Move .grids
data into separate cell_data
array. Also remove Direction
enum
This commit is contained in:
parent
fbf173072a
commit
551da07f3e
@ -16,7 +16,6 @@ Dependencies:
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- skimage [Grid.visualize_isosurface()]
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"""
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from .error import GridError
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from .direction import Direction
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from .grid import Grid
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__author__ = 'Jan Petykiewicz'
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@ -6,15 +6,16 @@ from typing import List, Optional, Union, Sequence, Callable
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import numpy # type: ignore
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from float_raster import raster
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from . import GridError, Direction
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from ._helpers import is_scalar
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from . import GridError
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eps_callable_t = Callable[[numpy.ndarray, numpy.ndarray, numpy.ndarray], numpy.ndarray]
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def draw_polygons(self,
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surface_normal: Union[Direction, int],
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cell_data: numpy.ndarray,
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surface_normal: int,
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center: numpy.ndarray,
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polygons: Sequence[numpy.ndarray],
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thickness: float,
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@ -24,8 +25,8 @@ def draw_polygons(self,
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Draw polygons on an axis-aligned plane.
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Args:
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surface_normal: Axis normal to the plane we're drawing on. Can be a `Direction` or
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integer in `range(3)`
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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surface_normal: Axis normal to the plane we're drawing on. Integer in `range(3)`.
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center: 3-element ndarray or list specifying an offset applied to all the polygons
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polygons: List of Nx2 or Nx3 ndarrays, each specifying the vertices of a polygon
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(non-closed, clockwise). If Nx3, the surface_normal coordinate is ignored. Each
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@ -39,11 +40,6 @@ def draw_polygons(self,
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Raises:
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GridError
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"""
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# Turn surface_normal into its integer representation
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if isinstance(surface_normal, Direction):
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surface_normal = surface_normal.value
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assert(isinstance(surface_normal, int))
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if surface_normal not in range(3):
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raise GridError('Invalid surface_normal direction')
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@ -66,8 +62,8 @@ def draw_polygons(self,
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% 'xyz'[surface_normal])
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# Broadcast eps where necessary
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if is_scalar(eps):
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eps = [eps] * len(self.grids)
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if numpy.size(eps) == 1:
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eps = [eps] * len(cell_data)
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elif isinstance(eps, numpy.ndarray):
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raise GridError('ndarray not supported for eps')
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@ -101,7 +97,7 @@ def draw_polygons(self,
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return numpy.insert(v_2d, surface_normal, (val,))
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# iterate over grids
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for i, grid in enumerate(self.grids):
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for i, grid in enumerate(cell_data):
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# ## Evaluate or expand eps[i]
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if callable(eps[i]):
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# meshgrid over the (shifted) domain
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@ -184,11 +180,12 @@ def draw_polygons(self,
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# ## Modify the grid
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g_slice = (i,) + tuple(numpy.s_[bdi_min[a]:bdi_max[a] + 1] for a in range(3))
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self.grids[g_slice] = (1 - w) * self.grids[g_slice] + w * eps_i
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cell_data[g_slice] = (1 - w) * cell_data[g_slice] + w * eps_i
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def draw_polygon(self,
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surface_normal: Union[Direction, int],
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cell_data: numpy.ndarray,
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surface_normal: int,
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center: numpy.ndarray,
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polygon: numpy.ndarray,
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thickness: float,
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@ -198,8 +195,8 @@ def draw_polygon(self,
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Draw a polygon on an axis-aligned plane.
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Args:
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surface_normal: Axis normal to the plane we're drawing on. Can be a Direction or
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integer in range(3)
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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surface_normal: Axis normal to the plane we're drawing on. Integer in `range(3)`.
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center: 3-element ndarray or list specifying an offset applied to the polygon
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polygon: Nx2 or Nx3 ndarray specifying the vertices of a polygon (non-closed,
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clockwise). If Nx3, the surface_normal coordinate is ignored. Must have at
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@ -207,11 +204,12 @@ def draw_polygon(self,
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thickness: Thickness of the layer to draw
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eps: Value to draw with ('epsilon'). See `draw_polygons()` for details.
