class BondEditor(ToolInstance):
help = "https://github.com/QChASM/SEQCROW/wiki/Bond-Editor-Tool"
SESSION_ENDURING = False
SESSION_SAVE = False
def __init__(self, session, name):
super().__init__(session, name)
self.tool_window = MainToolWindow(self)
self.settings = _BondEditorSettings(session, name)
self._build_ui()
def _build_ui(self):
layout = QGridLayout()
tabs = QTabWidget()
layout.addWidget(tabs)
ts_bond_tab = QWidget()
ts_options = QFormLayout(ts_bond_tab)
self.tsbond_color = ColorButton(has_alpha_channel=False,
max_size=(16, 16))
self.tsbond_color.set_color(self.settings.tsbond_color)
ts_options.addRow("color:", self.tsbond_color)
self.tsbond_transparency = QSpinBox()
self.tsbond_transparency.setRange(1, 99)
self.tsbond_transparency.setValue(self.settings.tsbond_transparency)
self.tsbond_transparency.setSuffix("%")
ts_options.addRow("transparency:", self.tsbond_transparency)
self.tsbond_radius = QDoubleSpinBox()
self.tsbond_radius.setRange(0.01, 1)
self.tsbond_radius.setDecimals(3)
self.tsbond_radius.setSingleStep(0.005)
self.tsbond_radius.setSuffix(" \u212B")
self.tsbond_radius.setValue(self.settings.tsbond_radius)
ts_options.addRow("radius:", self.tsbond_radius)
draw_tsbonds = QPushButton("draw TS bonds on selected atoms/bonds")
draw_tsbonds.clicked.connect(self.run_tsbond)
ts_options.addRow(draw_tsbonds)
self.draw_tsbonds = draw_tsbonds
erase_tsbonds = QPushButton("erase selected TS bonds")
erase_tsbonds.clicked.connect(self.run_erase_tsbond)
ts_options.addRow(erase_tsbonds)
self.erase_tsbonds = erase_tsbonds
bond_tab = QWidget()
bond_options = QFormLayout(bond_tab)
self.bond_halfbond = QCheckBox()
self.bond_halfbond.setChecked(self.settings.bond_halfbond)
self.bond_halfbond.setToolTip(
"each half of the bond will be colored according to the atom's color"
)
bond_options.addRow("half-bond:", self.bond_halfbond)
self.bond_color = ColorButton(has_alpha_channel=True,
max_size=(16, 16))
self.bond_color.set_color(self.settings.bond_color)
self.bond_color.setEnabled(
self.bond_halfbond.checkState() != Qt.Checked)
self.bond_halfbond.stateChanged.connect(
lambda state, widget=self.bond_color: self.bond_color.setEnabled(
state != Qt.Checked))
bond_options.addRow("color:", self.bond_color)
self.bond_radius = QDoubleSpinBox()
self.bond_radius.setRange(0.01, 1)
self.bond_radius.setDecimals(3)
self.bond_radius.setSingleStep(0.005)
self.bond_radius.setSuffix(" \u212B")
self.bond_radius.setValue(self.settings.bond_radius)
bond_options.addRow("radius:", self.bond_radius)
draw_tsbonds = QPushButton("draw bond between selected atoms")
draw_tsbonds.clicked.connect(self.run_bond)
bond_options.addRow(draw_tsbonds)
self.draw_tsbonds = draw_tsbonds
erase_bonds = QPushButton("erase selected bonds")
erase_bonds.clicked.connect(
lambda *, ses=self.session: run(ses, "delete bonds sel"))
bond_options.addRow(erase_bonds)
self.erase_bonds = erase_bonds
hbond_tab = QWidget()
hbond_options = QFormLayout(hbond_tab)
self.hbond_color = ColorButton(has_alpha_channel=True,
max_size=(16, 16))
self.hbond_color.set_color(self.settings.hbond_color)
hbond_options.addRow("color:", self.hbond_color)
self.hbond_radius = QDoubleSpinBox()
self.hbond_radius.setDecimals(3)
self.hbond_radius.setSuffix(" \u212B")
self.hbond_radius.setValue(self.settings.hbond_radius)
hbond_options.addRow("radius:", self.hbond_radius)
self.hbond_dashes = QSpinBox()
self.hbond_dashes.setRange(0, 28)
self.hbond_dashes.setSingleStep(2)
self.hbond_radius.setSingleStep(0.005)
self.hbond_dashes.setValue(self.settings.hbond_dashes)
hbond_options.addRow("dashes:", self.hbond_dashes)
draw_hbonds = QPushButton("draw H-bonds")
draw_hbonds.clicked.connect(self.run_hbond)
hbond_options.addRow(draw_hbonds)
self.draw_hbonds = draw_hbonds
erase_hbonds = QPushButton("erase all H-bonds")
erase_hbonds.clicked.connect(
lambda *, ses=self.session: run(ses, "~hbonds"))
hbond_options.addRow(erase_hbonds)
self.erase_hbonds = erase_hbonds
tm_bond_tab = QWidget()
tm_bond_options = QFormLayout(tm_bond_tab)
self.tm_bond_color = ColorButton(has_alpha_channel=True,
max_size=(16, 16))
self.tm_bond_color.set_color(self.settings.tm_bond_color)
tm_bond_options.addRow("color:", self.tm_bond_color)
self.tm_bond_radius = QDoubleSpinBox()
self.tm_bond_radius.setDecimals(3)
self.tm_bond_radius.setSuffix(" \u212B")
self.tm_bond_radius.setValue(self.settings.tm_bond_radius)
tm_bond_options.addRow("radius:", self.tm_bond_radius)
self.tm_bond_dashes = QSpinBox()
self.tm_bond_dashes.setRange(0, 28)
self.tm_bond_dashes.setSingleStep(2)
self.tm_bond_radius.setSingleStep(0.005)
self.tm_bond_dashes.setValue(self.settings.tm_bond_dashes)
tm_bond_options.addRow("dashes:", self.tm_bond_dashes)
draw_tm_bonds = QPushButton("draw metal coordination bonds")
draw_tm_bonds.clicked.connect(self.run_tm_bond)
tm_bond_options.addRow(draw_tm_bonds)
self.draw_tm_bonds = draw_tm_bonds
erase_tm_bonds = QPushButton("erase all metal coordination bonds")
erase_tm_bonds.clicked.connect(self.del_tm_bond)
tm_bond_options.addRow(erase_tm_bonds)
self.erase_tm_bonds = erase_tm_bonds
bond_length_tab = QWidget()
bond_length_layout = QFormLayout(bond_length_tab)
self.bond_distance = QDoubleSpinBox()
self.bond_distance.setRange(0.5, 10.0)
self.bond_distance.setSingleStep(0.05)
self.bond_distance.setValue(1.51)
self.bond_distance.setSuffix(" \u212B")
bond_length_layout.addRow("bond length:", self.bond_distance)
self.move_fragment = QComboBox()
self.move_fragment.addItems(["both", "smaller", "larger"])
bond_length_layout.addRow("move side:", self.move_fragment)
bond_lookup = QGroupBox("bond length lookup:")
bond_lookup_layout = QGridLayout(bond_lookup)
bond_lookup_layout.addWidget(
QLabel("elements:"),
0,
0,
)
self.ele1 = ElementButton("C", single_state=True)
self.ele1.clicked.connect(
lambda *args, button=self.ele1: self.open_ptable(button))
bond_lookup_layout.addWidget(self.ele1, 0, 1,
Qt.AlignRight | Qt.AlignTop)
bond_lookup_layout.addWidget(QLabel("-"), 0, 2,
Qt.AlignHCenter | Qt.AlignVCenter)
self.ele2 = ElementButton("C", single_state=True)
self.ele2.clicked.connect(
lambda *args, button=self.ele2: self.open_ptable(button))
bond_lookup_layout.addWidget(self.ele2, 0, 3,
Qt.AlignLeft | Qt.AlignTop)
bond_lookup_layout.addWidget(QLabel("bond order:"), 1, 0)
self.bond_order = BondOrderSpinBox()
self.bond_order.setRange(1., 3.)
self.bond_order.setValue(1)
self.bond_order.setSingleStep(0.5)
self.bond_order.setDecimals(1)
self.bond_order.valueChanged.connect(self.check_bond_lengths)
bond_lookup_layout.addWidget(self.bond_order, 1, 1, 1, 3)
bond_lookup_layout.setColumnStretch(0, 0)
bond_lookup_layout.setColumnStretch(1, 0)
bond_lookup_layout.setColumnStretch(2, 0)
bond_lookup_layout.setColumnStretch(3, 1)
bond_length_layout.addRow(bond_lookup)
self.status = QStatusBar()
self.status.setSizeGripEnabled(False)
bond_lookup_layout.addWidget(self.status, 2, 0, 1, 4)
self.do_bond_change = QPushButton("change selected bond lengths")
self.do_bond_change.clicked.connect(self.change_bond_length)
bond_length_layout.addRow(self.do_bond_change)
tabs.addTab(bond_tab, "covalent bonds")
tabs.addTab(ts_bond_tab, "TS bonds")
tabs.addTab(hbond_tab, "H-bonds")
tabs.addTab(tm_bond_tab, "coordination bonds")
tabs.addTab(bond_length_tab, "bond length")
self.tool_window.ui_area.setLayout(layout)
self.tool_window.manage(None)
def run_tsbond(self, *args):
args = ["tsbond", "sel"]
color = self.tsbond_color.get_color()
args.extend(["color", "rgb(%i, %i, %i)" % tuple(color[:-1])])
self.settings.tsbond_color = tuple([c / 255. for c in color])
radius = self.tsbond_radius.value()
args.extend(["radius", "%.3f" % radius])
self.settings.tsbond_radius = radius
transparency = self.tsbond_transparency.value()
args.extend(["transparency", "%i" % transparency])
self.settings.tsbond_transparency = transparency
run(self.session, " ".join(args))
def run_erase_tsbond(self, *args):
run(self.session, "~tsbond sel")
def run_bond(self, *args):
# TODO: switch to `bond sel` in 1.2
sel = selected_atoms(self.session)
halfbond = self.bond_halfbond.checkState() == Qt.Checked
self.settings.bond_halfbond = halfbond
if not halfbond:
color = self.bond_color.get_color()
color = tuple(x / 255. for x in color)
self.settings.bond_color = color
radius = self.bond_radius.value()
self.settings.bond_radius = radius
for b in selected_bonds(self.session):
b.halfbond = halfbond
if not halfbond:
b.color = np.array([int(x * 255) for x in color])
b.radius = radius
for i, a1 in enumerate(sel):
for a2 in sel[:i]:
if a1.structure is a2.structure and a2 not in a1.neighbors:
new_bond = a1.structure.new_bond(a1, a2)
new_bond.halfbond = halfbond
if not halfbond:
new_bond.color = np.array(
[int(x * 255) for x in color])
new_bond.radius = radius
def run_hbond(self, *args):
args = ["hbonds", "reveal", "true"]
color = self.hbond_color.get_color()
args.extend(["color", "rgb(%i, %i, %i)" % tuple(color[:-1])])
self.settings.hbond_color = tuple([c / 255. for c in color])
radius = self.hbond_radius.value()
args.extend(["radius", "%.3f" % radius])
self.settings.hbond_radius = radius
dashes = self.hbond_dashes.value()
args.extend(["dashes", "%i" % dashes])
self.settings.hbond_dashes = dashes
run(self.session, " ".join(args))
def run_tm_bond(self, *args):
color = self.tm_bond_color.get_color()
self.settings.tm_bond_color = tuple([c / 255. for c in color])
radius = self.tm_bond_radius.value()
self.settings.tm_bond_radius = radius
dashes = self.tm_bond_dashes.value()
self.settings.tm_bond_dashes = dashes
models = self.session.models.list(type=AtomicStructure)
for model in models:
rescol = ResidueCollection(model, bonds_matter=False)
try:
tm_list = rescol.find([
AnyTransitionMetal(), "Na", "K", "Rb", "Cs", "Fr", "Mg",
"Ca", "Sr", "Ba", "Ra"
])
for tm in tm_list:
for atom in rescol.atoms:
if atom is tm:
continue
if atom.is_connected(tm):
