Fri, 18 Oct 2013 17:57:42 +0300
Fixed: LDForge would sometimes crash over unitialized data in the GL renderer. This crash sure eluded me for a while. Turned out zoomToFit(), which uses m_width and m_height is called before resizeGL() which initializes these variables. This data is used in an operator new[] call.
/* * LDForge: LDraw parts authoring CAD * Copyright (C) 2013 Santeri Piippo * * 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/>. */ #include <QGLWidget> #include <QWheelEvent> #include <QMouseEvent> #include <QContextMenuEvent> #include <QInputDialog> #include <QToolTip> #include <QTimer> #include <GL/glu.h> #include "common.h" #include "config.h" #include "file.h" #include "gldraw.h" #include "colors.h" #include "gui.h" #include "misc.h" #include "history.h" #include "dialogs.h" #include "addObjectDialog.h" #include "messagelog.h" #include "primitives.h" #include "moc_gldraw.cpp" static const LDFixedCameraInfo g_FixedCameras[6] = { {{ 1, 0, 0 }, X, Z, false, false }, {{ 0, 0, 0 }, X, Y, false, true }, {{ 0, 1, 0 }, Z, Y, true, true }, {{ -1, 0, 0 }, X, Z, false, true }, {{ 0, 0, 0 }, X, Y, true, true }, {{ 0, -1, 0 }, Z, Y, false, true }, }; static const matrix g_circleDrawTransforms[3] = { { 2, 0, 0, 0, 1, 0, 0, 0, 2 }, { 2, 0, 0, 0, 0, 2, 0, 1, 0 }, { 0, 1, 0, 2, 0, 0, 0, 0, 2 }, }; cfg (String, gl_bgcolor, "#CCCCD9"); cfg (String, gl_maincolor, "#707078"); cfg (Float, gl_maincolor_alpha, 1.0); cfg (Int, gl_linethickness, 2); cfg (Bool, gl_colorbfc, false); cfg (Int, gl_camera, GLRenderer::Free); cfg (Bool, gl_blackedges, false); cfg (Bool, gl_axes, false); cfg (Bool, gl_wireframe, false); cfg (Bool, gl_logostuds, false); // argh const char* g_CameraNames[7] = { QT_TRANSLATE_NOOP ("GLRenderer", "Top"), QT_TRANSLATE_NOOP ("GLRenderer", "Front"), QT_TRANSLATE_NOOP ("GLRenderer", "Left"), QT_TRANSLATE_NOOP ("GLRenderer", "Bottom"), QT_TRANSLATE_NOOP ("GLRenderer", "Back"), QT_TRANSLATE_NOOP ("GLRenderer", "Right"), QT_TRANSLATE_NOOP ("GLRenderer", "Free") }; const GL::Camera g_Cameras[7] = { GL::Top, GL::Front, GL::Left, GL::Bottom, GL::Back, GL::Right, GL::Free }; const struct LDGLAxis { const QColor col; const vertex vert; } g_GLAxes[3] = { { QColor (255, 0, 0), vertex (10000, 0, 0) }, { QColor (80, 192, 0), vertex (0, 10000, 0) }, { QColor (0, 160, 192), vertex (0, 0, 10000) }, }; static bool g_glInvert = false; static QList<short> g_warnedColors; // ============================================================================= // ----------------------------------------------------------------------------- GLRenderer::GLRenderer (QWidget* parent) : QGLWidget (parent) { m_picking = m_rangepick = false; m_camera = (GL::Camera) gl_camera.value; m_drawToolTip = false; m_editMode = Select; m_rectdraw = false; m_panning = false; m_firstResize = true; setFile (null); setDrawOnly (false); setMessageLog (null); m_toolTipTimer = new QTimer (this); m_toolTipTimer->setSingleShot (true); connect (m_toolTipTimer, SIGNAL (timeout()), this, SLOT (slot_toolTipTimer())); m_thickBorderPen = QPen (QColor (0, 0, 0, 208), 2, Qt::SolidLine, Qt::RoundCap, Qt::RoundJoin); m_thinBorderPen = m_thickBorderPen; m_thinBorderPen.setWidth (1); // Init camera icons for (const GL::Camera cam : g_Cameras) { str iconname = fmt ("camera-%1", tr (g_CameraNames[cam]).toLower()); CameraIcon* info = &m_cameraIcons[cam]; info->img = new QPixmap (getIcon (iconname)); info->cam = cam; } for (int i = 0; i < 6; ++i) { m_overlays[i].img = null; m_depthValues[i] = 0.0f; } calcCameraIcons(); } // ============================================================================= // ----------------------------------------------------------------------------- GLRenderer::~GLRenderer() { for (int i = 0; i < 6; ++i) delete m_overlays[i].img; for (CameraIcon& info : m_cameraIcons) delete info.img; } // ============================================================================= // Calculates the "hitboxes" of the camera icons so that we can tell when the // cursor is pointing at the camera icon. // ----------------------------------------------------------------------------- void GLRenderer::calcCameraIcons() { int i = 0; for (CameraIcon& info : m_cameraIcons) { // MATH const long x1 = (m_width - (info.cam != Free ? 48 : 16)) + ((i % 3) * 16) - 1, y1 = ((i / 3) * 16) + 1; info.srcRect = QRect (0, 0, 16, 16); info.destRect = QRect (x1, y1, 16, 16); info.selRect = QRect ( info.destRect.x(), info.destRect.y(), info.destRect.width() + 1, info.destRect.height() + 1 ); ++i; } } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::initGLData() { glEnable (GL_BLEND); glBlendFunc (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); glEnable (GL_POLYGON_OFFSET_FILL); glPolygonOffset (1.0f, 1.0f); glEnable (GL_DEPTH_TEST); glShadeModel (GL_SMOOTH); glEnable (GL_MULTISAMPLE); glEnable (GL_LINE_SMOOTH); glHint (GL_LINE_SMOOTH_HINT, GL_NICEST); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::resetAngles() { m_rotX = 30.0f; m_rotY = 325.f; m_panX = m_panY = m_rotZ = 0.0f; zoomToFit(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::initializeGL() { setBackground(); glLineWidth (gl_linethickness); setAutoFillBackground (false); setMouseTracking (true); setFocusPolicy (Qt::WheelFocus); compileAllObjects(); } // ============================================================================= // ----------------------------------------------------------------------------- QColor GLRenderer::getMainColor() { QColor col (gl_maincolor); if (!col.isValid()) return QColor (0, 0, 0); col.setAlpha (gl_maincolor_alpha * 255.f); return col; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::setBackground() { QColor col (gl_bgcolor); if (!col.isValid()) return; col.setAlpha (255); m_darkbg = luma (col) < 80; m_bgcolor = col; qglClearColor (col); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::setObjectColor (LDObject* obj, const ListType list) { QColor qcol; if (!obj->isColored()) return; if (list == GL::PickList) { // Make the color by the object's ID if we're picking, so we can make the // ID again from the color we get from the picking results. Be sure to use // the top level parent's index since we want a subfile's children point // to the subfile itself. long i = obj->topLevelParent()->id(); // Calculate a color based from this index. This method caters for // 16777216 objects. I don't think that'll be exceeded anytime soon. :) // ATM biggest is 53588.dat with 12600 lines. double r = (i / (256 * 256)) % 256, g = (i / 256) % 256, b = i % 256; qglColor (QColor (r, g, b)); return; } if ( (list == BFCFrontList || list == BFCBackList) && obj->getType() != LDObject::Line && obj->getType() != LDObject::CndLine) { if (list == GL::BFCFrontList) qcol = QColor (40, 192, 0); else qcol = QColor (224, 0, 0); } else { if (obj->color() == maincolor) qcol = getMainColor(); else { LDColor* col = getColor (obj->color()); if (col) qcol = col->faceColor; } if (obj->color() == edgecolor) { qcol = luma (m_bgcolor) < 40 ? QColor (64, 64, 64) : Qt::black; LDColor* col; if (!gl_blackedges && obj->parent() && (col = getColor (obj->parent()->color()))) qcol = col->edgeColor; } if (qcol.isValid() == false) { // The color was unknown. Use main color to make the object at least // not appear pitch-black. if (obj->color() != edgecolor) qcol = getMainColor(); // Warn about the unknown colors, but only once. for (short i : g_warnedColors) if (obj->color() == i) return; print ("%1: Unknown color %2!\n", __func__, obj->color()); g_warnedColors << obj->color(); return; } } long r = qcol.red(), g = qcol.green(), b = qcol.blue(), a = qcol.alpha(); if (obj->topLevelParent()->selected()) { // Brighten it up for the select list. const uchar add = 51; r = min (r + add, 255l); g = min (g + add, 255l); b = min (b + add, 255l); } glColor4f ( ((double) r) / 255.0f, ((double) g) / 255.0f, ((double) b) / 255.0f, ((double) a) / 255.0f); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::refresh() { update(); swapBuffers(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::hardRefresh() { compileAllObjects(); refresh(); glLineWidth (gl_linethickness); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::resizeGL (int w, int h) { m_width = w; m_height = h; // If this is the first call to resizeGL, reset the angles. We cannot call // resetAngles() in the initializer because it does not know m_width or m_height, // which zoomToFit() must know. if (m_firstResize) { m_firstResize = false; resetAngles(); } calcCameraIcons(); glViewport (0, 0, w, h); glMatrixMode (GL_PROJECTION); glLoadIdentity(); gluPerspective (45.0f, (double) w / (double) h, 1.0f, 10000.0f); glMatrixMode (GL_MODELVIEW); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::drawGLScene() { if (file() == null) return; if (gl_wireframe && !picking()) glPolygonMode (GL_FRONT_AND_BACK, GL_LINE); glClear (GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); glEnable (GL_DEPTH_TEST); if (m_camera != Free) { glMatrixMode (GL_PROJECTION); glPushMatrix(); glLoadIdentity(); glOrtho (-m_virtWidth, m_virtWidth, -m_virtHeight, m_virtHeight, -100.0f, 100.0f); glTranslatef (m_panX, m_panY, 0.0f); if (m_camera != Front && m_camera != Back) { glRotatef (90.0f, g_FixedCameras[m_camera].glrotate[0], g_FixedCameras[m_camera].glrotate[1], g_FixedCameras[m_camera].glrotate[2]); } // Back camera needs to be handled differently if (m_camera == GLRenderer::Back) { glRotatef (180.0f, 1.0f, 0.0f, 0.0f); glRotatef (180.0f, 0.0f, 0.0f, 1.0f); } } else { glMatrixMode (GL_MODELVIEW); glPushMatrix(); glLoadIdentity(); glTranslatef (0.0f, 0.0f, -2.0f); glTranslatef (m_panX, m_panY, -zoom()); glRotatef (m_rotX, 1.0f, 0.0f, 0.0f); glRotatef (m_rotY, 0.0f, 1.0f, 0.0f); glRotatef (m_rotZ, 0.0f, 0.0f, 1.0f); } const GL::ListType list = (!drawOnly() && m_picking) ? PickList : NormalList; if (gl_colorbfc && !m_picking && !drawOnly()) { glEnable (GL_CULL_FACE); for (LDObject* obj : file()->objects()) { if (obj->hidden()) continue; glCullFace (GL_BACK); glCallList (obj->glLists[BFCFrontList]); glCullFace (GL_FRONT); glCallList (obj->glLists[BFCBackList]); } glDisable (GL_CULL_FACE); } else { for (LDObject* obj : file()->objects()) { if (obj->hidden()) continue; glCallList (obj->glLists[list]); } } if (gl_axes && !m_picking && !drawOnly()) glCallList (m_axeslist); glPopMatrix(); glMatrixMode (GL_MODELVIEW); glPolygonMode (GL_FRONT_AND_BACK, GL_FILL); } // ============================================================================= // ----------------------------------------------------------------------------- // This converts a 2D point on the screen to a 3D point in the model. If 'snap' // is true, the 3D point will snap to the current grid. // ----------------------------------------------------------------------------- vertex GLRenderer::coordconv2_3 (const QPoint& pos2d, bool snap) const { assert (camera() != Free); vertex pos3d; const LDFixedCameraInfo* cam = &g_FixedCameras[m_camera]; const Axis axisX = cam->axisX; const Axis axisY = cam->axisY; const short negXFac = cam->negX ? -1 : 1, negYFac = cam->negY ? -1 : 1; // Calculate cx and cy - these are the LDraw unit coords the cursor is at. double cx = (-m_virtWidth + ( (2 * pos2d.x() * m_virtWidth) / m_width) - m_panX); double cy = (m_virtHeight - ( (2 * pos2d.y() * m_virtHeight) / m_height) - m_panY); if (snap) { cx = Grid::snap (cx, (Grid::Config) axisX); cy = Grid::snap (cy, (Grid::Config) axisY); } cx *= negXFac; cy *= negYFac; str tmp; // Create the vertex from the coordinates pos3d[axisX] = tmp.sprintf ("%.3f", cx).toDouble(); pos3d[axisY] = tmp.sprintf ("%.3f", cy).toDouble(); pos3d[3 - axisX - axisY] = depthValue(); return pos3d; } // ============================================================================= // ----------------------------------------------------------------------------- // Inverse operation for the above - convert a 3D position to a 2D screen // position // ----------------------------------------------------------------------------- QPoint GLRenderer::coordconv3_2 (const vertex& pos3d) const { GLfloat m[16]; const LDFixedCameraInfo* cam = &g_FixedCameras[m_camera]; const Axis axisX = cam->axisX; const Axis axisY = cam->axisY; const short negXFac = cam->negX ? -1 : 1, negYFac = cam->negY ? -1 : 1; glGetFloatv (GL_MODELVIEW_MATRIX, m); const double x = pos3d.x(); const double y = pos3d.y(); const double z = pos3d.z(); vertex transformed; transformed[X] = (m[0] * x) + (m[1] * y) + (m[2] * z) + m[3]; transformed[Y] = (m[4] * x) + (m[5] * y) + (m[6] * z) + m[7]; transformed[Z] = (m[8] * x) + (m[9] * y) + (m[10] * z) + m[11]; double rx = ( ( (transformed[axisX] * negXFac) + m_virtWidth + m_panX) * m_width) / (2 * m_virtWidth); double ry = ( ( (transformed[axisY] * negYFac) - m_virtHeight + m_panY) * m_height) / (2 * m_virtHeight); return QPoint (rx, -ry); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::paintEvent (QPaintEvent* ev) { Q_UNUSED (ev) makeCurrent(); m_virtWidth = zoom(); m_virtHeight = (m_height * m_virtWidth) / m_width; initGLData(); drawGLScene(); const QPen textpen = getTextPen(); const QBrush polybrush (QColor (64, 192, 0, 128)); QPainter paint (this); QFontMetrics metrics = QFontMetrics (QFont()); paint.setRenderHint (QPainter::HighQualityAntialiasing); // If we wish to only draw the brick, stop here if (drawOnly()) return; if (m_camera != Free && !picking()) { // Paint the overlay image if we have one const LDGLOverlay& overlay = m_overlays[m_camera]; if (overlay.img != null) { QPoint v0 = coordconv3_2 (m_overlays[m_camera].v0), v1 = coordconv3_2 (m_overlays[m_camera].v1); QRect targRect (v0.x(), v0.y(), abs (v1.x() - v0.x()), abs (v1.y() - v0.y())), srcRect (0, 0, overlay.img->width(), overlay.img->height()); paint.drawImage (targRect, *overlay.img, srcRect); } // Paint the coordinates onto the screen. str text = fmt (tr ("X: %1, Y: %2, Z: %3"), m_hoverpos[X], m_hoverpos[Y], m_hoverpos[Z]); QFontMetrics metrics = QFontMetrics (font()); QRect textSize = metrics.boundingRect (0, 0, m_width, m_height, Qt::AlignCenter, text); paint.setPen (getTextPen()); paint.drawText (m_width - textSize.width(), m_height - 16, textSize.width(), textSize.height(), Qt::AlignCenter, text); QPen linepen = m_thinBorderPen; linepen.setWidth (2); linepen.setColor (luma (m_bgcolor) < 40 ? Qt::white : Qt::black); // If we're drawing, draw the vertices onto the screen. if (editMode() == Draw) { int numverts = 4; if (!m_rectdraw) numverts = m_drawedVerts.size() + 1; if (numverts > 0) { QPoint poly[4]; vertex polyverts[4]; if (!m_rectdraw) { uchar i = 0; for (vertex& vert : m_drawedVerts) { poly[i] = coordconv3_2 (vert); polyverts[i] = vert; ++i; } // Draw the cursor vertex as the last one in the list. if (numverts <= 4) { poly[i] = coordconv3_2 (m_hoverpos); polyverts[i] = m_hoverpos; } else { numverts = 4; } } else { if (m_drawedVerts.size() > 0) { // Get vertex information from m_rectverts for (int i = 0; i < numverts; ++i) { polyverts[i] = m_rectverts[i]; poly[i] = coordconv3_2 (polyverts[i]); } } else { poly[0] = coordconv3_2 (m_hoverpos); polyverts[0] = m_hoverpos; } } // Draw the polygon-to-be paint.setPen (linepen); paint.setBrush (polybrush); paint.drawPolygon (poly, numverts); // Draw vertex blips for (int i = 0; i < numverts; ++i) { QPoint& blip = poly[i]; drawBlip (paint, blip); // Draw their coordinates paint.drawText (blip.x(), blip.y() - 8, polyverts[i].stringRep (true)); } } } elif (editMode() == CircleMode) { // If we have not specified the center point of the circle yet, preview it on the screen. if (m_drawedVerts.size() == 0) drawBlip (paint, coordconv3_2 (m_hoverpos)); else { QVector<vertex> verts, verts2; const double dist0 = circleDrawDist(0), dist1 = (m_drawedVerts.size() >= 2) ? circleDrawDist (1) : -1; const int segs = lores; const double angleUnit = (2 * pi) / segs; Axis relX, relY; QVector<QPoint> ringpoints, circlepoints, circle2points; getRelativeAxes (relX, relY); // Calculate the preview positions of vertices for (int i = 0; i < segs; ++i) { vertex v = g_origin; v[relX] = m_drawedVerts[0][relX] + (cos (i * angleUnit) * dist0); v[relY] = m_drawedVerts[0][relY] + (sin (i * angleUnit) * dist0); verts << v; if (dist1 != -1) { v[relX] = m_drawedVerts[0][relX] + (cos (i * angleUnit) * dist1); v[relY] = m_drawedVerts[0][relY] + (sin (i * angleUnit) * dist1); verts2 << v; } } int i = 0; for (const vertex& v : verts + verts2) { // Calculate the 2D point of the vertex QPoint point = coordconv3_2 (v); // Draw a green blip at where it is drawBlip (paint, point); // Add it to the list of points for the green ring fill. ringpoints << point; // Also add the circle points to separate lists if (i < verts.size()) circlepoints << point; else circle2points << point; ++i; } // Insert the first point as the seventeenth one so that // the ring polygon is closed properly. if (ringpoints.size() >= 16) ringpoints.insert (16, ringpoints[0]); // Same for the outer ring. Note that the indices are offset by 1 // because of the insertion done above bumps the values. if (ringpoints.size() >= 33) ringpoints.insert (33, ringpoints[17]); // Draw the ring paint.setBrush ((m_drawedVerts.size() >= 2) ? polybrush : Qt::NoBrush); paint.setPen (Qt::NoPen); paint.drawPolygon (QPolygon (ringpoints)); // Draw the circles paint.setBrush (Qt::NoBrush); paint.setPen (linepen); paint.drawPolygon (QPolygon (circlepoints)); paint.drawPolygon (QPolygon (circle2points)); { // Draw the current radius in the middle of the circle. QPoint origin = coordconv3_2 (m_drawedVerts[0]); str label = str::number (dist0); paint.setPen (textpen); paint.drawText (origin.x() - (metrics.width (label) / 2), origin.y(), label); if (m_drawedVerts.size() >= 2) { label = str::number (dist1); paint.drawText (origin.x() - (metrics.width (label) / 2), origin.y() + metrics.height(), label); } } } } } // Camera icons if (!m_picking) { // Draw a background for