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"""
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self.draw_polygons(surface_normal, center, [polygon], thickness, eps)
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self.draw_polygons(cell_data, surface_normal, center, [polygon], thickness, eps)
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def draw_slab(self,
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surface_normal: Union[Direction, int],
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cell_data: numpy.ndarray,
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surface_normal: int,
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center: numpy.ndarray,
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thickness: float,
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eps: Union[List[Union[float, eps_callable_t]], float, eps_callable_t],
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@ -220,15 +218,13 @@ def draw_slab(self,
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Draw an axis-aligned infinite slab.
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Args:
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surface_normal: Axis normal to the plane we're drawing on. Can be a `Direction` or
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integer in `range(3)`
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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surface_normal: Axis normal to the plane we're drawing on. Integer in `range(3)`.
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center: Surface_normal coordinate at the center of the slab
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thickness: Thickness of the layer to draw
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eps: Value to draw with ('epsilon'). See `draw_polygons()` for details.
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"""
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# Turn surface_normal into its integer representation
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if isinstance(surface_normal, Direction):
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surface_normal = surface_normal.value
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if surface_normal not in range(3):
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raise GridError('Invalid surface_normal direction')
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@ -258,10 +254,11 @@ def draw_slab(self,
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[xyz_max[0], xyz_min[1]],
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[xyz_min[0], xyz_min[1]]], dtype=float)
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self.draw_polygon(surface_normal, center_shift, p, thickness, eps)
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self.draw_polygon(cell_data, surface_normal, center_shift, p, thickness, eps)
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def draw_cuboid(self,
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cell_data: numpy.ndarray,
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center: numpy.ndarray,
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dimensions: numpy.ndarray,
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eps: Union[List[Union[float, eps_callable_t]], float, eps_callable_t],
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@ -270,6 +267,7 @@ def draw_cuboid(self,
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Draw an axis-aligned cuboid
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Args:
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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center: 3-element ndarray or list specifying the cuboid's center
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dimensions: 3-element list or ndarray containing the x, y, and z edge-to-edge
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sizes of the cuboid
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@ -280,11 +278,12 @@ def draw_cuboid(self,
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[+dimensions[0], -dimensions[1]],
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[-dimensions[0], -dimensions[1]]], dtype=float) / 2.0
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thickness = dimensions[2]
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self.draw_polygon(Direction.z, center, p, thickness, eps)
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self.draw_polygon(cell_data, 2, center, p, thickness, eps)
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def draw_cylinder(self,
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surface_normal: Union[Direction, int],
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cell_data: numpy.ndarray,
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surface_normal: int,
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center: numpy.ndarray,
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radius: float,
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thickness: float,
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@ -295,8 +294,8 @@ def draw_cylinder(self,
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Draw an axis-aligned cylinder. Approximated by a num_points-gon
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Args:
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surface_normal: Axis normal to the plane we're drawing on. Can be a `Direction` or
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integer in `range(3)`
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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surface_normal: Axis normal to the plane we're drawing on. Integer in `range(3)`.
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center: 3-element ndarray or list specifying the cylinder's center
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radius: cylinder radius
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thickness: Thickness of the layer to draw
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@ -306,13 +305,14 @@ def draw_cylinder(self,
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theta = numpy.linspace(0, 2*numpy.pi, num_points, endpoint=False)
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x = radius * numpy.sin(theta)
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y = radius * numpy.cos(theta)
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self.draw_polygon(surface_normal, center, polygon, thickness, eps)
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polygon = numpy.hstack((x[:, None], y[:, None]))
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self.draw_polygon(cell_data, surface_normal, center, polygon, thickness, eps)
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def draw_extrude_rectangle(self,
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cell_data: numpy.ndarray,
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rectangle: numpy.ndarray,
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direction: Union[Direction, int],
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direction: int,
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polarity: int,
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distance: float,
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) -> None:
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@ -320,16 +320,12 @@ def draw_extrude_rectangle(self,
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Extrude a rectangle of a previously-drawn structure along an axis.
