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498 lines
15 KiB
C++
498 lines
15 KiB
C++
// -*- C++ -*-
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/* Copyright (C) 1989, 1990, 1991, 1992 Free Software Foundation, Inc.
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Written by James Clark (jjc@jclark.com)
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This file is part of groff.
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groff is free software; you can redistribute it and/or modify it under
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the terms of the GNU General Public License as published by the Free
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Software Foundation; either version 2, or (at your option) any later
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version.
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groff is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or
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FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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for more details.
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You should have received a copy of the GNU General Public License along
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with groff; see the file COPYING. If not, write to the Free Software
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Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
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#include "pic.h"
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#include "common.h"
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// output a dashed circle as a series of arcs
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void common_output::dashed_circle(const position ¢, double rad,
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const line_type <)
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{
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assert(lt.type == line_type::dashed);
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line_type slt = lt;
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slt.type = line_type::solid;
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double dash_angle = lt.dash_width/rad;
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int ndashes;
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double gap_angle;
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if (dash_angle >= M_PI/4.0) {
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if (dash_angle < M_PI/2.0) {
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gap_angle = M_PI/2.0 - dash_angle;
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ndashes = 4;
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}
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else if (dash_angle < M_PI) {
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gap_angle = M_PI - dash_angle;
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ndashes = 2;
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}
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else {
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circle(cent, rad, slt, -1.0);
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return;
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}
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}
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else {
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ndashes = 4*int(ceil(M_PI/(4.0*dash_angle)));
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gap_angle = (M_PI*2.0)/ndashes - dash_angle;
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}
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for (int i = 0; i < ndashes; i++) {
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double start_angle = i*(dash_angle+gap_angle) - dash_angle/2.0;
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solid_arc(cent, rad, start_angle, start_angle + dash_angle, lt);
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}
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}
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// output a dotted circle as a series of dots
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void common_output::dotted_circle(const position ¢, double rad,
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const line_type <)
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{
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assert(lt.type == line_type::dotted);
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double gap_angle = lt.dash_width/rad;
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int ndots;
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if (gap_angle >= M_PI/2.0) {
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// always have at least 2 dots
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gap_angle = M_PI;
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ndots = 2;
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}
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else {
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ndots = 4*int(M_PI/(2.0*gap_angle));
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gap_angle = (M_PI*2.0)/ndots;
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}
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double ang = 0.0;
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for (int i = 0; i < ndots; i++, ang += gap_angle)
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dot(cent + position(cos(ang), sin(ang))*rad, lt);
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}
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// return non-zero iff we can compute a center
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int compute_arc_center(const position &start, const position ¢,
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const position &end, position *result)
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{
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// This finds the point along the vector from start to cent that
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// is equidistant between start and end.
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distance c = cent - start;
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distance e = end - start;
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double n = c*e;
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if (n == 0.0)
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return 0;
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*result = start + c*((e*e)/(2.0*n));
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return 1;
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}
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// output a dashed arc as a series of arcs
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void common_output::dashed_arc(const position &start, const position ¢,
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const position &end, const line_type <)
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{
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assert(lt.type == line_type::dashed);
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position c;
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if (!compute_arc_center(start, cent, end, &c)) {
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line(start, &end, 1, lt);
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return;
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}
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distance start_offset = start - c;
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distance end_offset = end - c;
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double start_angle = atan2(start_offset.y, start_offset.x);