pbg = model.pseudobond_group(
model.PBG_METAL_COORDINATION,
create_type="normal")
pbg.new_pseudobond(tm.chix_atom, atom.chix_atom)
pbg.dashes = dashes
pbg.color = color
pbg.radius = radius
except LookupError:
pass
def del_tm_bond(self, *args):
models = self.session.models.list(type=AtomicStructure)
for model in models:
pbg = model.pseudobond_group(model.PBG_METAL_COORDINATION,
create_type=None)
if pbg is not None:
pbg.delete()
def open_ptable(self, button):
self.tool_window.create_child_window("select element",
window_class=PTable2,
button=button,
callback=self.check_bond_lengths)
def check_bond_lengths(self, *args):
ele1 = self.ele1.text()
ele2 = self.ele2.text()
key = ORDER_BOND_ORDER.key(ele1, ele2)
order = "%.1f" % self.bond_order.value()
if key in ORDER_BOND_ORDER.bonds and order in ORDER_BOND_ORDER.bonds[
key]:
self.bond_distance.setValue(ORDER_BOND_ORDER.bonds[key][order])
self.status.showMessage("")
else:
self.status.showMessage("no bond data for %s-%s %sx bonds" %
(ele1, ele2, order))
def change_bond_length(self, *args):
dist = self.bond_distance.value()
atom_pairs = []
sel = selected_atoms(self.session)
if len(sel) == 2 and sel[0].structure is sel[1].structure:
atom_pairs.append(sel)
for bond in selected_bonds(self.session):
if not all(atom in sel for atom in bond.atoms):
atom_pairs.append(bond.atoms)
for bond in selected_pseudobonds(self.session):
if not all(atom in sel for atom in bond.atoms):
atom_pairs.append(bond.atoms)
for pair in atom_pairs:
atom1, atom2 = pair
frag1 = get_fragment(atom1,
stop=atom2,
max_len=atom1.structure.num_atoms)
frag2 = get_fragment(atom2,
stop=atom1,
max_len=atom1.structure.num_atoms)
v = atom2.coord - atom1.coord
cur_dist = np.linalg.norm(v)
change = dist - cur_dist
if self.move_fragment.currentText() == "both":
change = 0.5 * change
frag1.coords -= change * v / cur_dist
frag2.coords += change * v / cur_dist
elif self.move_fragment.currentText() == "smaller":
if len(frag1) < len(frag2) or (len(frag1) == len(frag2)
and sum(frag1.elements.masses) <
sum(frag2.elements.masses)):
frag1.coords -= change * v / cur_dist
else:
frag2.coords += change * v / cur_dist
elif self.move_fragment.currentText() == "larger":
if len(frag1) > len(frag2) or (len(frag1) == len(frag2)
and sum(frag1.elements.masses) >
sum(frag2.elements.masses)):
frag1.coords -= change * v / cur_dist
else:
frag2.coords += change * v / cur_dist
class Thermochem(ToolInstance):
"""tool for calculating free energy corrections based on frequencies and energies
associated with FileReaders
there are two tabs: absolute and relative
the absolute tab can be used to combine the thermo corrections from one
FileReader with the energy of another
the relative tab can do the same, but it prints the energies relative to
those of another FileReader
multiple molecule groups can be added (i.e. for reactions with multiple
reactants and products)
each molecule group can have multiple conformers
the energies of these conformers are boltzmann weighted, and the boltzmann-weighted
energy is used to calculate the energy of either the reference group or the 'other' group"""
SESSION_ENDURING = False
SESSION_SAVE = False
help = "https://github.com/QChASM/SEQCROW/wiki/Process-Thermochemistry-Tool"
theory_helper = {
"Grimme's Quasi-RRHO": "https://doi.org/10.1002/chem.201200497",
"Truhlar's Quasi-Harmonic": "https://doi.org/10.1021/jp205508z"
}
def __init__(self, session, name):
super().__init__(session, name)
self.display_name = "Thermochemistry"
self.tool_window = MainToolWindow(self)
self.settings = _ComputeThermoSettings(self.session, name)
self.nrg_fr = {}
self.thermo_fr = {}
self.thermo_co = {}
self._headers = []
self._data = []
self._build_ui()
self.set_sp()
self.set_thermo_mdl()
self.calc_relative_thermo()
def _build_ui(self):
#each group has an empty widget at the bottom so they resize the way I want while also having the
#labels where I want them
layout = QGridLayout()
self.tab_widget = QTabWidget()
layout.addWidget(self.tab_widget)
#layout for absolute thermo stuff
absolute_widget = QWidget()
absolute_layout = QGridLayout(absolute_widget)
#box for sp
sp_area_widget = QGroupBox("Single-point")
sp_layout = QFormLayout(sp_area_widget)
self.sp_selector = FilereaderComboBox(self.session,
otherItems=['energy'])
self.sp_selector.currentIndexChanged.connect(self.set_sp)
sp_layout.addRow(self.sp_selector)
self.sp_table = QTableWidget()
self.sp_table.setColumnCount(3)
self.sp_table.setShowGrid(False)
self.sp_table.horizontalHeader().hide()
self.sp_table.verticalHeader().hide()
self.sp_table.setFrameShape(QTableWidget.NoFrame)
self.sp_table.setSelectionMode(QTableWidget.NoSelection)
self.sp_table.insertRow(0)
sp_layout.addRow(self.sp_table)
#box for thermo
therm_area_widget = QGroupBox("Thermal corrections")
thermo_layout = QFormLayout(therm_area_widget)
self.thermo_selector = FilereaderComboBox(self.session,
otherItems=['frequency'])
self.thermo_selector.currentIndexChanged.connect(self.set_thermo_mdl)
thermo_layout.addRow(self.thermo_selector)
self.temperature_line = QDoubleSpinBox()
self.temperature_line.setMaximum(2**31 - 1)
self.temperature_line.setValue(298.15)
self.temperature_line.setSingleStep(10)
self.temperature_line.setSuffix(" K")
self.temperature_line.setMinimum(0)
self.temperature_line.valueChanged.connect(self.set_thermo)
thermo_layout.addRow("T =", self.temperature_line)
self.v0_edit = QDoubleSpinBox()
self.v0_edit.setMaximum(4000)
self.v0_edit.setValue(self.settings.w0)
self.v0_edit.setSingleStep(25)
self.v0_edit.setSuffix(" cm\u207b\u00b9")
self.v0_edit.valueChanged.connect(self.set_thermo)
self.v0_edit.setMinimum(0)
self.v0_edit.setToolTip(
"frequency parameter for quasi treatments of entropy")
thermo_layout.addRow("𝜔<sub>0</sub> =", self.v0_edit)
self.thermo_table = QTableWidget()
self.thermo_table.setColumnCount(3)
self.thermo_table.setShowGrid(False)
self.thermo_table.horizontalHeader().hide()
self.thermo_table.verticalHeader().hide()
self.thermo_table.setFrameShape(QTableWidget.NoFrame)
self.thermo_table.setSelectionMode(QTableWidget.NoSelection)
thermo_layout.addRow(self.thermo_table)
# for for total
sum_area_widget = QGroupBox("Thermochemistry")
sum_layout = QFormLayout(sum_area_widget)
self.sum_table = QTableWidget()
self.sum_table.setColumnCount(3)
self.sum_table.setShowGrid(False)
self.sum_table.horizontalHeader().hide()
self.sum_table.verticalHeader().hide()
self.sum_table.setFrameShape(QTableWidget.NoFrame)
self.sum_table.setSelectionMode(QTableWidget.NoSelection)
sum_layout.addRow(self.sum_table)
splitter = QSplitter(Qt.Horizontal)
splitter.setChildrenCollapsible(False)
splitter.addWidget(sp_area_widget)
splitter.addWidget(therm_area_widget)
splitter.addWidget(sum_area_widget)
absolute_layout.addWidget(splitter)
self.status = QStatusBar()
self.status.setSizeGripEnabled(False)
self.status.setStyleSheet("color: red")
absolute_layout.addWidget(self.status, 1, 0, 1, 1, Qt.AlignTop)
self.tab_widget.addTab(absolute_widget, "absolute")
relative_widget = QWidget()
relative_layout = QGridLayout(relative_widget)
size = [self.settings.ref_col_1, self.settings.ref_col_2]
self.ref_group = ThermoGroup("reference group", self.session,
self.nrg_fr, self.thermo_co, size)
self.ref_group.changes.connect(self.calc_relative_thermo)
relative_layout.addWidget(self.ref_group, 0, 0, 1, 3, Qt.AlignTop)
size = [self.settings.other_col_1, self.settings.other_col_2]
self.other_group = ThermoGroup("other group", self.session,
self.nrg_fr, self.thermo_co, size)
self.other_group.changes.connect(self.calc_relative_thermo)
relative_layout.addWidget(self.other_group, 0, 3, 1, 3, Qt.AlignTop)
self.relative_temperature = QDoubleSpinBox()
self.relative_temperature.setMaximum(2**31 - 1)
self.relative_temperature.setValue(self.settings.rel_temp)
self.relative_temperature.setSingleStep(10)
self.relative_temperature.setSuffix(" K")
self.relative_temperature.setMinimum(0)
self.relative_temperature.valueChanged.connect(
self.calc_relative_thermo)
relative_layout.addWidget(QLabel("T ="), 1, 0, 1, 1,
Qt.AlignRight | Qt.AlignVCenter)
relative_layout.addWidget(self.relative_temperature, 1, 1, 1, 5,
Qt.AlignLeft | Qt.AlignVCenter)
self.relative_v0 = QDoubleSpinBox()
self.relative_v0.setMaximum(2**31 - 1)
self.relative_v0.setValue(self.settings.w0)
self.relative_v0.setSingleStep(25)
self.relative_v0.setSuffix(" cm\u207b\u00b9")
self.relative_v0.setMinimum(0)
self.relative_v0.setToolTip(
"frequency parameter for quasi treatments of entropy")
self.relative_v0.valueChanged.connect(self.calc_relative_thermo)
relative_layout.addWidget(QLabel("𝜔<sub>0</sub> ="), 2, 0, 1, 1,
Qt.AlignRight | Qt.AlignVCenter)
relative_layout.addWidget(self.relative_v0, 2, 1, 1, 5,
Qt.AlignLeft | Qt.AlignVCenter)
relative_layout.addWidget(
QLabel("Boltzmann-weighted relative energies in kcal/mol:"), 3, 0,
1, 6, Qt.AlignVCenter | Qt.AlignLeft)
self.relative_table = QTextBrowser()
self.relative_table.setMaximumHeight(
4 * self.relative_table.fontMetrics().boundingRect("Q").height())
relative_layout.addWidget(self.relative_table, 4, 0, 1, 6, Qt.AlignTop)
relative_layout.setRowStretch(0, 1)
relative_layout.setRowStretch(1, 0)
relative_layout.setRowStretch(2, 0)
relative_layout.setRowStretch(3, 0)
relative_layout.setRowStretch(4, 0)
self.tab_widget.addTab(relative_widget, "relative")
#menu stuff
menu = QMenuBar()
export = menu.addMenu("&Export")
copy = QAction("&Copy CSV to clipboard", self.tool_window.ui_area)
copy.triggered.connect(self.copy_csv)
shortcut = QKeySequence(Qt.CTRL + Qt.Key_C)
copy.setShortcut(shortcut)
export.addAction(copy)
self.copy = copy
save = QAction("&Save CSV...", self.tool_window.ui_area)
save.triggered.connect(self.save_csv)
#this shortcut interferes with main window's save shortcut
#I've tried different shortcut contexts to no avail
#thanks Qt...
