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//
// Copyright (C) 2016 Greg Landrum
//
// @@ All Rights Reserved @@
// This file is part of the RDKit.
// The contents are covered by the terms of the BSD license
// which is included in the file license.txt, found at the root
// of the RDKit source tree.
//
//
#include <GraphMol/MolDraw2D/MultiMolDraw2D.h>
#include <GraphMol/MolDraw2D/MolDraw2D.h>
namespace RDKit {
// ****************************************************************************
template <typename T>
MultiMolDraw2D<T>::MultiMolDraw2D(unsigned int nRows, unsigned int nCols,
int width, int height, bool globalScaling)
: nRows_(nRows),
nCols_(nCols),
width_(width),
globalScaling_(globalScaling) {
PRECONDITION(nRows > 0, "nRows must be greater than zero");
PRECONDITION(nCols > 0, "nCols must be greater than zero");
int widthPerDrawer = width / nCols;
int heightPerDrawer = height / nRows;
drawers_.reserve(nRows * nCols);
for (unsigned int i = 0, i < nRows * nCols; i++) {
drawers_.push_back(new T(widthPerDrawer, heightPerDrawer));
}
}
// ****************************************************************************
void MolDraw2D::drawMolecule(const ROMol &mol,
const vector<int> *highlight_atoms,
const map<int, DrawColour> *highlight_atom_map,
const std::map<int, double> *highlight_radii,
int confId) {
drawMolecule(mol, "", highlight_atoms, highlight_atom_map, highlight_radii,
confId);
}
// ****************************************************************************
void MolDraw2D::drawMolecule(const ROMol &mol, const std::string &legend,
const vector<int> *highlight_atoms,
const map<int, DrawColour> *highlight_atom_map,
const std::map<int, double> *highlight_radii,
int confId) {
vector<int> highlight_bonds;
if (highlight_atoms) {
for (vector<int>::const_iterator ai = highlight_atoms->begin();
ai != highlight_atoms->end(); ++ai) {
for (vector<int>::const_iterator aj = ai + 1;
aj != highlight_atoms->end(); ++aj) {
const Bond *bnd = mol.getBondBetweenAtoms(*ai, *aj);
if (bnd) highlight_bonds.push_back(bnd->getIdx());
}
}
}
drawMolecule(mol, legend, highlight_atoms, &highlight_bonds,
highlight_atom_map, NULL, highlight_radii, confId);
}
void MolDraw2D::doContinuousHighlighting(
const ROMol &mol, const vector<int> *highlight_atoms,
const vector<int> *highlight_bonds,
const map<int, DrawColour> *highlight_atom_map,
const map<int, DrawColour> *highlight_bond_map,
const std::map<int, double> *highlight_radii) {
int orig_lw = lineWidth();
int tgt_lw = lineWidth() * 8;
// try to scale lw to reflect the overall scaling:
tgt_lw = max(
orig_lw * 2,
min(tgt_lw,
(int)(scale_ / 25. * tgt_lw))); // the 25 here is extremely empirical
bool orig_fp = fillPolys();
ROMol::VERTEX_ITER this_at, end_at;
if (highlight_bonds) {
boost::tie(this_at, end_at) = mol.getVertices();
while (this_at != end_at) {
int this_idx = mol[*this_at]->getIdx();
ROMol::OEDGE_ITER nbr, end_nbr;
boost::tie(nbr, end_nbr) = mol.getAtomBonds(mol[*this_at].get());
while (nbr != end_nbr) {
const Bond* bond = mol[*nbr];
++nbr;
int nbr_idx = bond->getOtherAtomIdx(this_idx);
if (nbr_idx < static_cast<int>(at_cds_.size()) && nbr_idx > this_idx) {
if (std::find(highlight_bonds->begin(), highlight_bonds->end(),
bond->getIdx()) != highlight_bonds->end()) {
DrawColour col = drawOptions().highlightColour;
if (highlight_bond_map &&
highlight_bond_map->find(bond->getIdx()) !=
highlight_bond_map->end()) {
col = highlight_bond_map->find(bond->getIdx())->second;
}
setLineWidth(tgt_lw);
Point2D at1_cds = at_cds_[this_idx];
Point2D at2_cds = at_cds_[nbr_idx];
drawLine(at1_cds, at2_cds, col, col);
}
}
}
++this_at;
}
}
if (highlight_atoms) {
boost::tie(this_at, end_at) = mol.getVertices();
while (this_at != end_at) {
int this_idx = mol[*this_at]->getIdx();
if (std::find(highlight_atoms->begin(), highlight_atoms->end(),
this_idx) != highlight_atoms->end()) {
DrawColour col = drawOptions().highlightColour;
if (highlight_atom_map &&
highlight_atom_map->find(this_idx) != highlight_atom_map->end()) {
col = highlight_atom_map->find(this_idx)->second;
}
Point2D p1 = at_cds_[this_idx];
Point2D p2 = at_cds_[this_idx];
double radius = 0.4;
if (highlight_radii &&
highlight_radii->find(this_idx) != highlight_radii->end()) {
radius = highlight_radii->find(this_idx)->second;
}
Point2D offset(radius, radius);
p1 -= offset;
p2 += offset;
setColour(col);
setFillPolys(true);
setLineWidth(1);
drawEllipse(p1, p2);
}
++this_at;
}
}
setLineWidth(orig_lw);
setFillPolys(orig_fp);
}
void drawMolecules(
const std::vector<ROMOL_SPTR> &mols,
const std::vector<std::string> *legends = NULL,
const std::vector<std::vector<int> > *highlight_atoms = NULL,
const std::vector<std::vector<int> > *highlight_bonds = NULL,
const std::vector<std::map<int, DrawColour> > *highlight_atom_maps = NULL,
const std::vector<std::map<int, DrawColour> > *highlight_bond_maps = NULL,
