo.kind = Foo::X; ... and convert it to this: class Foo { enum class Kind : uint32_t { X = 1, Y = 2 }; Kind kind; } ... foo.kind = Foo::Kind::X; (In some cases the enumeration would not be in the class namespace, such as when it is generally useful.) The benefits are as follows: * The type of the field gives a clear indication of intent, both to humans and tools (such as binding generators). * The compiler is able to automatically warn when a switch is not exhaustive; but this is currently suppressed by the default: ssassert(false, ...) idiom. * Integers and plain enums are weakly type checked: they implicitly convert into each other. This can hide bugs where type conversion is performed but not intended. Enum classes are strongly type checked. * Plain enums pollute parent namespaces; enum classes do not. Almost every defined enum we have already has a kind of ad-hoc namespacing via `NAMESPACE_`, which is now explicit. * Plain enums do not have a well-defined ABI size, which is important for bindings. Enum classes can have it, if specified. We specify the base type for all enums as uint32_t, which is a safe choice and allows us to not change the numeric values of any variants. This commit introduces absolutely no functional change to the code, just renaming and change of types. It handles almost all cases, except GraphicsWindow::pending.operation, which needs minor functional change.
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if(r->type != Request::Type::CUBIC) continue;
if(r->extraPoints < 2) continue;
if(e->h.v != r->h.entity(1).v) continue;
}
d = e->GetDistance(mp);
if(d < SELECTION_RADIUS && d < dmin) {
s = {};
s.entity = e->h;
dmin = d;
}
}
// The constraints and faces happen only when nothing's in progress.
if(pending.operation == Pending::NONE) {
// Constraints
for(i = 0; i < SK.constraint.n; i++) {
d = SK.constraint.elem[i].GetDistance(mp);
if(d < SELECTION_RADIUS && d < dmin) {
s = {};
s.constraint = SK.constraint.elem[i].h;
dmin = d;
}
}
// Faces, from the triangle mesh; these are lowest priority
if(s.constraint.v == 0 && s.entity.v == 0 && showShaded && showFaces) {
Group *g = SK.GetGroup(activeGroup);
SMesh *m = &(g->displayMesh);
uint32_t v = m->FirstIntersectionWith(mp);
if(v) {
s.entity.v = v;
}
}
}
if(!s.Equals(&hover)) {
hover = s;
Don't perform hit testing if we haven't painted the graphics window. This change is quite subtle. The goal is to improve responsiveness of highlighting even further. To understand this change you need to keep in mind that Windows and Gtk have dramatically different behavior for paint (WM_PAINT in Windows, expose in Gtk) and mouse move events. In Windows, WM_PAINT and WM_MOUSEMOVE, unless sent explicitly, are synthesized: WM_MOUSEMOVE is delivered when there are no other messages and the current cursor position doesn't match the remembered one, and WM_PAINT is delivered when there are no other messages, even WM_MOUSEMOVE. This is pretty clever because it doesn't swamp programs that are slow to process either of those events with even more of them, ensuring they remain responsive. In Gtk, expose events are delivered at the end of the frame whenever there is an invalid view, and every single mouse move that happened will result in a separate event. If mouse move events are handled quickly, then the behavior is identical in either case: * process mouse move event * perform hit testing * invalidate view * no more events to process! * there are invalid views * repaint If, however, mouse move events are handled slower, then the behavior diverges. With Gtk: * process mouse move event * perform hit testing (slow) * while this happens, ten more mouse move events are added * invalidate view * end of frame! * there are invalid views * repaint * process mouse move event... As a result, the Gtk-hosted UI hopelessly lags behind user input. This is very irritating. With Windows: * process mouse move event * perform hit testing (slow) * while this happens, mouse was moved * invalidate view * process mouse move event... As a result, the Windows-hosted UI never repaints while the mouse is moved. This is also very irritating. Commit HEAD^ has fixed the problems with Gtk-based UI by making hit testing so fast that mouse move events never quite overflow the queue. There's still a barely noticeable lag but it's better. However, the problems with Windows remained because while the queue doesn't *overflow* with the faster hit testing code, it doesn't go *empty* either! Thus we still don't repaint. This commit builds on top of HEAD^ and makes it so that we don't actually hit test anything if we haven't painted the result of the previous hit test already. This fixes the problem on Windows but also helps Gtk a little bit. Curiously, the Cocoa-based UI never suffered from any of these problems. To my understanding (it's somewhat underdocumented), it processes mouse moves like Windows, but paints like Gtk.