#shortcut = QKeySequence(Qt.CTRL + Qt.Key_S)
#save.setShortcut(shortcut)
#save.setShortcutContext(Qt.WidgetShortcut)
export.addAction(save)
delimiter = export.addMenu("Delimiter")
comma = QAction("comma", self.tool_window.ui_area, checkable=True)
comma.setChecked(self.settings.delimiter == "comma")
comma.triggered.connect(lambda *args, delim="comma": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(comma)
tab = QAction("tab", self.tool_window.ui_area, checkable=True)
tab.setChecked(self.settings.delimiter == "tab")
tab.triggered.connect(lambda *args, delim="tab": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(tab)
space = QAction("space", self.tool_window.ui_area, checkable=True)
space.setChecked(self.settings.delimiter == "space")
space.triggered.connect(lambda *args, delim="space": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(space)
semicolon = QAction("semicolon",
self.tool_window.ui_area,
checkable=True)
semicolon.setChecked(self.settings.delimiter == "semicolon")
semicolon.triggered.connect(lambda *args, delim="semicolon": self.
settings.__setattr__("delimiter", delim))
delimiter.addAction(semicolon)
add_header = QAction("&Include CSV header",
self.tool_window.ui_area,
checkable=True)
add_header.setChecked(self.settings.include_header)
add_header.triggered.connect(self.header_check)
export.addAction(add_header)
comma.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=space: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=space: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
space.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
space.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
space.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=space: action.setChecked(False))
menu.setNativeMenuBar(False)
self._menu = menu
layout.setMenuBar(menu)
menu.setVisible(True)
self.tool_window.ui_area.setLayout(layout)
self.tool_window.manage(None)
def calc_relative_thermo(self, *args):
"""changes the values on the 'relative' tab
called when the tool is opened and whenever something changes on the relative tab"""
def calc_free_energies(nrg_list, co_list, T, w0):
"""returns lists for ZPVE, H, RRHO G, QRRHO G, and QHARM G
for the items in nrg_list and co_list at temperature T
and frequency parameter w0"""
ZPVEs = []
if all(co.frequency.anharm_data for co_group in co_list
for co in co_group):
anharm_ZVPEs = []
else:
anharm_ZVPEs = None
Hs = []
Gs = []
RRHOG = []
QHARMG = []
for i in range(0, len(nrg_list)):
ZPVEs.append([])
if anharm_ZVPEs is not None:
anharm_ZVPEs.append([])
Hs.append([])
Gs.append([])
RRHOG.append([])
QHARMG.append([])
for nrg, co in zip(nrg_list[i], co_list[i]):
ZPVE = co.ZPVE
ZPVEs[-1].append(nrg + ZPVE)
if anharm_ZVPEs is not None:
zpve_anharm = co.calc_zpe(anharmonic=True)
anharm_ZVPEs[-1].append(nrg + zpve_anharm)
dH = co.therm_corr(T, w0, CompOutput.RRHO)[1]
Hs[-1].append(nrg + dH)
dG = co.calc_G_corr(temperature=T,
v0=w0,
method=CompOutput.RRHO)
Gs[-1].append(nrg + dG)
dQRRHOG = co.calc_G_corr(temperature=T,
v0=w0,
method=CompOutput.QUASI_RRHO)
RRHOG[-1].append(nrg + dQRRHOG)
dQHARMG = co.calc_G_corr(temperature=T,
v0=w0,
method=CompOutput.QUASI_HARMONIC)
QHARMG[-1].append(nrg + dQHARMG)
return ZPVEs, anharm_ZVPEs, Hs, Gs, RRHOG, QHARMG
def boltzmann_weight(energies1, energies2, T):
"""
energies - list of lists
list axis 0 - molecule groups
axis 1 - energies of conformers
boltzmann weight energies for conformers
combine energies for molecule groups
return the difference"""
totals1 = []
totals2 = []
beta = UNIT.HART_TO_JOULE / (PHYSICAL.KB * T)
for energy_group in energies1:
if len(energy_group) == 0:
continue
rezero = min(energy_group)
rel_nrgs = [(x - rezero) for x in energy_group]
weights = [np.exp(-beta * nrg) for nrg in rel_nrgs]
totals1.append(-PHYSICAL.BOLTZMANN * T * np.log(sum(weights)) +
rezero * UNIT.HART_TO_KCAL)
for energy_group in energies2:
if len(energy_group) == 0:
continue
rezero = min(energy_group)
rel_nrgs = [(x - rezero) for x in energy_group]
weights = [np.exp(-beta * nrg) for nrg in rel_nrgs]
totals2.append(-PHYSICAL.BOLTZMANN * T * np.log(sum(weights)) +
rezero * UNIT.HART_TO_KCAL)
return sum(totals2) - sum(totals1)
ref_Es = self.ref_group.energies()
ref_cos = self.ref_group.compOutputs()
other_Es = self.other_group.energies()
other_cos = self.other_group.compOutputs()
if any(
len(x) == 0 or all(len(y) == 0 for y in x)
for x in [ref_Es, other_Es]):
self.relative_table.setText("not enough data")
return
T = self.relative_temperature.value()
self.settings.rel_temp = T
w0 = self.relative_v0.value()
if w0 != self.settings.w0:
self.settings.w0 = w0
rel_E = boltzmann_weight(ref_Es, other_Es, T)
headers = ["ΔE"]
data = [rel_E]
empty_groups = []
for i, group in enumerate(ref_cos):
if len(group) == 0:
empty_groups.append(i)
for ndx in empty_groups[::-1]:
ref_Es.pop(ndx)
ref_cos.pop(ndx)
empty_groups = []
for i, group in enumerate(other_cos):
if len(group) == 0:
empty_groups.append(i)
for ndx in empty_groups[::-1]:
other_Es.pop(ndx)
other_cos.pop(ndx)
if not any(
len(x) == 0 or all(len(y) == 0 for y in x)
for x in [ref_cos, other_cos]):
rel_E = boltzmann_weight(ref_Es, other_Es, T)
data = [rel_E]
ref_ZPVEs, ref_anharm_zpve, ref_Hs, ref_Gs, ref_QRRHOGs, ref_QHARMGs = calc_free_energies(
ref_Es, ref_cos, T, w0)
other_ZPVEs, other_anharm_zpve, other_Hs, other_Gs, other_QRRHOGs, other_QHARMGs = calc_free_energies(
other_Es, other_cos, T, w0)
rel_ZPVE = boltzmann_weight(ref_ZPVEs, other_ZPVEs, T)
rel_H = boltzmann_weight(ref_Hs, other_Hs, T)
rel_G = boltzmann_weight(ref_Gs, other_Gs, T)
rel_QRRHOG = boltzmann_weight(ref_QRRHOGs, other_QRRHOGs, T)
rel_QHARMG = boltzmann_weight(ref_QHARMGs, other_QHARMGs, T)
if ref_anharm_zpve and other_anharm_zpve:
rel_anharm_ZPVE = boltzmann_weight(ref_anharm_zpve,
other_anharm_zpve, T)
headers.extend([
"ΔZPE",
"ΔZPE<sub>anh</sub>",
"ΔH<sub>RRHO</sub>",
"ΔG<sub>RRHO</sub>",
"ΔG<sub>Quasi-RRHO</sub>",
"ΔG<sub>Quasi-Harmonic</sub>",
])
data.extend([
rel_ZPVE,
rel_anharm_ZPVE,
rel_H,
rel_G,
rel_QRRHOG,
rel_QHARMG,
])
else:
headers.extend([
"ΔZPE",
"ΔH<sub>RRHO</sub>",
"ΔG<sub>RRHO</sub>",
"ΔG<sub>Quasi-RRHO</sub>",
"ΔG<sub>Quasi-Harmonic</sub>",
])
data.extend([
rel_ZPVE,
rel_H,
rel_G,
rel_QRRHOG,
rel_QHARMG,
])
self._headers = headers
self._data = data
s = "<table style=\"border: 1px solid ghostwhite;\">\n"
s += "\t<tr>\n"
for header in headers:
s += "\t\t<th style=\"text-align: center; border: 1px solid ghostwhite; padding-left: 5px; padding-right: 5px\">%s</th>\n" % header
s += "\t</tr>\n"
s += "\t<tr>\n"
for val in data:
s += "\t\t<td style=\"text-align: center; border: 1px solid ghostwhite; padding-left: 5px; padding-right: 5px\">%.1f</td>\n" % val
s += "\t</tr>\n"
s += "</table>"
self.relative_table.setText(s)
def open_link(self, theory):
"""open the oft-cited QRRHO or QHARM reference"""
link = self.theory_helper[theory]
run(self.session, "open %s" % link)
def save_csv(self):
"""save data on current tab to CSV file"""
filename, _ = QFileDialog.getSaveFileName(filter="CSV Files (*.csv)")
if filename:
s = self.get_csv()
with open(filename, 'w') as f:
f.write(s.strip())
self.session.logger.status("saved to %s" % filename)
def copy_csv(self):
"""put CSV data for current tab on the clipboard"""
app = QApplication.instance()
clipboard = app.clipboard()
csv = self.get_csv()
clipboard.setText(csv)
self.session.logger.status("copied to clipboard")
def get_csv(self):
"""get CSV data for the current tab"""
if self.settings.delimiter == "comma":
delim = ","
elif self.settings.delimiter == "space":
delim = " "
elif self.settings.delimiter == "tab":
delim = "\t"
elif self.settings.delimiter == "semicolon":
delim = ";"
if self.tab_widget.currentIndex() == 0:
s = ""
if self.settings.include_header:
link_re = QRegularExpression("<a[\d\D]*>(𝛿?Δ?[\d\D]*)</a>")
# get header labels from the tables
for table in [
self.sp_table, self.thermo_table, self.sum_table
]:
for row in range(0, table.rowCount()):
item = table.cellWidget(row, 0)
text = item.text()
text = text.replace(" =", "")
text = text.replace("<sub>", "(")
text = text.replace("</sub>", ")")
