コード例 #1
0
ファイル: pdbxfile.py プロジェクト: z-gong/openmm
    def writeModel(topology, positions, file=sys.stdout, modelIndex=1, keepIds=False):
        """Write out a model to a PDBx/mmCIF file.

        Parameters
        ----------
        topology : Topology
            The Topology defining the model to write
        positions : list
            The list of atomic positions to write
        file : file=stdout
            A file to write the model to
        modelIndex : int=1
            The model number of this frame
        keepIds : bool=False
            If True, keep the residue and chain IDs specified in the Topology
            rather than generating new ones.  Warning: It is up to the caller to
            make sure these are valid IDs that satisfy the requirements of the
            PDBx/mmCIF format.  Otherwise, the output file will be invalid.
        """
        if len(list(topology.atoms())) != len(positions):
            raise ValueError('The number of positions must match the number of atoms')
        if is_quantity(positions):
            positions = positions.value_in_unit(angstroms)
        if any(math.isnan(norm(pos)) for pos in positions):
            raise ValueError('Particle position is NaN.  For more information, see https://github.com/openmm/openmm/wiki/Frequently-Asked-Questions#nan')
        if any(math.isinf(norm(pos)) for pos in positions):
            raise ValueError('Particle position is infinite.  For more information, see https://github.com/openmm/openmm/wiki/Frequently-Asked-Questions#nan')
        nonHeterogens = PDBFile._standardResidues[:]
        nonHeterogens.remove('HOH')
        atomIndex = 1
        posIndex = 0
        for (chainIndex, chain) in enumerate(topology.chains()):
            if keepIds:
                chainName = chain.id
            else:
                chainName = chr(ord('A')+chainIndex%26)
            residues = list(chain.residues())
            for (resIndex, res) in enumerate(residues):
                if keepIds:
                    resId = res.id
                    resIC = (res.insertionCode if res.insertionCode.strip() else '.')
                else:
                    resId = resIndex + 1
                    resIC = '.'
                if res.name in nonHeterogens:
                    recordName = "ATOM"
                else:
                    recordName = "HETATM"
                for atom in res.atoms():
                    coords = positions[posIndex]
                    if atom.element is not None:
                        symbol = atom.element.symbol
                    else:
                        symbol = '?'
                    line = "%s  %5d %-3s %-4s . %-4s %s ? %5s %s %10.4f %10.4f %10.4f  0.0  0.0  ?  ?  ?  ?  ?  .  %5s %4s %s %4s %5d"
                    print(line % (recordName, atomIndex, symbol, atom.name, res.name, chainName, resId, resIC, coords[0], coords[1], coords[2],
                                  resId, res.name, chainName, atom.name, modelIndex), file=file)
                    posIndex += 1
                    atomIndex += 1
コード例 #2
0
ファイル: unitcell.py プロジェクト: z-gong/openmm
def computeLengthsAndAngles(periodicBoxVectors):
    """Convert periodic box vectors to lengths and angles.

