Beispiel #1
0
def resetGlobals():
    global state, stack
    state = rs.XformIdentity()
    stack = [state]
def FixedFractureGen(n, aspect_ratio=None, sides=None):
    """
    A function to add a fixed number of circles in a cube. It also writes data 
    to fracture data text file for regenerating fracture networks.
    """
    if fracture_shape == 'circle':
        # initialize a to store fractures
        fracture_list = []
        # a loop to insert the fixed number of fractures
        for i in range(n):
            #layer name for the frcature
            layer_name = "FRACTURE_" + str(i + 1)
            #create an istance of Fracture class
            frac = Fracture()
            #store fracture name
            frac.fracture_name = layer_name
            #generate origin for fracture
            origin = GeneratePoint(boxlength)
            #store farcture center
            frac.fracture_center = origin
            #convert the origin to a plane
            plane = InclinePlane(origin)
            #add layer and color
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            #make current layer
            rs.CurrentLayer(layer_name)
            #insert the fracture in the domain
            my_circle = rs.AddCircle(plane, radius)
            #circle_list.append(my_circle)
            surf = rs.AddPlanarSrf(my_circle)
            #delete initial fracture drawn which is a curve
            rs.DeleteObject(my_circle)
            #save fracture's GUID
            frac.fracture_GUID = surf[0]
            #append fracture into fracture list
            fracture_list.append(frac)

    elif fracture_shape == 'ellipse':
        #list to store fracture surface GUIDs
        fracture_list = []
        for i in range(n):
            #layer name for the frcature
            layer_name = "FRACTURE_" + str(i + 1)
            #create an istance of Fracture class
            frac = Fracture()
            frac.fracture_name = layer_name
            #generate fracture origin
            origin = GeneratePoint(boxlength)
            frac.fracture_center = origin
            #plane for fracture
            plane = InclinePlane(origin)
            #calculate r_y
            ry = radius / aspect_ratio
            #create layer for fracture
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            rs.CurrentLayer(layer_name)
            #draw ellipse
            fracture = rs.AddEllipse(plane, radius, ry)
            # write the plane, r_x and r_y to file for re-plotting
            ##file.write("\n" + str(plane[0]) + "," +  str(plane[1]) + "," +  str(plane[2]) + "," + str(radius) + ","+ str(ry))
            #make fracture a surface
            frac_surf = rs.AddPlanarSrf(fracture)
            #delete initial fracture drawn which is a curve
            rs.DeleteObject(fracture)
            #append surface GUID to list of fracture surfaces
            frac.fracture_GUID = frac_surf[0]
            fracture_list.append(frac)

    elif fracture_shape == 'polygon':
        #list to store fracture surface GUIDs
        fracture_list = []
        #write the shape type
        ##file.write('\npolygon\n')
        for i in range(n):
            layer_name = "FRACTURE_" + str(i + 1)
            frac = Fracture()
            frac.fracture_name = layer_name
            #theta in radian
            theta_rad = (2 * math.pi) / sides
            #theta in degree (interior angles)
            theta_deg = theta_rad * (180 / math.pi)
            #generate origin
            origin = GeneratePoint(boxlength)
            frac.fracture_center = origin
            #create a 3D point object which isn't visible to the rhino document
            pt_01 = rs.coerce3dvector(
                [radius + origin[0], origin[1], origin[2]])
            #empty list to store all points
            points = []
            #a rotation axis
            ax = rs.coerce3dvector([0, 0, 1])
            #loop to generate points for polygon vertices
            #file.write("\n")
            for j in range(sides):
                #rotation transform with rotation from the origin
                trans = rs.XformRotation2(theta_deg * j, ax, origin)
                #transform the original 3D point and append to list
                points.append(rs.PointTransform(pt_01, trans))
            # append the initial point to close the polygon
            points.append(pt_01)
            # create layer for fracture
            # layer_name = "FRACTURE_" + str(i+1)
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            rs.CurrentLayer(layer_name)
            # get GUID of created polygon
            polygon = rs.AddPolyline(points)
            # polygon = rs.AddPolyline(points)
            plane = InclinePlane(origin, boxlength)
            cob = rs.XformChangeBasis(rs.WorldXYPlane(), plane)
            shear2d = rs.XformIdentity()
            shear2d[0, 2] = math.tan(math.radians(45.0))
            cob_inverse = rs.XformChangeBasis(plane, rs.WorldXYPlane())
            temp = rs.XformMultiply(shear2d, cob)
            xform = rs.XformMultiply(cob_inverse, temp)
            fracture = rs.TransformObjects(polygon, xform, False)
            # make fracture a surface
            frac_surf = rs.AddPlanarSrf(fracture)
            # delete initial fracture drawn which is a curve
            rs.DeleteObject(fracture)
            frac.fracture_GUID = frac_surf[0]
            fracture_list.append(frac)
    return fracture_list
Beispiel #3
0
def RedrawNetwork(path):
    """
    A function to reload/regenerate fracture networks.
    