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Args:
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cell_data: Cell data to modify (e.g. created by `Grid.allocate()`)
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rectangle: 2x3 ndarray or list specifying the rectangle's corners
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direction: Direction to extrude in. Direction enum or int in range(3)
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direction: Direction to extrude in. Integer in `range(3)`.
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polarity: +1 or -1, direction along axis to extrude in
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distance: How far to extrude
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"""
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# Turn extrude_direction into its integer representation
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if isinstance(direction, Direction):
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direction = direction.value
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assert(isinstance(direction, int))
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s = numpy.sign(polarity)
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rectangle = numpy.array(rectangle, dtype=float)
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@ -351,7 +347,7 @@ def draw_extrude_rectangle(self,
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thickness = distance
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eps_func = []
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for i, grid in enumerate(self.grids):
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for i, grid in enumerate(cell_data):
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z = self.pos2ind(rectangle[0, :], i, round_ind=False, check_bounds=False)[direction]
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ind = [int(numpy.floor(z)) if i == direction else slice(None) for i in range(3)]
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@ -373,5 +369,5 @@ def draw_extrude_rectangle(self,
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eps_func.append(f_eps)
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self.draw_polygon(direction, center, p, thickness, eps_func)
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self.draw_polygon(cell_data, direction, center, p, thickness, eps_func)
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@ -7,8 +7,8 @@ import pickle
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import warnings
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import copy
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from . import GridError, Direction
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from ._helpers import is_scalar
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from . import GridError
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__author__ = 'Jan Petykiewicz'
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@ -18,12 +18,18 @@ eps_callable_type = Callable[[numpy.ndarray, numpy.ndarray, numpy.ndarray], nump
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class Grid:
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"""
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Simulation grid generator intended for electromagnetic simulations.
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Can be used to generate non-uniform rectangular grids (the entire grid
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Simulation grid metadata for finite-difference simulations.
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Can be used to generate non-uniform rectangular grids (the entire grid
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is generated based on the coordinates of the boundary points). Also does
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straightforward natural <-> grid unit conversion.
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`self.grids[i][a,b,c]` contains the value of epsilon for the cell located around
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This class handles data describing the grid, and should be paired with a
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(separate) ndarray that contains the actual data in each cell. The `allocate()`
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method can be used to create this ndarray.
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The resulting `cell_data[i, a, b, c]` should correspond to the value in the
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`i`-th grid, in the cell centered around
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```
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(xyz[0][a] + dxyz[0][a] * shifts[i, 0],
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xyz[1][b] + dxyz[1][b] * shifts[i, 1],
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@ -47,9 +53,6 @@ class Grid:
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exyz: List[numpy.ndarray]
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"""Cell edges. Monotonically increasing without duplicates."""
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grids: numpy.ndarray
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"""epsilon (or mu, or whatever) grids. shape is (num_grids, X, Y, Z)"""
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periodic: List[bool]
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"""For each axis, determines how far the rightmost boundary gets shifted. """
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@ -103,6 +106,20 @@ class Grid:
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"""
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return numpy.array([coord.size - 1 for coord in self.exyz], dtype=int)
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@property
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def num_grids(self) -> int:
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"""
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The number of grids (number of shifts)
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"""
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return self.shifts.shape[0]
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@property
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def cell_data_shape(self):
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"""
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The shape of the cell_data ndarray (num_grids, *self.shape).
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"""
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return numpy.hstack((self.num_grids, self.shape))
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@property
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def dxyz_with_ghost(self) -> List[numpy.ndarray]:
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"""
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@ -218,16 +235,30 @@ class Grid:
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Returns:
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`[grid.shifted_dxyz(which_shifts=a)[a] for a in range(3)]`
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"""
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if len(self.grids) != 3:
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raise GridError('autoshifting requires exactly 3 grids')
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if self.num_grids != 3:
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raise GridError('Autoshifting requires exactly 3 grids')
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return [self.shifted_dxyz(which_shifts=a)[a] for a in range(3)]
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def allocate(self, fill_value: Optional[float] = 1.0, dtype=numpy.float64) -> numpy.ndarray:
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"""
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Allocate an ndarray for storing grid data.