the selected camera paint.setPen (m_thinBorderPen); paint.setBrush (QBrush (QColor (0, 128, 160, 128))); paint.drawRect (m_cameraIcons[camera()].selRect); // Draw the actual icons for (CameraIcon& info : m_cameraIcons) { // Don't draw the free camera icon when in draw mode if (&info == &m_cameraIcons[GL::Free] && editMode() != Select) continue; paint.drawPixmap (info.destRect, *info.img, info.srcRect); } str fmtstr = tr ("%1 Camera"); // Draw a label for the current camera in the bottom left corner { const int margin = 4; str label; label = fmt (fmtstr, tr (g_CameraNames[camera()])); paint.setPen (textpen); paint.drawText (QPoint (margin, height() - (margin + metrics.descent())), label); } // Tool tips if (m_drawToolTip) { if (m_cameraIcons[m_toolTipCamera].destRect.contains (m_pos) == false) m_drawToolTip = false; else { str label = fmt (fmtstr, tr (g_CameraNames[m_toolTipCamera])); QToolTip::showText (m_globalpos, label); } } } // Message log if (msglog()) { int y = 0; const int margin = 2; QColor penColor = getTextPen(); for (const MessageManager::Line& line : msglog()->getLines()) { penColor.setAlphaF (line.alpha); paint.setPen (penColor); paint.drawText (QPoint (margin, y + margin + metrics.ascent()), line.text); y += metrics.height(); } } // If we're range-picking, draw a rectangle encompassing the selection area. if (m_rangepick && !m_picking && m_totalmove >= 10) { int x0 = m_rangeStart.x(), y0 = m_rangeStart.y(), x1 = m_pos.x(), y1 = m_pos.y(); QRect rect (x0, y0, x1 - x0, y1 - y0); QColor fillColor = (m_addpick ? "#40FF00" : "#00CCFF"); fillColor.setAlphaF (0.2f); paint.setPen (m_thickBorderPen); paint.setBrush (QBrush (fillColor)); paint.drawRect (rect); } } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::drawBlip (QPainter& paint, QPoint pos) const { QPen pen = m_thinBorderPen; const int blipsize = 8; pen.setWidth (1); paint.setPen (pen); paint.setBrush (QColor (64, 192, 0)); paint.drawEllipse (pos.x() - blipsize / 2, pos.y() - blipsize / 2, blipsize, blipsize); } // ============================================================================= // ----------------------------------------------------------------------------- QColor GLRenderer::getTextPen () const { return m_darkbg ? Qt::white : Qt::black; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::compileAllObjects() { if (!file()) return; // Compiling all is a big job, use a busy cursor setCursor (Qt::BusyCursor); m_knownVerts.clear(); for (LDObject * obj : file()->objects()) compileObject (obj); // Compile axes glDeleteLists (m_axeslist, 1); m_axeslist = glGenLists (1); glNewList (m_axeslist, GL_COMPILE); glBegin (GL_LINES); for (const LDGLAxis & ax : g_GLAxes) { qglColor (ax.col); compileVertex (ax.vert); compileVertex (-ax.vert); } glEnd(); glEndList(); setCursor (Qt::ArrowCursor); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::compileSubObject (LDObject* obj, const GLenum gltype) { glBegin (gltype); const short numverts = (obj->getType() != LDObject::CndLine) ? obj->vertices() : 2; if (g_glInvert == false) for (short i = 0; i < numverts; ++i) compileVertex (obj->m_coords[i]); else for (short i = numverts - 1; i >= 0; --i) compileVertex (obj->m_coords[i]); glEnd(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::compileList (LDObject* obj, const GLRenderer::ListType list) { setObjectColor (obj, list); switch (obj->getType()) { case LDObject::Line: compileSubObject (obj, GL_LINES); break; case LDObject::CndLine: // Draw conditional lines with a dash pattern - however, use a full // line when drawing a pick list to make selecting them easier. if (list != GL::PickList) { glLineStipple (1, 0x6666); glEnable (GL_LINE_STIPPLE); } compileSubObject (obj, GL_LINES); glDisable (GL_LINE_STIPPLE); break; case LDObject::Triangle: compileSubObject (obj, GL_TRIANGLES); break; case LDObject::Quad: compileSubObject (obj, GL_QUADS); break; case LDObject::Subfile: { LDSubfile* ref = static_cast<LDSubfile*> (obj); QList<LDObject*> objs; objs = ref->inlineContents ( LDSubfile::DeepInline | LDSubfile::CacheInline | LDSubfile::RendererInline); bool oldinvert = g_glInvert; if (ref->transform().determinant() < 0) g_glInvert = !g_glInvert; LDObject* prev = ref->prev(); if (prev && prev->getType() == LDObject::BFC && static_cast<LDBFC*> (prev)->type == LDBFC::InvertNext) g_glInvert = !g_glInvert; for (LDObject * obj : objs) { compileList (obj, list); delete obj; } g_glInvert = oldinvert; } break; default: break; } } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::compileVertex (const vertex& vrt) { glVertex3d (vrt[X], -vrt[Y], -vrt[Z]); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::clampAngle (double& angle) const { while (angle < 0) angle += 360.0; while (angle > 360.0) angle -= 360.0; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::addDrawnVertex (vertex pos) { // If we picked an already-existing vertex, stop drawing if (editMode() != CircleMode) { for (vertex& vert : m_drawedVerts) { if (vert == pos) { endDraw (true); return; } } } m_drawedVerts << pos; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::mouseReleaseEvent (QMouseEvent* ev) { const bool wasLeft = (m_lastButtons & Qt::LeftButton) && ! (ev->buttons() & Qt::LeftButton), wasRight = (m_lastButtons & Qt::RightButton) && ! (ev->buttons() & Qt::RightButton), wasMid = (m_lastButtons & Qt::MidButton) && ! (ev->buttons() & Qt::MidButton); if (m_panning) m_panning = false; if (wasLeft) { // Check if we selected a camera icon if (!m_rangepick) { for (CameraIcon & info : m_cameraIcons) { if (info.destRect.contains (ev->pos())) { setCamera (info.cam); goto end; } } } switch (editMode()) { case Draw: { if (m_rectdraw) { if (m_drawedVerts.size() == 2) { endDraw (true); return; } } else { // If we have 4 verts, stop drawing. if (m_drawedVerts.size() >= 4) { endDraw (true); return; } if (m_drawedVerts.size() == 0 && ev->modifiers() & Qt::ShiftModifier) { m_rectdraw = true; updateRectVerts(); } } addDrawnVertex (m_hoverpos); } break; case CircleMode: { if (m_drawedVerts.size() == 3) { endDraw (true); return; } addDrawnVertex (m_hoverpos); } break; case Select: { if (!drawOnly()) { if (m_totalmove < 10) m_rangepick = false; if (!m_rangepick) m_addpick = (m_keymods & Qt::ControlModifier); if (m_totalmove < 10 || m_rangepick) pick (ev->x(), ev->y()); } } break; } m_rangepick = false; } if (wasMid && editMode() != Select && m_drawedVerts.size() < 4 && m_totalmove < 10) { // Find the closest vertex to our cursor double mindist = 1024.0f; vertex closest; bool valid = false; QPoint curspos = coordconv3_2 (m_hoverpos); for (const vertex& pos3d: m_knownVerts) { QPoint pos2d = coordconv3_2 (pos3d); // Measure squared distance const double dx = abs (pos2d.x() - curspos.x()), dy = abs (pos2d.y() - curspos.y()), distsq = (dx * dx) + (dy * dy); if (distsq >= 1024.0f) // 32.0f ** 2 continue; // too far away if (distsq < mindist) { mindist = distsq; closest = pos3d; valid = true; // If it's only 4 pixels away, I think we found our vertex now. if (distsq <= 16.0f) // 4.0f ** 2 break; } } if (valid) addDrawnVertex (closest); } if (wasRight && !m_drawedVerts.isEmpty()) { // Remove the last vertex m_drawedVerts.removeLast(); if (m_drawedVerts.isEmpty()) m_rectdraw = false; } end: update(); m_totalmove = 0; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::mousePressEvent (QMouseEvent* ev) { m_totalmove = 0; if (ev->modifiers() & Qt::ControlModifier) { m_rangepick = true; m_rangeStart.setX (ev->x()); m_rangeStart.setY (ev->y()); m_addpick = (m_keymods & Qt::AltModifier); ev->accept(); } m_lastButtons = ev->buttons(); } // ============================================================================= // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // ============================================================================= void GLRenderer::mouseMoveEvent (QMouseEvent* ev) { int dx = ev->x() - m_pos.x(); int dy = ev->y() - m_pos.y(); m_totalmove += abs (dx) + abs (dy); const bool left = ev->buttons() & Qt::LeftButton, mid = ev->buttons() & Qt::MidButton, shift = ev->modifiers() & Qt::ShiftModifier; if (mid || (left && shift)) { m_panX += 0.03f * dx * (zoom() / 7.5f); m_panY -= 0.03f * dy * (zoom() / 7.5f); m_panning = true; } elif (left && !m_rangepick && camera() == Free) { m_rotX = m_rotX + (dy); m_rotY = m_rotY + (dx); clampAngle (m_rotX); clampAngle (m_rotY); } // Start the tool tip timer if (!m_drawToolTip) m_toolTipTimer->start (500); // Update 2d position m_pos = ev->pos(); m_globalpos = ev->globalPos(); // Calculate 3d position of the cursor m_hoverpos = (camera() != Free) ? coordconv2_3 (m_pos, true) : g_origin; // Update rect vertices since m_hoverpos may have changed updateRectVerts(); update(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::keyPressEvent (QKeyEvent* ev) { m_keymods = ev->modifiers(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::keyReleaseEvent (QKeyEvent* ev) { m_keymods = ev->modifiers(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::wheelEvent (QWheelEvent* ev) { makeCurrent(); zoomNotch (ev->delta() > 0); setZoom (clamp<double> (zoom(), 0.01f, 10000.0f)); update(); ev->accept(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::leaveEvent (QEvent* ev) { (void) ev; m_drawToolTip = false; m_toolTipTimer->stop(); update(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::contextMenuEvent (QContextMenuEvent* ev) { g_win->spawnContextMenu (ev->globalPos()); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::setCamera (const GL::Camera cam) { m_camera = cam; gl_camera = (int) cam; g_win->updateEditModeActions(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::pick (int mouseX, int mouseY) { GLint viewport[4]; makeCurrent(); // Use particularly thick lines while picking ease up selecting lines. glLineWidth (max<double> (gl_linethickness, 6.5f)); // Clear the selection if we do not wish to add to it. if (!m_addpick) { QList<LDObject*> oldsel = g_win->sel(); g_win->sel().clear(); for (LDObject* obj : oldsel) { obj->setSelected (false); compileObject (obj); } } m_picking = true; // Paint the picking scene glDisable (GL_DITHER); glClearColor (1.0f, 1.0f, 1.0f, 1.0f); drawGLScene(); glGetIntegerv (GL_VIEWPORT, viewport); short x0 = mouseX, y0 = mouseY; short x1, y1; // Determine how big an area to read - with range picking, we pick by // the area given, with single pixel picking, we use an 1 x 1 area. if (m_rangepick) { x1 = m_rangeStart.x(); y1 = m_rangeStart.y(); } else { x1 = x0 + 1; y1 = y0 + 1; } // x0 and y0 must be less than x1 and y1, respectively. if (x0 > x1) dataswap (x0, x1); if (y0 > y1) dataswap (y0, y1); // Clamp the values to ensure they're within bounds x0 = max<short> (0, x0); y0 = max<short> (0, y0); x1 = min<short> (x1, m_width); y1 = min<short> (y1, m_height); const short areawidth = (x1 - x0); const short areaheight = (y1 - y0); const long numpixels = areawidth * areaheight; // Allocate space for the pixel data. uchar* const pixeldata = new uchar[4 * numpixels]; uchar* pixelptr = &pixeldata[0]; assert (viewport[3] == m_height); // Read pixels from the color buffer. glReadPixels (x0, viewport[3] - y1, areawidth, areaheight, GL_RGBA, GL_UNSIGNED_BYTE, pixeldata); LDObject* removedObj = null; // Go through each pixel read and add them to the selection. for (long i = 0; i < numpixels; ++i) { long idx = (* (pixelptr + 0) * 0x10000) + (* (pixelptr + 1) * 0x00100) + (* (pixelptr + 2) * 0x00001); pixelptr += 4; if (idx == 0xFFFFFF) continue; // White is background; skip LDObject* obj = LDObject::fromID (idx); // If this is an additive single pick and the object is currently selected, // we remove it from selection instead. if (!m_rangepick && m_addpick) { int pos = g_win->sel().indexOf (obj); if (pos != -1) { g_win->sel().removeAt (i); obj->setSelected (false); removedObj = obj; break; } } g_win->sel() << obj; } delete[] pixeldata; // Remove duplicated entries removeDuplicates (g_win->sel()); // Update