Example #1
0
def initialize():
    """Wrapper that initializes all necessary data structures.

    Returns
        U (3D array)   :  the state-variables-3D-matrix (populating a x,y grid)
                          - shape: (3, Nx + 2 * Ng, Ny + 2 * Ng)
                          - U[0] : state varables [h, hu, hv]
                          - U[1] : y dimention (rows)
                          - U[2] : x dimention (columns)
        h_hist (array) :  holds the step-wise height solutions for the
                                 post-processing animation
        t_hist (array) :  holds the step-wise times for the post-
                          processing animation
        U_ds (memmap)  :  holds the state-variables 3D matrix data for all
                          the timesteps
                          (conf.MAX_ITERS, 3, Nx + 2 * Ng, Ny + 2 * Ng)
    """
    logger.log('Initialization...')

    U = _init_U()
    h_hist = _init_h_hist(U)
    t_hist = t_hist = np.zeros(len(h_hist), dtype=conf.DTYPE)
    if conf.SAVE_DS_FOR_ML:
        U_ds = _init_U_ds(U)
    else:
        U_ds = None
    return U, h_hist, t_hist, U_ds
Example #2
0
def _plot_basin(sub):
    """Plots the basin that contains the fluid.

    Args:
        sub (axes.SubplotBase) : Axes3D subplot object
    """
    if conf.SHOW_BASIN is True:
        # Make the basin a bit wider, because water appears to be out of the
        # basin because of the perspective mode.
        X_bas, Y_bas = np.meshgrid(conf.CX[conf.Ng - 1:conf.Nx + conf.Ng + 1],
                                   conf.CY[conf.Ng - 1:conf.Ny + conf.Ng + 1])
        # BASIN
        BASIN = np.zeros((conf.Ny + 2, conf.Nx + 2))
        # left-right walls
        BASIN[:, 0] = 2.5
        BASIN[:, conf.Nx + 1] = 2.5
        # top-bottom walls
        BASIN[0, :] = 2.5
        BASIN[conf.Ny + 1, :] = 2.5
        sub.plot_surface(X_bas,
                         Y_bas,
                         BASIN,
                         rstride=2,
                         cstride=2,
                         linewidth=0,
                         color=(0.4, 0.4, 0.5, 0.1))
    elif conf.SHOW_BASIN is False:
        pass
    else:
        logger.log("Configure SHOW_BASIN. Options: True, False")
Example #3
0
def drop_iters_list():
    """list with the simulation iters at which a drop is going to fall."""
    drop_iters = [0]
    iters_cumsum = 0
    i = 0
    if conf.ITERS_BETWEEN_DROPS_MODE == "custom":
        while iters_cumsum <= conf.MAX_ITERS:
            iters_cumsum += conf.CUSTOM_ITERS_BETWEEN_DROPS[i % 10]
            drop_iters.append(iters_cumsum)
            i += 1
    elif conf.ITERS_BETWEEN_DROPS_MODE == "random":
        while iters_cumsum <= conf.MAX_ITERS:
            iters_cumsum += random.randint(60, 120)
            drop_iters.append(iters_cumsum)
    else:
        logger.log("Configure ITERS_BETWEEN_DROPS_MODE | options:"
                   " 'fixed', 'custom', 'random'")

    # # Remove drop iterations that fall after MAX_ITERS.
    # last_drop_idx = np.searchsorted(drop_iters, conf.MAX_ITERS)
    # drop_iters = drop_iters[:last_drop_idx]
    # # Overwrite max number of drops.
    # conf.MAX_N_DROPS = len(drop_iters)

    if conf.SAVE_DS_FOR_ML:
        # It is needed to retrieve the new drop frames, because these frames
        # cannot be used as labels (the previous frame cannot know when and
        # where a new drop will fall).
        # ds_shape
        dss = ds_shape()
        file_name = f"drop_iters_list_{dss[0]}x{dss[1]}x{dss[2]}x{dss[3]}.npy"
        np.save(os.path.join(os.getcwd(), file_name), drop_iters)
    return drop_iters
Example #4
0
def _save_ani(ani, fps, dpi):
    """Saves the animation in .mp4 and .gif formats.