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PaintGraphics();
}
}
//-----------------------------------------------------------------------------
// Project a point in model space to screen space, exactly as gl would; return
// units are pixels.
//-----------------------------------------------------------------------------
Point2d GraphicsWindow::ProjectPoint(Vector p) {
Vector p3 = ProjectPoint3(p);
Point2d p2 = { p3.x, p3.y };
return p2;
}
//-----------------------------------------------------------------------------
// Project a point in model space to screen space, exactly as gl would; return
// units are pixels. The z coordinate is also returned, also in pixels.
//-----------------------------------------------------------------------------
Vector GraphicsWindow::ProjectPoint3(Vector p) {
double w;
Vector r = ProjectPoint4(p, &w);
return r.ScaledBy(scale/w);
}
//-----------------------------------------------------------------------------
// Project a point in model space halfway into screen space. The scale is
// not applied, and the perspective divide isn't applied; instead the w
// coordinate is returned separately.
//-----------------------------------------------------------------------------
Vector GraphicsWindow::ProjectPoint4(Vector p, double *w) {
p = p.Plus(offset);
Vector r;
r.x = p.Dot(projRight);
r.y = p.Dot(projUp);
r.z = p.Dot(projUp.Cross(projRight));
*w = 1 + r.z*SS.CameraTangent()*scale;
return r;
}
//-----------------------------------------------------------------------------
// Return a point in the plane parallel to the screen and through the offset,
// that projects onto the specified (x, y) coordinates.
//-----------------------------------------------------------------------------
Vector GraphicsWindow::UnProjectPoint(Point2d p) {
Vector orig = offset.ScaledBy(-1);
// Note that we ignoring the effects of perspective. Since our returned
// point has the same component normal to the screen as the offset, it
// will have z = 0 after the rotation is applied, thus w = 1. So this is
// correct.
orig = orig.Plus(projRight.ScaledBy(p.x / scale)).Plus(
projUp. ScaledBy(p.y / scale));
return orig;
}
Vector GraphicsWindow::UnProjectPoint3(Vector p) {
p.z = p.z / (scale - p.z * SS.CameraTangent() * scale);
double w = 1 + p.z * SS.CameraTangent() * scale;
p.x *= w / scale;
p.y *= w / scale;
Vector orig = offset.ScaledBy(-1);
orig = orig.Plus(projRight.ScaledBy(p.x)).Plus(
projUp. ScaledBy(p.y).Plus(
projRight.Cross(projUp). ScaledBy(p.z)));
return orig;
}
void GraphicsWindow::NormalizeProjectionVectors() {
if(projRight.Magnitude() < LENGTH_EPS) {
projRight = Vector::From(1, 0, 0);
}
Vector norm = projRight.Cross(projUp);
// If projRight and projUp somehow ended up parallel, then pick an
// arbitrary projUp normal to projRight.