const std::vector<std::map<int, double> > *highlight_radii = NULL,
const std::vector<int> *confIds = NULL){};
void MolDraw2D::drawMolecule(const ROMol &mol,
const vector<int> *highlight_atoms,
const vector<int> *highlight_bonds,
const map<int, DrawColour> *highlight_atom_map,
const map<int, DrawColour> *highlight_bond_map,
const std::map<int, double> *highlight_radii,
int confId) {
if (drawOptions().clearBackground) {
clearDrawing();
}
extractAtomCoords(mol, confId);
extractAtomSymbols(mol);
calculateScale();
// make sure the font doesn't end up too large (the constants are empirical)
if (scale_ <= 40.) {
setFontSize(font_size_);
} else {
setFontSize(font_size_ * 30. / scale_);
}
// std::cerr << "scale: " << scale_ << " font_size_: " << font_size_
// << std::endl;
if (drawOptions().includeAtomTags) {
tagAtoms(mol);
}
if (drawOptions().atomRegions.size()) {
BOOST_FOREACH (const std::vector<int> ®ion, drawOptions().atomRegions) {
if (region.size() > 1) {
Point2D minv = at_cds_[region[0]];
Point2D maxv = at_cds_[region[0]];
BOOST_FOREACH (int idx, region) {
const Point2D &pt = at_cds_[idx];
minv.x = std::min(minv.x, pt.x);
minv.y = std::min(minv.y, pt.y);
maxv.x = std::max(maxv.x, pt.x);
maxv.y = std::max(maxv.y, pt.y);
}
Point2D center = (maxv + minv) / 2;
Point2D size = (maxv - minv);
size *= 0.2;
minv -= size / 2;
maxv += size / 2;
setColour(DrawColour(.8, .8, .8));
// drawEllipse(minv,maxv);
drawRect(minv, maxv);
}
}
}
if (drawOptions().continuousHighlight) {
// if we're doing continuous highlighting, start by drawing the highlights
doContinuousHighlighting(mol, highlight_atoms, highlight_bonds,
highlight_atom_map, highlight_bond_map,
highlight_radii);
// at this point we shouldn't be doing any more higlighting, so blow out
// those variables:
highlight_bonds = NULL;
highlight_atoms = NULL;
} else if (drawOptions().circleAtoms && highlight_atoms) {
ROMol::VERTEX_ITER this_at, end_at;
boost::tie(this_at, end_at) = mol.getVertices();
setFillPolys(false);
while (this_at != end_at) {
int this_idx = mol[*this_at]->getIdx();
if (std::find(highlight_atoms->begin(), highlight_atoms->end(),
this_idx) != highlight_atoms->end()) {
if (highlight_atom_map &&
highlight_atom_map->find(this_idx) != highlight_atom_map->end()) {
setColour(highlight_atom_map->find(this_idx)->second);
} else {
setColour(drawOptions().highlightColour);
}
Point2D p1 = at_cds_[this_idx];
Point2D p2 = at_cds_[this_idx];
double radius = 0.3;
if (highlight_radii &&
highlight_radii->find(this_idx) != highlight_radii->end()) {
radius = highlight_radii->find(this_idx)->second;
}
Point2D offset(radius, radius);
p1 -= offset;
p2 += offset;
drawEllipse(p1, p2);
}
++this_at;
}
setFillPolys(true);
}
ROMol::VERTEX_ITER this_at, end_at;
boost::tie(this_at, end_at) = mol.getVertices();
while (this_at != end_at) {
int this_idx = mol[*this_at]->getIdx();
ROMol::OEDGE_ITER nbr, end_nbr;
boost::tie(nbr, end_nbr) = mol.getAtomBonds(mol[*this_at].get());
while (nbr != end_nbr) {
const Bond* bond = mol[*nbr];
++nbr;
int nbr_idx = bond->getOtherAtomIdx(this_idx);
if (nbr_idx < static_cast<int>(at_cds_.size()) && nbr_idx > this_idx) {
drawBond(mol, bond, this_idx, nbr_idx, highlight_atoms,
highlight_atom_map, highlight_bonds, highlight_bond_map);
}
}
++this_at;
}
if (drawOptions().dummiesAreAttachments) {
ROMol::VERTEX_ITER atom, end_atom;
boost::tie(atom, end_atom) = mol.getVertices();
while (atom != end_atom) {
const Atom *at1 = mol[*atom].get();
++atom;
if (drawOptions().atomLabels.find(at1->getIdx()) !=
drawOptions().atomLabels.end()) {
// skip dummies that explicitly have a label provided
continue;
}
if (at1->getAtomicNum() == 0 && at1->getDegree() == 1) {
Point2D &at1_cds = at_cds_[at1->getIdx()];
ROMol::ADJ_ITER nbrIdx, endNbrs;
boost::tie(nbrIdx, endNbrs) = mol.getAtomNeighbors(at1);
const Atom* at2 = mol[*nbrIdx];
Point2D &at2_cds = at_cds_[at2->getIdx()];
drawAttachmentLine(at2_cds, at1_cds, DrawColour(.5, .5, .5));
}
}
}
for (int i = 0, is = atom_syms_.size(); i < is; ++i) {
if (!atom_syms_[i].first.empty()) {
drawAtomLabel(i, highlight_atoms, highlight_atom_map);
}
}
if (drawOptions().flagCloseContactsDist >= 0) {
highlightCloseContacts();
}
}
void MolDraw2D::drawMolecule(const ROMol &mol, const std::string &legend,
const vector<int> *highlight_atoms,
const vector<int> *highlight_bonds,
const map<int, DrawColour> *highlight_atom_map,
const map<int, DrawColour> *highlight_bond_map,
const std::map<int, double> *highlight_radii,
int confId) {
drawMolecule(mol, highlight_atoms, highlight_bonds, highlight_atom_map,
highlight_bond_map, highlight_radii, confId);
if (legend != "") {
// the 0.94 is completely empirical and was brought over from Python
Point2D loc = getAtomCoords(std::make_pair(width_ / 2., 0.94 * height_));
double o_font_size = fontSize();
setFontSize(options_.legendFontSize /
scale_); // set the font size to about 12 pixels high