    Parameter
    --------
    path: str
        path where the text file containing fracture data is stored.
    """
    # open text file
    m = open(path, 'r')
    # read first line of text file; length of the domain
    l = m.readline()
    # convert length to float
    length = float(l)
    # read the second line of the domain; shape of the fracture
    shape = m.readline().split()
    #corners = ([(0,0,0),(length,0,0),(length,length,0),(0,length,0),(0,0,length),(length,0,length),(length,length,length),(0,length,length)])
    #rs.AddBox(corners)
    # create the domain
    dom = Domain.Domain(length)
    # display the domain
    dom.Show()
    if shape[0] != 'polygon':
        # a list to store GUIDs of regenerated fractures
        frac_list = []
        # list to store the x_axis of the fracture plane
        x_axis = []
        # list to store the y_axis of the fracture plane
        y_axis = []
        # list to store the origin of the fracture location
        origin = []
        # list to store the size of fracture
        size = []
        # read file line by line
        for line in m:
            # split line by comma
            words = line.split(",")
            #if words[0] != 'circle':
            # append the origin, x_axis and y_axis values in each line
            origin.append(float(words[0]))
            origin.append(float(words[1]))
            origin.append(float(words[2]))
            x_axis.append(float(words[3]))
            x_axis.append(float(words[4]))
            x_axis.append(float(words[5]))
            y_axis.append(float(words[6]))
            y_axis.append(float(words[7]))
            y_axis.append(float(words[8]))
            size.append(float((words[9])))
            # if the shape is ellipse, we have two radii, so append the second radius
            if shape[0] == 'ellipse':
                size.append(float((words[10])))
        # close file
        m.close()
        # display fractures if they are circles/disks
        if shape[0] == 'circle':
            n = 0
            # go through the lists of origin, x_axis and y_axis
            # we divide by 3, because the list contains 3 consecutive values
            # representing a single origin, x_axis or y_axis
            for i in range(int(len(origin) / 3)):
                # lists to store the origin, x_axis and y_axis of each fracture
                o = []
                x = []
                y = []
                # append the origin, x_axis and y_axis of each fracture
                for j in range(3):
                    o.append(origin[n + j])
                    x.append(x_axis[n + j])
                    y.append(y_axis[n + j])
                # convert the origin, x_axis and y_axis to a plane
                plane = rs.PlaneFromFrame(o, x, y)
                # name the current layer
                # we are creating layers so that we can trim out of bounds fractures
                # the function that does this makes use of the layer names
                layer_name = "FRACTURE_" + str(i + 1)
                # give the layer a color
                rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
                # make layer the current layer
                rs.CurrentLayer(layer_name)
                # draw fracture
                my_disk = rs.AddCircle(plane, size[i])
                # convert to a surface
                surf = rs.AddPlanarSrf(my_disk)
                #delete initial fracture drawn which is a curve
                rs.DeleteObject(my_disk)
                # append fracture
                frac_list.append(surf)
                # increment n used for parsing
                n += 3
            # trim out of bounds fractures
            # the function all creates new fractures at the locations of all
            # exixting fractures
            dom.RemoveSurfacesOutsideOfBox(length)
            # delete all old fractures
            for frac in frac_list:
                rs.DeleteObject(frac)
            dom_frac = dom.my_fractures  #get the fractures in the domain
            #print(dom_frac)
            #swap old guids with new ones and put new guids in old frac layers
            #new_frac_guids = Frac.NewFracturesGuids(dom_frac,frac_list)