# if there's a link like for QRRHO G, remove the link
if "href=" in text:
match = link_re.match(text)
text = match.captured(1)
text = text.replace("𝛿", "d")
s += "%s%s" % (text, delim)
s += "SP_File%sThermo_File\n" % delim
# get values from tables
for table in [self.sp_table, self.thermo_table, self.sum_table]:
for row in range(0, table.rowCount()):
item = table.cellWidget(row, 1)
s += "%s%s" % (item.text(), delim)
sp_mdl = self.sp_selector.currentData()
sp_name = sp_mdl.name
therm_mdl = self.thermo_selector.currentData()
s += "%s" % sp_name
if therm_mdl:
therm_name = therm_mdl.name
s += "%s%s" % (delim, therm_name)
s += "\n"
elif self.tab_widget.currentIndex() == 1:
s = ""
if self.settings.include_header:
link_re = QRegularExpression("<a[\d\D]*>(𝛿?Δ?[\d\D]*)</a>")
# get header labels from the tables
for text in self._headers:
text = text.replace(" =", "")
text = text.replace("<sub>", "(")
text = text.replace("</sub>", ")")
# if there's a link like for QRRHO G, remove the link
if "href=" in text:
match = link_re.match(text)
text = match.captured(1)
text = text.replace("𝛿", "d")
s += "%s%s" % (text, delim)
s = s.rstrip(delim)
s += "\n"
s += delim.join(["%.1f" % val for val in self._data])
return s
def header_check(self, state):
"""user has [un]checked the 'include header' option on the menu"""
if state:
self.settings.include_header = True
else:
self.settings.include_header = False
def set_sp(self):
"""set energy entry for when sp model changes"""
self.sp_table.setRowCount(0)
if self.sp_selector.currentIndex() >= 0:
fr = self.sp_selector.currentData()
self.check_geometry_rmsd("SP")
self.sp_table.insertRow(0)
nrg_label = QLabel("E =")
nrg_label.setAlignment(Qt.AlignRight | Qt.AlignVCenter)
self.sp_table.setCellWidget(0, 0, nrg_label)
unit_label = ReadOnlyTableItem()
unit_label.setData(Qt.DisplayRole, "E\u2095")
unit_label.setTextAlignment(Qt.AlignLeft | Qt.AlignVCenter)
self.sp_table.setItem(0, 2, unit_label)
sp_nrg = SmallLineEdit("%.6f" % fr.other['energy'])
sp_nrg.setReadOnly(True)
sp_nrg.setFrame(False)
self.sp_table.setCellWidget(0, 1, sp_nrg)
self.sp_table.resizeRowToContents(0)
self.sp_table.resizeColumnToContents(0)
self.sp_table.resizeColumnToContents(1)
self.sp_table.resizeColumnToContents(2)
self.update_sum()
def set_thermo_mdl(self):
"""
frequencies filereader has changed on the absolute tab
also changes the temperature option (on the absolute tab only)
"""
if self.thermo_selector.currentIndex() >= 0:
fr = self.thermo_selector.currentData()
self.check_geometry_rmsd("THERM")
if 'temperature' in fr.other:
self.temperature_line.setValue(fr.other['temperature'])
self.set_thermo()
def check_geometry_rmsd(self, *args):
"""check RMSD between energy and frequency filereader on the absolute tab
if the RMSD is > 10^-5 or the number of atoms is different, put a warning in the
status bar"""
if self.thermo_selector.currentIndex(
) >= 0 and self.sp_selector.currentIndex() >= 0:
fr = self.sp_selector.currentData()
fr2 = self.thermo_selector.currentData()
if len(fr.atoms) != len(fr2.atoms):
self.status.showMessage(
"structures are not the same: different number of atoms")
return
geom = Geometry(fr)
geom2 = Geometry(fr2)
rmsd = geom.RMSD(geom2)
if not isclose(rmsd, 0, atol=10**-5):
rmsd = geom.RMSD(geom2, sort=True)
if not isclose(rmsd, 0, atol=10**-5):
self.status.showMessage(
"structures might not be the same - RMSD = %.4f" % rmsd)
else:
self.status.showMessage("")
def set_thermo(self):
"""computes thermo corrections and sets thermo entries for when thermo model changes"""
#index of combobox is -1 when combobox has no entries
self.thermo_table.setRowCount(0)
if self.thermo_selector.currentIndex() >= 0:
fr = self.thermo_selector.currentData()
if fr not in self.thermo_co:
self.thermo_co[fr] = CompOutput(fr)
co = self.thermo_co[fr]
v0 = self.v0_edit.value()
if v0 != self.settings.w0:
self.settings.w0 = v0
T = self.temperature_line.value()
if not T:
return
dZPE = co.ZPVE
#compute enthalpy and entropy at this temperature
#AaronTools uses Grimme's Quasi-RRHO, but this is the same as RRHO when w0=0
dE, dH, s = co.therm_corr(temperature=T, v0=0, method="RRHO")
rrho_dg = dH - T * s
#compute G with quasi entropy treatments
qrrho_dg = co.calc_G_corr(v0=v0, temperature=T, method="QRRHO")
qharm_dg = co.calc_G_corr(v0=v0, temperature=T, method="QHARM")
items = [(
"𝛿ZPE =",
dZPE,
None,
"lowest energy the molecule can have\n"
"no rotational or vibrational modes populated\n"
"equal to enthalpy at 0 K",
)]
if fr.other["frequency"].anharm_data:
dZPE_anh = co.calc_zpe(anharmonic=True)
items.append((
"𝛿ZPE<sub>anh</sub> =",
dZPE_anh,
None,
"lowest energy the molecule can have\n"
"no rotational or vibrational modes populated\n"
"includes corrections for anharmonic vibrations",
))
items.extend([
(
"𝛿H<sub>RRHO</sub> =",
dH,
None,
"enthalpy of formation",
),
(
"𝛿G<sub>RRHO</sub> =",
rrho_dg,
None,
"energy after taking into account the average\n"
"population of vibrational, rotational, and translational\n"
"degrees of freedom",
),
(
"𝛿G<sub>Quasi-RRHO</sub> =",
qrrho_dg,
"Grimme's Quasi-RRHO",
"vibrational entropy of each real mode is damped and complemented\n"
"with rotational entropy, with the damping function being stronger for\n"
"frequencies < 𝜔\u2080\n"
"can mitigate error from inaccuracies in the harmonic oscillator\n"
"approximation for low-frequency vibrations",
),
(
"𝛿G<sub>Quasi-Harmonic</sub> =",
qharm_dg,
"Truhlar's Quasi-Harmonic",
"real vibrational frequencies below 𝜔\u2080 are treated as 𝜔\u2080\n"
"can mitigate error from inaccuracies in the harmonic oscillator\n"
"approximation for low-frequency vibrations",
),
])
for i, (label_text, val, link, tooltip) in enumerate(items):
self.thermo_table.insertRow(i)
label = QLabel(label_text)
if link:
label = QLabel()
label.setText(
"<a href=\"%s\" style=\"text-decoration: none;\">%s</a>"
% (link, label_text))
label.setTextFormat(Qt.RichText)
label.setTextInteractionFlags(Qt.TextBrowserInteraction)
label.linkActivated.connect(self.open_link)
label.setAlignment(Qt.AlignRight | Qt.AlignVCenter)
label.setToolTip(tooltip)
self.thermo_table.setCellWidget(i, 0, label)
unit_label = ReadOnlyTableItem()
unit_label.setData(Qt.DisplayRole, "E\u2095")
unit_label.setTextAlignment(Qt.AlignLeft | Qt.AlignVCenter)
unit_label.setToolTip(tooltip)
self.thermo_table.setItem(i, 2, unit_label)
d_nrg = SmallLineEdit("%.6f" % val)
d_nrg.setReadOnly(True)
d_nrg.setFrame(False)
d_nrg.setToolTip(tooltip)
self.thermo_table.setCellWidget(i, 1, d_nrg)
self.thermo_table.resizeRowToContents(i)
self.thermo_table.resizeColumnToContents(0)
self.thermo_table.resizeColumnToContents(1)
self.thermo_table.resizeColumnToContents(2)
self.update_sum()
def update_sum(self):
"""updates the sum of energy and thermo corrections"""
self.sum_table.setRowCount(0)
if not self.sp_table.rowCount():
return
sp_nrg = float(self.sp_table.cellWidget(0, 1).text())
for row in range(0, self.thermo_table.rowCount()):
self.sum_table.insertRow(row)
label = self.thermo_table.cellWidget(row, 0)
tooltip = label.toolTip()
text = label.text().replace("𝛿", "")
sum_label = QLabel(text)
if "href=" in text:
sum_label = QLabel()
sum_label.setText(text)
sum_label.setTextFormat(Qt.RichText)
sum_label.setTextInteractionFlags(Qt.TextBrowserInteraction)
sum_label.linkActivated.connect(self.open_link)
sum_label.setAlignment(Qt.AlignRight | Qt.AlignVCenter)
sum_label.setToolTip(tooltip)
self.sum_table.setCellWidget(row, 0, sum_label)
thermo = float(self.thermo_table.cellWidget(row, 1).text())
total = sp_nrg + thermo
total_nrg = SmallLineEdit("%.6f" % total)
total_nrg.setFrame(False)
total_nrg.setReadOnly(True)
total_nrg.setToolTip(tooltip)
self.sum_table.setCellWidget(row, 1, total_nrg)
unit_label = ReadOnlyTableItem()
unit_label.setData(Qt.DisplayRole, "E\u2095")
unit_label.setTextAlignment(Qt.AlignLeft | Qt.AlignVCenter)
unit_label.setToolTip(tooltip)
self.sum_table.setItem(row, 2, unit_label)
self.sum_table.resizeRowToContents(row)
self.sum_table.resizeColumnToContents(0)
self.sum_table.resizeColumnToContents(1)
self.sum_table.resizeColumnToContents(2)
def display_help(self):
"""Show the help for this tool in the help viewer."""
