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area_funcs.py
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area_funcs.py
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import area
from nc.nc import *
import math
import kurve_funcs
# ramping parameters
ramp_angle = 6
ramp_start_above_height = 0.2
helix_diameter_factor = 0.7
helix_ramp_direction = 1 # 1 for clockwise, -1 for anti-clockwise
# some globals, to save passing variables as parameters too much
area_for_feed_possible = None
tool_radius_for_pocket = None
ramp_h_angles_to_try = [0,90,180,270,45,135,225,315]
def check_ramp_angle():
if ramp_angle < 0.1:
raise Exception('Invalid Ramp Angle: ' + str(ramp_angle) + ', must be at least 0.1 degrees!')
if ramp_angle > 89.9:
raise Exception('Invalid Ramp Angle: ' + str(ramp_angle) + ', must be no more than 89.9 degrees!')
def GetRampStartGivenAngle(p, h_angle, ramp_depth):
ramp_length = ramp_depth / math.tan(math.radians(float(ramp_angle)))
r_angle = math.radians(h_angle)
p1 = p + area.Point(ramp_length * math.cos(r_angle), ramp_length * math.sin(r_angle))
obround = make_obround(p, p1, tool_radius_for_pocket)
a = area.Area(area_for_feed_possible)
obround.Subtract(a)
if obround.num_curves() > 0:
return None
return p1
def GetRampStart(p, ramp_depth):
for h_angle in ramp_h_angles_to_try:
ramp_start = GetRampStartGivenAngle(p, h_angle, ramp_depth)
if ramp_start != None:
return ramp_start
return None
def do_ramp_entry_move(p, rapid_safety_space, current_start_depth, final_depth):
check_ramp_angle()
ramp_depth = float(ramp_start_above_height) + current_start_depth - final_depth
ramp_start_point = GetRampStart(p, ramp_depth)
if ramp_start_point == None:
raise Exception('could not fit ramp entry in pocket operation at X' + str(p.x) + ' Y' + str(p.y))
else:
# rapid across
rapid(ramp_start_point.x, ramp_start_point.y)
# rapid down
rapid(z = current_start_depth + rapid_safety_space)
# feed down
feed(z = current_start_depth + ramp_start_above_height)
#feed across and down
feed(p.x, p.y, final_depth)
def GetHelixRampCircleCentreGivenAngle(p, h_angle, circle_radius):
if helix_diameter_factor < 0.1:
raise Exception('Invalid helix_diameter_factor: ' + str(helix_diameter_factor) + ', must be at least 0.1')
if helix_diameter_factor > 1.0:
raise Exception('Invalid helix_diameter_factor: ' + str(helix_diameter_factor) + ', must be no more than 1.0')
centre = p + area.Point(math.cos(math.radians(helix_diameter_factor)), math.sin(math.radians(helix_diameter_factor))) * circle_radius
circle = make_circle(centre, circle_radius + tool_radius_for_pocket)
a = area.Area(area_for_feed_possible)
circle.Subtract(a)
if circle.num_curves() > 0:
return None
return centre
def GetHelixRampCircleCentre(p, circle_radius):
for h_angle in ramp_h_angles_to_try:
c = GetHelixRampCircleCentreGivenAngle(p, h_angle, circle_radius)
if c != None:
return c
return None
def do_helix_entry_move(p, rapid_safety_space, current_start_depth, final_depth):
check_ramp_angle()
circle_radius = float(helix_diameter_factor) * tool_radius_for_pocket
circle_centre = GetHelixRampCircleCentre(p, circle_radius)
if circle_centre == None:
raise Exception('could not fit helical ramp entry in pocket operation at X' + str(p.x) + ' Y' + str(p.y))
ramp_depth = float(ramp_start_above_height) + current_start_depth - final_depth
ramp_length = ramp_depth / math.tan(math.radians(float(ramp_angle)))
