Exemplo n.º 1
0
def arange_long(start, stop=-1):
    """ Creates a LongArray working same as builtin range with upto 2 arguments
    both expected to be positive
    """

    if stop == -1:
        arange = LongArray(start)
        for i in range(start):
            arange.data[i] = i
        return arange
    else:
        size = stop - start
        arange = LongArray(size)
        for i in range(size):
            arange.data[i] = start + i
        return arange
Exemplo n.º 2
0
    def create_particles(self, **kwargs):
        fluid_column_height = self.fluid_column_height
        fluid_column_width = self.fluid_column_width
        fluid_column_length = self.fluid_column_length

        container_height = self.container_height
        container_length = self.container_length
        container_width = self.container_width

        obstacle_height = self.obstacle_height
        obstacle_length = self.obstacle_length
        obstacle_width = self.obstacle_width

        obstacle_center_x = self.obstacle_center_x
        obstacle_center_y = self.obstacle_center_y

        nboundary_layers = self.nboundary_layers
        dx = self.dx

        # get the domain limits
        ghostlims = nboundary_layers * dx

        xmin, xmax = 0.0 - ghostlims, container_length + ghostlims
        zmin, zmax = 0.0 - ghostlims, container_height + ghostlims

        cw2 = 0.5 * container_width
        ymin, ymax = -cw2 - ghostlims, cw2 + ghostlims

        # create all particles
        eps = 0.1 * dx
        xx, yy, zz = numpy.mgrid[xmin:xmax + eps:dx,
                                 ymin:ymax + eps:dx,
                                 zmin:zmax + eps:dx]

        x = xx.ravel()
        y = yy.ravel()
        z = zz.ravel()

        # create a dummy particle array from which we'll sort
        pa = get_particle_array_wcsph(name='block', x=x, y=y, z=z)

        # get the individual arrays
        indices = []
        findices = []
        oindices = []

        obw2 = 0.5 * obstacle_width
        obl2 = 0.5 * obstacle_length
        obh = obstacle_height
        ocx = obstacle_center_x
        ocy = obstacle_center_y

        for i in range(x.size):
            xi = x[i]
            yi = y[i]
            zi = z[i]

            # fluid
            if ((0 < xi <= fluid_column_length) and
                (-cw2 < yi < cw2) and
                    (0 < zi <= fluid_column_height)):

                findices.append(i)

            # obstacle
            if ((ocx - obl2 <= xi <= ocx + obl2) and
                (ocy - obw2 <= yi <= ocy + obw2) and
                    (0 < zi <= obh)):

                oindices.append(i)

        # extract the individual arrays
        fa = LongArray(len(findices))
        fa.set_data(numpy.array(findices))
        fluid = pa.extract_particles(fa)
        fluid.set_name('fluid')

        if self.with_obstacle:
            oa = LongArray(len(oindices))
            oa.set_data(numpy.array(oindices))
            obstacle = pa.extract_particles(oa)
            obstacle.set_name('obstacle')

        indices = concatenate((where(y <= -cw2)[0],
                               where(y >= cw2)[0],
                               where(x >= container_length)[0],
                               where(x <= 0)[0],
                               where(z <= 0)[0]))

        # remove duplicates
        indices = array(list(set(indices)))

        wa = LongArray(indices.size)
        wa.set_data(indices)
        boundary = pa.extract_particles(wa)
        boundary.set_name('boundary')

        # create the particles
        if self.with_obstacle:
            particles = [fluid, boundary, obstacle]
        else:
            particles = [fluid, boundary]

        # set up particle properties
        h0 = self.hdx * dx

        volume = dx**3
        m0 = self.rho0 * volume

        for pa in particles:
            pa.m[:] = m0
            pa.h[:] = h0

            pa.rho[:] = self.rho0

        nf = fluid.num_real_particles
        nb = boundary.num_real_particles

        if self.with_obstacle:
            no = obstacle.num_real_particles
            print(
                "3D dam break with %d fluid, %d boundary, %d obstacle particles" %
                (nf, nb, no))
        else:
            print(
                "3D dam break with %d fluid, %d boundary particles" %
                (nf, nb))

        # load balancing props for the arrays
        # fluid.set_lb_props(['x', 'y', 'z', 'u', 'v', 'w', 'rho', 'h', 'm', 'gid',
        #                    'x0', 'y0', 'z0', 'u0', 'v0', 'w0', 'rho0'])
        fluid.set_lb_props(list(fluid.properties.keys()))

        #boundary.set_lb_props(['x', 'y', 'z', 'rho', 'h', 'm', 'gid', 'rho0'])
        #obstacle.set_lb_props(['x', 'y', 'z', 'rho', 'h', 'm', 'gid', 'rho0'])
        boundary.set_lb_props(list(boundary.properties.keys()))

        # boundary and obstacle particles can do with a reduced list of properties
        # to be saved to disk since they are fixed
        boundary.set_output_arrays(
            ['x', 'y', 'z', 'rho', 'm', 'h', 'p', 'tag', 'pid', 'gid'])

        if self.with_obstacle:
            obstacle.set_lb_props(list(obstacle.properties.keys()))
            obstacle.set_output_arrays(
                ['x', 'y', 'z', 'rho', 'm', 'h', 'p', 'tag', 'pid', 'gid'])

        return particles