    Args:
        ani (obj) : animation.FuncAnimation() object
        fps (int) : frames per second
        dpi (int) : dots per inch
    """
    if conf.SAVE_ANIMATION is True:
        # file name
        date_n_time = str(datetime.now())[:19]
        # Replace ':' with '-' for compatibility with windows file formating.
        date_n_time = date_n_time.replace(':', '-').replace(' ', '_')
        file_name = conf.MODE + '_animation_' + date_n_time

        # Configure the writer
        plt.rcParams['animation.ffmpeg_path'] = conf.PATH_TO_FFMPEG
        FFwriter = animation.FFMpegWriter(fps=fps,
                                          bitrate=-1,
                                          extra_args=[
                                              '-r',
                                              str(fps), '-pix_fmt', 'yuv420p',
                                              '-vcodec', 'libx264',
                                              '-qscale:v', '1'
                                          ])

        # Save
        try:
            ani.save(file_name + '.' + conf.VID_FORMAT,
                     writer=FFwriter,
                     dpi=dpi)

            # log only if a log file is already initialzed
            if isinstance(logger.find_open_log(), str):
                logger.log('Animation saved as: ' + file_name + '.' +
                           conf.VID_FORMAT + ' | fps: ' + str(fps))

            # convert to a lighter gif
            cmd = 'ffmpeg -i ' + file_name + '.' + conf.VID_FORMAT + ' -vf '   \
                  '"fps=' + str(fps) + ',scale=240:-1:flags=lanczos,split'     \
                  '[s0][s1];[s0]palettegen[p];[s1][p]paletteuse" -hide_banner' \
                  ' -loglevel panic -loop 0 ' + file_name + '.gif'
            os.system(cmd)
            if isinstance(logger.find_open_log(), str):
                logger.log('Animation saved as: ' + file_name + '.gif' +
                           ' | fps: ' + str(fps))
        except FileNotFoundError:
            logger.log('Configure PATH_TO_FFMPEG')
    elif conf.SAVE_ANIMATION is False:
        pass
    else:
        logger.log("Configure SAVE_ANIMATION | Options: True, False")
Example #5
0
def _save_ani(ani):
    """Saves the animation in .mp4 and .gif formats.

    Args:
        ani (obj) : animation.FuncAnimation() object
    """
    dpi = conf.DPI
    fps = conf.FPS
    # file name
    date_n_time = str(datetime.now())[:19]
    # Replace ':' with '-' for compatibility with windows file formating.
    date_n_time = date_n_time.replace(':', '-').replace(' ', '_')
    file_name = conf.MODE + '_animation_' + date_n_time

    # Configure the writer
    plt.rcParams['animation.ffmpeg_path'] = conf.PATH_TO_FFMPEG
    FFwriter = animation.FFMpegWriter(
        fps=fps, bitrate=-1,
        extra_args=['-r', str(fps), '-pix_fmt', 'yuv420p', '-vcodec',
                    'libx264', '-qscale:v', '1']
    )

    # Save
    try:
        ani.save(os.path.join(conf.SAVE_DIR, f"{file_name}.{conf.VID_FORMAT}"),
                 writer=FFwriter,
                 dpi=dpi)

        # log only if a log file is already initialzed
        if isinstance(logger.find_open_log(), str):
            logger.log(f'Animation saved as: {file_name}.'
                       f'{conf.VID_FORMAT} | fps: {fps}')

        # convert to a lighter gif
        cmd = (f'ffmpeg -i {file_name}.{conf.VID_FORMAT} -vf '
               f'"fps={fps},scale=240:-1:flags=lanczos,split'
               '[s0][s1];[s0]palettegen[p];[s1][p]paletteuse" -hide_banner'
               f' -loglevel panic -loop 0 {file_name}.gif')
        os.system(cmd)
        if isinstance(logger.find_open_log(), str):
            logger.log(f'Animation saved as: {file_name}.gif | fps: {fps}')
    except FileNotFoundError:
        logger.log('Configure PATH_TO_FFMPEG')
Example #6
0
def plot_from_dat(time, it):
    """Creates and saves a frame as .png, reading data from a .dat file.