circle_circumference = 2 * math.pi * circle_radius
helix_total_angle = ramp_length / circle_radius # gives angle in radians
far_point = p + (circle_centre - p) * 2
angle = 0
positions_and_depths = []
add_far = False
depth = final_depth
while helix_total_angle > angle:
if add_far:
positions_and_depths.append((far_point, depth))
else:
positions_and_depths.append((p, depth))
add_far = not add_far
depth += math.pi * circle_radius * math.tan(math.radians(float(ramp_angle)))
angle = float(angle) + math.pi
start_angle = math.atan2(p.y - circle_centre.y, p.x - circle_centre.x)
if helix_ramp_direction > 0:
final_angle = start_angle - helix_total_angle
else:
final_angle = start_angle + helix_total_angle
final_pos = circle_centre + area.Point(math.cos(final_angle) * circle_radius, math.sin(final_angle) * circle_radius)
# rapid across
rapid(final_pos.x, final_pos.y)
# rapid down
rapid(z = current_start_depth + rapid_safety_space)
# feed down
feed(z = current_start_depth + ramp_start_above_height)
for pos_and_depth in reversed(positions_and_depths):
pos = pos_and_depth[0]
depth = pos_and_depth[1]
#spiral around and down
if helix_ramp_direction > 0:
arc_ccw(pos.x, pos.y, depth, circle_centre.x, circle_centre.y)
else:
arc_cw(pos.x, pos.y, depth, circle_centre.x, circle_centre.y)
def cut_curve(curve, need_rapid, p, rapid_safety_space, current_start_depth, final_depth, entry_style = 'plunge'):
prev_p = p
first = True
for vertex in curve.getVertices():
if need_rapid and first:
if entry_style == 'ramp':
do_ramp_entry_move(vertex.p, rapid_safety_space, current_start_depth, final_depth)
elif entry_style == 'helical':
do_helix_entry_move(vertex.p, rapid_safety_space, current_start_depth, final_depth)
else:
# rapid across
rapid(vertex.p.x, vertex.p.y)
##rapid down
rapid(z = current_start_depth + rapid_safety_space)
#feed down
feed(z = final_depth)
first = False
else:
if vertex.type == 1:
arc_ccw(vertex.p.x, vertex.p.y, i = vertex.c.x, j = vertex.c.y)
elif vertex.type == -1:
arc_cw(vertex.p.x, vertex.p.y, i = vertex.c.x, j = vertex.c.y)
else:
feed(vertex.p.x, vertex.p.y)
prev_p = vertex.p
return prev_p
def area_distance(a, old_area):
best_dist = None
for curve in a.getCurves():
for vertex in curve.getVertices():
c = old_area.NearestPoint(vertex.p)
d = c.dist(vertex.p)
if best_dist == None or d < best_dist:
best_dist = d
for curve in old_area.getCurves():
for vertex in curve.getVertices():
c = a.NearestPoint(vertex.p)
d = c.dist(vertex.p)
if best_dist == None or d < best_dist:
best_dist = d
return best_dist
def make_obround(p0, p1, radius):
dir = p1 - p0
d = dir.length()
dir.normalize()
right = area.Point(dir.y, -dir.x)
obround = area.Area()
c = area.Curve()
vt0 = p0 + right * radius
vt1 = p1 + right * radius
vt2 = p1 - right * radius
vt3 = p0 - right * radius
c.append(area.Vertex(0, vt0, area.Point(0, 0)))
c.append(area.Vertex(0, vt1, area.Point(0, 0)))
c.append(area.Vertex(1, vt2, p1))
c.append(area.Vertex(0, vt3, area.Point(0, 0)))
c.append(area.Vertex(1, vt0, p0))
obround.append(c)
return obround
def make_circle(p, radius):
circle = area.Area()
c = area.Curve()
c.append(p + area.Point(radius, 0))
c.append(area.Vertex(1, p + area.Point(-radius, 0), p))
c.append(area.Vertex(1, p + area.Point(radius, 0), p))
circle.append(c)
return circle
def feed_possible(p0, p1):
if p0 == p1:
return True
obround = make_obround(p0, p1, tool_radius_for_pocket)