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double end_angle = atan2(end_offset.y, end_offset.x);
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double rad = hypot(c - start);
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double dash_angle = lt.dash_width/rad;
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double total_angle = end_angle - start_angle;
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while (total_angle < 0)
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total_angle += M_PI + M_PI;
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if (total_angle <= dash_angle*2.0) {
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solid_arc(cent, rad, start_angle, end_angle, lt);
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return;
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}
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int ndashes = int((total_angle - dash_angle)/(dash_angle*2.0) + .5);
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double dash_and_gap_angle = (total_angle - dash_angle)/ndashes;
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for (int i = 0; i <= ndashes; i++)
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solid_arc(cent, rad, start_angle + i*dash_and_gap_angle,
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start_angle + i*dash_and_gap_angle + dash_angle, lt);
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}
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// output a dotted arc as a series of dots
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void common_output::dotted_arc(const position &start, const position ¢,
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const position &end, const line_type <)
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{
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assert(lt.type == line_type::dotted);
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position c;
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if (!compute_arc_center(start, cent, end, &c)) {
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line(start, &end, 1, lt);
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return;
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}
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distance start_offset = start - c;
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distance end_offset = end - c;
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double start_angle = atan2(start_offset.y, start_offset.x);
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double total_angle = atan2(end_offset.y, end_offset.x) - start_angle;
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while (total_angle < 0)
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total_angle += M_PI + M_PI;
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double rad = hypot(c - start);
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int ndots = int(total_angle/(lt.dash_width/rad) + .5);
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if (ndots == 0)
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dot(start, lt);
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else {
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for (int i = 0; i <= ndots; i++) {
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double a = start_angle + (total_angle*i)/ndots;
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dot(cent + position(cos(a), sin(a))*rad, lt);
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}
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}
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}
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void common_output::solid_arc(const position ¢, double rad,
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double start_angle, double end_angle,
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const line_type <)
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{
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line_type slt = lt;
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slt.type = line_type::solid;
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arc(cent + position(cos(start_angle), sin(start_angle))*rad,
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cent,
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cent + position(cos(end_angle), sin(end_angle))*rad,
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slt);
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}
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void common_output::rounded_box(const position ¢, const distance &dim,
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double rad, const line_type <, double fill)
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{
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if (fill >= 0.0)
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filled_rounded_box(cent, dim, rad, fill);
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switch (lt.type) {
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case line_type::invisible:
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break;
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case line_type::dashed:
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dashed_rounded_box(cent, dim, rad, lt);
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break;
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case line_type::dotted:
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dotted_rounded_box(cent, dim, rad, lt);
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break;
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case line_type::solid:
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solid_rounded_box(cent, dim, rad, lt);
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break;
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default:
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assert(0);
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}
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}
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void common_output::dashed_rounded_box(const position ¢,
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const distance &dim, double rad,
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const line_type <)
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{
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line_type slt = lt;
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slt.type = line_type::solid;
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double hor_length = dim.x + (M_PI/2.0 - 2.0)*rad;
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int n_hor_dashes = int(hor_length/(lt.dash_width*2.0) + .5);
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double hor_gap_width = (n_hor_dashes != 0
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? hor_length/n_hor_dashes - lt.dash_width
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: 0.0);
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double vert_length = dim.y + (M_PI/2.0 - 2.0)*rad;
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int n_vert_dashes = int(vert_length/(lt.dash_width*2.0) + .5);
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double vert_gap_width = (n_vert_dashes != 0
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? vert_length/n_vert_dashes - lt.dash_width
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: 0.0);
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// Note that each corner arc has to be split into two for dashing,
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// because one part is dashed using vert_gap_width, and the other
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// using hor_gap_width.