DrawColour odc = colour();
setColour(options_.legendColour);
drawString(legend, loc);
setColour(odc);
setFontSize(o_font_size);
}
}
void MolDraw2D::highlightCloseContacts() {
if (drawOptions().flagCloseContactsDist < 0) return;
int tol =
drawOptions().flagCloseContactsDist * drawOptions().flagCloseContactsDist;
boost::dynamic_bitset<> flagged(at_cds_.size());
for (unsigned int i = 0; i < at_cds_.size(); ++i) {
if (flagged[i]) continue;
Point2D ci = getDrawCoords(at_cds_[i]);
for (unsigned int j = i + 1; j < at_cds_.size(); ++j) {
if (flagged[j]) continue;
Point2D cj = getDrawCoords(at_cds_[j]);
double d = (cj - ci).lengthSq();
if (d <= tol) {
flagged.set(i);
flagged.set(j);
break;
}
}
if (flagged[i]) {
Point2D p1 = at_cds_[i];
Point2D p2 = p1;
Point2D offset(0.1, 0.1);
p1 -= offset;
p2 += offset;
bool ofp = fillPolys();
setFillPolys(false);
DrawColour odc = colour();
setColour(DrawColour(1, 0, 0));
drawRect(p1, p2);
setColour(odc);
setFillPolys(ofp);
}
}
}
// ****************************************************************************
// transform a set of coords in the molecule's coordinate system
// to drawing system coordinates
Point2D MolDraw2D::getDrawCoords(const Point2D &mol_cds) const {
double x = scale_ * (mol_cds.x - x_min_ + x_trans_);
double y = scale_ * (mol_cds.y - y_min_ + y_trans_);
// y is now the distance from the top of the image, we need to
// invert that:
y = height() - y;
return Point2D(x, y);
}
// ****************************************************************************
Point2D MolDraw2D::getDrawCoords(int at_num) const {
return getDrawCoords(at_cds_[at_num]);
}
// ****************************************************************************
Point2D MolDraw2D::getAtomCoords(const pair<int, int> &screen_cds) const {
int x = int(double(screen_cds.first) / scale_ + x_min_ - x_trans_);
int y =
int(double(y_min_ - y_trans_ - (screen_cds.second - height()) / scale_));
return Point2D(x, y);
}
Point2D MolDraw2D::getAtomCoords(const pair<double, double> &screen_cds) const {
double x = double(screen_cds.first / scale_ + x_min_ - x_trans_);
double y =
double(y_min_ - y_trans_ - (screen_cds.second - height()) / scale_);
return Point2D(x, y);
}
// ****************************************************************************
Point2D MolDraw2D::getAtomCoords(int at_num) const { return at_cds_[at_num]; }
// ****************************************************************************
void MolDraw2D::setFontSize(double new_size) { font_size_ = new_size; }
// ****************************************************************************
void MolDraw2D::calculateScale() {
x_min_ = y_min_ = numeric_limits<double>::max();
double x_max(-numeric_limits<double>::max()),
y_max(-numeric_limits<double>::max());
for (int i = 0, is = at_cds_.size(); i < is; ++i) {
const Point2D &pt = at_cds_[i];
x_min_ = std::min(pt.x, x_min_);
y_min_ = std::min(pt.y, y_min_);
x_max = std::max(pt.x, x_max);
y_max = std::max(pt.y, y_max);
}
x_range_ = x_max - x_min_;
y_range_ = y_max - y_min_;
scale_ = std::min(double(width_) / x_range_, double(height_) / y_range_);
// we may need to adjust the scale if there are atom symbols that go off
// the edges, and we probably need to do it iteratively because
// get_string_size
// uses the current value of scale_.
while (1) {
for (int i = 0, is = atom_syms_.size(); i < is; ++i) {
if (!atom_syms_[i].first.empty()) {
double atsym_width, atsym_height;
getStringSize(atom_syms_[i].first, atsym_width, atsym_height);
double this_x_min = at_cds_[i].x;
double this_x_max = at_cds_[i].x;
double this_y = at_cds_[i].y - atsym_height / 2;
if (W == atom_syms_[i].second) {
this_x_min -= atsym_width;
} else if (E == atom_syms_[i].second) {
this_x_max += atsym_width;
} else {
this_x_max += atsym_width / 2;
this_x_min -= atsym_width / 2;
}
x_max = std::max(x_max, this_x_max);
x_min_ = std::min(x_min_, this_x_min);
y_max = std::max(y_max, this_y);
}
}
double old_scale = scale_;
x_range_ = x_max - x_min_;
y_range_ = y_max - y_min_;
scale_ = std::min(double(width_) / x_range_, double(height_) / y_range_);
if (fabs(scale_ - old_scale) < 0.1) {
break;
}
}
// put a 5% buffer round the drawing and calculate a final scale
x_min_ -= 0.05 * x_range_;
x_range_ *= 1.1;
y_min_ -= 0.05 * y_range_;
y_range_ *= 1.1;
scale_ = std::min(double(width_) / x_range_, double(height_) / y_range_);
double x_mid = x_min_ + 0.5 * x_range_;
double y_mid = y_min_ + 0.5 * y_range_;
Point2D mid = getDrawCoords(Point2D(x_mid, y_mid));
x_trans_ = (width_ / 2 - mid.x) / scale_;
y_trans_ = (mid.y - height_ / 2) / scale_;
}
// ****************************************************************************
// establishes whether to put string draw mode into super- or sub-script
// mode based on contents of instring from i onwards. Increments i appropriately
// and returns true or false depending on whether it did something or not.