everything now. g_win->updateSelection(); // Recompile the objects now to update their color for (LDObject* obj : g_win->sel()) compileObject (obj); if (removedObj) compileObject (removedObj); // Restore line thickness glLineWidth (gl_linethickness); m_picking = false; m_rangepick = false; glEnable (GL_DITHER); setBackground(); repaint(); } // ============================================================================= // ----------------------------------------------------------------------------- READ_ACCESSOR (EditMode, GLRenderer::editMode) { return m_editMode; } // ============================================================================= // ----------------------------------------------------------------------------- SET_ACCESSOR (EditMode, GLRenderer::setEditMode) { m_editMode = val; switch (editMode()) { case Select: { unsetCursor(); setContextMenuPolicy (Qt::DefaultContextMenu); } break; case Draw: case CircleMode: { // Cannot draw into the free camera - use top instead. if (m_camera == Free) setCamera (Top); // Disable the context menu - we need the right mouse button // for removing vertices. setContextMenuPolicy (Qt::NoContextMenu); // Use the crosshair cursor when drawing. setCursor (Qt::CrossCursor); // Clear the selection when beginning to draw. // FIXME: make the selection clearing stuff in ::pick a method and use it // here! This code doesn't update the GL lists. g_win->sel().clear(); g_win->updateSelection(); m_drawedVerts.clear(); } break; } g_win->updateEditModeActions(); update(); } // ============================================================================= // ----------------------------------------------------------------------------- READ_ACCESSOR (LDFile*, GLRenderer::file) { return m_file; } // ============================================================================= // ----------------------------------------------------------------------------- SET_ACCESSOR (LDFile*, GLRenderer::setFile) { m_file = val; if (val != null) overlaysFromObjects(); } // ============================================================================= // ----------------------------------------------------------------------------- matrix GLRenderer::getCircleDrawMatrix (double scale) { matrix transform = g_circleDrawTransforms[camera() % 3]; for (int i = 0; i < 9; ++i) { if (transform[i] == 2) transform[i] = scale; elif (transform[i] == 1 && camera() >= 3) transform[i] = -1; } return transform; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::endDraw (bool accept) { (void) accept; // Clean the selection and create the object QList<vertex>& verts = m_drawedVerts; QList<LDObject*> objs; switch (editMode()) { case Draw: { if (m_rectdraw) { LDQuad* quad = new LDQuad; // Copy the vertices from m_rectverts updateRectVerts(); for (int i = 0; i < quad->vertices(); ++i) quad->setVertex (i, m_rectverts[i]); quad->setColor (maincolor); objs << quad; } else { switch (verts.size()) { case 1: { // 1 vertex - add a vertex object LDVertex* obj = new LDVertex; obj->pos = verts[0]; obj->setColor (maincolor); objs << obj; } break; case 2: { // 2 verts - make a line LDLine* obj = new LDLine (verts[0], verts[1]); obj->setColor (edgecolor); objs << obj; } break; case 3: case 4: { LDObject* obj = (verts.size() == 3) ? static_cast<LDObject*> (new LDTriangle) : static_cast<LDObject*> (new LDQuad); obj->setColor (maincolor); for (int i = 0; i < obj->vertices(); ++i) obj->setVertex (i, verts[i]); objs << obj; } break; } } } break; case CircleMode: { const int segs = lores, divs = lores; // TODO: make customizable double dist0 = circleDrawDist (0), dist1 = circleDrawDist (1); LDFile* refFile = null; matrix transform; bool circleOrDisc = false; if (dist1 < dist0) std::swap<double> (dist0, dist1); if (dist0 == dist1) { // If the radii are the same, there's no ring space to fill. Use a circle. refFile = getFile ("4-4edge.dat"); transform = getCircleDrawMatrix (dist0); circleOrDisc = true; } elif (dist0 == 0 || dist1 == 0) { // If either radii is 0, use a disc. refFile = getFile ("4-4disc.dat"); transform = getCircleDrawMatrix ((dist0 != 0) ? dist0 : dist1); circleOrDisc = true; } elif (g_RingFinder (dist0, dist1)) { // The ring finder found a solution, use that. Add the component rings to the file. for (const RingFinder::Component& cmp : g_RingFinder.bestSolution()->components()) { if ((refFile = getFile (radialFileName (::Ring, lores, lores, cmp.num))) == null) { refFile = generatePrimitive (::Ring, lores, lores, cmp.num); refFile->setImplicit (false); } LDSubfile* ref = new LDSubfile; ref->setFileInfo (refFile); ref->setTransform (getCircleDrawMatrix (cmp.scale)); ref->setPosition (m_drawedVerts[0]); ref->setColor (maincolor); objs << ref; } } else { // Last resort: draw the ring with quads QList<QLineF> c0, c1; Axis relX, relY, relZ; getRelativeAxes (relX, relY); relZ = (Axis) (3 - relX - relY); double x0 = m_drawedVerts[0][relX], y0 = m_drawedVerts[0][relY]; vertex templ; templ[relX] = x0; templ[relY] = y0; templ[relZ] = depthValue(); // Calculate circle coords makeCircle (segs, divs, dist0, c0); makeCircle (segs, divs, dist1, c1); for (int i = 0; i < segs; ++i) { vertex v0, v1, v2, v3; v0 = v1 = v2 = v3 = templ; v0[relX] += c0[i].x1(); v0[relY] += c0[i].y1(); v1[relX] += c0[i].x2(); v1[relY] += c0[i].y2(); v2[relX] += c1[i].x2(); v2[relY] += c1[i].y2(); v3[relX] += c1[i].x1(); v3[relY] += c1[i].y1(); LDQuad* q = new LDQuad (v0, v1, v2, v3); q->setColor (maincolor); // Ensure the quads always are BFC-front towards the camera if (camera() % 3 <= 0) q->invert(); objs << q; } } if (circleOrDisc) { LDSubfile* ref = new LDSubfile; ref->setFileInfo (refFile); ref->setTransform (transform); ref->setPosition (m_drawedVerts[0]); ref->setColor (maincolor); objs << ref; } } break; case Select: { assert (false); return; } break; } if (objs.size() > 0) { g_win->beginAction (null); for (LDObject* obj : objs) { file()->addObject (obj); compileObject (obj); } g_win->refresh(); g_win->endAction(); } m_drawedVerts.clear(); m_rectdraw = false; } // ============================================================================= // ----------------------------------------------------------------------------- double GLRenderer::circleDrawDist (int pos) const { assert (m_drawedVerts.size() >= pos + 1); const vertex& v1 = (m_drawedVerts.size() >= pos + 2) ? m_drawedVerts[pos + 1] : m_hoverpos; Axis relX, relY; getRelativeAxes (relX, relY); const double dx = m_drawedVerts[0][relX] - v1[relX]; const double dy = m_drawedVerts[0][relY] - v1[relY]; return sqrt ((dx * dx) + (dy * dy)); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::getRelativeAxes (Axis& relX, Axis& relY) const { const LDFixedCameraInfo* cam = &g_FixedCameras[m_camera]; relX = cam->axisX; relY = cam->axisY; } // ============================================================================= // ----------------------------------------------------------------------------- static QList<vertex> getVertices (LDObject* obj) { QList<vertex> verts; if (obj->vertices() >= 2) { for (int i = 0; i < obj->vertices(); ++i) verts << obj->getVertex (i); } elif (obj->getType() == LDObject::Subfile) { LDSubfile* ref = static_cast<LDSubfile*> (obj); QList<LDObject*> objs = ref->inlineContents (LDSubfile::DeepCacheInline); for (LDObject * obj : objs) { verts << getVertices (obj); delete obj; } } return verts; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::compileObject (LDObject* obj) { deleteLists (obj); for (const GL::ListType listType : g_glListTypes) { if (drawOnly() && listType != GL::NormalList) continue; GLuint list = glGenLists (1); glNewList (list, GL_COMPILE); obj->glLists[listType] = list; compileList (obj, listType); glEndList(); } // Mark in known vertices of this object QList<vertex> verts = getVertices (obj); m_knownVerts << verts; removeDuplicates (m_knownVerts); obj->m_glinit = true; } // ============================================================================= // ----------------------------------------------------------------------------- uchar* GLRenderer::screencap (int& w, int& h) { w = m_width; h = m_height; uchar* cap = new uchar[4 * w * h]; m_screencap = true; update(); m_screencap = false; // Capture the pixels glReadPixels (0, 0, w, h, GL_RGBA, GL_UNSIGNED_BYTE, cap); return cap; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::slot_toolTipTimer() { // We come here if the cursor has stayed in one place for longer than a // a second. Check if we're holding it over a camera icon - if so, draw // a tooltip. for (CameraIcon & icon : m_cameraIcons) { if (icon.destRect.contains (m_pos)) { m_toolTipCamera = icon.cam; m_drawToolTip = true; update(); break; } } } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::deleteLists (LDObject* obj) { // Delete the lists but only if they have been initialized if (!obj->m_glinit) return; for (const GL::ListType listType : g_glListTypes) glDeleteLists (obj->glLists[listType], 1); obj->m_glinit = false; } // ============================================================================= // ----------------------------------------------------------------------------- Axis GLRenderer::cameraAxis (bool y, GL::Camera camid) { if (camid == (GL::Camera) - 1) camid = m_camera; const LDFixedCameraInfo* cam = &g_FixedCameras[camid]; return (y) ? cam->axisY : cam->axisX; } // ============================================================================= // ----------------------------------------------------------------------------- bool GLRenderer::setupOverlay (GL::Camera cam, str file, int x, int y, int w, int h) { QImage* img = new QImage (file); LDGLOverlay& info = getOverlay (cam); if (img->isNull()) { critical (tr ("Failed to load overlay image!")); delete img; return false; } delete info.img; // delete the old image info.fname = file; info.lw = w; info.lh = h; info.ox = x; info.oy = y; info.img = img; if (info.lw == 0) info.lw = (info.lh * img->width()) / img->height(); elif (info.lh == 0) info.lh = (info.lw * img->height()) / img->width(); const Axis x2d = cameraAxis (false, cam), y2d = cameraAxis (true, cam); double negXFac = g_FixedCameras[cam].negX ? -1 : 1, negYFac = g_FixedCameras[cam].negY ? -1 : 1; info.v0 = info.v1 = g_origin; info.v0[x2d] = - (info.ox * info.lw * negXFac) / img->width(); info.v0[y2d] = (info.oy * info.lh * negYFac) / img->height(); info.v1[x2d] = info.v0[x2d] + info.lw; info.v1[y2d] = info.v0[y2d] + info.lh; // Set alpha of all pixels to 0.5 for (long i = 0; i < img->width(); ++i) for (long j = 0; j < img->height(); ++j) { uint32 pixel = img->pixel (i, j); img->setPixel (i, j, 0x80000000 | (pixel & 0x00FFFFFF)); } updateOverlayObjects(); return true; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::clearOverlay() { if (camera() == Free) return; LDGLOverlay& info = m_overlays[camera()]; delete info.img; info.img = null; updateOverlayObjects(); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::setDepthValue (double depth) { assert (camera() < Free); m_depthValues[camera()] = depth; } // ============================================================================= // ----------------------------------------------------------------------------- double GLRenderer::depthValue() const { assert (camera() < Free); return m_depthValues[camera()]; } // ============================================================================= // ----------------------------------------------------------------------------- const char* GLRenderer::cameraName() const { return g_CameraNames[camera()]; } // ============================================================================= // ----------------------------------------------------------------------------- LDGLOverlay& GLRenderer::getOverlay (int newcam) { return m_overlays[newcam]; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::zoomNotch (bool inward) { if (zoom() > 15) setZoom (zoom() * (inward ? 