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double offset = lt.dash_width/2.0;
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dash_arc(cent + position(dim.x/2.0 - rad, -dim.y/2.0 + rad), rad,
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-M_PI/4.0, 0, slt, lt.dash_width, vert_gap_width, &offset);
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dash_line(cent + position(dim.x/2.0, -dim.y/2.0 + rad),
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cent + position(dim.x/2.0, dim.y/2.0 - rad),
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slt, lt.dash_width, vert_gap_width, &offset);
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dash_arc(cent + position(dim.x/2.0 - rad, dim.y/2.0 - rad), rad,
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0, M_PI/4.0, slt, lt.dash_width, vert_gap_width, &offset);
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offset = lt.dash_width/2.0;
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dash_arc(cent + position(dim.x/2.0 - rad, dim.y/2.0 - rad), rad,
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M_PI/4.0, M_PI/2, slt, lt.dash_width, hor_gap_width, &offset);
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dash_line(cent + position(dim.x/2.0 - rad, dim.y/2.0),
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cent + position(-dim.x/2.0 + rad, dim.y/2.0),
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slt, lt.dash_width, hor_gap_width, &offset);
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dash_arc(cent + position(-dim.x/2.0 + rad, dim.y/2.0 - rad), rad,
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M_PI/2, 3*M_PI/4.0, slt, lt.dash_width, hor_gap_width, &offset);
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offset = lt.dash_width/2.0;
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dash_arc(cent + position(-dim.x/2.0 + rad, dim.y/2.0 - rad), rad,
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3.0*M_PI/4.0, M_PI, slt, lt.dash_width, vert_gap_width, &offset);
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dash_line(cent + position(-dim.x/2.0, dim.y/2.0 - rad),
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cent + position(-dim.x/2.0, -dim.y/2.0 + rad),
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slt, lt.dash_width, vert_gap_width, &offset);
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dash_arc(cent + position(-dim.x/2.0 + rad, -dim.y/2.0 + rad), rad,
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M_PI, 5.0*M_PI/4.0, slt, lt.dash_width, vert_gap_width, &offset);
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offset = lt.dash_width/2.0;
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dash_arc(cent + position(-dim.x/2.0 + rad, -dim.y/2.0 + rad), rad,
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5*M_PI/4.0, 3*M_PI/2.0, slt, lt.dash_width, hor_gap_width, &offset);
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dash_line(cent + position(-dim.x/2.0 + rad, -dim.y/2.0),
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cent + position(dim.x/2.0 - rad, -dim.y/2.0),
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slt, lt.dash_width, hor_gap_width, &offset);
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dash_arc(cent + position(dim.x/2.0 - rad, -dim.y/2.0 + rad), rad,
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3*M_PI/2, 7*M_PI/4, slt, lt.dash_width, hor_gap_width, &offset);
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}
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// Used by dashed_rounded_box.
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void common_output::dash_arc(const position ¢, double rad,
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double start_angle, double end_angle,
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const line_type <,
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double dash_width, double gap_width,
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double *offsetp)
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{
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double length = (end_angle - start_angle)*rad;
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double pos = 0.0;
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for (;;) {
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if (*offsetp >= dash_width) {
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double rem = dash_width + gap_width - *offsetp;
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if (pos + rem > length) {
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*offsetp += length - pos;
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break;
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}
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else {
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pos += rem;
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*offsetp = 0.0;
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}
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}
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else {
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double rem = dash_width - *offsetp;
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if (pos + rem > length) {
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solid_arc(cent, rad, start_angle + pos/rad, end_angle, lt);
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*offsetp += length - pos;
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break;
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}
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else {
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solid_arc(cent, rad, start_angle + pos/rad,
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start_angle + (pos + rem)/rad, lt);
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pos += rem;
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*offsetp = dash_width;
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}
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}
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}
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}
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// Used by dashed_rounded_box.