bool MolDraw2D::setStringDrawMode(const string &instring,
TextDrawType &draw_mode, int &i) const {
string bit1 = instring.substr(i, 5);
string bit2 = instring.substr(i, 6);
// could be markup for super- or sub-script
if (string("<sub>") == bit1) {
draw_mode = TextDrawSubscript;
i += 4;
return true;
} else if (string("<sup>") == bit1) {
draw_mode = TextDrawSuperscript;
i += 4;
return true;
} else if (string("</sub>") == bit2) {
draw_mode = TextDrawNormal;
i += 5;
return true;
} else if (string("</sup>") == bit2) {
draw_mode = TextDrawNormal;
i += 5;
return true;
}
return false;
}
// ****************************************************************************
void MolDraw2D::drawLine(const Point2D &cds1, const Point2D &cds2,
const DrawColour &col1, const DrawColour &col2) {
if (col1 == col2) {
setColour(col1);
drawLine(cds1, cds2);
} else {
Point2D mid = (cds1 + cds2);
mid *= .5;
setColour(col1);
drawLine(cds1, mid);
setColour(col2);
drawLine(mid, cds2);
}
}
// ****************************************************************************
// draws the string centred on cds
void MolDraw2D::drawString(const string &str, const Point2D &cds) {
double string_width, string_height;
getStringSize(str, string_width, string_height);
// FIX: this shouldn't stay
double M_width, M_height;
getStringSize(std::string("M"), M_width, M_height);
double draw_x = cds.x - string_width / 2.0;
double draw_y = cds.y - string_height / 2.0;
double full_font_size = fontSize();
TextDrawType draw_mode = TextDrawNormal;
string next_char(" ");
for (int i = 0, is = str.length(); i < is; ++i) {
// setStringDrawMode moves i along to the end of any <sub> or <sup>
// markup
if ('<' == str[i] && setStringDrawMode(str, draw_mode, i)) {
continue;
}
char next_c = str[i];
next_char[0] = next_c;
double char_width, char_height;
getStringSize(next_char, char_width, char_height);
// these font sizes and positions work best for Qt, IMO. They may want
// tweaking for a more general solution.
if (TextDrawSubscript == draw_mode) {
// y goes from top to bottom, so add for a subscript!
setFontSize(0.75 * full_font_size);
char_width *= 0.5;
drawChar(next_c,
// getDrawCoords(Point2D(draw_x, draw_y + 0.5 *
// char_height)));
getDrawCoords(Point2D(draw_x, draw_y - 0.5 * char_height)));
setFontSize(full_font_size);
} else if (TextDrawSuperscript == draw_mode) {
setFontSize(0.75 * full_font_size);
char_width *= 0.5;
drawChar(next_c,
// getDrawCoords(Point2D(draw_x, draw_y - 0.25 *
// char_height)));
getDrawCoords(Point2D(draw_x, draw_y + .5 * M_height)));
setFontSize(full_font_size);
} else {
drawChar(next_c, getDrawCoords(Point2D(draw_x, draw_y)));
}
draw_x += char_width;
}
}
// ****************************************************************************
DrawColour MolDraw2D::getColour(
int atom_idx, const std::vector<int> *highlight_atoms,
const std::map<int, DrawColour> *highlight_map) {
PRECONDITION(atom_idx >= 0, "bad atom_idx");
PRECONDITION(rdcast<int>(atomic_nums_.size()) > atom_idx, "bad atom_idx");
DrawColour retval = getColourByAtomicNum(atomic_nums_[atom_idx]);
// set contents of highlight_atoms to red
if (!drawOptions().circleAtoms && !drawOptions().continuousHighlight) {
if (highlight_atoms &&
highlight_atoms->end() !=
find(highlight_atoms->begin(), highlight_atoms->end(), atom_idx)) {
retval = drawOptions().highlightColour;
}
// over-ride with explicit colour from highlight_map if there is one
if (highlight_map) {
map<int, DrawColour>::const_iterator p = highlight_map->find(atom_idx);
if (p != highlight_map->end()) {
retval = p->second;
}
}
}
return retval;
}
// ****************************************************************************
DrawColour MolDraw2D::getColourByAtomicNum(int atomic_num) {
// RGB values taken from Qt's QColor. The seem to work pretty well on my
// machine. Using them as fractions of 255, as that's the way Cairo does it.