    Args:
        time (float) : current time
        it (int)     : current itereration
    """
    # Create ./session directory for saving the results.
    utils.child_dir("session")

    # Extract data from dat.
    X, Y, Z, Nx, Ny = _data_from_dat(it)

    # plot {
    #
    fig = plt.figure(figsize=(9.6, 6.4), dpi=112)  # 1080x720
    sub = fig.add_subplot(111, projection="3d")
    plt.subplots_adjust(left=0, bottom=0, right=1, top=1, wspace=0, hspace=0)

    if conf.PLOTTING_STYLE == 'water':
        if conf.ROTATION:
            # Azimuthal rotate every 8 frames and vetical every 20 frames
            azimuth = 45 + it / 8
            elevation = 55 - it / 20
            sub.view_init(elevation, azimuth)
        else:
            sub.view_init(45, 55)
        sub.plot_surface(X,
                         Y,
                         Z,
                         rstride=1,
                         cstride=1,
                         linewidth=0,
                         color=(0.251, 0.643, 0.875, 0.95),
                         shade=True,
                         antialiased=False)
    elif conf.PLOTTING_STYLE == 'contour':
        sub.view_init(45, 55)
        sub.contour3D(X, Y, Z, 140, cmap='plasma', vmin=0.6, vmax=1.4)
    elif conf.PLOTTING_STYLE == 'wireframe':
        if conf.ROTATION:
            # Azimuthal rotate every 3 frames and vetical every 4 frames
            azimuth = 45 + it / 3
            elevation = 55 - it / 4
            sub.view_init(elevation, azimuth)
        else:
            sub.view_init(45, 55)
        sub.plot_wireframe(
            X,
            Y,
            Z,
            rstride=2,
            cstride=2,
            linewidth=1,
        )
    else:
        styles = ['water', 'contour', 'wireframe']
        logger.log(f"Configure PLOTTING_STYLE | options: {styles}")

    fig.gca().set_zlim([-0.5, 4])
    plt.title(f"time: {time: >{6}.3f}\titer: {it: >{4}d}", y=0.8, fontsize=18)
    sub.title.set_position([0.51, 0.80])
    plt.rcParams.update({'font.size': 20})
    plt.axis('off')

    # Render the basin that contains the fluid.
    _plot_basin(sub)

    # save
    # fig.tight_layout()
    fig_file = os.path.join("session", f"iter_{it:0>{4}}.png")
    plt.savefig(fig_file)
    plt.close()
Example #7
0
def animate(h_hist, t_hist=None):
    """Generates and saves an animation of the simulation.

    Args:
        h_hist (array) :  array of iter-wise heights solutions
        t_hist (array) :  holds the iter-wise times

    Returns:
        ani (animation.FuncAnimation) : It is returned in case of ipython
    """
    # resolution = figsize * dpi
    # --------------------------
    # example:
    # figsize = (9.6, 5.4), dpi=200
    # resolution: 1920x1080 (1920/200=9.6)
    fps = conf.FPS
    dpi = conf.DPI
    figsize = conf.FIGSIZE

    # total frames
    frames = len(h_hist)

    # X, Y, Z
    X, Y = np.meshgrid(conf.CX[conf.Ng:-conf.Ng], conf.CY[conf.Ng:-conf.Ng])
    Z = h_hist

    # Plot configuration
    fig = plt.figure(figsize=figsize, dpi=dpi)
    sub = fig.add_subplot(111, projection="3d")
    if conf.ROTATION:
        sub.view_init(45, 55)
    else:
        sub.view_init(30, 20)
    plt.subplots_adjust(left=0, bottom=0, right=1, top=1, wspace=0, hspace=0)
    fig.gca().set_zlim([-0.5, 4])
    plt.axis('off')
    if t_hist is None:
        ani_title = f"iter: {0:>{5}d}"
    else:
        ani_title = f"time: {t_hist[0]:>{6}.3f}    iter: {0:>{5}d}"
    plt.title(ani_title, y=0.8, fontsize=18)
    sub.title.set_position([0.51, 0.80])
    plt.rcParams.update({'font.size': 20})
    # Program name and version text
    fig.text(0.85, 0.06, s=f"MattFlow v{__version__}", fontsize=16, c='navy')