if(norm.Magnitude() < LENGTH_EPS) {
norm = projRight.Normal(0);
}
projUp = norm.Cross(projRight);
projUp = projUp.WithMagnitude(1);
projRight = projRight.WithMagnitude(1);
}
Vector GraphicsWindow::VectorFromProjs(Vector rightUpForward) {
Vector n = projRight.Cross(projUp);
Vector r = (projRight.ScaledBy(rightUpForward.x));
r = r.Plus(projUp.ScaledBy(rightUpForward.y));
r = r.Plus(n.ScaledBy(rightUpForward.z));
return r;
}
void GraphicsWindow::Paint() {
int i;
havePainted = true;
int w, h;
GetGraphicsWindowSize(&w, &h);
width = w; height = h;
glViewport(0, 0, w, h);
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glMatrixMode(GL_PROJECTION);
glLoadIdentity();
glScaled(scale*2.0/w, scale*2.0/h, scale*1.0/30000);
double mat[16];
// Last thing before display is to apply the perspective
double clp = SS.CameraTangent()*scale;
MakeMatrix(mat, 1, 0, 0, 0,
0, 1, 0, 0,
0, 0, 1, 0,
0, 0, clp, 1);
glMultMatrixd(mat);
// Before that, we apply the rotation
Vector n = projUp.Cross(projRight);
MakeMatrix(mat, projRight.x, projRight.y, projRight.z, 0,
projUp.x, projUp.y, projUp.z, 0,
n.x, n.y, n.z, 0,
0, 0, 0, 1);
glMultMatrixd(mat);
// And before that, the translation
MakeMatrix(mat, 1, 0, 0, offset.x,
0, 1, 0, offset.y,
0, 0, 1, offset.z,
0, 0, 0, 1);
glMultMatrixd(mat);
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glMatrixMode(GL_MODELVIEW);
glLoadIdentity();
glShadeModel(GL_SMOOTH);
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glEnable(GL_BLEND);
glEnable(GL_LINE_SMOOTH);
// don't enable GL_POLYGON_SMOOTH; that looks ugly on some graphics cards,
// drawn with leaks in the mesh
glEnable(GL_POLYGON_OFFSET_LINE);
glEnable(GL_POLYGON_OFFSET_FILL);
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glEnable(GL_DEPTH_TEST);
glHint(GL_LINE_SMOOTH_HINT, GL_NICEST);
glEnable(GL_NORMALIZE);
2015-03-29 00:30:52 +00:00
// At the same depth, we want later lines drawn over earlier.
glDepthFunc(GL_LEQUAL);
if(SS.ActiveGroupsOkay()) {
Replaced RGB-color integers with dedicated data structure RGB colors were represented using a uint32_t with the red, green and blue values stuffed into the lower three octets (i.e. 0x00BBGGRR), like Microsoft's COLORREF. This approach did not lend itself to type safety, however, so this change replaces it with an RgbColor class that provides the same infomation plus a handful of useful methods to work with it. (Note that sizeof(RgbColor) == sizeof(uint32_t), so this change should not lead to memory bloat.) Some of the new methods/fields replace what were previously macro calls; e.g. RED(c) is now c.red, REDf(c) is now c.redF(). The .Equals() method is now used instead of == to compare colors. RGB colors still need to be represented as packed integers in file I/O and preferences, so the methods .FromPackedInt() and .ToPackedInt() are provided. Also implemented are Cnf{Freeze,Thaw}Color(), type-safe wrappers around Cnf{Freeze,Thaw}Int() that facilitate I/O with preferences. (Cnf{Freeze,Thaw}Color() are defined outside of the system-dependent code to minimize the footprint of the latter; because the same can be done with Cnf{Freeze,Thaw}Bool(), those are also moved out of the system code with this commit.) Color integers were being OR'ed with 0x80000000 in some places for two distinct purposes: One, to indicate use of a default color in glxFillMesh(); this has been replaced by use of the .UseDefault() method. Two, to indicate to TextWindow::Printf() that the format argument of a "%Bp"/"%Fp" specifier is an RGB color rather than a color "code" from TextWindow::bgColors[] or TextWindow::fgColors[] (as the specifier can accept either); instead, we define a new flag "z" (as in "%Bz" or "%Fz") to indicate an RGBcolor pointer, leaving "%Bp"/"%Fp" to indicate a color code exclusively. (This also allows TextWindow::meta[][].bg to be a char instead of an int, partly compensating for the new .bgRgb field added immediately after.) In array declarations, RGB colors could previously be specified as 0 (often in a terminating element). As that no longer works, we define NULL_COLOR, which serves much the same purpose for RgbColor variables as NULL serves for pointers.
2013-10-16 20:00:58 +00:00
glClearColor(SS.backgroundColor.redF(),
SS.backgroundColor.greenF(),
SS.backgroundColor.blueF(), 1.0f);
} else {
// Draw a different background whenever we're having solve problems.