DrawColour res(0., 0., 0.); // default to black
switch (atomic_num) {
case 0:
res = DrawColour(0.5, 0.5, 0.5);
break;
case 1: // Hs and Carbons are the same colour
case 6:
res = DrawColour(0.0, 0.0, 0.0);
break;
case 7:
res = DrawColour(0.0, 0.0, 1.0);
break;
case 8:
res = DrawColour(1.0, 0.0, 0.0);
break;
case 9:
res = DrawColour(0.2, 0.8, 0.8);
break;
case 15:
res = DrawColour(1.0, 0.5, 0.0);
break;
case 16:
res = DrawColour(0.8, 0.8, 0.0);
break;
case 17:
res = DrawColour(0.0, 0.802, 0.0);
break;
case 35:
res = DrawColour(0.5, 0.3, 0.1);
break;
case 53:
res = DrawColour(0.63, 0.12, 0.94);
break;
default:
break;
}
return res;
}
// ****************************************************************************
void MolDraw2D::extractAtomCoords(const ROMol &mol, int confId) {
at_cds_.clear();
atomic_nums_.clear();
bbox_[0].x = bbox_[0].y = numeric_limits<double>::max();
bbox_[1].x = bbox_[1].y = -1 * numeric_limits<double>::max();
const RDGeom::POINT3D_VECT &locs = mol.getConformer(confId).getPositions();
ROMol::VERTEX_ITER this_at, end_at;
boost::tie(this_at, end_at) = mol.getVertices();
while (this_at != end_at) {
int this_idx = mol[*this_at]->getIdx();
at_cds_.push_back(Point2D(locs[this_idx].x, locs[this_idx].y));
bbox_[0].x = std::min(bbox_[0].x, locs[this_idx].x);
bbox_[0].y = std::min(bbox_[0].y, locs[this_idx].y);
bbox_[1].x = std::max(bbox_[1].x, locs[this_idx].x);
bbox_[1].y = std::max(bbox_[1].y, locs[this_idx].y);
++this_at;
}
}
// ****************************************************************************
void MolDraw2D::extractAtomSymbols(const ROMol &mol) {
ROMol::VERTEX_ITER atom, end_atom;
boost::tie(atom, end_atom) = mol.getVertices();
while (atom != end_atom) {
ROMol::OEDGE_ITER nbr, end_nbrs;
const Atom *at1 = mol[*atom].get();
boost::tie(nbr, end_nbrs) = mol.getAtomBonds(at1);
Point2D &at1_cds = at_cds_[at1->getIdx()];
Point2D nbr_sum(0.0, 0.0);
while (nbr != end_nbrs) {
const Bond* bond = mol[*nbr];
++nbr;
Point2D &at2_cds = at_cds_[bond->getOtherAtomIdx(at1->getIdx())];
nbr_sum += at2_cds - at1_cds;
}
atom_syms_.push_back(getAtomSymbolAndOrientation(*at1, nbr_sum));
atomic_nums_.push_back(at1->getAtomicNum());
++atom;
}
}
// ****************************************************************************
void MolDraw2D::drawBond(const ROMol &mol, const Bond* &bond, int at1_idx,
int at2_idx, const vector<int> *highlight_atoms,
const map<int, DrawColour> *highlight_atom_map,
const vector<int> *highlight_bonds,
const map<int, DrawColour> *highlight_bond_map) {
RDUNUSED_PARAM(highlight_atoms);
RDUNUSED_PARAM(highlight_atom_map);
static const DashPattern noDash;
static const DashPattern dots = assign::list_of(2)(6);
static const DashPattern dashes = assign::list_of(6)(6);
// the percent shorter that the extra bonds in a double bond are
const double multipleBondTruncation = 0.15;
const Atom *at1 = mol.getAtomWithIdx(at1_idx);
const Atom *at2 = mol.getAtomWithIdx(at2_idx);
Point2D at1_cds = at_cds_[at1_idx];
Point2D at2_cds = at_cds_[at2_idx];
double double_bond_offset = options_.multipleBondOffset;
// mol files from, for example, Marvin use a bond length of 1 for just about
// everything. When this is the case, the default multipleBondOffset is just
// too much, so scale it back.
if ((at1_cds - at2_cds).lengthSq() < 1.4) double_bond_offset *= 0.6;
adjustBondEndForLabel(at1_idx, at2_cds, at1_cds);
adjustBondEndForLabel(at2_idx, at1_cds, at2_cds);
bool highlight_bond = false;
if (highlight_bonds &&
std::find(highlight_bonds->begin(), highlight_bonds->end(),
bond->getIdx()) != highlight_bonds->end()) {
highlight_bond = true;
}
DrawColour col1, col2;
int orig_lw = lineWidth();
if (!highlight_bond) {
col1 = getColour(at1_idx);
col2 = getColour(at2_idx);
} else {
if (highlight_bond_map &&
highlight_bond_map->find(bond->getIdx()) != highlight_bond_map->end()) {
col1 = col2 = highlight_bond_map->find(bond->getIdx())->second;
} else {
col1 = col2 = drawOptions().highlightColour;
}
if (drawOptions().continuousHighlight) {
setLineWidth(orig_lw * 8);
} else {
setLineWidth(orig_lw * 2);
}
}
Bond::BondType bt = bond->getBondType();
bool isComplex = false;
if (bond->hasQuery()) {
std::string descr = bond->getQuery()->getDescription();
if (bond->getQuery()->getNegation() || descr != "BondOrder") {
isComplex = true;
}
if (isComplex) {
setDash(dots);
drawLine(at1_cds, at2_cds, col1, col2);
setDash(noDash);
} else {
bt = static_cast<Bond::BondType>(
static_cast<BOND_EQUALS_QUERY *>(bond->getQuery())->getVal());
}
}
if (!isComplex) {
// it's a double bond and one end is 1-connected, do two lines parallel
// to the atom-atom line.