    # Plot initialization
    if conf.PLOTTING_STYLE == 'water':
        plot = [
            sub.plot_surface(X,
                             Y,
                             Z[0],
                             rstride=1,
                             cstride=1,
                             linewidth=0,
                             color=(0.251, 0.643, 0.875, 0.9),
                             shade=True,
                             antialiased=False)
        ]
    elif conf.PLOTTING_STYLE == 'contour':
        plot = [
            sub.contour3D(X, Y, Z[0], 150, cmap='ocean', vmin=0.5, vmax=1.5)
        ]
    elif conf.PLOTTING_STYLE == 'wireframe':
        plot = [
            sub.plot_wireframe(X, Y, Z[0], rstride=2, cstride=2, linewidth=1)
        ]
    else:
        logger.log("Configure PLOTTING_STYLE | options: 'water', 'contour',",
                   "'wireframe'")
    # Render the basin that contains the fluid.
    _plot_basin(sub)

    # Generate the animation.
    ani = animation.FuncAnimation(fig,
                                  _update_plot,
                                  frames,
                                  fargs=(X, Y, Z, plot, fig, sub, t_hist,
                                         ani_title),
                                  interval=1000 / fps,
                                  repeat=True)

    # Save the animation.
    _save_ani(ani, fps, dpi)

    # Play the animation.
    if conf.SHOW_ANIMATION is True:
        logger.log('Playing animation...')
        try:
            # In case of jupyter notebook, don't run plt.show(), to prevent
            # displaying a static figure. Instead, return the Funcanimation
            # object.
            get_ipython()
            return ani
        except NameError:
            plt.show()
    elif conf.SHOW_ANIMATION is False:
        pass
    else:
        logger.log("Configure SHOW_ANIMATION | Options: True, False")
Example #8
0
def _solve(U, delta_t, it, drops_count, drop_its_iterator, next_drop_it):
    """Evaluates the state variables (h, hu, hv) at a new time-step.

    It can be used in a for/while loop, iterating through each time-step.

    Args:
        U (3D array)       :  the state variables, populating a x,y grid
        delta_t (float)    :  time discretization step
        it (int)           :  current iteration
        drops_count (int)  :  number of drops been generated
        drop_its_iterator (iterator)
                           :  iterator of the drop_its list (the list with
                              the iters at which a new drop falls)
        next_drop_it (int) :  the next iteration at which a new drop will fall

    Returns:
        U, drops_count, drop_its_iterator, next_drop_it
    """
    # Retrieve the mesh
    Ng = conf.Ng
    cx = conf.CX
    cy = conf.CY
    cellArea = conf.dx * conf.dy

    # Simulation mode
    # ---------------
    # 'single drop': handled at the initialization
    if conf.MODE == 'single drop':
        pass

    # 'drops': specified number of drops are generated at specified frequency
    elif conf.MODE == 'drops':
        if conf.ITERS_BETWEEN_DROPS_MODE == "fixed":
            drop_condition = (it % conf.FIXED_ITERS_BETWEEN_DROPS == 0
                              and drops_count < conf.MAX_N_DROPS)
        else:  # conf.ITERS_TO_NEXT_DROP_MODE in ["custom", "random"]
            drop_condition = (it == next_drop_it
                              and drops_count < conf.MAX_N_DROPS)

        if drop_condition:
            U[0, :, :] = initializer.drop(U[0, :, :], drops_count + 1)
            drops_count += 1
            if (conf.ITERS_BETWEEN_DROPS_MODE in ["custom", "random"]
                    and drops_count < conf.MAX_N_DROPS):
                next_drop_it = next(drop_its_iterator)

    # 'rain': random number of drops are generated at random frequency
    elif conf.MODE == 'rain':
        if it % random.randrange(1, 15) == 0:
            simultaneous_drops = range(random.randrange(1, 2))
            for _ in simultaneous_drops:
                U[0, :, :] = initializer.drop(U[0, :, :])
    else:
        modes = ['single drop', 'drops', 'rain']
        logger.log(f"Configure MODE | options: {modes}")