2015-07-10 11:54:39 +00:00
RgbaColor rgb = Style::Color(Style::DRAW_ERROR);
Replaced RGB-color integers with dedicated data structure RGB colors were represented using a uint32_t with the red, green and blue values stuffed into the lower three octets (i.e. 0x00BBGGRR), like Microsoft's COLORREF. This approach did not lend itself to type safety, however, so this change replaces it with an RgbColor class that provides the same infomation plus a handful of useful methods to work with it. (Note that sizeof(RgbColor) == sizeof(uint32_t), so this change should not lead to memory bloat.) Some of the new methods/fields replace what were previously macro calls; e.g. RED(c) is now c.red, REDf(c) is now c.redF(). The .Equals() method is now used instead of == to compare colors. RGB colors still need to be represented as packed integers in file I/O and preferences, so the methods .FromPackedInt() and .ToPackedInt() are provided. Also implemented are Cnf{Freeze,Thaw}Color(), type-safe wrappers around Cnf{Freeze,Thaw}Int() that facilitate I/O with preferences. (Cnf{Freeze,Thaw}Color() are defined outside of the system-dependent code to minimize the footprint of the latter; because the same can be done with Cnf{Freeze,Thaw}Bool(), those are also moved out of the system code with this commit.) Color integers were being OR'ed with 0x80000000 in some places for two distinct purposes: One, to indicate use of a default color in glxFillMesh(); this has been replaced by use of the .UseDefault() method. Two, to indicate to TextWindow::Printf() that the format argument of a "%Bp"/"%Fp" specifier is an RGB color rather than a color "code" from TextWindow::bgColors[] or TextWindow::fgColors[] (as the specifier can accept either); instead, we define a new flag "z" (as in "%Bz" or "%Fz") to indicate an RGBcolor pointer, leaving "%Bp"/"%Fp" to indicate a color code exclusively. (This also allows TextWindow::meta[][].bg to be a char instead of an int, partly compensating for the new .bgRgb field added immediately after.) In array declarations, RGB colors could previously be specified as 0 (often in a terminating element). As that no longer works, we define NULL_COLOR, which serves much the same purpose for RgbColor variables as NULL serves for pointers.
2013-10-16 20:00:58 +00:00
glClearColor(0.4f*rgb.redF(), 0.4f*rgb.greenF(), 0.4f*rgb.blueF(), 1.0f);
// And show the text window, which has info to debug it
ForceTextWindowShown();
}
2015-03-29 00:30:52 +00:00
glClear(GL_COLOR_BUFFER_BIT);
glClearDepth(1.0);
glClear(GL_DEPTH_BUFFER_BIT);
2016-05-24 08:40:02 +00:00
if(!SS.bgImage.pixmap.IsEmpty()) {
double mmw = SS.bgImage.pixmap.width / SS.bgImage.scale,
mmh = SS.bgImage.pixmap.height / SS.bgImage.scale;
Vector origin = SS.bgImage.origin;
origin = origin.DotInToCsys(projRight, projUp, n);
// Place the depth of our origin at the point that corresponds to
// w = 1, so that it's unaffected by perspective.
origin.z = (offset.ScaledBy(-1)).Dot(n);
origin = origin.ScaleOutOfCsys(projRight, projUp, n);
// Place the background at the very back of the Z order, though, by
// mucking with the depth range.
glDepthRange(1, 1);
2016-05-24 08:40:02 +00:00
ssglDrawPixmap(SS.bgImage.pixmap,
origin,
origin.Plus(projUp.ScaledBy(mmh)),
origin.Plus(projRight.ScaledBy(mmw).Plus(
projUp. ScaledBy(mmh))),
origin.Plus(projRight.ScaledBy(mmw)));
}
ssglDepthRangeOffset(0);
// Nasty case when we're reloading the linked files; could be that
// we get an error, so a dialog pops up, and a message loop starts, and
// we have to get called to paint ourselves. If the sketch is screwed
// up, then we could trigger an oops trying to draw.