if ((bt == Bond::DOUBLE) &&
(1 == at1->getDegree() || 1 == at2->getDegree())) {
Point2D perp = calcPerpendicular(at1_cds, at2_cds) * double_bond_offset;
drawLine(at1_cds + perp, at2_cds + perp, col1, col2);
drawLine(at1_cds - perp, at2_cds - perp, col1, col2);
if (bt == Bond::TRIPLE) {
drawLine(at1_cds, at2_cds, col1, col2);
}
} else if (Bond::SINGLE == bt && (Bond::BEGINWEDGE == bond->getBondDir() ||
Bond::BEGINDASH == bond->getBondDir())) {
// std::cerr << "WEDGE: from " << at1->getIdx() << " | "
// << bond->getBeginAtomIdx() << "-" << bond->getEndAtomIdx()
// << std::endl;
// swap the direction if at1 has does not have stereochem set
// or if at2 does have stereochem set and the bond starts there
if ((at1->getChiralTag() != Atom::CHI_TETRAHEDRAL_CW &&
at1->getChiralTag() != Atom::CHI_TETRAHEDRAL_CCW) ||
(at1->getIdx() != bond->getBeginAtomIdx() &&
(at2->getChiralTag() == Atom::CHI_TETRAHEDRAL_CW ||
at2->getChiralTag() == Atom::CHI_TETRAHEDRAL_CCW))) {
// std::cerr << " swap" << std::endl;
swap(at1_cds, at2_cds);
swap(col1, col2);
}
if (Bond::BEGINWEDGE == bond->getBondDir()) {
drawWedgedBond(at1_cds, at2_cds, false, col1, col2);
} else {
drawWedgedBond(at1_cds, at2_cds, true, col1, col2);
}
} else if (Bond::SINGLE == bt && Bond::UNKNOWN == bond->getBondDir()) {
// unspecified stereo
drawWavyLine(at1_cds, at2_cds, col1, col2);
} else {
// in all other cases, we will definitely want to draw a line between the
// two atoms
drawLine(at1_cds, at2_cds, col1, col2);
if (Bond::TRIPLE == bt) {
// 2 further lines, a bit shorter and offset on the perpendicular
double dbo = 2.0 * double_bond_offset;
Point2D perp = calcPerpendicular(at1_cds, at2_cds);
double end1_trunc =
1 == at1->getDegree() ? 0.0 : multipleBondTruncation;
double end2_trunc =
1 == at2->getDegree() ? 0.0 : multipleBondTruncation;
Point2D bv = at1_cds - at2_cds;
Point2D p1 = at1_cds - (bv * end1_trunc) + perp * dbo;
Point2D p2 = at2_cds + (bv * end2_trunc) + perp * dbo;
drawLine(p1, p2, col1, col2);
p1 = at1_cds - (bv * end1_trunc) - perp * dbo;
p2 = at2_cds + (bv * end2_trunc) - perp * dbo;
drawLine(p1, p2, col1, col2);
}
// all we have left now are double bonds in a ring or not in a ring
// and multiply connected
else if (Bond::DOUBLE == bt || Bond::AROMATIC == bt) {
Point2D perp;
if (mol.getRingInfo()->numBondRings(bond->getIdx())) {
// in a ring, we need to draw the bond inside the ring
perp = bondInsideRing(mol, bond, at1_cds, at2_cds);
} else {
perp = bondInsideDoubleBond(mol, bond);
}
double dbo = 2.0 * double_bond_offset;
Point2D bv = at1_cds - at2_cds;
Point2D p1 = at1_cds - bv * multipleBondTruncation + perp * dbo;
Point2D p2 = at2_cds + bv * multipleBondTruncation + perp * dbo;
if (bt == Bond::AROMATIC) setDash(dashes);
drawLine(p1, p2, col1, col2);
if (bt == Bond::AROMATIC) setDash(noDash);
}
}
}
if (highlight_bond) {
setLineWidth(orig_lw);
}
}
// ****************************************************************************
void MolDraw2D::drawWedgedBond(const Point2D &cds1, const Point2D &cds2,
bool draw_dashed, const DrawColour &col1,
const DrawColour &col2) {
Point2D perp = calcPerpendicular(cds1, cds2);
Point2D disp = perp * 0.15;
// make sure the displacement isn't too large using the current scale factor
// (part of github #985)
// the constants are empirical to make sure that the wedge is visible, but not
// absurdly large.