        # display fractures if they are ellipse
        if shape[0] == 'ellipse':
            # lists to store the origin, x_axis and y_axis of each fracture
            n = 0
            p = 0
            q = 1
            # go through the lists of origin, x_axis and y_axis
            # we divide by 3, because the list contains 3 consecutive values
            # representing a single origin, x_axis or y_axis
            for i in range(int(len(origin) / 3)):
                o = []
                x = []
                y = []
                # append the origin, x_axis and y_axis of each fracture
                for j in range(3):
                    o.append(origin[n + j])
                    x.append(x_axis[n + j])
                    y.append(y_axis[n + j])
                # convert the origin, x_axis and y_axis to a plane
                plane = rs.PlaneFromFrame(o, x, y)
                # name the current layer
                # we are creating layers so that we can trim out of bounds fractures
                # the function that does this makes use of the layer names
                layer_name = "FRACTURE_" + str(i + 1)
                # give the layer a color
                rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
                # make layer current layer
                rs.CurrentLayer(layer_name)
                # draw fracture
                my_frac = rs.AddEllipse(plane, size[i + p], size[i + q])
                # convert to a surface from curve
                surf = rs.AddPlanarSrf(my_frac)
                # delete initial fracture drawn which is a curve
                rs.DeleteObject(my_frac)
                # append fracture
                frac_list.append(surf)
                # increment varaiables used for parsing
                n += 3
                p += 1
                q += 1
            # trim out of bounds fractures
            dom.RemoveSurfacesOutsideOfBox(length)
            # delete old fractures
            for frac in frac_list:
                rs.DeleteObject(frac)
            dom_frac = dom.my_fractures

    if shape[0] == 'polygon':
        # list to store origin
        origin = []
        # list to store number of sides of each polygon
        size = []
        # list to store the x_axis of the fracture plane
        x_axis = []
        # list to store the y_axis of the fracture plane
        y_axis = []
        # list to store fractures
        frac_list = []
        # list to store points
        points = []
        for line in m:
            # split each line by comma
            words = line.split(",")
            # store the number of sides of the polygon
            size.append(float(words[-1]))
            # store the x axis
            x_axis.extend(
                (float(words[-7]), float(words[-6]), float(words[-5])))

            y_axis.extend(
                (float(words[-4]), float(words[-3]), float(words[-2])))
            # store the origin
            origin.extend(
                (float(words[-10]), float(words[-9]), float(words[-8])))
            # length of all points on the line
            # this will ensure we capture lines with disparate points when
            # generating polygon of different sides
            ex = int(3 * (size[-1] + 1))
            # store all points on the line
            points.extend((words[:ex]))
        # close file
        m.close()

        # variables to use for parsing
        n = 0
        m = 0
        # iterate for the number of fractures generated
        for i in range(len(size)):
            # list to store points and origin
            o = []
            x = []
            y = []
            p = []
            # get the origin and axes of the fracture
            for j in range(3):
                o.append(origin[n + j])
                x.append(x_axis[n + j])
                y.append(y_axis[n + j])
            # variable for parsing
            r = 0
            # get the points of fracture edges
            for k in range(int(size[i]) + 1):
                p.append([])
                for l in range(3):
                    p[k].append(float(points[m + l + r]))
                # increment r
                r += 3
            # increment parsing variables
            m += ((int(size[i]) + 1) * 3)
            n += 3
            # name the current layer
            # we are creating layers so that we can trim out of bounds fractures
            # the function that does this makes use of the layer names
            layer_name = "FRACTURE_" + str(i + 1)
            # give the layer a color
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            # make layer the current layer
            rs.CurrentLayer(layer_name)
            # joing the points
            poly = rs.AddPolyline(p)
            # get the plane
            plane = rs.PlaneFromFrame(o, x, y)
            # transform fracture to the plane
            cob = rs.XformChangeBasis(rs.WorldXYPlane(), plane)
            shear2d = rs.XformIdentity()
            shear2d[0, 2] = math.tan(math.radians(45.0))
            cob_inverse = rs.XformChangeBasis(plane, rs.WorldXYPlane())
            temp = rs.XformMultiply(shear2d, cob)
            xform = rs.XformMultiply(cob_inverse, temp)
            frac = rs.TransformObjects(poly, xform, False)
            # convert to a surface
            surf = rs.AddPlanarSrf(frac)
            #delete initial fracture drawn which is a curve
            rs.DeleteObject(frac)
            frac_list.append(surf)
        # trim out of bounds fractures
        # the function all creates new fractures at the locations of all
        # exixting fractures
        dom.RemoveSurfacesOutsideOfBox(length)
        # delete all old fractures
        for fr in frac_list:
            rs.DeleteObject(fr)
        dom_frac = dom.my_fractures
    return dom_frac
Beispiel #4
0
def RandomFractureGen(frac_min,
                      frac_max,
                      radius_min,
                      radius_max,
                      aspect_min=None,
                      aspect_max=None,
                      polysize_min=None,
                      polysize_max=None):
    """
    Funtions to generate fractures of random number and sizes
    