if(!SS.allConsistent) return;
// Let's use two lights, at the user-specified locations
GLfloat f;
glEnable(GL_LIGHT0);
f = (GLfloat)SS.lightIntensity[0];
GLfloat li0[] = { f, f, f, 1.0f };
glLightfv(GL_LIGHT0, GL_DIFFUSE, li0);
glLightfv(GL_LIGHT0, GL_SPECULAR, li0);
glEnable(GL_LIGHT1);
f = (GLfloat)SS.lightIntensity[1];
GLfloat li1[] = { f, f, f, 1.0f };
glLightfv(GL_LIGHT1, GL_DIFFUSE, li1);
glLightfv(GL_LIGHT1, GL_SPECULAR, li1);
Vector ld;
ld = VectorFromProjs(SS.lightDir[0]);
GLfloat ld0[4] = { (GLfloat)ld.x, (GLfloat)ld.y, (GLfloat)ld.z, 0 };
glLightfv(GL_LIGHT0, GL_POSITION, ld0);
ld = VectorFromProjs(SS.lightDir[1]);
GLfloat ld1[4] = { (GLfloat)ld.x, (GLfloat)ld.y, (GLfloat)ld.z, 0 };
glLightfv(GL_LIGHT1, GL_POSITION, ld1);
GLfloat ambient[4] = { (float)SS.ambientIntensity,
(float)SS.ambientIntensity,
(float)SS.ambientIntensity, 1 };
glLightModelfv(GL_LIGHT_MODEL_AMBIENT, ambient);
ssglUnlockColor();
if(showSnapGrid && LockedInWorkplane()) {
hEntity he = ActiveWorkplane();
EntityBase *wrkpl = SK.GetEntity(he),
*norm = wrkpl->Normal();
Vector wu, wv, wn, wp;
wp = SK.GetEntity(wrkpl->point[0])->PointGetNum();
wu = norm->NormalU();
wv = norm->NormalV();
wn = norm->NormalN();
double g = SS.gridSpacing;
2015-03-29 00:30:52 +00:00
double umin = VERY_POSITIVE, umax = VERY_NEGATIVE,
vmin = VERY_POSITIVE, vmax = VERY_NEGATIVE;
int a;
for(a = 0; a < 4; a++) {
// Ideally, we would just do +/- half the width and height; but
// allow some extra slop for rounding.
Vector horiz = projRight.ScaledBy((0.6*width)/scale + 2*g),
vert = projUp. ScaledBy((0.6*height)/scale + 2*g);
if(a == 2 || a == 3) horiz = horiz.ScaledBy(-1);
if(a == 1 || a == 3) vert = vert. ScaledBy(-1);
Vector tp = horiz.Plus(vert).Minus(offset);
2015-03-29 00:30:52 +00:00
// Project the point into our grid plane, normal to the screen
// (not to the grid plane). If the plane is on edge then this is
// impossible so don't try to draw the grid.
bool parallel;
Vector tpp = Vector::AtIntersectionOfPlaneAndLine(
wn, wn.Dot(wp),
tp, tp.Plus(n),
&parallel);
if(parallel) goto nogrid;
tpp = tpp.Minus(wp);
double uu = tpp.Dot(wu),
vv = tpp.Dot(wv);
umin = min(uu, umin);
umax = max(uu, umax);
vmin = min(vv, vmin);
vmax = max(vv, vmax);
}
int i, j, i0, i1, j0, j1;
i0 = (int)(umin / g);
i1 = (int)(umax / g);
j0 = (int)(vmin / g);
j1 = (int)(vmax / g);
if(i0 > i1 || i1 - i0 > 400) goto nogrid;
if(j0 > j1 || j1 - j0 > 400) goto nogrid;
ssglLineWidth(1);
ssglColorRGBa(Style::Color(Style::DATUM), 0.3);
glBegin(GL_LINES);
for(i = i0 + 1; i < i1; i++) {
ssglVertex3v(wp.Plus(wu.ScaledBy(i*g)).Plus(wv.ScaledBy(j0*g)));
ssglVertex3v(wp.Plus(wu.ScaledBy(i*g)).Plus(wv.ScaledBy(j1*g)));
}
for(j = j0 + 1; j < j1; j++) {
ssglVertex3v(wp.Plus(wu.ScaledBy(i0*g)).Plus(wv.ScaledBy(j*g)));
ssglVertex3v(wp.Plus(wu.ScaledBy(i1*g)).Plus(wv.ScaledBy(j*g)));
}
2015-03-29 00:30:52 +00:00
glEnd();
// Clear the depth buffer, so that the grid is at the very back of
// the Z order.
2015-03-29 00:30:52 +00:00
glClear(GL_DEPTH_BUFFER_BIT);
nogrid:;
}
// Draw the active group; this does stuff like the mesh and edges.
