/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * 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 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * */ #include "common/algorithm.h" #include "common/util.h" #include "graphics/primitives.h" namespace Graphics { void drawLine(int x0, int y0, int x1, int y1, int color, void (*plotProc)(int, int, int, void *), void *data) { // Bresenham's line algorithm, as described by Wikipedia const bool steep = ABS(y1 - y0) > ABS(x1 - x0); if (steep) { SWAP(x0, y0); SWAP(x1, y1); } const int delta_x = ABS(x1 - x0); const int delta_y = ABS(y1 - y0); const int delta_err = delta_y; int x = x0; int y = y0; int err = 0; const int x_step = (x0 < x1) ? 1 : -1; const int y_step = (y0 < y1) ? 1 : -1; if (steep) (*plotProc)(y, x, color, data); else (*plotProc)(x, y, color, data); while (x != x1) { x += x_step; err += delta_err; if (2 * err > delta_x) { y += y_step; err -= delta_x; } if (steep) (*plotProc)(y, x, color, data); else (*plotProc)(x, y, color, data); } } void drawHLine(int x1, int x2, int y, int color, void (*plotProc)(int, int, int, void *), void *data) { if (x1 > x2) SWAP(x1, x2); for (int x = x1; x <= x2; x++) (*plotProc)(x, y, color, data); } void drawVLine(int x, int y1, int y2, int color, void (*plotProc)(int, int, int, void *), void *data) { if (y1 > y2) SWAP(y1, y2); for (int y = y1; y <= y2; y++) (*plotProc)(x, y, color, data); } void drawThickLine(int x0, int y0, int x1, int y1, int penX, int penY, int color, void (*plotProc)(int, int, int, void *), void *data) { assert(penX > 0 && penY > 0); // Shortcut if (penX == 1 && penY == 1) { drawLine(x0, y0, x1, y1, color, plotProc, data); return; } // TODO: Optimize this. It currently is a very naive way of handling // thick lines since quite often it will be drawing to the same pixel // multiple times. for (int x = 0; x < penX; x++) for (int y = 0; y < penY; y++) drawLine(x0 + x, y0 + y, x1 + x, y1 + y, color, plotProc, data); } /* Bresenham as presented in Foley & Van Dam */ /* Code is based on GD lib http://libgd.github.io/ */ void drawThickLine2(int x1, int y1, int x2, int y2, int thick, int color, void (*plotProc)(int, int, int, void *), void *data) { int incr1, incr2, d, x, y, xend, yend, xdirflag, ydirflag; int wid; int w, wstart; int dx = abs(x2 - x1); int dy = abs(y2 - y1); if (dx == 0) { int xn = x1 - thick / 2; Common::Rect r(xn, MIN(y1, y2), xn + thick - 1, MAX(y1, y2)); drawFilledRect(r, color, plotProc, data); return; } else if (dy == 0) { int yn = y1 - thick / 2; Common::Rect r(MIN(x1, x2), yn, MAX(x1, x2), yn + thick - 1); drawFilledRect(r, color, plotProc, data); return; } if (dy <= dx) { /* More-or-less horizontal. use wid for vertical stroke */ /* 2.0.12: Michael Schwartz: divide rather than multiply; TBB: but watch out for /0! */ if (dx != 0 && thick != 0) { double ac_recip = 1/dx * sqrt((double)(dx * dx + dy * dy)); // 1 / cos(atan2((double)dy, (double)dx)); wid = thick * ac_recip; } else { wid = 1; } d = 2 * dy - dx; incr1 = 2 * dy; incr2 = 2 * (dy - dx); if (x1 > x2) { x = x2; y = y2; ydirflag = (-1); xend = x1; } else { x = x1; y = y1; ydirflag = 1; xend = x2; } /* Set up line thickness */ wstart = y - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(x, y, color, data); if (((y2 - y1) * ydirflag) > 0) { while (x < xend) { x++; if (d < 0) { d += incr1; } else { y++; d += incr2; } wstart = y - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(x, w, color, data); } } else { while (x < xend) { x++; if (d < 0) { d += incr1; } else { y--; d += incr2; } wstart = y - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(x, w, color, data); } } } else { /* More-or-less