    Lengths are returned in nanometers and angles in radians.
    """
    if is_quantity(periodicBoxVectors):
        (a, b, c) = periodicBoxVectors.value_in_unit(nanometers)
    else:
        a, b, c = periodicBoxVectors
    a_length = norm(a)
    b_length = norm(b)
    c_length = norm(c)
    alpha = math.acos(dot(b, c) / (b_length * c_length))
    beta = math.acos(dot(c, a) / (c_length * a_length))
    gamma = math.acos(dot(a, b) / (a_length * b_length))
    return (a_length, b_length, c_length, alpha, beta, gamma)
コード例 #3
0
 def testUnitMathModule(self):
     """ Tests the unit_math functions on Quantity objects """
     self.assertEqual(u.sqrt(1.0 * u.kilogram * u.joule),
                      1.0 * u.kilogram * u.meter / u.second)
     self.assertEqual(u.sqrt(1.0 * u.kilogram * u.calorie),
                      math.sqrt(4.184) * u.kilogram * u.meter / u.second)
     self.assertEqual(u.sqrt(9), 3)  # Test on a scalar
     self.assertEqual(u.sin(90 * u.degrees), 1)
     self.assertEqual(u.sin(math.pi / 2 * u.radians), 1)
     self.assertEqual(u.sin(math.pi / 2), 1)
     self.assertEqual(u.cos(180 * u.degrees), -1)
     self.assertEqual(u.cos(math.pi * u.radians), -1)
     self.assertEqual(u.cos(math.pi), -1)
     self.assertAlmostEqual(u.tan(45 * u.degrees), 1)
     self.assertAlmostEqual(u.tan(math.pi / 4 * u.radians), 1)
     self.assertAlmostEqual(u.tan(math.pi / 4), 1)
     acos = u.acos(1.0)
     asin = u.asin(1.0)
     atan = u.atan(1.0)
     self.assertTrue(u.is_quantity(acos))
     self.assertTrue(u.is_quantity(asin))
     self.assertTrue(u.is_quantity(atan))
     self.assertEqual(acos.unit, u.radians)
     self.assertEqual(asin.unit, u.radians)
     self.assertEqual(atan.unit, u.radians)
     self.assertEqual(acos.value_in_unit(u.degrees), 0)
     self.assertEqual(acos / u.radians, 0)
     self.assertEqual(asin.value_in_unit(u.degrees), 90)
     self.assertEqual(asin / u.radians, math.pi / 2)
     self.assertAlmostEqual(atan.value_in_unit(u.degrees), 45)
     self.assertAlmostEqual(atan / u.radians, math.pi / 4)
     # Check some sequence maths
     seq = [1, 2, 3, 4] * u.meters
     self.assertEqual(u.sum(seq), 10 * u.meters)
     self.assertEqual(u.dot(seq, seq), (1 + 4 + 9 + 16) * u.meters**2)
     self.assertEqual(u.norm(seq), math.sqrt(30) * u.meters)
コード例 #4
0
ファイル: pdbfile.py プロジェクト: wouterboomsma/openmm
    def writeModel(topology,
                   positions,
                   file=sys.stdout,
                   modelIndex=None,
                   keepIds=False,
                   extraParticleIdentifier='EP'):
        """Write out a model to a PDB file.

        Parameters
        ----------
        topology : Topology
            The Topology defining the model to write
        positions : list
            The list of atomic positions to write
        file : file=stdout
            A file to write the model to
        modelIndex : int=None
            If not None, the model will be surrounded by MODEL/ENDMDL records
            with this index
        keepIds : bool=False
            If True, keep the residue and chain IDs specified in the Topology
            rather than generating new ones.  Warning: It is up to the caller to
            make sure these are valid IDs that satisfy the requirements of the
            PDB format.  No guarantees are made about what will happen if they
            are not, and the output file could be invalid.
        extraParticleIdentifier : string='EP'
            String to write in the element column of the ATOM records for atoms whose element is None (extra particles)
        """

        if len(list(topology.atoms())) != len(positions):
            raise ValueError(
                'The number of positions must match the number of atoms')
        if is_quantity(positions):
            positions = positions.value_in_unit(angstroms)
        if any(math.isnan(norm(pos)) for pos in positions):
            raise ValueError('Particle position is NaN')
        if any(math.isinf(norm(pos)) for pos in positions):
            raise ValueError('Particle position is infinite')
        nonHeterogens = PDBFile._standardResidues[:]
        nonHeterogens.remove('HOH')
        atomIndex = 1
        posIndex = 0
        if modelIndex is not None:
            print("MODEL     %4d" % modelIndex, file=file)
        for (chainIndex, chain) in enumerate(topology.chains()):
            if keepIds and len(chain.id) == 1:
                chainName = chain.id
            else:
                chainName = chr(ord('A') + chainIndex % 26)
            residues = list(chain.residues())
            for (resIndex, res) in enumerate(residues):
                if len(res.name) > 3:
                    resName = res.name[:3]
                else:
                    resName = res.name
                if keepIds and len(res.id) < 5:
                    resId = res.id
                else:
                    resId = "%4d" % ((resIndex + 1) % 10000)
                if len(res.insertionCode) == 1:
                    resIC = res.insertionCode
                else:
                    resIC = " "
                if res.name in nonHeterogens:
                    recordName = "ATOM  "
                else:
                    recordName = "HETATM"
                for atom in res.atoms():
                    if atom.element is not None:
                        symbol = atom.element.symbol
                    else:
                        symbol = extraParticleIdentifier
                    if len(atom.name) < 4 and atom.name[:1].isalpha(
                    ) and len(symbol) < 2:
                        atomName = ' ' + atom.name
                    elif len(atom.name) > 4:
                        atomName = atom.name[:4]
                    else:
                        atomName = atom.name
                    coords = positions[posIndex]
                    line = "%s%5d %-4s %3s %s%4s%1s   %s%s%s  1.00  0.00          %2s  " % (
                        recordName, atomIndex % 100000, atomName, resName,
                        chainName, resId, resIC, _format_83(coords[0]),
                        _format_83(coords[1]), _format_83(coords[2]), symbol)
                    if len(line) != 80:
                        raise ValueError('Fixed width overflow detected')
                    print(line, file=file)
                    posIndex += 1
                    atomIndex += 1
                if resIndex == len(residues) - 1:
                    print("TER   %5d      %3s %s%4s" %
                          (atomIndex, resName, chainName, resId),
                          file=file)
                    atomIndex += 1
        if modelIndex is not None:
            print("ENDMDL", file=file)
コード例 #5
0
ファイル: dcdfile.py プロジェクト: wouterboomsma/openmm
    def writeModel(self, positions, unitCellDimensions=None, periodicBoxVectors=None):
        """Write out a model to the DCD file.