a = area.Area(area_for_feed_possible)
obround.Subtract(a)
if obround.num_curves() > 0:
return False
return True
def cut_curvelist1(curve_list, rapid_safety_space, current_start_depth, depth, clearance_height, keep_tool_down_if_poss, entry_style):
p = None
first = True
for curve in curve_list:
need_rapid = True
if first == False:
s = curve.FirstVertex().p
if keep_tool_down_if_poss == True:
# see if we can feed across
if feed_possible(p, s):
need_rapid = False
elif s.x == p.x and s.y == p.y:
need_rapid = False
if need_rapid:
rapid(z = clearance_height)
p = cut_curve(curve, need_rapid, p, rapid_safety_space, current_start_depth, depth, entry_style)
first = False
rapid(z = clearance_height)
def cut_curvelist2(curve_list, rapid_safety_space, current_start_depth, depth, clearance_height, keep_tool_down_if_poss,start_point):
p = area.Point(0, 0)
start_x,start_y=start_point
first = True
for curve in curve_list:
need_rapid = True
if first == True:
direction = "on";radius = 0.0;offset_extra = 0.0; roll_radius = 0.0;roll_on = 0.0; roll_off = 0.0; rapid_safety_space; step_down = math.fabs(depth);extend_at_start = 0.0;extend_at_end = 0.0
kurve_funcs.make_smaller( curve, start = area.Point(start_x,start_y))
kurve_funcs.profile(curve, direction, radius , offset_extra, roll_radius, roll_on, roll_off, rapid_safety_space , clearance_height, current_start_depth, step_down , depth, extend_at_start, extend_at_end)
else:
s = curve.FirstVertex().p
if keep_tool_down_if_poss == True:
# see if we can feed across
if feed_possible(p, s):
need_rapid = False
elif s.x == p.x and s.y == p.y:
need_rapid = False
cut_curve(curve, need_rapid, p, rapid_safety_space, current_start_depth, depth)
first = False #change to True if you want to rapid back to start side before zigging again with unidirectional set
rapid(z = clearance_height)
def recur(arealist, a1, stepover, from_center):
# this makes arealist by recursively offsetting a1 inwards
if a1.num_curves() == 0:
return
if from_center:
arealist.insert(0, a1)
else:
arealist.append(a1)
a_offset = area.Area(a1)
a_offset.Offset(stepover)
# split curves into new areas
if area.holes_linked():
for curve in a_offset.getCurves():
a2 = area.Area()
a2.append(curve)
recur(arealist, a2, stepover, from_center)
else:
# split curves into new areas
a_offset.Reorder()
a2 = None
for curve in a_offset.getCurves():
if curve.IsClockwise():
if a2 != None:
a2.append(curve)
else:
if a2 != None:
recur(arealist, a2, stepover, from_center)
a2 = area.Area()
a2.append(curve)
if a2 != None:
recur(arealist, a2, stepover, from_center)
def get_curve_list(arealist, reverse_curves = False):
curve_list = list()
for a in arealist:
for curve in a.getCurves():
if reverse_curves == True:
curve.Reverse()
curve_list.append(curve)
return curve_list
curve_list_for_zigs = []
rightward_for_zigs = True
sin_angle_for_zigs = 0.0
cos_angle_for_zigs = 1.0
sin_minus_angle_for_zigs = 0.0
cos_minus_angle_for_zigs = 1.0
one_over_units = 1.0
def make_zig_curve(curve, y0, y, zig_unidirectional):
if rightward_for_zigs:
curve.Reverse()
# find a high point to start looking from
high_point = None
for vertex in curve.getVertices():
if high_point == None:
high_point = vertex.p
elif vertex.p.y > high_point.y:
# use this as the new high point
high_point = vertex.p
elif math.fabs(vertex.p.y - high_point.y) < 0.002 * one_over_units:
# equal high point
if rightward_for_zigs:
# use the furthest left point
if vertex.p.x < high_point.x:
high_point = vertex.p
else:
# use the furthest right point
if vertex.p.x > high_point.x:
high_point = vertex.p
zig = area.Curve()
high_point_found = False
zig_started = False
zag_found = False
for i in range(0, 2): # process the curve twice because we don't know where it will start
prev_p = None
for vertex in curve.getVertices():
if zag_found: break
if prev_p != None:
if zig_started:
zig.append(unrotated_vertex(vertex))
if math.fabs(vertex.p.y - y) < 0.002 * one_over_units:
zag_found = True
break
elif high_point_found:
if math.fabs(vertex.p.y - y0) < 0.002 * one_over_units:
if zig_started:
zig.append(unrotated_vertex(vertex))
elif math.fabs(prev_p.y - y0) < 0.002 * one_over_units and vertex.type == 0:
zig.append(area.Vertex(0, unrotated_point(prev_p), area.Point(0, 0)))
zig.append(unrotated_vertex(vertex))
zig_started = True
elif vertex.p.x == high_point.x and vertex.p.y == high_point.y:
high_point_found = True
prev_p = vertex.p
if zig_started:
if zig_unidirectional == True:
# remove the last bit of zig
if math.fabs(zig.LastVertex().p.y - y) < 0.002 * one_over_units:
vertices = zig.getVertices()
while len(vertices) > 0:
v = vertices[len(vertices)-1]
if math.fabs(v.p.y - y0) < 0.002 * one_over_units:
break
else:
vertices.pop()
zig = area.Curve()
for v in vertices:
zig.append(v)
curve_list_for_zigs.append(zig)
def make_zig(a, y0, y, zig_unidirectional):
for curve in a.getCurves():
make_zig_curve(curve, y0, y, zig_unidirectional)
reorder_zig_list_list = []
def add_reorder_zig(curve):
global reorder_zig_list_list
# look in existing lists
s = curve.FirstVertex().p
for curve_list in reorder_zig_list_list:
last_curve = curve_list[len(curve_list) - 1]
e = last_curve.LastVertex().p
if math.fabs(s.x - e.x) < 0.002 * one_over_units and math.fabs(s.y - e.y) < 0.002 * one_over_units:
curve_list.append(curve)
return
# else add a new list
curve_list = []
curve_list.append(curve)
reorder_zig_list_list.append(curve_list)
def reorder_zigs():
global curve_list_for_zigs
global reorder_zig_list_list
reorder_zig_list_list = []
for curve in curve_list_for_zigs:
add_reorder_zig(curve)
curve_list_for_zigs = []
for curve_list in reorder_zig_list_list:
for curve in curve_list:
curve_list_for_zigs.append(curve)
def rotated_point(p):
return area.Point(p.x * cos_angle_for_zigs - p.y * sin_angle_for_zigs, p.x * sin_angle_for_zigs + p.y * cos_angle_for_zigs)
def unrotated_point(p):
return area.Point(p.x * cos_minus_angle_for_zigs - p.y * sin_minus_angle_for_zigs, p.x * sin_minus_angle_for_zigs + p.y * cos_minus_angle_for_zigs)
def rotated_vertex(v):
if v.type:
return area.Vertex(v.type, rotated_point(v.p), rotated_point(v.c))
return area.Vertex(v.type, rotated_point(v.p), area.Point(0, 0))
def unrotated_vertex(v):
if v.type:
return area.Vertex(v.type, unrotated_point(v.p), unrotated_point(v.c))
return area.Vertex(v.type, unrotated_point(v.p), area.Point(0, 0))
def rotated_area(a):
an = area.Area()
for curve in a.getCurves():
curve_new = area.Curve()
for v in curve.getVertices():
curve_new.append(rotated_vertex(v))
an.append(curve_new)
return an
def zigzag(a, stepover, zig_unidirectional):
if a.num_curves() == 0:
return
global rightward_for_zigs
global curve_list_for_zigs
global sin_angle_for_zigs
global cos_angle_for_zigs
global sin_minus_angle_for_zigs