    # Numerical scheme
    # flux.flux() returns the total flux entering and leaving each cell.
    if conf.SOLVER_TYPE == 'Lax-Friedrichs Riemann':
        U[:, Ng:-Ng, Ng:-Ng] += delta_t / cellArea * flux.flux(U)
    elif conf.SOLVER_TYPE == '2-stage Runge-Kutta':
        # 1st stage
        U_pred = U
        U_pred[:, Ng:-Ng, Ng:-Ng] += delta_t / cellArea * flux.flux(U)

        # 2nd stage
        U[:, Ng: -Ng, Ng: -Ng] = \
            0.5 * (U[:, Ng: -Ng, Ng: -Ng]
                   + U_pred[:, Ng: -Ng, Ng: -Ng]
                   + delta_t / cellArea * flux.flux(U_pred)
                   )
    else:
        solver_types = ['Lax-Friedrichs Riemann', '2-stage Runge-Kutta']
        logger.log(f"Configure SOLVER_TYPE | Options: {solver_types}")
    return U, drops_count, drop_its_iterator, next_drop_it
    '''
Example #9
0
def simulate():
    time = 0

    U, h_hist, t_hist, U_ds = initializer.initialize()
    drops_count = 1
    # idx of the frame saved in h_hist
    saving_frame_idx = 0
    # Counts up to conf.FRAMES_PER_PERIOD (1st frame saved at initialization).
    consecutive_frames_counter = 1

    if conf.ITERS_BETWEEN_DROPS_MODE in ["custom", "random"]:
        # List with the simulation iterations at which a drop is going to fall
        drop_its = utils.drop_iters_list()
        # Drop the 0th drop
        drop_its_iterator = iter(drop_its[1:])
        # The iteration at which the next drop will fall
        try:
            next_drop_it = next(drop_its_iterator)
        except StopIteration:
            drop_its_iterator = None
            next_drop_it = None
    else:
        drop_its_iterator = None
        next_drop_it = None

    for it in range(1, conf.MAX_ITERS):

        # Time discretization step (CFL condition)
        delta_t = dt(U)

        # Update current time
        time += delta_t
        if time > conf.STOPPING_TIME:
            break

        # Apply boundary conditions (reflective)
        U = bcmanager.update_ghost_cells(U)

        # Numerical iterative scheme
        U, drops_count, drop_its_iterator, next_drop_it = _solve(
            U=U,
            delta_t=delta_t,
            it=it,
            drops_count=drops_count,
            drop_its_iterator=drop_its_iterator,
            next_drop_it=next_drop_it)

        if conf.WRITE_DAT:
            dat_writer.write_dat(
                U[0, conf.Ng:conf.Ny + conf.Ng, conf.Ng:conf.Nx + conf.Ng],
                time, it)
            mattflow_post.plot_from_dat(time, it)
        elif not conf.WRITE_DAT:
            # Append current frame to the list, to be animated at
            # post-processing.
            if it % conf.FRAME_SAVE_FREQ == 0:
                # Zero the counter, when a perfect division occurs.
                consecutive_frames_counter = 0
            if consecutive_frames_counter < conf.FRAMES_PER_PERIOD:
                saving_frame_idx += 1
                h_hist[saving_frame_idx] = \
                    U[0, conf.Ng: -conf.Ng, conf.Ng: -conf.Ng]
                # time * 10 is insertd, because space is scaled about x10.
                t_hist[saving_frame_idx] = time * 10
                consecutive_frames_counter += 1
            if conf.SAVE_DS_FOR_ML:
                U_ds[it] = U[:, conf.Ng:-conf.Ng, conf.Ng:-conf.Ng]
        else:
            logger.log("Configure WRITE_DAT | Options: True, False")

        logger.log_timestep(it, time)

    # Clean-up the memmap
    if conf.DUMP_MEMMAP and conf.WORKERS > 1:
        utils.delete_memmap()

    return h_hist, t_hist, U_ds