/* Copyright (C) 2007, 2010 - Bit-Blot This file is part of Aquaria. Aquaria 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 2 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, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "Quad.h" #include "Core.h" #include "RenderBase.h" #include Vector Quad::renderBorderColor = Vector(1,1,1); Quad::Quad(const std::string &tex, const Vector &pos) : RenderObject() { initQuad(); position = pos; setTexture(tex); } void Quad::setSegs(int x, int y, float dgox, float dgoy, float dgmx, float dgmy, float dgtm, bool dgo) { deleteGrid(); if (x == 0 || y == 0) { doUpdateGrid = false; } else { doUpdateGrid = true; this->drawGridOffsetX = dgox; this->drawGridOffsetY = dgoy; this->drawGridModX = dgmx; this->drawGridModY = dgmy; this->drawGridTimeMultiplier = dgtm; drawGridOut = dgo; createGrid(x, y); } gridTimer = 0; } void Quad::createGrid(int xd, int yd) { drawGrid.init(xd, yd); resetGrid(); Vector *dg = drawGrid.data(); for(size_t i = 0; i < drawGrid.linearsize(); ++i) dg[i].z = 1.0f; } void Quad::setDrawGridAlpha(size_t x, size_t y, float alpha) { if (x < drawGrid.width() && y < drawGrid.height()) { drawGrid(x, y).z = alpha; } } void Quad::setStripPoints(bool vert, const Vector *points, size_t n) { if (drawGrid.empty()) return; resetGrid(); const float mul = float(n); if (!vert) // horz { const size_t xmax = std::min(drawGrid.width(), n); for (size_t y = 0; y < drawGrid.height(); y++) { Vector *row = drawGrid.row(y); for (size_t x = 0; x < xmax; x++) row[x] += points[x] * mul; } } else { const size_t ymax = std::min(drawGrid.height(), n); for (size_t x = 0; x < drawGrid.width(); x++) for (size_t y = 0; y < ymax; y++) drawGrid(x, y) += points[y] * mul; } } void Quad::resetGrid() { const float yMulF = 1.0f / (float)(drawGrid.height()-1); const float xMulF = 1.0f / (float)(drawGrid.width()-1); for (size_t y = 0; y < drawGrid.height(); y++) { Vector *row = drawGrid.row(y); const float yval = float(y)*yMulF-0.5f; for (size_t x = 0; x < drawGrid.width(); x++) { row[x].x = float(x)*xMulF-0.5f; row[x].y = yval; } } } void Quad::initQuad() { repeatToFillScale = Vector(1,1); gridType = GRID_WAVY; gridTimer = 0; doUpdateGrid = false; autoWidth = autoHeight = 0; renderBorder = false; renderCenter = true; width = 2; height = 2; upperLeftTextureCoordinates = Vector(0,0); lowerRightTextureCoordinates = Vector(1,1); renderQuad = true; } Quad::Quad() : RenderObject() { addType(SCO_QUAD); borderAlpha = 0.5; initQuad(); } void Quad::deleteGrid() { drawGrid.clear(); } void Quad::destroy() { deleteGrid(); RenderObject::destroy(); } bool Quad::isCoordinateInside(Vector coord, int minSize) const { Vector realscale = getRealScale(); int hw = fabsf((width)*realscale.x)*0.5f; int hh = fabsf((height)*realscale.y)*0.5f; if (hw < minSize) hw = minSize; if (hh < minSize) hh = minSize; Vector pos = getRealPosition(); if (coord.x >= pos.x - hw && coord.x <= pos.x + hw) { if (coord.y >= pos.y - hh && coord.y <= pos.y + hh) { return true; } } return false; } bool Quad::isCoordinateInsideWorld(const Vector &coord, int minSize) const { int hw = fabsf((width)*getRealScale().x)*0.5f; int hh = fabsf((height)*getRealScale().y)*0.5f; if (hw < minSize) hw = minSize; if (hh < minSize) hh = minSize; Vector pos = getWorldPosition(); if (coord.x >= pos.x + offset.x - hw && coord.x <= pos.x + offset.x + hw) { if (coord.y >= pos.y + offset.y - hh && coord.y <= pos.y + offset.y + hh) { return true; } } return false; } bool Quad::isCoordinateInsideWorldRect(const Vector &coord, int w, int h) const { int hw = w*0.5f; int hh = h*0.5f; Vector pos = getWorldPosition(); if (coord.x >= pos.x + offset.x - hw && coord.x <= pos.x + offset.x + hw) { if (coord.y >= pos.y + offset.y - hh && coord.y <= pos.y + offset.y + hh) { return true; } } return false; } void Quad::updateGrid(float dt) { if (!doUpdateGrid) return; if (gridType == GRID_WAVY) { gridTimer += dt * drawGridTimeMultiplier; resetGrid(); size_t hx = drawGrid.width()/2; for (size_t x = 0; x < drawGrid.width(); x++) { float yoffset = x * drawGridOffsetY; float addY = 0; if (drawGridModY != 0) addY = cosf(gridTimer+yoffset)*drawGridModY; for (size_t y = 0; y < drawGrid.height(); y++) { float xoffset = y * drawGridOffsetX; if (drawGridModX != 0) { float addX = (sinf(gridTimer+xoffset)*drawGridModX); if (drawGridOut && x < hx) drawGrid(x,y).x += addX; else drawGrid(x,y).x -= addX; } drawGrid(x,y).y += addY; } } } } void Quad::renderGrid(const RenderState& rs) const { if (drawGrid.width() < 2 || drawGrid.height() < 2) return; const float percentX = fabsf(this->lowerRightTextureCoordinates.x - this->upperLeftTextureCoordinates.x); const float percentY = fabsf(this->upperLeftTextureCoordinates.y - this->lowerRightTextureCoordinates.y); const float baseX = (lowerRightTextureCoordinates.x < upperLeftTextureCoordinates.x) ? lowerRightTextureCoordinates.x : upperLeftTextureCoordinates.x; const float baseY = (lowerRightTextureCoordinates.y < upperLeftTextureCoordinates.y) ? lowerRightTextureCoordinates.y : upperLeftTextureCoordinates.y; const size_t NX = drawGrid.width()-1; const size_t NY = drawGrid.height()-1; // NOTE: These are used to avoid repeated expensive divide operations, // but they may cause rounding error of around 1 part per million, // which could in theory cause minor graphical glitches with broken // OpenGL implementations. --achurch const float incX = percentX / float(NX); const float incY = percentY / float(NY); const float w = this->getWidth(); const float h = this->getHeight(); const float red = rs.color.x * this->color.x; const float green = rs.color.y * this->color.y; const float blue = rs.color.z * this->color.z; const float alpha = rs.alpha * this->alpha.x * this->alphaMod; glBegin(GL_QUADS); float u0 = baseX; float u1 = u0 + incX; for (size_t x = 0; x < NX; x++, u0 = u1, u1 += incX) { float v0 = 1 - percentY + baseY; float v1 = v0 + incY; for (size_t y = 0; y < NY; y++, v0 = v1, v1 += incY) { if (drawGrid(x,y).z != 0 || drawGrid(x,y+1).z != 0 || drawGrid(x+1,y).z != 0 || drawGrid(x+1,y+1).z != 0) { glColor4f(red, green, blue, alpha*drawGrid(x,y).z); glTexCoord2f(u0, v0); glVertex2f(w*drawGrid(x,y).x, h*drawGrid(x,y).y); glColor4f(red, green, blue, alpha*drawGrid(x,y+1).z); glTexCoord2f(u0, v1); glVertex2f(w*drawGrid(x,y+1).x, h*drawGrid(x,y+1).y); glColor4f(red, green, blue, alpha*drawGrid(x+1,y+1).z); glTexCoord2f(u1, v1); glVertex2f(w*drawGrid(x+1,y+1).x, h*drawGrid(x+1,y+1).y); glColor4f(red, green, blue, alpha*drawGrid(x+1,y).z); glTexCoord2f(u1, v0); glVertex2f(w*drawGrid(x+1,y).x, h*drawGrid(x+1,y).y); } } } glEnd(); // debug points if (RenderObject::renderCollisionShape) { glBindTexture(GL_TEXTURE_2D, 0); glPointSize(2); glColor3f(1,0,0); glBegin(GL_POINTS); for (size_t x = 0; x < NX; x++) { for (size_t y = 0; y < NY; y++) { glVertex2f(w*drawGrid(x,y).x, h*drawGrid(x,y).y); glVertex2f(w*drawGrid(x,y+1).x, h*drawGrid(x,y+1).y); glVertex2f(w*drawGrid(x+1,y+1).x, h*drawGrid(x+1,y+1).y); glVertex2f(w*drawGrid(x+1,y).x, h*drawGrid(x+1,y).y); } } glEnd(); if (texture) glBindTexture(GL_TEXTURE_2D, texture->textures[0]); } } void Quad::repeatTextureToFill(bool on) { repeatTexture = on; refreshRepeatTextureToFill(); } void Quad::onRender(const RenderState& rs) const { if (!renderQuad) return; const float _w2 = width*0.5f; const float _h2 = height*0.5f; if (drawGrid.empty()) { glBegin(GL_QUADS); { glTexCoord2f(upperLeftTextureCoordinates.x, 