if (scale_ > 40) disp *= .6;
Point2D end1 = cds2 + disp;
Point2D end2 = cds2 - disp;
setColour(col1);
if (draw_dashed) {
unsigned int nDashes = 10;
// empirical cutoff to make sure we don't have too many dashes in the wedge:
if ((cds1 - cds2).lengthSq() < 1.0) nDashes /= 2;
int orig_lw = lineWidth();
int tgt_lw = 1; // use the minimum line width
setLineWidth(tgt_lw);
Point2D e1 = end1 - cds1;
Point2D e2 = end2 - cds1;
for (unsigned int i = 1; i < nDashes + 1; ++i) {
if ((nDashes / 2 + 1) == i) {
setColour(col2);
}
Point2D e11 = cds1 + e1 * (rdcast<double>(i) / nDashes);
Point2D e22 = cds1 + e2 * (rdcast<double>(i) / nDashes);
drawLine(e11, e22);
}
setLineWidth(orig_lw);
} else {
if (col1 == col2) {
drawTriangle(cds1, end1, end2);
} else {
Point2D e1 = end1 - cds1;
Point2D e2 = end2 - cds1;
Point2D mid1 = cds1 + e1 * 0.5;
Point2D mid2 = cds1 + e2 * 0.5;
drawTriangle(cds1, mid1, mid2);
setColour(col2);
drawTriangle(mid1, end2, end1);
drawTriangle(mid1, mid2, end2);
}
}
}
// ****************************************************************************
void MolDraw2D::drawAtomLabel(int atom_num,
const std::vector<int> *highlight_atoms,
const std::map<int, DrawColour> *highlight_map) {
setColour(getColour(atom_num, highlight_atoms, highlight_map));
drawString(atom_syms_[atom_num].first, at_cds_[atom_num]);
}
// ****************************************************************************
// calculate normalised perpendicular to vector between two coords
Point2D MolDraw2D::calcPerpendicular(const Point2D &cds1, const Point2D &cds2) {
double bv[2] = {cds1.x - cds2.x, cds1.y - cds2.y};
double perp[2] = {-bv[1], bv[0]};
double perp_len = sqrt(perp[0] * perp[0] + perp[1] * perp[1]);
perp[0] /= perp_len;
perp[1] /= perp_len;
return Point2D(perp[0], perp[1]);
}
// ****************************************************************************
// cds1 and cds2 are 2 atoms in a ring. Returns the perpendicular pointing into
// the ring
Point2D MolDraw2D::bondInsideRing(const ROMol &mol, const Bond* &bond,
const Point2D &cds1, const Point2D &cds2) {
Atom *bgn_atom = bond->getBeginAtom();
ROMol::OEDGE_ITER nbr2, end_nbrs2;
boost::tie(nbr2, end_nbrs2) = mol.getAtomBonds(bgn_atom);
while (nbr2 != end_nbrs2) {
const Bond* bond2 = mol[*nbr2];
++nbr2;
if (bond2->getIdx() == bond->getIdx() ||
!mol.getRingInfo()->numBondRings(bond2->getIdx())) {
continue;
}
bool same_ring = false;
BOOST_FOREACH (const INT_VECT &ring, mol.getRingInfo()->bondRings()) {
if (find(ring.begin(), ring.end(), bond->getIdx()) != ring.end() &&
find(ring.begin(), ring.end(), bond2->getIdx()) != ring.end()) {
same_ring = true;
break;
}
}
if (same_ring) {
// bond and bond2 are in the same ring, so use their vectors to define
// the sign of the perpendicular.
int atom3 = bond2->getOtherAtomIdx(bond->getBeginAtomIdx());
return calcInnerPerpendicular(cds1, cds2, at_cds_[atom3]);
}
}
return calcPerpendicular(cds1, cds2);
}
// ****************************************************************************
// cds1 and cds2 are 2 atoms in a chain double bond. Returns the perpendicular
// pointing into the inside of the bond
Point2D MolDraw2D::bondInsideDoubleBond(const ROMol &mol,
const Bond* &bond) {
// a chain double bond, were it looks nicer IMO if the 2nd line is inside
// the angle of outgoing bond. Unless it's an allene, where nothing
// looks great.
const Atom *at1 = bond->getBeginAtom();
const Atom *at2 = bond->getEndAtom();
const Atom *bond_atom, *end_atom;
if (at1->getDegree() > 1) {
bond_atom = at1;
end_atom = at2;
} else {
bond_atom = at2;
end_atom = at1;
}
int at3 = -1; // to stop the compiler whinging.
ROMol::OEDGE_ITER nbr2, end_nbrs2;
boost::tie(nbr2, end_nbrs2) = mol.getAtomBonds(bond_atom);
while (nbr2 != end_nbrs2) {
const Bond* bond2 = mol[*nbr2];
++nbr2;
if (bond != bond2) {
at3 = bond2->getOtherAtomIdx(bond_atom->getIdx());
break;
}
}
return calcInnerPerpendicular(at_cds_[end_atom->getIdx()],
at_cds_[bond_atom->getIdx()], at_cds_[at3]);
}
// ****************************************************************************
// calculate normalised perpendicular to vector between two coords, such that
// it's inside the angle made between (1 and 2) and (2 and 3).
Point2D MolDraw2D::calcInnerPerpendicular(const Point2D &cds1,
const Point2D &cds2,
const Point2D &cds3) {
Point2D perp = calcPerpendicular(cds1, cds2);
double v1[2] = {cds1.x - cds2.x, cds1.y - cds2.y};
double v2[2] = {cds2.x - cds3.x, cds2.y - cds3.y};
double obv[2] = {v1[0] - v2[0], v1[1] - v2[1]};
// if dot product of centre_dir and perp < 0.0, they're pointing in opposite
// directions, so reverse perp
if (obv[0] * perp.x + obv[1] * perp.y < 0.0) {
perp.x *= -1.0;
perp.y *= -1.0;
}
return perp;
}
// ****************************************************************************
// take the coords for atnum, with neighbour nbr_cds, and move cds out to
// accommodate
// the label associated with it.
void MolDraw2D::adjustBondEndForLabel(int atnum, const Point2D &nbr_cds,
Point2D &cds) const {
if (atom_syms_[atnum].first.empty()) {
return;
}
double label_width, label_height;
getStringSize(atom_syms_[atnum].first, label_width, label_height);
double lw2 = label_width / 2.0;
double lh2 = label_height / 2.0;
double x_offset = 0.0, y_offset = 0.0;
if (fabs(nbr_cds.y - cds.y) < 1.0e-5) {
// if the bond is horizontal
x_offset = lw2;
} else {
x_offset = fabs(lh2 * (nbr_cds.x - cds.x) / (nbr_cds.y - cds.y));
if (x_offset >= lw2) {
x_offset = lw2;
}
}
if (nbr_cds.x < cds.x) {
x_offset *= -1.0;
}
if (fabs(nbr_cds.x - cds.x) < 1.0e-5) {
// if the bond is vertical
y_offset = lh2;
} else {
y_offset = fabs(lw2 * (cds.y - nbr_cds.y) / (nbr_cds.x - cds.x));
if (y_offset >= lh2) {
y_offset = lh2;
}
}
if (nbr_cds.y < cds.y) {
y_offset *= -1.0;
}
cds.x += x_offset;
cds.y += y_offset;
}
// ****************************************************************************
// adds XML-like annotation for super- and sub-script, in the same manner
// as MolDrawing.py. My first thought was for a LaTeX-like system, obviously...