        The periodic box can be specified either by the unit cell dimensions
        (for a rectangular box), or the full set of box vectors (for an
        arbitrary triclinic box).  If neither is specified, the box vectors
        specified in the Topology will be used. Regardless of the value
        specified, no dimensions will be written if the Topology does not
        represent a periodic system.

        Parameters
        ----------
        positions : list
            The list of atomic positions to write
        unitCellDimensions : Vec3=None
            The dimensions of the crystallographic unit cell.
        periodicBoxVectors : tuple of Vec3=None
            The vectors defining the periodic box.
        """
        if len(list(self._topology.atoms())) != len(positions):
            raise ValueError('The number of positions must match the number of atoms')
        if is_quantity(positions):
            positions = positions.value_in_unit(nanometers)
        if any(math.isnan(norm(pos)) for pos in positions):
            raise ValueError('Particle position is NaN')
        if any(math.isinf(norm(pos)) for pos in positions):
            raise ValueError('Particle position is infinite')
        file = self._file

        self._modelCount += 1
        if self._interval > 1 and self._firstStep+self._modelCount*self._interval > 1<<31:
            # This will exceed the range of a 32 bit integer.  To avoid crashing or producing a corrupt file,
            # update the header to say the trajectory consisted of a smaller number of larger steps (so the
            # total trajectory length remains correct).
            self._firstStep //= self._interval
            self._dt *= self._interval
            self._interval = 1
            file.seek(0, os.SEEK_SET)
            file.write(struct.pack('<i4c9if', 84, b'C', b'O', b'R', b'D', 0, self._firstStep, self._interval, 0, 0, 0, 0, 0, 0, self._dt))

        # Update the header.

        file.seek(8, os.SEEK_SET)
        file.write(struct.pack('<i', self._modelCount))
        file.seek(20, os.SEEK_SET)
        file.write(struct.pack('<i', self._firstStep+self._modelCount*self._interval))

        # Write the data.

        file.seek(0, os.SEEK_END)
        boxVectors = self._topology.getPeriodicBoxVectors()
        if boxVectors is not None:
            if periodicBoxVectors is not None:
                boxVectors = periodicBoxVectors
            elif unitCellDimensions is not None:
                if is_quantity(unitCellDimensions):
                    unitCellDimensions = unitCellDimensions.value_in_unit(nanometers)
                boxVectors = (Vec3(unitCellDimensions[0], 0, 0), Vec3(0, unitCellDimensions[1], 0), Vec3(0, 0, unitCellDimensions[2]))*nanometers
            (a_length, b_length, c_length, alpha, beta, gamma) = computeLengthsAndAngles(boxVectors)
            a_length = a_length * 10.  # computeLengthsAndAngles returns unitless nanometers, but need angstroms here.
            b_length = b_length * 10.  # computeLengthsAndAngles returns unitless nanometers, but need angstroms here.
            c_length = c_length * 10.  # computeLengthsAndAngles returns unitless nanometers, but need angstroms here.
            angle1 = math.sin(math.pi/2-gamma)
            angle2 = math.sin(math.pi/2-beta)
            angle3 = math.sin(math.pi/2-alpha)
            file.write(struct.pack('<i6di', 48, a_length, angle1, b_length, angle2, angle3, c_length, 48))
        length = struct.pack('<i', 4*len(positions))
        for i in range(3):
            file.write(length)
            data = array.array('f', (10*x[i] for x in positions))
            data.tofile(file)
            file.write(length)
        try:
            file.flush()
        except AttributeError:
            pass