Exemplo n.º 1
0
def read_files(mol_files):
    mol_strings = []
    try:
        # open files describing input molecules
        for file in mol_files:
            if os.path.exists(file):
                f = open(file, "r")
            else:
                raise IOError("Cannot find " + file)
            mystr = f.read()
            f.close()
            mol_strings.append(mystr)

        return mol_strings

    except IOError, e:
        msg = "IOError" + str(e)
        raise ParseError(msg)
Exemplo n.º 2
0
    def number(self, dot=True, test=False, inc=True):
        num = ''
        first = True
        pos = self.pos
        while self.more(pos):
            char = self.source[pos]
            if char == '-' and first: pass
            elif not char.isdigit():
                break

            first = False
            num += char
            pos += 1

        if char == '.' and dot:
            num += '.'
            pos += 1

            self.pos, tmp = pos, self.pos
            try:
                num += str(self.number(dot=False))
            except ParseError:
                pass

            pos, self.pos = self.pos, tmp

        if inc and not test: self.pos = pos

        if is_number(num):
            if test: return True
            try:
                n = int(num)
            except ValueError:
                n = float(num)

            return n
        else:
            if test: return False
            lines = self.source[:pos]
            line = lines.count('\n') + 1
            col = max(self.pos - lines.rfind('\n'), 0)
            raise ParseError('invalid number ending at {}:{}: {}'.format(
                line, col, num))
Exemplo n.º 3
0
 def error(self, msg):
     raise ParseError(msg)
Exemplo n.º 4
0
    def parse(self):
        while self.more():
            char = self.source[self.pos]
            result = None
            if self.lines and self.lines[-1]:
                token = self.lines[-1][-1]
            else:
                token = None

            if token and hasattr(token, 'dynamic') and hasattr(
                    token.dynamic, '__call__') and token.dynamic(char):
                self.inc()
                continue
            elif char in ('\n', ':'):
                self.close_brackets()

                self.inc()
                self.line += 1
                continue
            elif char in ' \t':
                self.inc()
                continue
            elif char in '([{':
                if char == '(':
                    cls = ParenExpr
                elif char == '[':
                    if self.more(self.pos + 1) and self.source[self.pos +
                                                               1].isalpha():
                        result = self.matrix()
                    else:
                        cls = MatrixExpr
                elif char == '{':
                    cls = ListExpr

                if result is None:
                    self.stack.append(cls(char))
                    self.inc()
                    continue
            elif char in ')]}':
                if self.stack:
                    stacks = []
                    l = len(self.stack)
                    for i in xrange(l):
                        stack = self.stack.pop(l - i - 1)
                        if isinstance(stack, Bracketed):
                            if stack.close(char):
                                for s in stacks:
                                    stack.append(s)

                                if not isinstance(stack, FunctionArgs):
                                    result = stack

                                stack.finish()
                                self.inc()
                                break
                            elif char != stack.end:
                                self.error(
                                    'tried to end \'%s\' with: "%s" (expecting "%s")'
                                    % (stack, char, stack.end))
                            else:
                                stacks.append(stack)
                        else:
                            stacks.append(stack)
                else:
                    self.error(
                        'encountered "%s" but we have no expression on the stack to terminate'
                        % char)
            elif char == ',':
                if len(self.stack) > 1 and isinstance(self.stack[-2], Tuple)\
                        and not isinstance(self.stack[-1], Tuple):
                    expr = self.stack.pop()
                    tup = self.stack[-1]
                    tup.append(expr)
                    tup.sep()
                elif self.stack and isinstance(self.stack[-1], Tuple):
                    self.stack[-1].sep()
                elif self.stack:
                    raise ParseError(
                        'comma encountered with an unclosed non-tuple expression on the stack'
                    )
                else:
                    if self.lines[-1]:
                        token = self.lines[-1].pop()
                    else:
                        self.error(
                            'Encountered comma, but cannot find anything to put in the tuple'
                        )

                    tup = Tuple()
                    tup.append(token)
                    self.stack.append(tup)
                    tup.sep()

                if isinstance(self.stack[-1], FunctionArgs):
                    self.stack.append(Expression())

                self.inc()
                continue
            elif '0' <= char <= '9' or char == '.'\
                    or isinstance(self.token(sub=True, inc=False), tokens.Minus) and self.number(test=True):
                result = tokens.Value(self.number())
            elif char in u'l∟' and self.more(self.pos + 1) and self.source[
                    self.pos + 1] in 'ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789':
                result = self.list()
            elif char.isalpha():
                result = self.token()
            elif char in self.SYMBOLS:
                result = self.symbol()
            elif char == '"':
                result = tokens.Value(self.string())
            else:
                self.error('could not tokenize: %s' % repr(char))

            if isinstance(result, tokens.Stor):
                self.close_brackets()

            if result is not None:
                self.add(result)

            argument = False
            if isinstance(result, tokens.Function):
                argument = True

            if isinstance(result, (tokens.List, tokens.Matrix)):
                if self.more() and self.source[self.pos] == '(':
                    self.inc()
                    argument = True