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void common_output::dash_line(const position &start, const position &end,
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const line_type <,
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double dash_width, double gap_width,
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double *offsetp)
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{
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distance dist = end - start;
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double length = hypot(dist);
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if (length == 0.0)
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return;
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double pos = 0.0;
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for (;;) {
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if (*offsetp >= dash_width) {
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double rem = dash_width + gap_width - *offsetp;
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if (pos + rem > length) {
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*offsetp += length - pos;
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break;
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}
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else {
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pos += rem;
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*offsetp = 0.0;
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}
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}
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else {
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double rem = dash_width - *offsetp;
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if (pos + rem > length) {
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line(start + dist*(pos/length), &end, 1, lt);
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*offsetp += length - pos;
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break;
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}
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else {
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position p(start + dist*((pos + rem)/length));
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line(start + dist*(pos/length), &p, 1, lt);
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pos += rem;
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*offsetp = dash_width;
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}
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}
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}
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}
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void common_output::dotted_rounded_box(const position ¢,
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const distance &dim, double rad,
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const line_type <)
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{
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line_type slt = lt;
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slt.type = line_type::solid;
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double hor_length = dim.x + (M_PI/2.0 - 2.0)*rad;
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int n_hor_dots = int(hor_length/lt.dash_width + .5);
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double hor_gap_width = (n_hor_dots != 0
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? hor_length/n_hor_dots
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: lt.dash_width);
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double vert_length = dim.y + (M_PI/2.0 - 2.0)*rad;
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int n_vert_dots = int(vert_length/lt.dash_width + .5);
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double vert_gap_width = (n_vert_dots != 0
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? vert_length/n_vert_dots
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: lt.dash_width);
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double epsilon = lt.dash_width/(rad*100.0);
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double offset = 0.0;
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dot_arc(cent + position(dim.x/2.0 - rad, -dim.y/2.0 + rad), rad,
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-M_PI/4.0, 0, slt, vert_gap_width, &offset);
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dot_line(cent + position(dim.x/2.0, -dim.y/2.0 + rad),
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cent + position(dim.x/2.0, dim.y/2.0 - rad),
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slt, vert_gap_width, &offset);
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dot_arc(cent + position(dim.x/2.0 - rad, dim.y/2.0 - rad), rad,
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0, M_PI/4.0 - epsilon, slt, vert_gap_width, &offset);
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offset = 0.0;
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dot_arc(cent + position(dim.x/2.0 - rad, dim.y/2.0 - rad), rad,
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M_PI/4.0, M_PI/2, slt, hor_gap_width, &offset);
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dot_line(cent + position(dim.x/2.0 - rad, dim.y/2.0),
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cent + position(-dim.x/2.0 + rad, dim.y/2.0),
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slt, hor_gap_width, &offset);
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dot_arc(cent + position(-dim.x/2.0 + rad, dim.y/2.0 - rad), rad,
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M_PI/2, 3*M_PI/4.0 - epsilon, slt, hor_gap_width, &offset);
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offset = 0.0;
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dot_arc(cent + position(-dim.x/2.0 + rad, dim.y/2.0 - rad), rad,
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3.0*M_PI/4.0, M_PI, slt, vert_gap_width, &offset);
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dot_line(cent + position(-dim.x/2.0, dim.y/2.0 - rad),
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cent + position(-dim.x/2.0, -dim.y/2.0 + rad),
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slt, vert_gap_width, &offset);
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dot_arc(cent + position(-dim.x/2.0 + rad, -dim.y/2.0 + rad), rad,
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M_PI, 5.0*M_PI/4.0 - epsilon, slt, vert_gap_width, &offset);
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offset = 0.0;
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dot_arc(cent + position(-dim.x/2.0 + rad, -dim.y/2.0 + rad), rad,
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5*M_PI/4.0, 3*M_PI/2.0, slt, hor_gap_width, &offset);
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dot_line(cent + position(-dim.x/2.0 + rad, -dim.y/2.0),
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cent + position(dim.x/2.0 - rad, -dim.y/2.0),
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slt, hor_gap_width, &offset);
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dot_arc(cent + position(dim.x/2.0 - rad, -dim.y/2.0 + rad), rad,
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3*M_PI/2, 7*M_PI/4 - epsilon, slt, hor_gap_width, &offset);
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}
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// Used by dotted_rounded_box.
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void common_output::dot_arc(const position ¢, double rad,
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double start_angle, double end_angle,
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const line_type <, double gap_width,
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double *offsetp)
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{
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double length = (end_angle - start_angle)*rad;
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double pos = 0.0;
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for (;;) {
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if (*offsetp == 0.0) {
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double ang = start_angle + pos/rad;
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dot(cent + position(cos(ang), sin(ang))*rad, lt);
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}
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double rem = gap_width - *offsetp;
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if (pos + rem > length) {
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*offsetp += length - pos;
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break;
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}
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else {
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pos += rem;
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*offsetp = 0.0;
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}
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}
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}
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// Used by dotted_rounded_box.