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Args:
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fill_value: Value to initialize the grid to. If None, an
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uninitialized array is returned.
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dtype: Numpy dtype for the array. Default is `numpy.float64`.
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Returns:
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The allocated array
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"""
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if fill_value is None:
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return numpy.empty(self.cell_data_shape)
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else:
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return numpy.full(self.cell_data_shape, fill_value)
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def __init__(self,
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pixel_edge_coordinates: Sequence[numpy.ndarray],
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shifts: numpy.ndarray = Yee_Shifts_E,
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initial: Union[float, numpy.ndarray] = 1.0,
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num_grids: Optional[int] = None,
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periodic: Union[bool, Sequence[bool]] = False,
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) -> None:
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"""
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@ -238,12 +269,6 @@ class Grid:
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x=`x1`, the second has edges x=`x1` and x=`x2`, etc.)
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shifts: Nx3 array containing `[x, y, z]` offsets for each of N grids.
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E-field Yee shifts are used by default.
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initial: Grids are initialized to this value. If scalar, all grids are initialized
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with ndarrays full of the scalar. If a list of scalars, `grid[i]` is initialized to an
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ndarray full of `initial[i]`. If a list of ndarrays of the same shape as the grids, `grid[i]`
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is set to `initial[i]`. Default `1.0`.
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num_grids: How many grids to create. Must be <= `shifts.shape[0]`.
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Default is `shifts.shape[0]`
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periodic: Specifies how the sizes of edge cells are calculated; see main class
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documentation. List of 3 bool, or a single bool that gets broadcast. Default `False`.
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@ -276,33 +301,6 @@ class Grid:
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# TODO: Test negative shifts
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warnings.warn('Negative shifts are still experimental and mostly untested, be careful!', stacklevel=2)
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num_shifts = self.shifts.shape[0]
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if num_grids is None:
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num_grids = num_shifts
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elif num_grids > num_shifts:
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raise GridError('Number of grids exceeds number of shifts (%u)' % num_shifts)
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grids_shape = hstack((num_grids, self.shape))
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if isinstance(initial, (float, int)):
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if isinstance(initial, int):
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warnings.warn('Initial value is an int, grids will be integer-typed!', stacklevel=2)
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self.grids = numpy.full(grids_shape, initial)
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else:
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if len(initial) < num_grids:
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raise GridError('Too few initial grids specified!')
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self.grids = numpy.empty(grids_shape)
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for i in range(num_grids):
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if is_scalar(initial[i]):
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if initial[i] is not None:
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if isinstance(initial[i], int):
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warnings.warn('Initial value is an int, grid {} will be integer-typed!'.format(i), stacklevel=2)
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self.grids[i] = numpy.full(self.shape, initial[i])
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else:
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if not numpy.array_equal(initial[i].shape, self.shape):
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raise GridError('Initial grid sizes must match given coordinates')
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self.grids[i] = initial[i]
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@staticmethod
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def load(filename: str) -> 'Grid':
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"""
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@ -5,8 +5,8 @@ from typing import Dict, Optional, Union, Any
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import numpy # type: ignore
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from . import GridError, Direction
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from ._helpers import is_scalar
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from . import GridError
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# .visualize_* uses matplotlib
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# .visualize_isosurface uses skimage
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@ -14,7 +14,8 @@ from ._helpers import is_scalar
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def get_slice(self,
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surface_normal: Union[Direction, int],
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cell_data: numpy.ndarray,
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surface_normal: int,
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center: float,
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which_shifts: int = 0,
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sample_period: int = 1
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@ -24,8 +25,8 @@ def get_slice(self,
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Interpolates if given a position between two planes.
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Args:
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surface_normal: Axis normal to the plane we're displaying. Can be a `Direction` or
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integer in `range(3)`
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cell_data: Cell data to slice
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surface_normal: Axis normal to the plane we're displaying. Integer in `range(3)`.
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center: Scalar specifying position along surface_normal axis.