from chimerax.core.commands import run
run(self.session,
'open %s' % self.help if self.help is not None else "")
def delete(self):
#overload because closing a tool window doesn't destroy any widgets on it
self.settings.ref_col_1 = self.ref_group.tree.columnWidth(0)
self.settings.ref_col_2 = self.ref_group.tree.columnWidth(1)
self.settings.other_col_1 = self.other_group.tree.columnWidth(0)
self.settings.other_col_2 = self.other_group.tree.columnWidth(1)
self.sp_selector.deleteLater()
self.thermo_selector.deleteLater()
self.ref_group.deleteLater()
self.other_group.deleteLater()
return super().delete()
def close(self):
#overload because closing a tool window doesn't destroy any widgets on it
self.settings.ref_col_1 = self.ref_group.tree.columnWidth(0)
self.settings.ref_col_2 = self.ref_group.tree.columnWidth(1)
self.settings.other_col_1 = self.other_group.tree.columnWidth(0)
self.settings.other_col_2 = self.other_group.tree.columnWidth(1)
self.sp_selector.deleteLater()
self.thermo_selector.deleteLater()
self.ref_group.deleteLater()
self.other_group.deleteLater()
return super().close()
class PrecisionRotate(ToolInstance):
help = "https://github.com/QChASM/SEQCROW/wiki/Rotate-Tool"
SESSION_ENDURING = False
SESSION_SAVE = False
def __init__(self, session, name):
super().__init__(session, name)
self.tool_window = MainToolWindow(self)
self.settings = _PrecisionRotateSettings(session, name)
self.bonds = {}
self.bond_centers = {}
self.groups = {}
self.perpendiculars = {}
self.perp_centers = {}
self.manual_center = {}
self._build_ui()
self._show_rot_vec = self.session.triggers.add_handler(
SELECTION_CHANGED, self.show_rot_vec)
global_triggers = get_triggers()
self._changes = global_triggers.add_handler("changes done",
self.show_rot_vec)
self.show_rot_vec()
def _build_ui(self):
layout = QGridLayout()
layout.addWidget(QLabel("center of rotation:"), 0, 0, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
self.cor_button = QComboBox()
self.cor_button.addItems(
["automatic", "select atoms", "view's center of rotation"])
layout.addWidget(self.cor_button, 0, 1, 1, 1, Qt.AlignTop)
self.set_cor_selection = QPushButton("set selection")
self.cor_button.currentTextChanged.connect(
lambda t, widget=self.set_cor_selection: widget.setEnabled(
t == "select atoms"))
self.set_cor_selection.clicked.connect(self.manual_cor)
layout.addWidget(self.set_cor_selection, 0, 2, 1, 1, Qt.AlignTop)
self.set_cor_selection.setEnabled(False)
layout.addWidget(QLabel("rotation vector:"), 1, 0, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
self.vector_option = QComboBox()
self.vector_option.addItems([
"axis", "view axis", "bond", "perpendicular to plane",
"centroid of atoms", "custom"
])
layout.addWidget(self.vector_option, 1, 1, 1, 1, Qt.AlignVCenter)
vector = QWidget()
vector.setToolTip("vector will be normalized before rotating")
vector_layout = QHBoxLayout(vector)
vector_layout.setContentsMargins(0, 0, 0, 0)
self.vector_x = QDoubleSpinBox()
self.vector_y = QDoubleSpinBox()
self.vector_z = QDoubleSpinBox()
self.vector_z.setValue(1.0)
for c, t in zip([self.vector_x, self.vector_y, self.vector_z],
[" x", " y", " z"]):
c.setSingleStep(0.01)
c.setRange(-100, 100)
# c.setSuffix(t)
c.valueChanged.connect(self.show_rot_vec)
vector_layout.addWidget(c)
layout.addWidget(vector, 1, 2, 1, 1, Qt.AlignTop)
vector.setVisible(self.vector_option.currentText() == "custom")
self.vector_option.currentTextChanged.connect(
lambda text, widget=vector: widget.setVisible(text == "custom"))
self.view_axis = QComboBox()
self.view_axis.addItems(["z", "y", "x"])
layout.addWidget(self.view_axis, 1, 2, 1, 1, Qt.AlignTop)
self.view_axis.setVisible(
self.vector_option.currentText() == "view axis")
self.vector_option.currentTextChanged.connect(
lambda text, widget=self.view_axis: widget.setVisible(text ==
"view axis"))
self.axis = QComboBox()
self.axis.addItems(["z", "y", "x"])
layout.addWidget(self.axis, 1, 2, 1, 1, Qt.AlignTop)
self.axis.setVisible(self.vector_option.currentText() == "axis")
self.vector_option.currentTextChanged.connect(
lambda text, widget=self.axis: widget.setVisible(text == "axis"))
self.bond_button = QPushButton("set selected bond")
self.bond_button.clicked.connect(self.set_bonds)
layout.addWidget(self.bond_button, 1, 2, 1, 1, Qt.AlignTop)
self.bond_button.setVisible(self.vector_option.currentText() == "bond")
self.vector_option.currentTextChanged.connect(
lambda text, widget=self.bond_button: widget.setVisible(text ==
"bond"))
self.perp_button = QPushButton("set selected atoms")
self.perp_button.clicked.connect(self.set_perpendicular)
layout.addWidget(self.perp_button, 1, 2, 1, 1, Qt.AlignTop)
self.perp_button.setVisible(
self.vector_option.currentText() == "perpendicular to plane")
self.vector_option.currentTextChanged.connect(
lambda text, widget=self.perp_button: widget.setVisible(
text == "perpendicular to plane"))
self.group_button = QPushButton("set selected atoms")
self.group_button.clicked.connect(self.set_group)
layout.addWidget(self.group_button, 1, 2, 1, 1, Qt.AlignTop)
self.group_button.setVisible(
self.vector_option.currentText() == "centroid of atoms")
self.vector_option.currentTextChanged.connect(
lambda text, widget=self.group_button: widget.setVisible(
text == "centroid of atoms"))
layout.addWidget(QLabel("angle:"), 2, 0, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
self.angle = QDoubleSpinBox()
self.angle.setRange(-360, 360)
self.angle.setSingleStep(5)
self.angle.setSuffix("°")
layout.addWidget(self.angle, 2, 1, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
layout.addWidget(QLabel("preview rotation axis:"), 3, 0, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
self.display_rot_vec = QCheckBox()
self.display_rot_vec.setCheckState(Qt.Checked)
self.display_rot_vec.stateChanged.connect(self.show_rot_vec)
layout.addWidget(self.display_rot_vec, 3, 1, 1, 1,
Qt.AlignLeft | Qt.AlignVCenter)
rotate_button = QPushButton("rotate selected atoms")
rotate_button.clicked.connect(self.do_rotate)
layout.addWidget(rotate_button, 4, 0, 1, 3, Qt.AlignTop)
self.rotate_button = rotate_button
self.status_bar = QStatusBar()
self.status_bar.setSizeGripEnabled(False)
layout.addWidget(self.status_bar, 5, 0, 1, 3, Qt.AlignTop)
self.vector_option.currentTextChanged.connect(self.show_auto_status)
self.cor_button.currentIndexChanged.connect(
lambda *args: self.show_auto_status("select atoms"))
self.cor_button.currentIndexChanged.connect(self.show_rot_vec)
self.set_cor_selection.clicked.connect(self.show_rot_vec)
self.vector_option.currentIndexChanged.connect(self.show_rot_vec)
self.axis.currentIndexChanged.connect(self.show_rot_vec)
self.view_axis.currentIndexChanged.connect(self.show_rot_vec)
self.bond_button.clicked.connect(self.show_rot_vec)
self.perp_button.clicked.connect(self.show_rot_vec)
self.group_button.clicked.connect(self.show_rot_vec)
layout.setRowStretch(0, 0)
layout.setRowStretch(1, 0)
layout.setRowStretch(2, 0)
layout.setRowStretch(3, 0)
layout.setRowStretch(4, 0)
layout.setRowStretch(5, 1)
layout.setColumnStretch(0, 0)
layout.setColumnStretch(1, 1)
layout.setColumnStretch(2, 1)
self.tool_window.ui_area.setLayout(layout)
self.tool_window.manage(None)
def manual_cor(self, *args):
selection = selected_atoms(self.session)
models = {}
for atom in selection:
if atom.structure not in models:
models[atom.structure] = [atom]
else:
models[atom.structure].append(atom)
self.manual_center = {}
for model in models:
atoms = models[model]
coords = np.array([atom.coord for atom in atoms])
self.manual_center[model] = np.mean(coords, axis=0)
def show_auto_status(self, text):
if self.cor_button.currentText() == "automatic":
if text == "bond":
self.status_bar.showMessage(
"center set to one of the bonded atoms")
elif text == "perpendicular to plane":
self.status_bar.showMessage("center set to centroid of atoms")
else:
self.status_bar.showMessage(
"center set to centroid of rotating atoms")
elif self.cor_button.currentText() == "select atoms":
self.status_bar.showMessage(
"center set to centroid of specified atoms")
else:
self.status_bar.showMessage(
"center set to view's center of rotation")
def set_bonds(self, *args):
bonds = selected_bonds(self.session)
if len(bonds) == 0:
self.session.logger.error("no bonds selected")
return
models = [bond.structure for bond in bonds]
if any(models.count(m) > 1 for m in models):
self.session.logger.error(
"multiple bonds selected on the same structure")
return
self.bonds = {
model: (bond.atoms[0].coord - bond.atoms[1].coord)
for model, bond in zip(models, bonds)
}
self.bond_centers = {
model: bond.atoms[1].coord
for model, bond in zip(models, bonds)
}
def set_perpendicular(self, *args):
atoms = selected_atoms(self.session)
if len(atoms) == 0:
self.session.logger.error("no atoms selected")
return
self.perpendiculars = {}
self.perp_centers = {}
models = set(atom.structure for atom in atoms)
for model in models:
atom_coords = []
for atom in atoms:
if atom.structure is model:
atom_coords.append(atom.coord)
if len(atom_coords) < 3:
self.session.logger.error("fewer than 3 atoms selected on %s" %
model.atomspec)
continue
xyz = np.array(atom_coords)
xyz -= np.mean(atom_coords, axis=0)
R = np.dot(xyz.T, xyz)
u, s, vh = np.linalg.svd(R, compute_uv=True)
vector = u[:, -1]
self.perpendiculars[model] = vector
self.perp_centers[model] = np.mean(atom_coords, axis=0)
def set_group(self, *args):
atoms = selected_atoms(self.session)
if len(atoms) == 0:
self.session.logger.error("no atoms selected")
return
self.groups = {}
models = set(atom.structure for atom in atoms)
for model in models:
atom_coords = []
for atom in atoms:
if atom.structure is model:
atom_coords.append(atom.coord)
self.groups[model] = np.mean(atom_coords, axis=0)
def do_rotate(self, *args):
selection = selected_atoms(self.session)
models = {}
for atom in selection:
if atom.structure not in models:
models[atom.structure] = [atom]
else:
models[atom.structure].append(atom)
if len(models.keys()) == 0:
return
if self.vector_option.currentText() == "axis":
if self.axis.currentText() == "z":
vector = np.array([0., 0., 1.])
elif self.axis.currentText() == "y":
vector = np.array([0., 1., 0.])
elif self.axis.currentText() == "x":
vector = np.array([1., 0., 0.])
elif self.vector_option.currentText() == "view axis":
if self.view_axis.currentText() == "z":
vector = self.session.view.camera.get_position().axes()[2]
elif self.view_axis.currentText() == "y":
vector = self.session.view.camera.get_position().axes()[1]
elif self.view_axis.currentText() == "x":
vector = self.session.view.camera.get_position().axes()[0]
elif self.vector_option.currentText() == "bond":
vector = self.bonds
elif self.vector_option.currentText() == "perpendicular to plane":
vector = self.perpendiculars
elif self.vector_option.currentText() == "centroid of atoms":
vector = self.groups
elif self.vector_option.currentText() == "custom":
x = self.vector_x.value()
y = self.vector_y.value()
z = self.vector_z.value()
vector = np.array([x, y, z])
angle = np.deg2rad(self.angle.value())
center = {}
for model in models:
atoms = models[model]
coords = np.array([atom.coord for atom in atoms])
center[model] = np.mean(coords, axis=0)
if self.cor_button.currentText() == "automatic":
if self.vector_option.currentText() == "perpendicular to plane":
center = self.perp_centers
elif self.vector_option.currentText() == "bond":
center = self.bond_centers
elif self.cor_button.currentText() == "select atoms":
center = self.manual_center
else:
center = self.session.main_view.center_of_rotation
for model in models:
if isinstance(vector, dict):
if model not in vector.keys():
continue
else:
v = vector[model]
else:
v = vector
if isinstance(center, dict):
if model not in center.keys():
continue
else:
c = center[model]
else:
c = center
if self.vector_option.currentText(
) == "centroid of atoms" and self.cor_button.currentText(
) != "automatic":
v = v - c
v = v / np.linalg.norm(v)
q = np.hstack(([np.cos(angle / 2)], v * np.sin(angle / 2)))
q /= np.linalg.norm(q)
qs = q[0]
qv = q[1:]
xyz = np.array([a.coord for a in models[model]])
xyz -= c
xprod = np.cross(qv, xyz)
qs_xprod = 2 * qs * xprod
qv_xprod = 2 * np.cross(qv, xprod)
xyz += qs_xprod + qv_xprod + c
for t, coord in zip(models[model], xyz):
t.coord = coord
def show_rot_vec(self, *args):
for model in self.session.models.list(type=Generic3DModel):
if model.name == "rotation vector":
model.delete()
if self.display_rot_vec.checkState() == Qt.Unchecked:
return
selection = selected_atoms(self.session)
if len(selection) == 0:
return
models = {}
for atom in selection:
if atom.structure not in models:
models[atom.structure] = [atom]
else:
models[atom.structure].append(atom)
if len(models.keys()) == 0:
return
if self.vector_option.currentText() == "axis":
if self.axis.currentText() == "z":
vector = np.array([0., 0., 1.])
elif self.axis.currentText() == "y":
vector = np.array([0., 1., 0.])
elif self.axis.currentText() == "x":
vector = np.array([1., 0., 0.])