global cos_minus_angle_for_zigs
global one_over_units
one_over_units = 1 / area.get_units()
a = rotated_area(a)
b = area.Box()
a.GetBox(b)
x0 = b.MinX() - 1.0
x1 = b.MaxX() + 1.0
height = b.MaxY() - b.MinY()
num_steps = int(height / stepover + 1)
y = b.MinY() + 0.1 * one_over_units
null_point = area.Point(0, 0)
rightward_for_zigs = True
curve_list_for_zigs = []
for i in range(0, num_steps):
y0 = y
y = y + stepover
p0 = area.Point(x0, y0)
p1 = area.Point(x0, y)
p2 = area.Point(x1, y)
p3 = area.Point(x1, y0)
c = area.Curve()
c.append(area.Vertex(0, p0, null_point, 0))
c.append(area.Vertex(0, p1, null_point, 0))
c.append(area.Vertex(0, p2, null_point, 1))
c.append(area.Vertex(0, p3, null_point, 0))
c.append(area.Vertex(0, p0, null_point, 1))
a2 = area.Area()
a2.append(c)
a2.Intersect(a)
make_zig(a2, y0, y, zig_unidirectional)
if zig_unidirectional == False:
rightward_for_zigs = (rightward_for_zigs == False)
reorder_zigs()
def pocket(a,tool_radius, extra_offset, stepover, depthparams, from_center, keep_tool_down_if_poss, use_zig_zag, zig_angle, zig_unidirectional = False,start_point=None, cut_mode = 'conventional', entry_style = 'plunge'):
global tool_radius_for_pocket
global area_for_feed_possible
#if len(a.getCurves()) > 1:
# for crv in a.getCurves():
# ar = area.Area()
# ar.append(crv)
# pocket(ar, tool_radius, extra_offset, rapid_safety_space, start_depth, final_depth, stepover, stepdown, clearance_height, from_center, keep_tool_down_if_poss, use_zig_zag, zig_angle, zig_unidirectional)
# return
tool_radius_for_pocket = tool_radius
if keep_tool_down_if_poss:
area_for_feed_possible = area.Area(a)
area_for_feed_possible.Offset(extra_offset - 0.01)
use_internal_function = (area.holes_linked() == False) # use internal function, if area module is the Clipper library
if use_internal_function:
curve_list = a.MakePocketToolpath(tool_radius, extra_offset, stepover, from_center, use_zig_zag, zig_angle)
else:
global sin_angle_for_zigs
global cos_angle_for_zigs
global sin_minus_angle_for_zigs
global cos_minus_angle_for_zigs
radians_angle = zig_angle * math.pi / 180
sin_angle_for_zigs = math.sin(-radians_angle)
cos_angle_for_zigs = math.cos(-radians_angle)
sin_minus_angle_for_zigs = math.sin(radians_angle)
cos_minus_angle_for_zigs = math.cos(radians_angle)
arealist = list()
a_offset = area.Area(a)
current_offset = tool_radius + extra_offset
a_offset.Offset(current_offset)
do_recursive = True
if use_zig_zag:
zigzag(a_offset, stepover, zig_unidirectional)
curve_list = curve_list_for_zigs
else:
if do_recursive:
recur(arealist, a_offset, stepover, from_center)
else:
while(a_offset.num_curves() > 0):
if from_center:
arealist.insert(0, a_offset)
else:
arealist.append(a_offset)
current_offset = current_offset + stepover
a_offset = area.Area(a)
a_offset.Offset(current_offset)
curve_list = get_curve_list(arealist, cut_mode == 'climb')
depths = depthparams.get_depths()
current_start_depth = depthparams.start_depth
if start_point==None:
for depth in depths:
cut_curvelist1(curve_list, depthparams.rapid_safety_space, current_start_depth, depth, depthparams.clearance_height, keep_tool_down_if_poss, entry_style)
current_start_depth = depth
else:
for depth in depths:
cut_curvelist2(curve_list, depthparams.rapid_safety_space, current_start_depth, depth, depthparams.clearance_height, keep_tool_down_if_poss, start_point)
current_start_depth = depth