vertical. use wid for horizontal stroke */ /* 2.0.12: Michael Schwartz: divide rather than multiply; TBB: but watch out for /0! */ if (dy != 0 && thick != 0) { double as_recip = 1/dy * sqrt((double)(dx * dx + dy * dy)); // 1 / sin(atan2((double)dy, (double)dx)); wid = thick * as_recip; } else { wid = 1; } d = 2 * dx - dy; incr1 = 2 * dx; incr2 = 2 * (dx - dy); if (y1 > y2) { y = y2; x = x2; yend = y1; xdirflag = (-1); } else { y = y1; x = x1; yend = y2; xdirflag = 1; } /* Set up line thickness */ wstart = x - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(w, y, color, data); if (((x2 - x1) * xdirflag) > 0) { while (y < yend) { y++; if (d < 0) { d += incr1; } else { x++; d += incr2; } wstart = x - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(w, y, color, data); } } else { while (y < yend) { y++; if (d < 0) { d += incr1; } else { x--; d += incr2; } wstart = x - wid / 2; for (w = wstart; w < wstart + wid; w++) (*plotProc)(w, y, color, data); } } } } void drawFilledRect(Common::Rect &rect, int color, void (*plotProc)(int, int, int, void *), void *data) { for (int y = rect.top; y <= rect.bottom; y++) drawHLine(rect.left, rect.right, y, color, plotProc, data); } void drawRect(Common::Rect &rect, int color, void (*plotProc)(int, int, int, void *), void *data) { drawHLine(rect.left, rect.right, rect.top, color, plotProc, data); drawHLine(rect.left, rect.right, rect.bottom, color, plotProc, data); drawVLine(rect.left, rect.top, rect.bottom, color, plotProc, data); drawVLine(rect.right, rect.top, rect.bottom, color, plotProc, data); } // http://members.chello.at/easyfilter/bresenham.html void drawRoundRect(Common::Rect &rect, int arc, int color, bool filled, void (*plotProc)(int, int, int, void *), void *data) { if (rect.height() < rect.width()) { int x = -arc, y = 0, err = 2-2*arc; /* II. Quadrant */ int dy = rect.height() - arc * 2; int r = arc; int stop = 0; int lastx = 0, lasty = 0; if (dy < 0) stop = -dy / 2; do { if (filled) { drawHLine(rect.left + x + r, rect.right - x - r, rect.top - y + r - stop, color, plotProc, data); drawHLine(rect.left + x + r, rect.right - x - r, rect.bottom + y - r + stop, color, plotProc, data); } else { (*plotProc)(rect.left + x + r, rect.top - y + r - stop, color, data); (*plotProc)(rect.right - x - r, rect.top - y + r - stop, color, data); (*plotProc)(rect.left + x + r, rect.bottom + y - r + stop, color, data); (*plotProc)(rect.right - x - r, rect.bottom + y - r + stop, color, data); lastx = x; lasty = y; } arc = err; if (arc <= y) err += ++y*2+1; /* e_xy+e_y < 0 */ if (arc > x || err > y) err += ++x*2+1; /* e_xy+e_x > 0 or no 2nd y-step */ if (stop && y > stop) break; } while (x < 0); if (!filled) { x = lastx; y = lasty; drawHLine(rect.left + x + r, rect.right - x - r, rect.top - y + r - stop, color, plotProc, data); drawHLine(rect.left + x + r, rect.right - x - r, rect.bottom + y - r + stop, color, plotProc, data); } for (int i = 0; i < dy; i++) { if (filled) { drawHLine(rect.left, rect.right, rect.top + r + i, color, plotProc, data); } else { (*plotProc)(rect.left, rect.top + r + i, color, data); (*plotProc)(rect.right, rect.top + r + i, color, data); } } } else { int y = -arc, x = 0, err = 2-2*arc; /* II. Quadrant */ int dx = rect.width() - arc * 2; int r = arc; int stop = 0; int lastx = 0, lasty = 0; if (dx < 0) stop = -dx / 2; do { if (filled) { drawVLine(rect.left - x + r - stop, rect.top + y + r, rect.bottom - y - r, color, plotProc, data); drawVLine(rect.right + x - r + stop, rect.top + y + r, rect.bottom - y - r, color, plotProc, data); } else { (*plotProc)(rect.left - x + r - stop, rect.top + y + r, color, data); (*plotProc)(rect.left - x + r - stop, rect.bottom - y - r, color, data); (*plotProc)(rect.right + x - r + stop, rect.top + y + r, color, data); (*plotProc)(rect.right + x - r + stop, rect.bottom - y - r, color, data); lastx = x; lasty = y; } arc = err; if (arc <= x) err += ++x*2+1; /* e_xy+e_y < 0 */ if (arc > y || err > x) err += ++y*2+1; /* e_xy+e_x > 0 or no 2nd y-step */ if (stop && x > stop) break; } while (y < 0); if (!filled) { x = lastx; y = lasty; drawVLine(rect.left - x + r - stop, rect.top + y + r, rect.bottom - y - r, color, plotProc, data); drawVLine(rect.right + x - r + stop, rect.top + y + r, rect.bottom - y - r, color, plotProc, data); } for (int i = 0; i < dx; i++) { if (filled) { drawVLine(rect.left + r + i, rect.top, rect.bottom, color, plotProc, data); } else { (*plotProc)(rect.left + r + i, rect.top, color, data); (*plotProc)(rect.left + r + i, rect.bottom, color, data); } } } } // Based on public-domain code by Darel Rex Finley, 2007 // http://alienryderflex.com/polygon_fill/ void drawPolygonScan(int *polyX, int *polyY, int npoints, Common::Rect &bbox, int color, void (*plotProc)(int, int, int, void *), void *data) { int *nodeX = (int *)calloc(npoints, sizeof(int)); int i, j; // Loop through the rows of the image. for (int pixelY = bbox.top; pixelY < bbox.bottom; pixelY++) { // Build a list of nodes. int nodes = 0; j = npoints - 1; for (i = 0; i < npoints; i++) { if ((polyY[i] < pixelY && polyY[j] >= pixelY) || (polyY[j] < pixelY && polyY[i] >= pixelY)) { nodeX[nodes++] = (int)(polyX[i] + (double)(pixelY - polyY[i]) / (double)(polyY[j]-polyY[i]) * (double)(polyX[j] - polyX[i]) + 0.5); } j = i; } // Sort the nodes Common::sort(nodeX, &nodeX[nodes]); // Fill the pixels between node pairs. for (i = 0; i < nodes; i += 2) { if (nodeX[i ] >= bbox.right) break; if (nodeX[i + 1] > bbox.left) { nodeX[i] = MAX(nodeX[i], bbox.left); nodeX[i + 1] = MIN(nodeX[i + 1], bbox.right); drawHLine(nodeX[i], nodeX[i + 1], pixelY, color, plotProc, data); } } } free(nodeX); } // http://members.chello.at/easyfilter/bresenham.html void drawEllipse(int x0, int y0, int x1, int y1, int color, bool filled, void (*plotProc)(int, int, int, void *), void *data) { int a = abs(x1 - x0), b = abs(y1 - y0), b1 = b & 1; /* values of diameter */ long dx = 4 * (1 - a) * b * b, dy = 4 * (b1 + 1) * a * a; /* error increment */ long err = dx + dy + b1 * a * a, e2; /* error of 1.step */ if (x0 > x1) { x0 = x1; x1 += a; } /* if called with swapped points */ if (y0 > y1) y0 = y1; /* .. exchange them */ y0 += (b + 1) / 2; y1 = y0 - b1; /* starting pixel */ a *= 8 * a; b1 = 8 * b * b; do { if (filled) { drawHLine(x0, x1, y0, color, plotProc, data); drawHLine(x0, x1, y1, color, plotProc, data); } else { (*plotProc)(x1, y0, color, data); /* I. Quadrant */ (*plotProc)(x0, y0, color, data); /* II. Quadrant */ (*plotProc)(x0, y1, color, data); /* III. Quadrant */ (*plotProc)(x1, y1, color, data); /* IV. Quadrant */ } e2 = 2*err; if (e2 <= dy) { y0++; y1--; err += dy += a; } /* y step */ if (e2 >= dx || 2*err > dy) { x0++; x1--; err += dx += b1; } /* x step */ } while (x0 <= x1); while (y0-y1 < b) { /* too early stop of flat ellipses a=1 */ if (filled) { drawHLine(x0 - 1, x0 - 1, y0, color, plotProc, data); /* -> finish tip of ellipse */ drawHLine(x1 + 1, x1 + 1, y0, color, plotProc, data); drawHLine(x0 - 1, x0 - 1, y1, color, plotProc, data); drawHLine(x1 + 1, x1 + 1, y1, color, plotProc, data); } else { (*plotProc)(x0 - 1, y0, color, data); /* -> finish tip of ellipse */ (*plotProc)(x1 + 1, y0, color, data); (*plotProc)(x0 - 1, y1, color, data); (*plotProc)(x1 + 1, y1, color, data); } y0++; y1--; } } } // End of namespace Graphics