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which_shifts: Which grid to display. Default is the first grid (0).
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sample_period: Period for down-sampling the image. Default 1 (disabled)
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@ -43,9 +44,6 @@ def get_slice(self,
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if not is_scalar(which_shifts) or which_shifts < 0:
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raise GridError('Invalid which_shifts')
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# Turn surface_normal into its integer representation
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if isinstance(surface_normal, Direction):
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surface_normal = surface_normal.value
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if surface_normal not in range(3):
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raise GridError('Invalid surface_normal direction')
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@ -70,7 +68,7 @@ def get_slice(self,
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sliced_grid = numpy.zeros(self.shape[surface])
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for ci, weight in zip(centers, w):
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s = tuple(ci if a == surface_normal else numpy.s_[::sp] for a in range(3))
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sliced_grid += weight * self.grids[which_shifts][tuple(s)]
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sliced_grid += weight * cell_data[which_shifts][tuple(s)]
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# Remove extra dimensions
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sliced_grid = numpy.squeeze(sliced_grid)
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@ -79,7 +77,8 @@ def get_slice(self,
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def visualize_slice(self,
|
||||
surface_normal: Union[Direction, int],
|
||||
cell_data: numpy.ndarray,
|
||||
surface_normal: int,
|
||||
center: float,
|
||||
which_shifts: int = 0,
|
||||
sample_period: int = 1,
|
||||
@ -91,8 +90,7 @@ def visualize_slice(self,
|
||||
Interpolates if given a position between two planes.
|
||||
|
||||
Args:
|
||||
surface_normal: Axis normal to the plane we're displaying. Can be a `Direction` or
|
||||
integer in `range(3)`
|
||||
surface_normal: Axis normal to the plane we're displaying. Integer in `range(3)`.
|
||||
center: Scalar specifying position along surface_normal axis.
|
||||
which_shifts: Which grid to display. Default is the first grid (0).
|
||||
sample_period: Period for down-sampling the image. Default 1 (disabled)
|
||||
@ -100,14 +98,11 @@ def visualize_slice(self,
|
||||
"""
|
||||
from matplotlib import pyplot
|
||||
|
||||
# Set surface normal to its integer value
|
||||
if isinstance(surface_normal, Direction):
|
||||
surface_normal = surface_normal.value
|
||||
|
||||
if pcolormesh_args is None:
|
||||
pcolormesh_args = {}
|
||||
|
||||
grid_slice = self.get_slice(surface_normal=surface_normal,
|
||||
grid_slice = self.get_slice(cell_data=cell_data,
|
||||
surface_normal=surface_normal,
|
||||
center=center,
|
||||
which_shifts=which_shifts,
|
||||
sample_period=sample_period)
|
||||
@ -129,6 +124,7 @@ def visualize_slice(self,
|
||||
|
||||
|
||||
def visualize_isosurface(self,
|
||||
cell_data: numpy.ndarray,
|
||||
level: Optional[float] = None,
|
||||
which_shifts: int = 0,
|
||||
sample_period: int = 1,
|
||||
@ -139,6 +135,7 @@ def visualize_isosurface(self,
|
||||
Draw an isosurface plot of the device.
|
||||
|
||||
Args:
|
||||
cell_data: Cell data to visualize
|
||||
level: Value at which to find isosurface. Default (None) uses mean value in grid.
|
||||
which_shifts: Which grid to display. Default is the first grid (0).
|
||||
sample_period: Period for down-sampling the image. Default 1 (disabled)
|
||||
@ -150,8 +147,8 @@ def visualize_isosurface(self,
|
||||
# Claims to be unused, but needed for subplot(projection='3d')
|
||||
from mpl_toolkits.mplot3d import Axes3D
|
||||
|
||||
# Get data from self.grids
|
||||
grid = self.grids[which_shifts][::sample_period, ::sample_period, ::sample_period]
|
||||
# Get data from cell_data
|
||||
grid = cell_data[which_shifts][::sample_period, ::sample_period, ::sample_period]
|
||||
if level is None:
|
||||
level = grid.mean()
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user