elif self.vector_option.currentText() == "view axis":
if self.view_axis.currentText() == "z":
vector = self.session.view.camera.get_position().axes()[2]
elif self.view_axis.currentText() == "y":
vector = self.session.view.camera.get_position().axes()[1]
elif self.view_axis.currentText() == "x":
vector = self.session.view.camera.get_position().axes()[0]
elif self.vector_option.currentText() == "bond":
vector = self.bonds
elif self.vector_option.currentText() == "perpendicular to plane":
vector = self.perpendiculars
elif self.vector_option.currentText() == "centroid of atoms":
vector = self.groups
elif self.vector_option.currentText() == "custom":
x = self.vector_x.value()
y = self.vector_y.value()
z = self.vector_z.value()
vector = np.array([x, y, z])
center = {}
for model in models:
atoms = models[model]
coords = np.array([atom.coord for atom in atoms])
center[model] = np.mean(coords, axis=0)
if self.cor_button.currentText() == "automatic":
if self.vector_option.currentText() == "perpendicular to plane":
center = self.perp_centers
elif self.vector_option.currentText() == "bond":
center = self.bond_centers
elif self.cor_button.currentText() == "select atoms":
center = self.manual_center
else:
center = self.session.main_view.center_of_rotation
for model in models:
if isinstance(vector, dict):
if model not in vector.keys():
continue
else:
v = vector[model]
else:
v = vector
if isinstance(center, dict):
if model not in center.keys():
continue
else:
c = center[model]
else:
c = center
if self.vector_option.currentText(
) == "centroid of atoms" and self.cor_button.currentText(
) != "automatic":
v = v - c
if np.linalg.norm(v) == 0:
continue
residues = []
for atom in models[model]:
if atom.residue not in residues:
residues.append(atom.residue)
v_c = c + v
s = ".color red\n"
s += ".arrow %10.6f %10.6f %10.6f %10.6f %10.6f %10.6f 0.2 0.4 0.7\n" % (
*c, *v_c)
stream = BytesIO(bytes(s, 'utf-8'))
bild_obj, status = read_bild(self.session, stream,
"rotation vector")
self.session.models.add(bild_obj, parent=model)
def delete(self):
self.session.triggers.remove_handler(self._show_rot_vec)
global_triggers = get_triggers()
global_triggers.remove_handler(self._changes)
for model in self.session.models.list(type=Generic3DModel):
if model.name == "rotation vector":
model.delete()
return super().delete()
def close(self):
self.session.triggers.remove_handler(self._show_rot_vec)
global_triggers = get_triggers()
global_triggers.remove_handler(self._changes)
for model in self.session.models.list(type=Generic3DModel):
if model.name == "rotation vector":
model.delete()
return super().close()
class LigandSterimol(ToolInstance):
help = "https://github.com/QChASM/SEQCROW/wiki/Ligand-Sterimol-Tool"
SESSION_ENDURING = False
SESSION_SAVE = False
def __init__(self, session, name):
super().__init__(session, name)
from chimerax.ui import MainToolWindow
self.tool_window = MainToolWindow(self)
self.settings = _SterimolSettings(self.session, name)
self._build_ui()
def _build_ui(self):
layout = QFormLayout()
self.radii_option = QComboBox()
self.radii_option.addItems(["Bondi", "UMN"])
ndx = self.radii_option.findText(self.settings.radii, Qt.MatchExactly)
self.radii_option.setCurrentIndex(ndx)
layout.addRow("radii:", self.radii_option)
self.L_option = QComboBox()
self.L_option.addItems([
"to centroid of coordinating atoms",
"bisect angle between coordinating atoms"
])
ndx = self.L_option.findText(self.settings.L_option, Qt.MatchExactly)
self.L_option.setCurrentIndex(ndx)
layout.addRow("L axis:", self.L_option)
self.sterimol2vec = QGroupBox("Sterimol2Vec")
sterimol2vec_layout = QFormLayout(self.sterimol2vec)
self.at_L = QDoubleSpinBox()
self.at_L.setRange(-10, 30)
self.at_L.setDecimals(2)
self.at_L.setSingleStep(0.25)
self.at_L.setValue(self.settings.at_L)
sterimol2vec_layout.addRow("L value:", self.at_L)
layout.addRow(self.sterimol2vec)
self.sterimol2vec.setCheckable(True)
self.sterimol2vec.toggled.connect(lambda x: self.at_L.setEnabled(x))
self.sterimol2vec.setChecked(self.settings.sterimol2vec)
self.display_vectors = QCheckBox()
self.display_vectors.setChecked(self.settings.display_vectors)
layout.addRow("show vectors:", self.display_vectors)
self.display_radii = QCheckBox()
self.display_radii.setChecked(self.settings.display_radii)
layout.addRow("show radii:", self.display_radii)
calc_sterimol_button = QPushButton(
"calculate parameters for selected ligands")
calc_sterimol_button.clicked.connect(self.calc_sterimol)
layout.addRow(calc_sterimol_button)
self.calc_sterimol_button = calc_sterimol_button
remove_sterimol_button = QPushButton("remove Sterimol visualizations")
remove_sterimol_button.clicked.connect(self.del_sterimol)
layout.addRow(remove_sterimol_button)
self.remove_sterimol_button = remove_sterimol_button
self.table = QTableWidget()
self.table.setColumnCount(8)
self.table.setHorizontalHeaderLabels([
'model',
'coord. atoms',
'B\u2081',
'B\u2082',
'B\u2083',
'B\u2084',
'B\u2085',
'L',
])
self.table.setSelectionBehavior(QTableWidget.SelectRows)
self.table.setEditTriggers(QTableWidget.NoEditTriggers)
self.table.resizeColumnToContents(0)
self.table.resizeColumnToContents(1)
self.table.resizeColumnToContents(2)
self.table.resizeColumnToContents(3)
self.table.resizeColumnToContents(4)
self.table.resizeColumnToContents(5)
self.table.resizeColumnToContents(6)
self.table.resizeColumnToContents(7)
self.table.horizontalHeader().setSectionResizeMode(
2, QHeaderView.Stretch)
self.table.horizontalHeader().setSectionResizeMode(
3, QHeaderView.Stretch)
self.table.horizontalHeader().setSectionResizeMode(
4, QHeaderView.Stretch)
self.table.horizontalHeader().setSectionResizeMode(
5, QHeaderView.Stretch)
self.table.horizontalHeader().setSectionResizeMode(
6, QHeaderView.Stretch)
self.table.horizontalHeader().setSectionResizeMode(
7, QHeaderView.Stretch)
layout.addRow(self.table)
menu = QMenuBar()
export = menu.addMenu("&Export")
clear = QAction("Clear data table", self.tool_window.ui_area)
clear.triggered.connect(self.clear_table)
export.addAction(clear)
copy = QAction("&Copy CSV to clipboard", self.tool_window.ui_area)
copy.triggered.connect(self.copy_csv)
shortcut = QKeySequence(Qt.CTRL + Qt.Key_C)
copy.setShortcut(shortcut)
export.addAction(copy)
save = QAction("&Save CSV...", self.tool_window.ui_area)
save.triggered.connect(self.save_csv)
#this shortcut interferes with main window's save shortcut
#I've tried different shortcut contexts to no avail
#thanks Qt...
#shortcut = QKeySequence(Qt.CTRL + Qt.Key_S)
#save.setShortcut(shortcut)
#save.setShortcutContext(Qt.WidgetShortcut)
export.addAction(save)
delimiter = export.addMenu("Delimiter")
comma = QAction("comma", self.tool_window.ui_area, checkable=True)
comma.setChecked(self.settings.delimiter == "comma")
comma.triggered.connect(lambda *args, delim="comma": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(comma)
tab = QAction("tab", self.tool_window.ui_area, checkable=True)
tab.setChecked(self.settings.delimiter == "tab")
tab.triggered.connect(lambda *args, delim="tab": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(tab)
space = QAction("space", self.tool_window.ui_area, checkable=True)
space.setChecked(self.settings.delimiter == "space")
space.triggered.connect(lambda *args, delim="space": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(space)
semicolon = QAction("semicolon",
self.tool_window.ui_area,
checkable=True)
semicolon.setChecked(self.settings.delimiter == "semicolon")
semicolon.triggered.connect(lambda *args, delim="semicolon": self.
settings.__setattr__("delimiter", delim))
delimiter.addAction(semicolon)
add_header = QAction("&Include CSV header",
self.tool_window.ui_area,
checkable=True)
add_header.setChecked(self.settings.include_header)
add_header.triggered.connect(self.header_check)
export.addAction(add_header)
comma.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=space: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=space: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
space.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
space.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
space.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=space: action.setChecked(False))
menu.setNativeMenuBar(False)
self._menu = menu
layout.setMenuBar(menu)
menu.setVisible(True)
self.tool_window.ui_area.setLayout(layout)
self.tool_window.manage(None)
def clear_table(self):
are_you_sure = QMessageBox.question(
None,
"Clear table?",
"Are you sure you want to clear the data table?",
)
if are_you_sure != QMessageBox.Yes:
return
self.table.setRowCount(0)
def calc_sterimol(self, *args):
self.settings.radii = self.radii_option.currentText()
self.settings.display_radii = self.display_radii.checkState(
) == Qt.Checked
self.settings.display_vectors = self.display_vectors.checkState(
) == Qt.Checked
self.settings.at_L = self.at_L.value()
self.settings.sterimol2vec = self.sterimol2vec.isChecked()
self.settings.L_option = self.L_option.currentText()
targets, neighbors, datas = sterimol_cmd(
self.session,
selected_atoms(self.session),
radii=self.radii_option.currentText(),
showVectors=self.display_vectors.checkState() == Qt.Checked,
showRadii=self.display_radii.checkState() == Qt.Checked,
return_values=True,
at_L=self.at_L.value() if self.sterimol2vec.isChecked() else None,
bisect_L=self.L_option.currentText() ==
"bisect angle between coordinating atoms",
)
if len(targets) == 0:
return
if self.settings.delimiter == "comma":
delim = ","
elif self.settings.delimiter == "space":
delim = " "
elif self.settings.delimiter == "tab":
delim = "\t"
elif self.settings.delimiter == "semicolon":
delim = ";"
# self.table.setRowCount(0)
for t, b, data in zip(targets, neighbors, datas):
row = self.table.rowCount()
self.table.insertRow(row)
targ = QTableWidgetItem()
targ.setData(Qt.DisplayRole, t)
self.table.setItem(row, 0, targ)
neigh = QTableWidgetItem()
neigh.setData(Qt.DisplayRole, delim.join(b))
self.table.setItem(row, 1, neigh)
l = np.linalg.norm(data["L"][1] - data["L"][0])
b1 = np.linalg.norm(data["B1"][1] - data["B1"][0])
b2 = np.linalg.norm(data["B2"][1] - data["B2"][0])
b3 = np.linalg.norm(data["B3"][1] - data["B3"][0])
b4 = np.linalg.norm(data["B4"][1] - data["B4"][0])
b5 = np.linalg.norm(data["B5"][1] - data["B5"][0])
li = QTableWidgetItem()
li.setData(Qt.DisplayRole, "%.2f" % l)
self.table.setItem(row, 7, li)
b1i = QTableWidgetItem()
b1i.setData(Qt.DisplayRole, "%.2f" % b1)
self.table.setItem(row, 2, b1i)
b2i = QTableWidgetItem()
b2i.setData(Qt.DisplayRole, "%.2f" % b2)
self.table.setItem(row, 3, b2i)
b3i = QTableWidgetItem()
b3i.setData(Qt.DisplayRole, "%.2f" % b3)
self.table.setItem(row, 4, b3i)
b4i = QTableWidgetItem()
b4i.setData(Qt.DisplayRole, "%.2f" % b4)
self.table.setItem(row, 5, b4i)
b5i = QTableWidgetItem()
b5i.setData(Qt.DisplayRole, "%.2f" % b5)
self.table.setItem(row, 6, b5i)
for i in range(0, 7):
if i == 1:
continue
self.table.resizeColumnToContents(i)
def header_check(self, state):
"""user has [un]checked the 'include header' option on the menu"""
if state:
self.settings.include_header = True
else:
self.settings.include_header = False
def get_csv(self):
if self.settings.delimiter == "comma":
delim = ","
elif self.settings.delimiter == "space":
delim = " "
elif self.settings.delimiter == "tab":
delim = "\t"
elif self.settings.delimiter == "semicolon":
delim = ";"
if self.settings.include_header:
s = delim.join([
"substituent_atom", "bonded_atom", "B1", "B2", "B3", "B4",
"B5", "L"
])
s += "\n"
else:
s = ""
for i in range(0, self.table.rowCount()):
s += delim.join([
item.data(Qt.DisplayRole)
for item in [self.table.item(i, j) for j in range(0, 8)]
])
s += "\n"
return s
def copy_csv(self):
app = QApplication.instance()
clipboard = app.clipboard()
csv = self.get_csv()
clipboard.setText(csv)
self.session.logger.status("copied to clipboard")
def save_csv(self):
"""save data on current tab to CSV file"""
filename, _ = QFileDialog.getSaveFileName(filter="CSV Files (*.csv)")
if filename:
s = self.get_csv()
with open(filename, 'w') as f:
f.write(s.strip())
self.session.logger.status("saved to %s" % filename)
def del_sterimol(self):
for model in self.session.models.list(type=Generic3DModel):
if model.name.startswith("Sterimol"):
model.delete()
def display_help(self):
"""Show the help for this tool in the help viewer."""