0.833f : 1.2f)); else setZoom (zoom() + (inward ? -1.2f : 1.2f)); } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::zoomToFit() { if (file() == null) { setZoom (30.0f); return; } bool lastfilled = false; bool firstrun = true; const uint32 white = 0xFFFFFFFF; bool inward = true; int run = 0; const int w = m_width, h = m_height; glClearColor (1.0, 1.0, 1.0, 1.0); glDisable (GL_DITHER); // Use the pick list while drawing the scene, this way we can tell whether borders // are background or not. m_picking = true; for (;;) { if (zoom() > 10000.0f || zoom() < 0.0f) { // Obviously, there's nothing to draw if we get here. // Default to 30.0f and break out. setZoom (30.0f); break; } zoomNotch (inward); uchar* cap = new uchar[4 * w * h]; drawGLScene(); glReadPixels (0, 0, w, h, GL_RGBA, GL_UNSIGNED_BYTE, cap); uint32* imgdata = reinterpret_cast<uint32*> (cap); bool filled = false; // Check the top and bottom rows for (int i = 0; i < w && !filled; ++i) if (imgdata[i] != white || imgdata[ ( (h - 1) * w) + i] != white) filled = true; // Left and right edges for (int i = 0; i < h && !filled; ++i) if (imgdata[i * w] != white || imgdata[ (i * w) + (w - 1)] != white) filled = true; if (firstrun) { // If this is the first run, we don't know enough to determine // whether the zoom was to fit, so we mark in our knowledge so // far and start over. inward = !filled; firstrun = false; } else { // If this run filled the screen and the last one did not, the // last run had ideal zoom - zoom a bit back and we should reach it. if (filled && !lastfilled) { zoomNotch (false); break; } // If this run did not fill the screen and the last one did, we've // now reached ideal zoom so we're done here. if (!filled && lastfilled) break; inward = !filled; } delete[] cap; lastfilled = filled; ++run; } setBackground(); m_picking = false; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::updateRectVerts() { if (!m_rectdraw) return; if (m_drawedVerts.size() == 0) { for (int i = 0; i < 4; ++i) m_rectverts[i] = m_hoverpos; return; } vertex v0 = m_drawedVerts[0], v1 = (m_drawedVerts.size() >= 2) ? m_drawedVerts[1] : m_hoverpos; const Axis ax = cameraAxis (false), ay = cameraAxis (true), az = (Axis) (3 - ax - ay); for (int i = 0; i < 4; ++i) m_rectverts[i][az] = depthValue(); m_rectverts[0][ax] = v0[ax]; m_rectverts[0][ay] = v0[ay]; m_rectverts[1][ax] = v1[ax]; m_rectverts[1][ay] = v0[ay]; m_rectverts[2][ax] = v1[ax]; m_rectverts[2][ay] = v1[ay]; m_rectverts[3][ax] = v0[ax]; m_rectverts[3][ay] = v1[ay]; } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::mouseDoubleClickEvent (QMouseEvent* ev) { if (! (ev->buttons() & Qt::LeftButton) || editMode() != Select) return; pick (ev->x(), ev->y()); if (g_win->sel().size() == 0) return; g_win->beginAction (null); LDObject* obj = g_win->sel() [0]; AddObjectDialog::staticDialog (obj->getType(), obj); g_win->endAction(); ev->accept(); } // ============================================================================= // ----------------------------------------------------------------------------- LDOverlay* GLRenderer::findOverlayObject (GLRenderer::Camera cam) { LDOverlay* ovlobj = null; for (LDObject * obj : file()->objects()) { if (obj->getType() == LDObject::Overlay && static_cast<LDOverlay*> (obj)->camera() == cam) { ovlobj = static_cast<LDOverlay*> (obj); break; } } return ovlobj; } // ============================================================================= // ----------------------------------------------------------------------------- // Read in overlays from the current file and update overlay info accordingly. // ----------------------------------------------------------------------------- void GLRenderer::overlaysFromObjects() { for (Camera cam : g_Cameras) { if (cam == Free) continue; LDGLOverlay& meta = m_overlays[cam]; LDOverlay* ovlobj = findOverlayObject (cam); if (!ovlobj && meta.img) { delete meta.img; meta.img = null; } elif (ovlobj && (!meta.img || meta.fname != ovlobj->filename())) setupOverlay (cam, ovlobj->filename(), ovlobj->x(), ovlobj->y(), ovlobj->width(), ovlobj->height()); } } // ============================================================================= // ----------------------------------------------------------------------------- void GLRenderer::updateOverlayObjects() { for (Camera cam : g_Cameras) { if (cam == Free) continue; LDGLOverlay& meta = m_overlays[cam]; LDOverlay* ovlobj = findOverlayObject (cam); if (!meta.img && ovlobj) { // If this is the last overlay image, we need to remove the empty space after it as well. LDObject* nextobj = ovlobj->next(); if (nextobj && nextobj->getType() == LDObject::Empty) { m_file->forgetObject (nextobj); delete nextobj; } // If the overlay object was there and the overlay itself is // not, remove the object. m_file->forgetObject (ovlobj); delete ovlobj; } elif (meta.img && !ovlobj) { // Inverse case: image is there but the overlay object is // not, thus create the object. ovlobj = new LDOverlay; // Find a suitable position to place this object. We want to place // this into the header, which is everything up to the first scemantic // object. If we find another overlay object, place this object after // the last one found. Otherwise, place it before the first schemantic // object and put an empty object after it (though don't do this if // there was no schemantic elements at all) int i, lastOverlay = -1; bool found = false; for (i = 0; i < file()->numObjs(); ++i) { LDObject* obj = file()->obj (i); if (obj->isScemantic()) { found = true; break; } if (obj->getType() == LDObject::Overlay) lastOverlay = i; } if (lastOverlay != -1) file()->insertObj (lastOverlay + 1, ovlobj); else { file()->insertObj (i, ovlobj); if (found) file()->insertObj (i + 1, new LDEmpty); } } if (meta.img && ovlobj) { ovlobj->setCamera (cam); ovlobj->setFilename (meta.fname); ovlobj->setX (meta.ox); ovlobj->setY (meta.oy); ovlobj->setWidth (meta.lw); ovlobj->setHeight (meta.lh); } } if (g_win->R() == this) g_win->refresh(); }