    Parameters
    ----------
    frac_min: int
        minimum number of fractures to generate
    frac_max: int
        maximum number of fractures to generate
    radius_min: float
        minimum size of fractures
    radius_max: float
        maximum number of fractures to generate
    aspect_min: float
        minimum aspect ratio fpr ellipses (Default:None)
    aspect_max: float
        maximum aspect ratio fpr ellipses (Default:None)
    polysize_min: int
        minimum size of polygon (Default:None)
    polysize_max: int
        maximum size of polygon (Default:None)
    """
    # randomly determine the number of fractures to generate
    num_frac = random.randint(frac_min, frac_max)
    # open file and append to it
    file = open(path, 'a')
    if fracture_shape == 'circle':
        # write the shape type
        file.write('\ncircle')
        # initialize list to store fractures
        fracture_list = []
        # loop to generate fractures
        for i in range(num_frac):
            # name the layer
            layer_name = "FRACTURE_" + str(i + 1)
            # an instance of fracture object
            frac = Fracture()
            # get fracture name
            frac.fracture_name = layer_name
            # generate fracture center
            origin = GeneratePoint(boxlength)
            # store fracture center
            frac.fracture_center = origin
            # convert the origin to a plane
            plane = InclinePlane(origin, boxlength)
            # add layer and create color for it
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            # make layer current layer
            rs.CurrentLayer(layer_name)
            # generate fracture size
            radius = FractureSize(size_dist, radius_min, radius_max)
            # insert the circle in the domain
            my_circle = rs.AddCircle(plane, radius)
            # write the plane and radius to file for re-plotting
            file.write("\n" + str(plane[0]) + "," + str(plane[1]) + "," +
                       str(plane[2]) + "," + str(radius))
            surf = rs.AddPlanarSrf(my_circle)
            # delete initial fracture drawn which is a curve
            rs.DeleteObject(my_circle)
            # set fracture guid into its object
            frac.fracture_GUID = surf[0]
            fracture_list.append(frac)

    elif fracture_shape == 'ellipse':
        # initialize list to store fractures
        fracture_list = []
        # write the shape type
        file.write('\nellipse')
        for i in range(num_frac):
            # name the layer
            layer_name = "FRACTURE_" + str(i + 1)
            # an instance of fracture object
            frac = Fracture()
            # get fracture name
            frac.fracture_name = layer_name
            # generate fracture center
            origin = GeneratePoint(boxlength)
            # store fracture center
            frac.fracture_center = origin
            # plane for fracture
            plane = InclinePlane(origin, boxlength)
            # randomly generate radius(rx)
            radius = FractureSize(size_dist, radius_min, radius_max)
            # randomly generate aspect ratio
            aspect_ratio = random.randint(aspect_min, aspect_max)
            # calculate r_y
            ry = radius / aspect_ratio
            # add layer with color
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            # make current layer
            rs.CurrentLayer(layer_name)
            # draw fracture
            fracture = rs.AddEllipse(plane, radius, ry)
            # write the plane, r_x and r_y to file for re-plotting
            file.write("\n" + str(plane[0]) + "," + str(plane[1]) + "," +
                       str(plane[2]) + "," + str(radius) + "," + str(ry))
            # make fracture a surface
            frac_surf = rs.AddPlanarSrf(fracture)
            # delete initial fracture drawn which is a curve
            rs.DeleteObject(fracture)
            # set fracture guid into its object
            frac.fracture_GUID = frac_surf[0]
            # append fracture guid to list
            fracture_list.append(frac)