from chimerax.core.commands import run
run(self.session,
'open %s' % self.help if self.help is not None else "")
class PercentVolumeBuried(ToolInstance):
help = "https://github.com/QChASM/SEQCROW/wiki/Buried-Volume-Tool"
SESSION_ENDURING = False
SESSION_SAVE = False
def __init__(self, session, name):
super().__init__(session, name)
self.tool_window = MainToolWindow(self)
self.settings = _VburSettings(self.session, name)
self.ligand_atoms = []
self._build_ui()
def _build_ui(self):
layout = QGridLayout()
tabs = QTabWidget()
calc_widget = QWidget()
calc_layout = QFormLayout(calc_widget)
settings_widget = QWidget()
settings_layout = QFormLayout(settings_widget)
steric_map_widget = QWidget()
steric_layout = QFormLayout(steric_map_widget)
cutout_widget = QWidget()
vol_cutout_layout = QFormLayout(cutout_widget)
layout.addWidget(tabs)
tabs.addTab(calc_widget, "calculation")
tabs.addTab(settings_widget, "settings")
tabs.addTab(steric_map_widget, "steric map")
tabs.addTab(cutout_widget, "volume cutout")
self.radii_option = QComboBox()
self.radii_option.addItems(["Bondi", "UMN"])
ndx = self.radii_option.findText(self.settings.radii, Qt.MatchExactly)
self.radii_option.setCurrentIndex(ndx)
settings_layout.addRow("radii:", self.radii_option)
self.scale = QDoubleSpinBox()
self.scale.setValue(self.settings.vdw_scale)
self.scale.setSingleStep(0.01)
self.scale.setRange(1., 1.5)
settings_layout.addRow("VDW scale:", self.scale)
set_ligand_atoms = QPushButton("set ligands to current selection")
set_ligand_atoms.clicked.connect(self.set_ligand_atoms)
set_ligand_atoms.setToolTip(
"specify atoms to use in calculation\n" +
"by default, all atoms will be used unless a single center is specified\n"
+
"in the case of a single center, all atoms except the center is used"
)
calc_layout.addRow(set_ligand_atoms)
self.set_ligand_atoms = set_ligand_atoms
self.radius = QDoubleSpinBox()
self.radius.setValue(self.settings.center_radius)
self.radius.setSuffix(" \u212B")
self.radius.setDecimals(1)
self.radius.setSingleStep(0.1)
self.radius.setRange(1., 15.)
settings_layout.addRow("radius around center:", self.radius)
self.method = QComboBox()
self.method.addItems(["Lebedev", "Monte-Carlo"])
self.method.setToolTip("Lebedev: deterministic method\n" +
"Monte-Carlo: non-deterministic method")
ndx = self.method.findText(self.settings.method, Qt.MatchExactly)
self.method.setCurrentIndex(ndx)
settings_layout.addRow("integration method:", self.method)
leb_widget = QWidget()
leb_layout = QFormLayout(leb_widget)
leb_layout.setContentsMargins(0, 0, 0, 0)
self.radial_points = QComboBox()
self.radial_points.addItems(["20", "32", "64", "75", "99", "127"])
self.radial_points.setToolTip(
"more radial points will give more accurate results, but integration will take longer"
)
ndx = self.radial_points.findText(self.settings.radial_points,
Qt.MatchExactly)
self.radial_points.setCurrentIndex(ndx)
leb_layout.addRow("radial points:", self.radial_points)
self.angular_points = QComboBox()
self.angular_points.addItems([
"110", "194", "302", "590", "974", "1454", "2030", "2702", "5810"
])
self.angular_points.setToolTip(
"more angular points will give more accurate results, but integration will take longer"
)
ndx = self.angular_points.findText(self.settings.angular_points,
Qt.MatchExactly)
self.angular_points.setCurrentIndex(ndx)
leb_layout.addRow("angular points:", self.angular_points)
settings_layout.addRow(leb_widget)
mc_widget = QWidget()
mc_layout = QFormLayout(mc_widget)
mc_layout.setContentsMargins(0, 0, 0, 0)
self.min_iter = QSpinBox()
self.min_iter.setValue(self.settings.minimum_iterations)
self.min_iter.setRange(0, 10000)
self.min_iter.setToolTip(
"each iteration is 3000 points\n" +
"iterations continue until convergence criteria are met")
mc_layout.addRow("minimum interations:", self.min_iter)
settings_layout.addRow(mc_widget)
if self.settings.method == "Lebedev":
mc_widget.setVisible(False)
elif self.settings.method == "Monte-Carlo":
leb_widget.setVisible(False)
self.report_component = QComboBox()
self.report_component.addItems(["total", "quadrants", "octants"])
ndx = self.report_component.findText(self.settings.report_component,
Qt.MatchExactly)
self.report_component.setCurrentIndex(ndx)
settings_layout.addRow("report volume:", self.report_component)
self.use_scene = QCheckBox()
self.use_scene.setChecked(self.settings.use_scene)
self.use_scene.setToolTip(
"quadrants/octants will use the orientation the molecule is displayed in"
)
settings_layout.addRow("use display orientation:", self.use_scene)
self.method.currentTextChanged.connect(
lambda text, widget=leb_widget: widget.setVisible(text == "Lebedev"
))
self.method.currentTextChanged.connect(
lambda text, widget=mc_widget: widget.setVisible(text ==
"Monte-Carlo"))
self.use_centroid = QCheckBox()
self.use_centroid.setChecked(self.settings.use_centroid)
self.use_centroid.setToolTip(
"place the center between selected atoms\n" +
"might be useful for polydentate ligands")
calc_layout.addRow("use centroid of centers:", self.use_centroid)
self.steric_map = QCheckBox()
self.steric_map.setChecked(self.settings.steric_map)
self.steric_map.setToolTip(
"produce a 2D projection of steric bulk\ncauses buried volume to be reported for individual quadrants"
)
steric_layout.addRow("create steric map:", self.steric_map)
self.num_pts = QSpinBox()
self.num_pts.setRange(25, 250)
self.num_pts.setValue(self.settings.num_pts)
self.num_pts.setToolTip("number of points along x and y axes")
steric_layout.addRow("number of points:", self.num_pts)
self.include_vbur = QCheckBox()
self.include_vbur.setChecked(self.settings.include_vbur)
steric_layout.addRow("label quadrants with %V<sub>bur</sub>",
self.include_vbur)
self.map_shape = QComboBox()
self.map_shape.addItems(["circle", "square"])
ndx = self.map_shape.findText(self.settings.map_shape, Qt.MatchExactly)
self.map_shape.setCurrentIndex(ndx)
steric_layout.addRow("map shape:", self.map_shape)
self.auto_minmax = QCheckBox()
self.auto_minmax.setChecked(self.settings.auto_minmax)
steric_layout.addRow("automatic min. and max.:", self.auto_minmax)
self.map_min = QDoubleSpinBox()
self.map_min.setRange(-15., 0.)
self.map_min.setSuffix(" \u212B")
self.map_min.setSingleStep(0.1)
self.map_min.setValue(self.settings.map_min)
steric_layout.addRow("minimum value:", self.map_min)
self.map_max = QDoubleSpinBox()
self.map_max.setRange(0., 15.)
self.map_max.setSuffix(" \u212B")
self.map_max.setSingleStep(0.1)
self.map_max.setValue(self.settings.map_max)
steric_layout.addRow("maximum value:", self.map_max)
self.num_pts.setEnabled(self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.num_pts: widget.setEnabled(state == Qt.
Checked))
self.include_vbur.setEnabled(self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.include_vbur: widget.setEnabled(
state == Qt.Checked))
self.map_shape.setEnabled(self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.map_shape: widget.setEnabled(state == Qt.
Checked))
self.auto_minmax.setEnabled(self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.auto_minmax: widget.setEnabled(
state == Qt.Checked))
self.map_min.setEnabled(not self.settings.auto_minmax
and self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.map_min, widget2=self.auto_minmax: widget
.setEnabled(state == Qt.Checked and not widget2.isChecked()))
self.auto_minmax.stateChanged.connect(
lambda state, widget=self.map_min, widget2=self.steric_map: widget.
setEnabled(not state == Qt.Checked and widget2.isChecked()))
self.map_max.setEnabled(not self.settings.auto_minmax
and self.settings.steric_map)
self.steric_map.stateChanged.connect(
lambda state, widget=self.map_max, widget2=self.auto_minmax: widget
.setEnabled(state == Qt.Checked and not widget2.isChecked()))
self.auto_minmax.stateChanged.connect(
lambda state, widget=self.map_max, widget2=self.steric_map: widget.
setEnabled(not state == Qt.Checked and widget2.isChecked()))
self.display_cutout = QComboBox()
self.display_cutout.addItems(["no", "free", "buried"])
ndx = self.display_cutout.findText(self.settings.display_cutout,
Qt.MatchExactly)
self.display_cutout.setCurrentIndex(ndx)
self.display_cutout.setToolTip("show free or buried volume")
vol_cutout_layout.addRow("display volume:", self.display_cutout)
self.point_spacing = QDoubleSpinBox()
self.point_spacing.setDecimals(3)
self.point_spacing.setRange(0.01, 0.5)
self.point_spacing.setSingleStep(0.005)
self.point_spacing.setSuffix(" \u212B")
self.point_spacing.setValue(self.settings.point_spacing)
self.point_spacing.setToolTip(
"distance between points on cutout\n" +
"smaller spacing will narrow gaps, but increase time to create the cutout"
)
vol_cutout_layout.addRow("point spacing:", self.point_spacing)
self.intersection_scale = QDoubleSpinBox()
self.intersection_scale.setDecimals(2)
self.intersection_scale.setRange(1., 10.)