            # we were told to push the stack into argument mode
            if argument:
                args = FunctionArgs('(')
                self.stack.append(args)
                self.stack.append(Expression())
                result.absorb(args)

        self.close_brackets()
        return [line for line in self.post()]
Exemplo n.º 5
0
def neb_calc(molinterface, calc_man, params):
    """Setup NEB object, optimiser, etc."""

    spr_const = float(params["spr_const"])
    beads_count = int(params["beads_count"])
    neb = pts.searcher.NEB(molinterface.reagent_coords,
                           calc_man,
                           spr_const,
                           beads_count,
                           parallel=True)
    # initial path
    #dump_beads(molinterface, neb, params)
    dump_steps(neb)

    # callback function
    mycb = lambda x: generic_callback(x, molinterface, neb, **params)

    # opt params
    maxit = params['maxit']
    tol = params['tol']

    print "Launching optimiser..."
    if params["optimizer"] == "l_bfgs_b":

        import cosopt.lbfgsb as so

        #import ase
        #dyn = ase.LBFGS(neb)
        #dyn.run()
        opt, energy, dict = so.fmin_l_bfgs_b(neb.obj_func,
                                             neb.get_state_as_array(),
                                             fprime=neb.obj_func_grad,
                                             callback=mycb,
                                             pgtol=tol,
                                             maxfun=maxit)
    elif params["optimizer"] == "bfgs":
        from scipy.optimize import fmin_bfgs
        opt = fmin_bfgs(neb.obj_func,
                        neb.get_state_as_array(),
                        fprime=neb.obj_func_grad,
                        callback=mycb,
                        maxiter=maxit)

    elif params["optimizer"] == "ase_lbfgs":
        import ase
        optimizer = ase.LBFGS(neb)
        optimizer.run(fmax=tol)
        opt = neb.state_vec

    elif params["optimizer"] == "grad_descent":
        opt = opt_gd(neb.obj_func,
                     neb.get_state_as_array(),
                     fprime=neb.obj_func_grad,
                     callback=mycb)

    else:
        raise ParseError("Unknown optimizer: " + params["optimizer"])

    # PRODUCE OUTPUT
    print "Finished"
    #    print opt
    #    print energy

    dump_beads(molinterface, neb, params)
    print "steps"
    dump_steps(neb)
Exemplo n.º 6
0
def string_calc(molinterface, calc_man, reagent_coords, params):
    """Setup String object, optimiser, etc."""

    beads_count = int(params["beads_count"])
    string = pts.searcher.GrowingString(molinterface.reagent_coords,
                                        calc_man,
                                        beads_count,
                                        rho=lambda x: 1,
                                        growing=params['growing'],
                                        parallel=True)
    # initial path
    dump_beads(molinterface, string, params)
    #dump_steps(string)

    mycb = lambda x: generic_callback(x, molinterface, string, **params)

    # opt params
    maxit = params['maxit']
    tol = params['tol']

    print "Launching optimiser..."
    if params['growing']:
        gqs = pts.searcher.QuadraticStringMethod(string,
                                                 callback=mycb,
                                                 update_trust_rads=True)
        while True:
            opt = gqs.opt()

            # grow the string, but break if not possible
            print "Growing"
            if not string.grow_string():
                break

    elif params["optimizer"] == "l_bfgs_b":

        import cosopt.lbfgsb as so

        opt, energy, dict = so.fmin_l_bfgs_b(string.obj_func,
                                             string.get_state_as_array(),
                                             fprime=string.obj_func_grad,
                                             callback=mycb,
                                             pgtol=tol,
                                             maxfun=maxit)
        print opt
        print energy
        print dict

    elif params["optimizer"] == "quadratic_string":
        qs = pts.searcher.QuadraticStringMethod(string,
                                                callback=mycb,
                                                update_trust_rads=True)
        opt = qs.opt()
        print opt

    elif params["optimizer"] == "ase_lbfgs":

        import ase
        dyn = ase.LBFGS(string)
        dyn.run()

    else:
        raise ParseError("Unknown optimizer: " + params["optimizer"])
Exemplo n.º 7
0
        print >> sys.stderr, "for help use --help"
        return 2

    # try to parse config file
    mol_files = []
    params = []
    try:
        config = ConfigParser.RawConfigParser()
        config.read(inputfile)

        if config.has_section('parameters'):
            params = dict(config.items('parameters'))
            params["name"] = os.path.splitext(inputfile)[0]
        else:
            print config.sections()
            raise ParseError("Could not find section 'parameters'")

        # extract ASE calculator specification
        if config.has_section('calculator'):
            calc_params = dict(config.items('calculator'))

            # TODO: add some error checking for the following values
            cons = eval(calc_params['constructor'])
            args = eval(calc_params['args'])
            kwargs = eval(calc_params['kwargs'])
            kwargs = dict(kwargs)

            calc_tuple = cons, args, kwargs
            params['calculator'] = calc_tuple

            mask = calc_params.get('mask')