pair<string, MolDraw2D::OrientType> MolDraw2D::getAtomSymbolAndOrientation(
const Atom &atom, const Point2D &nbr_sum) {
string symbol("");
// -----------------------------------
// consider the orientation
OrientType orient = C;
if (1 == atom.getDegree()) {
double islope = 0.0;
if (fabs(nbr_sum.y) > 1.0) {
islope = nbr_sum.x / fabs(nbr_sum.y);
} else {
islope = nbr_sum.x;
}
if (fabs(islope) > 0.85) {
if (islope > 0.0) {
orient = W;
} else {
orient = E;
}
} else {
if (nbr_sum.y > 0.0) {
orient = N;
} else {
orient = S;
}
}
}
// -----------------------------------
// the symbol
unsigned int iso = atom.getIsotope();
if (drawOptions().atomLabels.find(atom.getIdx()) !=
drawOptions().atomLabels.end()) {
// specified labels are trump: no matter what else happens we will show
// them.
symbol = drawOptions().atomLabels.find(atom.getIdx())->second;
} else if (drawOptions().dummiesAreAttachments && atom.getAtomicNum() == 0 &&
atom.getDegree() == 1) {
symbol = "";
} else if (isComplexQuery(&atom)) {
symbol = "?";
} else if (drawOptions().atomLabelDeuteriumTritium &&
atom.getAtomicNum() == 1 && (iso == 2 || iso == 3)) {
symbol = ((iso == 2) ? "D" : "T");
iso = 0;
} else {
std::vector<std::string> preText, postText;
int num_h = (atom.getAtomicNum() == 6 && atom.getDegree() > 0)
? 0
: atom.getTotalNumHs(); // FIX: still not quite right
if (num_h > 0 && !atom.hasQuery()) {
// the H text can come before or after the atomic symbol, depending on the
// orientation
std::string h = "H";
if (num_h > 1) {
// put the number as a subscript
h += string("<sub>") + lexical_cast<string>(num_h) + string("</sub>");
}
if (orient == MolDraw2D::W) {
preText.push_back(h);
} else {
postText.push_back(h);
}
}
if (0 != iso) {
// isotope always comes before the symbol
preText.push_back(std::string("<sup>") + lexical_cast<string>(iso) +
std::string("</sup>"));
}
if (0 != atom.getFormalCharge()) {
// charge always comes post the symbol
int ichg = atom.getFormalCharge();
string sgn = ichg > 0 ? string("+") : string("-");
ichg = abs(ichg);
if (ichg > 1) {
sgn += lexical_cast<string>(ichg);
}
// put the charge as a superscript
postText.push_back(string("<sup>") + sgn + string("</sup>"));
}
if (atom.hasProp("molAtomMapNumber")) {
// atom map always comes at the end
string map_num = "";
atom.getProp("molAtomMapNumber", map_num);
postText.push_back(std::string(":") + map_num);
}
symbol = "";
BOOST_FOREACH (const std::string &se, preText) { symbol += se; }
if (atom.getAtomicNum() != 6 || atom.getDegree() == 0 || preText.size() ||
postText.size()) {
symbol += atom.getSymbol();
}
BOOST_FOREACH (const std::string &se, postText) { symbol += se; }
}
// std::cerr << " res: " << symbol << " orient: " << orient
// << " nbr_sum:" << nbr_sum << std::endl;
return std::make_pair(symbol, orient);
}
void MolDraw2D::drawTriangle(const Point2D &cds1, const Point2D &cds2,
const Point2D &cds3) {
std::vector<Point2D> pts(3);
pts[0] = cds1;
pts[1] = cds2;
pts[2] = cds3;
drawPolygon(pts);
};
// ****************************************************************************
void MolDraw2D::drawEllipse(const Point2D &cds1, const Point2D &cds2) {
std::vector<Point2D> pts;
MolDraw2D_detail::arcPoints(cds1, cds2, pts, 0, 360);
drawPolygon(pts);
}
// ****************************************************************************
void MolDraw2D::drawRect(const Point2D &cds1, const Point2D &cds2) {
std::vector<Point2D> pts(4);
pts[0] = cds1;
pts[1] = Point2D(cds1.x, cds2.y);
pts[2] = cds2;
pts[3] = Point2D(cds2.x, cds1.y);
drawPolygon(pts);
}
void MolDraw2D::drawWavyLine(const Point2D &cds1, const Point2D &cds2,
const DrawColour &col1, const DrawColour &col2,
unsigned int nSegments, double vertOffset) {
RDUNUSED_PARAM(nSegments);
RDUNUSED_PARAM(vertOffset);
drawLine(cds1, cds2, col1, col2);
}
// ****************************************************************************
// we draw the line at cds2, perpendicular to the line cds1-cds2
void MolDraw2D::drawAttachmentLine(const Point2D &cds1, const Point2D &cds2,
const DrawColour &col, double len,
unsigned int nSegments) {
Point2D perp = calcPerpendicular(cds1, cds2);
Point2D p1 = Point2D(cds2.x - perp.x * len / 2, cds2.y - perp.y * len / 2);
Point2D p2 = Point2D(cds2.x + perp.x * len / 2, cds2.y + perp.y * len / 2);
drawWavyLine(p1, p2, col, col, nSegments);
}
} // EO namespace RDKit
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