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void common_output::dot_line(const position &start, const position &end,
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const line_type <, double gap_width,
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double *offsetp)
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{
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distance dist = end - start;
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double length = hypot(dist);
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if (length == 0.0)
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return;
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double pos = 0.0;
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for (;;) {
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if (*offsetp == 0.0)
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dot(start + dist*(pos/length), lt);
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double rem = gap_width - *offsetp;
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if (pos + rem > length) {
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*offsetp += length - pos;
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break;
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}
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else {
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pos += rem;
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*offsetp = 0.0;
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}
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}
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}
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void common_output::solid_rounded_box(const position ¢,
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const distance &dim, double rad,
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const line_type <)
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{
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position tem = cent - dim/2.0;
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arc(tem + position(0.0, rad),
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tem + position(rad, rad),
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tem + position(rad, 0.0),
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lt);
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tem = cent + position(-dim.x/2.0, dim.y/2.0);
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arc(tem + position(rad, 0.0),
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tem + position(rad, -rad),
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tem + position(0.0, -rad),
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lt);
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tem = cent + dim/2.0;
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arc(tem + position(0.0, -rad),
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|
tem + position(-rad, -rad),
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|
tem + position(-rad, 0.0),
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|
lt);
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|
tem = cent + position(dim.x/2.0, -dim.y/2.0);
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arc(tem + position(-rad, 0.0),
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|
tem + position(-rad, rad),
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|
tem + position(0.0, rad),
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|
lt);
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|
position end;
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end = cent + position(-dim.x/2.0, dim.y/2.0 - rad);
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line(cent - dim/2.0 + position(0.0, rad), &end, 1, lt);
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end = cent + position(dim.x/2.0 - rad, dim.y/2.0);
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|
line(cent + position(-dim.x/2.0 + rad, dim.y/2.0), &end, 1, lt);
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|
end = cent + position(dim.x/2.0, -dim.y/2.0 + rad);
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|
line(cent + position(dim.x/2.0, dim.y/2.0 - rad), &end, 1, lt);
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|
end = cent + position(-dim.x/2.0 + rad, -dim.y/2.0);
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|
line(cent + position(dim.x/2.0 - rad, -dim.y/2.0), &end, 1, lt);
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|
}
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|
|
|
void common_output::filled_rounded_box(const position ¢,
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|
const distance &dim, double rad,
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|
double fill)
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|
{
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|
line_type ilt;
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|
ilt.type = line_type::invisible;
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|
circle(cent + position(dim.x/2.0 - rad, dim.y/2.0 - rad), rad, ilt, fill);
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|
circle(cent + position(-dim.x/2.0 + rad, dim.y/2.0 - rad), rad, ilt, fill);
|
|
circle(cent + position(-dim.x/2.0 + rad, -dim.y/2.0 + rad), rad, ilt, fill);
|
|
circle(cent + position(dim.x/2.0 - rad, -dim.y/2.0 + rad), rad, ilt, fill);
|
|
position vec[4];
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|
vec[0] = cent + position(dim.x/2.0, dim.y/2.0 - rad);
|
|
vec[1] = cent + position(-dim.x/2.0, dim.y/2.0 - rad);
|
|
vec[2] = cent + position(-dim.x/2.0, -dim.y/2.0 + rad);
|
|
vec[3] = cent + position(dim.x/2.0, -dim.y/2.0 + rad);
|
|
polygon(vec, 4, ilt, fill);
|
|
vec[0] = cent + position(dim.x/2.0 - rad, dim.y/2.0);
|
|
vec[1] = cent + position(-dim.x/2.0 + rad, dim.y/2.0);
|
|
vec[2] = cent + position(-dim.x/2.0 + rad, -dim.y/2.0);
|
|
vec[3] = cent + position(dim.x/2.0 - rad, -dim.y/2.0);
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|
polygon(vec, 4, ilt, fill);
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|
}
|