    elif fracture_shape == 'polygon':
        # initialize list to store fractures
        fracture_list = []
        # write the shape type
        file.write('\npolygon\n')
        for i in range(num_frac):
            # name the layer
            layer_name = "FRACTURE" + str(i + 1)
            # an instance of fracture class
            frac = Fracture()
            # get farcture name
            frac.fracture_name = layer_name
            # randomly determine the sides of the polygon
            sides = random.randint(polysize_min, polysize_max)
            # theta in radian
            theta_rad = (2 * math.pi) / sides
            # theta in degree (interior angles)
            theta_deg = theta_rad * (180 / math.pi)
            # generate origin
            origin = GeneratePoint(boxlength)
            # save fracture center
            frac.fracture_center = origin
            # randomly generate radius(rx)
            radius = FractureSize(size_dist, radius_min, radius_max)
            # create a 3D point object which isn't visible to the rhino document
            pt_01 = rs.coerce3dvector(
                [radius + origin[0], origin[1], origin[2]])
            # empty list to store all points
            points = []
            # a rotation axis
            ax = rs.coerce3dvector([0, 0, 1])
            # loop to generate points for polygon vertices
            for j in range(sides):
                # rotation transform with rotation from the origin
                trans = rs.XformRotation2(theta_deg * j, ax, origin)
                # transform the original 3D point and append to list
                points.append(rs.PointTransform(pt_01, trans))
                if j == 0:
                    file.write(
                        str(rs.PointTransform(pt_01, trans)[0]) + "," +
                        str(rs.PointTransform(pt_01, trans)[1]) + "," +
                        str(rs.PointTransform(pt_01, trans)[2]) + ",")
                if j != 0:
                    file.write(
                        str(rs.PointTransform(pt_01, trans)[0]) + "," +
                        str(rs.PointTransform(pt_01, trans)[1]) + "," +
                        str(rs.PointTransform(pt_01, trans)[2]) + ",")
            # append the initial point to close the polygon
            points.append(pt_01)
            file.write(
                str(pt_01[0]) + "," + str(pt_01[1]) + "," + str(pt_01[2]) +
                ",")
            # create layer for fracture
            layer_name = "FRACTURE_" + str(i + 1)
            rs.AddLayer(layer_name, rs.CreateColor(0, 255, 0))
            rs.CurrentLayer(layer_name)
            # get GUID of created polygon
            polygon = rs.AddPolyline(points)
            # get the plane
            plane = InclinePlane(origin, boxlength)
            # transform the polygon to the plane
            cob = rs.XformChangeBasis(rs.WorldXYPlane(), plane)
            shear2d = rs.XformIdentity()
            shear2d[0, 2] = math.tan(math.radians(45.0))
            cob_inverse = rs.XformChangeBasis(plane, rs.WorldXYPlane())
            temp = rs.XformMultiply(shear2d, cob)
            xform = rs.XformMultiply(cob_inverse, temp)
            fracture = rs.TransformObjects(polygon, xform, False)
            # write to file
            #file.write(str(origin[0]) + "," + str(origin[1]) + "," + str(origin[2])+ "," )
            file.write(
                str(plane[0]) + "," + str(plane[1]) + "," + str(plane[2]) +
                "," + str(sides) + "\n")
            # make fracture a surface
            frac_surf = rs.AddPlanarSrf(fracture)
            # delete initial fracture drawn which is a curve
            rs.DeleteObject(fracture)
            # set fracture guid into its objects
            frac.fracture_GUID = frac_surf[0]
            # append fracture guid to list
            fracture_list.append(frac)
    # close file
    file.close()
    return fracture_list
Beispiel #5
0
def initState():
    global state, stack
    state = rs.XformIdentity()
    stack = [state]
Beispiel #6
0
import rhinoscriptsyntax as rs

state = rs.XformIdentity()
stack = [state]


def getPos(xForm):
    x = xForm[0, 3]
    y = xForm[1, 3]
    z = xForm[2, 3]
    return rs.VectorCreate([x, y, z], [0, 0, 0])


def getX(xForm):
    u = xForm[0, 0]
    v = xForm[1, 0]
    w = xForm[2, 0]
    return rs.VectorCreate([u, v, w], [0, 0, 0])


def getY(xForm):
    u = xForm[0, 1]
    v = xForm[1, 1]
    w = xForm[2, 1]
    return rs.VectorCreate([u, v, w], [0, 0, 0])


def getZ(xForm):
    u = xForm[0, 2]
    v = xForm[1, 2]
    w = xForm[2, 2]