(SK.GetGroup(activeGroup))->Draw();
Allow rendering hidden solid edges using a distinct style. Before this change, the two buttons "Show/hide shaded model" (S) and "Show/hide hidden lines" (H) resulted in drawing the following elements in the following styles: Button | Non-occluded | Non-occluded | Occluded | Occluded state | solid edges | entities | solid edges | entities --------+--------------+--------------+-------------+-------------- !S !H | | | solid-edge | entity style --------+ | +-------------+-------------- S !H | | | invisible --------+ solid-edge | entity style +-------------+-------------- !S H | | | | --------+ | | solid-edge | entity style S H | | | | --------+--------------+--------------+-------------+-------------- After this change, they are drawn as follows: Button | Non-occluded | Non-occluded | Occluded | Occluded state | solid edges | entities | solid edges | entities --------+--------------+--------------+-------------+-------------- !S !H | | | solid-edge | entity style --------+ | +-------------+-------------- S !H | | | invisible --------+ solid-edge | entity style +-------------+-------------- !S H | | | | --------+ | | hidden-edge | stippled¹ S H | | | | --------+--------------+--------------+-------------+-------------- ¹ entity style, but the stipple parameters taken from hidden-edge In SolveSpace's true WYSIWYG tradition, the 2d view export follows the rendered view exactly. Also, it is now possible to edit the stipple parameters of built-in styles, so that by changing the hidden-edge style to non-stippled it is possible to regain the old behavior.
2016-03-09 04:53:46 +00:00
// Now draw the entities.
if(SS.GW.showHdnLines) {
ssglDepthRangeOffset(2);
glDepthFunc(GL_GREATER);
Entity::DrawAll(/*drawAsHidden=*/true);
glDepthFunc(GL_LEQUAL);
}
ssglDepthRangeOffset(0);
Entity::DrawAll(/*drawAsHidden=*/false);
// Draw filled paths in all groups, when those filled paths were requested
// specially by assigning a style with a fill color, or when the filled
// paths are just being filled by default. This should go last, to make
// the transparency work.
for(i = 0; i < SK.groupOrder.n; i++) {
Group *g = SK.GetGroup(SK.groupOrder.elem[i]);
if(!(g->IsVisible())) continue;
g->DrawFilledPaths();
}
glDisable(GL_DEPTH_TEST);
// Draw the constraints
for(i = 0; i < SK.constraint.n; i++) {
SK.constraint.elem[i].Draw();
}
// Draw the "pending" constraint, i.e. a constraint that would be
// placed on a line that is almost horizontal or vertical
Enable exhaustive switch coverage warnings as an error, and use them. Specifically, this enables -Wswitch=error on GCC/Clang and its MSVC equivalent; the exact way it is handled varies slightly, but what they all have in common is that in a switch statement over an enumeration, any enumerand that is not explicitly (via case:) or implicitly (via default:) handled in the switch triggers an error. Moreover, we also change the switch statements in three ways: * Switch statements that ought to be extended every time a new enumerand is added (e.g. Entity::DrawOrGetDistance(), are changed to explicitly list every single enumerand, and not have a default: branch. Note that the assertions are kept because it is legal for a enumeration to have a value unlike any of its defined enumerands, and we can e.g. read garbage from a file, or an uninitialized variable. This requires some rearranging if a default: branch is undesired. * Switch statements that ought to only ever see a few select enumerands, are changed to always assert in the default: branch. * Switch statements that do something meaningful for a few enumerands, and ignore everything else, are changed to do nothing in a default: branch, under the assumption that changing them every time an enumerand is added or removed would just result in noise and catch no bugs. This commit also removes the {Request,Entity,Constraint}::UNKNOWN and Entity::DATUM_POINT enumerands, as those were just fancy names for zeroes. They mess up switch exhaustiveness checks and most of the time were not the best way to implement what they did anyway.
2016-05-25 06:55:50 +00:00
if(SS.GW.pending.operation == Pending::DRAGGING_NEW_LINE_POINT &&
SS.GW.pending.hasSuggestion) {
Constraint c = {};
c.group = SS.GW.activeGroup;
c.workplane = SS.GW.ActiveWorkplane();
c.type = SS.GW.pending.suggestion;
c.ptA = Entity::NO_ENTITY;
c.ptB = Entity::NO_ENTITY;
c.entityA = SS.GW.pending.request.entity(0);
c.entityB = Entity::NO_ENTITY;
c.other = false;
c.other2 = false;
// Only draw.
c.Draw();
}
// Draw the traced path, if one exists
ssglLineWidth(Style::Width(Style::ANALYZE));
ssglColorRGB(Style::Color(Style::ANALYZE));
SContour *sc = &(SS.traced.path);
glBegin(GL_LINE_STRIP);
for(i = 0; i < sc->l.n; i++) {
ssglVertex3v(sc->l.elem[i].p);
}
glEnd();
// And the naked edges, if the user did Analyze -> Show Naked Edges.
ssglDrawEdges(&(SS.nakedEdges), /*endpointsToo=*/true, { Style::DRAW_ERROR });
// Then redraw whatever the mouse is hovering over, highlighted.