1.0f-upperLeftTextureCoordinates.y); glVertex2f(-_w2, +_h2); glTexCoord2f(lowerRightTextureCoordinates.x, 1.0f-upperLeftTextureCoordinates.y); glVertex2f(+_w2, +_h2); glTexCoord2f(lowerRightTextureCoordinates.x, 1.0f-lowerRightTextureCoordinates.y); glVertex2f(+_w2, -_h2); glTexCoord2f(upperLeftTextureCoordinates.x, 1.0f-lowerRightTextureCoordinates.y); glVertex2f(-_w2, -_h2); } glEnd(); } else { renderGrid(rs); } if (renderBorder) { glLineWidth(2); glBindTexture(GL_TEXTURE_2D, 0); glColor4f(renderBorderColor.x, renderBorderColor.y, renderBorderColor.z, borderAlpha*alpha.x*alphaMod); if (renderCenter) { glPointSize(16); glBegin(GL_POINTS); glVertex2f(0,0); glEnd(); } glColor4f(renderBorderColor.x, renderBorderColor.y, renderBorderColor.z, 1*alpha.x*alphaMod); glBegin(GL_LINES); glVertex2f(-_w2, _h2); glVertex2f(_w2, _h2); glVertex2f(_w2, -_h2); glVertex2f(_w2, _h2); glVertex2f(-_w2, -_h2); glVertex2f(-_w2, _h2); glVertex2f(-_w2, -_h2); glVertex2f(_w2, -_h2); glEnd(); RenderObject::lastTextureApplied = 0; } } void Quad::flipHorizontal() { RenderObject::flipHorizontal(); } void Quad::flipVertical() { if (!_fv) { lowerRightTextureCoordinates.y = 0; upperLeftTextureCoordinates.y = 1; } else { lowerRightTextureCoordinates.y = 1; upperLeftTextureCoordinates.y = 0; } RenderObject::flipVertical(); } void Quad::refreshRepeatTextureToFill() { if (repeatTexture && texture) { upperLeftTextureCoordinates.x = texOff.x; upperLeftTextureCoordinates.y = texOff.y; lowerRightTextureCoordinates.x = (width*scale.x*repeatToFillScale.x)/texture->width + texOff.x; lowerRightTextureCoordinates.y = (height*scale.y*repeatToFillScale.y)/texture->height + texOff.y; } else { if (fabsf(lowerRightTextureCoordinates.x) > 1 || fabsf(lowerRightTextureCoordinates.y)>1) lowerRightTextureCoordinates = Vector(1,1); } } void Quad::reloadDevice() { RenderObject::reloadDevice(); } void Quad::onUpdate(float dt) { RenderObject::onUpdate(dt); if (autoWidth == AUTO_VIRTUALWIDTH) width = core->getVirtualWidth(); else if (autoWidth == AUTO_VIRTUALHEIGHT) width = core->getVirtualHeight(); if (autoHeight == AUTO_VIRTUALWIDTH) height = core->getVirtualWidth(); else if (autoHeight == AUTO_VIRTUALHEIGHT) height = core->getVirtualHeight(); refreshRepeatTextureToFill(); lowerRightTextureCoordinates.update(dt); upperLeftTextureCoordinates.update(dt); if (!drawGrid.empty() && alpha.x > 0 && alphaMod > 0) { updateGrid(dt); } } void Quad::setWidthHeight(float w, float h) { if (h == -1) height = w; else height = h; width = w; } void Quad::setWidth(float w) { width = w; } void Quad::setHeight(float h) { height = h; } void Quad::onSetTexture() { if (texture) { width = this->texture->width; height = this->texture->height; } else { width = 64; height = 64; } } PauseQuad::PauseQuad() : Quad(), pauseLevel(0), positionSnapTo(0) { addType(SCO_PAUSEQUAD); } PauseQuad::~PauseQuad() { } void PauseQuad::onUpdate(float dt) { if (positionSnapTo) this->position = *positionSnapTo; if (core->particlesPaused <= pauseLevel) { Quad::onUpdate(dt); } } void PauseQuad::setPositionSnapTo(InterpolatedVector *positionSnapTo) { this->positionSnapTo = positionSnapTo; } CollideQuad::CollideQuad() : collideRadius(0) { addType(SCO_COLLIDE_QUAD); } CollideQuad::~CollideQuad() { } void CollideQuad::renderCollision(const RenderState& rs) const { if (collideRadius > 0) { glPushMatrix(); glLoadIdentity(); core->setupRenderPositionAndScale(); glBindTexture(GL_TEXTURE_2D, 0); glTranslatef(position.x+offset.x, position.y+offset.y, 0); glTranslatef(internalOffset.x, internalOffset.y, 0); glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); glColor4f(1,0,0,0.5); drawCircle(collideRadius, 8); glDisable(GL_BLEND); glTranslatef(offset.x, offset.y,0); glPopMatrix(); } }