self.intersection_scale.setSingleStep(0.5)
self.intersection_scale.setSuffix("x")
self.intersection_scale.setToolTip(
"relative density of points where VDW radii intersect\n" +
"higher density will narrow gaps, but increase time to create cutout"
)
self.intersection_scale.setValue(self.settings.intersection_scale)
vol_cutout_layout.addRow("intersection density:",
self.intersection_scale)
self.cutout_labels = QComboBox()
self.cutout_labels.addItems(["none", "quadrants", "octants"])
ndx = self.cutout_labels.findText(self.settings.cutout_labels,
Qt.MatchExactly)
self.cutout_labels.setCurrentIndex(ndx)
vol_cutout_layout.addRow("label sections:", self.cutout_labels)
self.point_spacing.setEnabled(self.settings.display_cutout != "no")
self.intersection_scale.setEnabled(
self.settings.display_cutout != "no")
self.cutout_labels.setEnabled(self.settings.display_cutout != "no")
self.display_cutout.currentTextChanged.connect(
lambda text, widget=self.point_spacing: widget.setEnabled(text !=
"no"))
self.display_cutout.currentTextChanged.connect(
lambda text, widget=self.intersection_scale: widget.setEnabled(
text != "no"))
self.display_cutout.currentTextChanged.connect(
lambda text, widget=self.cutout_labels: widget.setEnabled(text !=
"no"))
calc_vbur_button = QPushButton(
"calculate % buried volume for selected centers")
calc_vbur_button.clicked.connect(self.calc_vbur)
calc_layout.addRow(calc_vbur_button)
self.calc_vbur_button = calc_vbur_button
remove_vbur_button = QPushButton(
"remove % buried volume visualizations")
remove_vbur_button.clicked.connect(self.del_vbur)
vol_cutout_layout.addRow(remove_vbur_button)
self.table = QTableWidget()
self.table.setColumnCount(3)
self.table.setHorizontalHeaderLabels(['model', 'center', '%Vbur'])
self.table.setSelectionBehavior(QTableWidget.SelectRows)
self.table.setEditTriggers(QTableWidget.NoEditTriggers)
self.table.resizeColumnToContents(0)
self.table.resizeColumnToContents(1)
self.table.resizeColumnToContents(2)
self.table.horizontalHeader().setSectionResizeMode(
0, QHeaderView.Interactive)
self.table.horizontalHeader().setSectionResizeMode(
1, QHeaderView.Interactive)
self.table.horizontalHeader().setSectionResizeMode(
2, QHeaderView.Stretch)
calc_layout.addRow(self.table)
menu = QMenuBar()
export = menu.addMenu("&Export")
clear = QAction("Clear data table", self.tool_window.ui_area)
clear.triggered.connect(self.clear_table)
export.addAction(clear)
copy = QAction("&Copy CSV to clipboard", self.tool_window.ui_area)
copy.triggered.connect(self.copy_csv)
shortcut = QKeySequence(Qt.CTRL + Qt.Key_C)
copy.setShortcut(shortcut)
export.addAction(copy)
self.copy = copy
save = QAction("&Save CSV...", self.tool_window.ui_area)
save.triggered.connect(self.save_csv)
#this shortcut interferes with main window's save shortcut
#I've tried different shortcut contexts to no avail
#thanks Qt...
#shortcut = QKeySequence(Qt.CTRL + Qt.Key_S)
#save.setShortcut(shortcut)
#save.setShortcutContext(Qt.WidgetShortcut)
export.addAction(save)
delimiter = export.addMenu("Delimiter")
comma = QAction("comma", self.tool_window.ui_area, checkable=True)
comma.setChecked(self.settings.delimiter == "comma")
comma.triggered.connect(lambda *args, delim="comma": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(comma)
tab = QAction("tab", self.tool_window.ui_area, checkable=True)
tab.setChecked(self.settings.delimiter == "tab")
tab.triggered.connect(lambda *args, delim="tab": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(tab)
space = QAction("space", self.tool_window.ui_area, checkable=True)
space.setChecked(self.settings.delimiter == "space")
space.triggered.connect(lambda *args, delim="space": self.settings.
__setattr__("delimiter", delim))
delimiter.addAction(space)
semicolon = QAction("semicolon",
self.tool_window.ui_area,
checkable=True)
semicolon.setChecked(self.settings.delimiter == "semicolon")
semicolon.triggered.connect(lambda *args, delim="semicolon": self.
settings.__setattr__("delimiter", delim))
delimiter.addAction(semicolon)
add_header = QAction("&Include CSV header",
self.tool_window.ui_area,
checkable=True)
add_header.setChecked(self.settings.include_header)
add_header.triggered.connect(self.header_check)
export.addAction(add_header)
comma.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=space: action.setChecked(False))
comma.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=space: action.setChecked(False))
tab.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
space.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
space.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
space.triggered.connect(
lambda *args, action=semicolon: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=comma: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=tab: action.setChecked(False))
semicolon.triggered.connect(
lambda *args, action=space: action.setChecked(False))
menu.setNativeMenuBar(False)
self._menu = menu
layout.setMenuBar(menu)
menu.setVisible(True)
self.tool_window.ui_area.setLayout(layout)
self.tool_window.manage(None)
def clear_table(self):
are_you_sure = QMessageBox.question(
None,
"Clear table?",
"Are you sure you want to clear the data table?",
)
if are_you_sure != QMessageBox.Yes:
return
self.table.setRowCount(0)
def set_ligand_atoms(self):
self.ligand_atoms = selected_atoms(self.session)
self.session.logger.status("set ligand to current selection")
def calc_vbur(self):
args = dict()
cur_sel = selected_atoms(self.session)
if len(cur_sel) == 0:
return
models = []
for atom in cur_sel:
if atom.structure not in models:
models.append(atom.structure)
center = []
for atom in cur_sel:
center.append(atom)
args["center"] = center
radii = self.radii_option.currentText()
self.settings.radii = radii
args["radii"] = radii
scale = self.scale.value()
self.settings.vdw_scale = scale
args["scale"] = scale
radius = self.radius.value()
self.settings.center_radius = radius
args["radius"] = radius
steric_map = self.steric_map.checkState() == Qt.Checked
self.settings.steric_map = steric_map
args["steric_map"] = steric_map
use_scene = self.use_scene.checkState() == Qt.Checked
self.settings.use_scene = use_scene
args["useScene"] = use_scene
num_pts = self.num_pts.value()
self.settings.num_pts = num_pts
args["num_pts"] = num_pts
include_vbur = self.include_vbur.checkState() == Qt.Checked
self.settings.include_vbur = include_vbur
use_centroid = self.use_centroid.checkState() == Qt.Checked
self.settings.use_centroid = use_centroid
args["useCentroid"] = use_centroid
shape = self.map_shape.currentText()
self.settings.map_shape = shape
args["shape"] = shape
report_component = self.report_component.currentText()
self.settings.report_component = report_component
args["reportComponent"] = report_component
method = self.method.currentText()
self.settings.method = method
if method == "Lebedev":
args["method"] = "lebedev"
rad_pts = self.radial_points.currentText()
self.settings.radial_points = rad_pts
args["radialPoints"] = rad_pts
ang_pts = self.angular_points.currentText()
self.settings.angular_points = ang_pts
args["angularPoints"] = ang_pts
elif method == "Monte-Carlo":
args["method"] = "mc"
min_iter = self.min_iter.value()
self.settings.minimum_iterations = min_iter
args["minimumIterations"] = min_iter
display_cutout = self.display_cutout.currentText()
self.settings.display_cutout = display_cutout
if display_cutout != "no":
args["displaySphere"] = display_cutout
if display_cutout != "no":
point_spacing = self.point_spacing.value()
self.settings.point_spacing = point_spacing
args["pointSpacing"] = point_spacing
intersection_scale = self.intersection_scale.value()
self.settings.intersection_scale = intersection_scale
args["intersectionScale"] = intersection_scale
cutout_labels = self.cutout_labels.currentText()
self.settings.cutout_labels = cutout_labels
args["labels"] = cutout_labels
if len(self.ligand_atoms) > 0:
args["onlyAtoms"] = [a for a in self.ligand_atoms if not a.deleted]
if len(args["onlyAtoms"]) == 0:
args["onlyAtoms"] = None
auto_minmax = self.auto_minmax.checkState() == Qt.Checked
self.settings.auto_minmax = auto_minmax
if not auto_minmax:
map_max = self.map_max.value()
self.settings.map_max = map_max
map_min = self.settings.map_min
self.settings.map_min = map_min
info = percent_vbur_cmd(self.session,
models,
return_values=True,
**args)
# self.table.setRowCount(0)
if steric_map:
for mdl, cent, vbur, map_info in info:
row = self.table.rowCount()
self.table.insertRow(row)
m = QTableWidgetItem()
m.setData(Qt.DisplayRole, mdl.name)
self.table.setItem(row, 0, m)
c = QTableWidgetItem()
c.setData(Qt.DisplayRole, cent)
self.table.setItem(row, 1, c)
v = QTableWidgetItem()
if report_component == "octants":
v.setData(Qt.DisplayRole,
",".join(["%.1f" % x for x in vbur]))
elif report_component == "quadrants":
v.setData(
Qt.DisplayRole, ",".join("%.1f" % x for x in [
vbur[0] + vbur[7],
vbur[1] + vbur[6],
vbur[2] + vbur[5],
vbur[3] + vbur[4],
]))
else:
if hasattr(vbur, "__iter__"):
v.setData(Qt.DisplayRole, "%.1f" % sum(vbur))
else:
v.setData(Qt.DisplayRole, "%.1f" % vbur)
v.setTextAlignment(Qt.AlignHCenter | Qt.AlignVCenter)
self.table.setItem(row, 2, v)
x, y, z, min_alt, max_alt = map_info
plot = self.tool_window.create_child_window(
"steric map of %s" % mdl.name, window_class=StericMap)
if auto_minmax:
plot.set_data(x, y, z, min_alt, max_alt, vbur, radius,
include_vbur)
else:
plot.set_data(x, y, z, map_min, map_max, vbur, radius,
include_vbur)
else:
for mdl, cent, vbur in info:
row = self.table.rowCount()
self.table.insertRow(row)
m = QTableWidgetItem()
m.setData(Qt.DisplayRole, mdl.name)
self.table.setItem(row, 0, m)
c = QTableWidgetItem()
c.setData(Qt.DisplayRole, cent)
self.table.setItem(row, 1, c)
v = QTableWidgetItem()
if report_component == "octants":
v.setData(Qt.DisplayRole,
",".join(["%.1f" % x for x in vbur]))
elif report_component == "quadrants":
v.setData(
Qt.DisplayRole, ",".join("%.1f" % x for x in [
vbur[0] + vbur[7],
vbur[1] + vbur[6],
vbur[2] + vbur[5],
vbur[3] + vbur[4],
]))
else:
if hasattr(vbur, "__iter__"):
v.setData(Qt.DisplayRole, "%.1f" % sum(vbur))
else:
v.setData(Qt.DisplayRole, "%.1f" % vbur)
v.setTextAlignment(Qt.AlignHCenter | Qt.AlignVCenter)
self.table.setItem(row, 2, v)
self.table.resizeColumnToContents(1)
self.table.resizeColumnToContents(2)
def header_check(self, state):
"""user has [un]checked the 'include header' option on the menu"""
if state:
self.settings.include_header = True
else:
self.settings.include_header = False
def get_csv(self):
if self.settings.delimiter == "comma":
delim = ","
elif self.settings.delimiter == "space":
delim = " "
elif self.settings.delimiter == "tab":
delim = "\t"
elif self.settings.delimiter == "semicolon":
delim = ";"
if self.settings.include_header:
s = delim.join(["model", "center", "%Vbur"])
s += "\n"
else:
s = ""
for i in range(0, self.table.rowCount()):
s += delim.join([
item.data(Qt.DisplayRole)
for item in [self.table.item(i, j) for j in range(0, 3)]
])
s += "\n"
return s
def copy_csv(self):
app = QApplication.instance()
clipboard = app.clipboard()
csv = self.get_csv()
clipboard.setText(csv)
self.session.logger.status("copied to clipboard")
def save_csv(self):
"""save data on current tab to CSV file"""
filename, _ = QFileDialog.getSaveFileName(filter="CSV Files (*.csv)")
if filename:
s = self.get_csv()
with open(filename, 'w') as f:
f.write(s.strip())
self.session.logger.status("saved to %s" % filename)
def del_vbur(self):
for model in self.session.models.list(type=Surface):
if model.name.startswith("%Vbur") or model.name.startswith(
"%Vfree"):
model.delete()
def display_help(self):
"""Show the help for this tool in the help viewer."""
from chimerax.core.commands import run
run(self.session,
'open %s' % self.help if self.help is not None else "")