2015-03-29 00:30:52 +00:00
glDisable(GL_DEPTH_TEST);
ssglLockColorTo(Style::Color(Style::HOVERED));
hover.Draw();
// And finally draw the selection, same mechanism.
ssglLockColorTo(Style::Color(Style::SELECTED));
for(Selection *s = selection.First(); s; s = selection.NextAfter(s)) {
s->Draw();
}
ssglUnlockColor();
// If a marquee selection is in progress, then draw the selection
// rectangle, as an outline and a transparent fill.
if(pending.operation == Pending::DRAGGING_MARQUEE) {
Point2d begin = ProjectPoint(orig.marqueePoint);
double xmin = min(orig.mouse.x, begin.x),
xmax = max(orig.mouse.x, begin.x),
ymin = min(orig.mouse.y, begin.y),
ymax = max(orig.mouse.y, begin.y);
Vector tl = UnProjectPoint(Point2d::From(xmin, ymin)),
tr = UnProjectPoint(Point2d::From(xmax, ymin)),
br = UnProjectPoint(Point2d::From(xmax, ymax)),
bl = UnProjectPoint(Point2d::From(xmin, ymax));
ssglLineWidth((GLfloat)1.3);
ssglColorRGB(Style::Color(Style::HOVERED));
glBegin(GL_LINE_LOOP);
ssglVertex3v(tl);
ssglVertex3v(tr);
ssglVertex3v(br);
ssglVertex3v(bl);
glEnd();
ssglColorRGBa(Style::Color(Style::HOVERED), 0.10);
glBegin(GL_QUADS);
ssglVertex3v(tl);
ssglVertex3v(tr);
ssglVertex3v(br);
ssglVertex3v(bl);
glEnd();
}
// An extra line, used to indicate the origin when rotating within the
// plane of the monitor.
if(SS.extraLine.draw) {
ssglLineWidth(1);
ssglLockColorTo(Style::Color(Style::DATUM));
glBegin(GL_LINES);
ssglVertex3v(SS.extraLine.ptA);
ssglVertex3v(SS.extraLine.ptB);
glEnd();
}
// A note to indicate the origin in the just-exported file.
if(SS.justExportedInfo.draw) {
Vector p, u, v;
if(SS.justExportedInfo.showOrigin) {
p = SS.justExportedInfo.pt,
u = SS.justExportedInfo.u,
v = SS.justExportedInfo.v;
} else {
p = SS.GW.offset.ScaledBy(-1);
u = SS.GW.projRight;
v = SS.GW.projUp;
}
ssglColorRGB(Style::Color(Style::DATUM));
ssglWriteText("previewing exported geometry; press Esc to return",
Style::DefaultTextHeight(),
2015-03-29 00:30:52 +00:00
p.Plus(u.ScaledBy(10/scale)).Plus(v.ScaledBy(10/scale)),
u, v, NULL, NULL);
if(SS.justExportedInfo.showOrigin) {
ssglLineWidth(1.5);
glBegin(GL_LINES);
ssglVertex3v(p.Plus(u.WithMagnitude(-15/scale)));
ssglVertex3v(p.Plus(u.WithMagnitude(30/scale)));
ssglVertex3v(p.Plus(v.WithMagnitude(-15/scale)));
ssglVertex3v(p.Plus(v.WithMagnitude(30/scale)));
glEnd();
ssglWriteText("(x, y) = (0, 0) for file just exported",
Style::DefaultTextHeight(),
p.Plus(u.ScaledBy(40/scale)).Plus(
v.ScaledBy(-(Style::DefaultTextHeight())/scale)),
u, v, NULL, NULL);
}
}
// And finally the toolbar.
if(SS.showToolbar) {
ToolbarDraw();
}
}