#!/usr/bin/env python3 # -*- coding: utf-8 -*- # Copyright (C) 2013-2016 Florian Festi # # This program is free software: you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . import math import inspect from boxes import gears def getDescriptions(): d = {edge.char: edge.description for edge in globals().values() if inspect.isclass(edge) and issubclass(edge, BaseEdge) and edge.char} d['k'] = "Straight edge with hinge eye (both ends)" return d class BoltPolicy(object): """Abstract class Distributes (bed) bolts on a number of segments (fingers of a finger joint) """ def drawbolt(self, pos): """Add a bolt to this segment? :param pos: number of the finger """ return False def numFingers(self, numfingers): """Return next smaller, possible number of fingers :param numfingers: number of fingers to aim for """ return numfingers def _even(self, numFingers): """ Return same or next smaller even number :param numFingers: """ return (numFingers // 2) * 2 def _odd(self, numFingers): """ Return same or next smaller odd number :param numFingers: """ if numFingers % 2: return numFingers else: return numFingers - 1 class Bolts(BoltPolicy): """Distribute a fixed number of bolts evenly""" def __init__(self, bolts=1): self.bolts = bolts def numFingers(self, numFingers): if self.bolts % 2: self.fingers = self._even(numFingers) else: self.fingers = numFingers return self.fingers def drawBolt(self, pos): """ Return if this finger needs a bolt :param pos: number of this finger """ if pos > self.fingers // 2: pos = self.fingers - pos if pos == 0: return False if pos == self.fingers // 2 and not (self.bolts % 2): return False return (math.floor((float(pos) * (self.bolts + 1) / self.fingers) - 0.01) != math.floor((float(pos + 1) * (self.bolts + 1) / self.fingers) - 0.01)) ############################################################################# ### Settings ############################################################################# class Settings(object): """Generic Settings class Used by different other classes to store messurements and details. Supports absolute values and settings that grow with the thickness of the material used. Overload the absolute_params and relative_params class attributes with the suported keys and default values. The values are available via attribute access. """ absolute_params = {} relative_params = {} def __init__(self, thickness, relative=True, **kw): self.values = self.absolute_params.copy() self.thickness = thickness factor = 1.0 if relative: factor = thickness for name, value in self.relative_params.items(): self.values[name] = value * factor self.setValues(thickness, relative, **kw) def setValues(self, thickness, relative=True, **kw): """ Set values :param thickness: thickness of the material used :param relative: (Default value = True) Do scale by thickness :param \*\*kw: parameters to set """ factor = 1.0 if relative: factor = thickness for name, value in kw.items(): if name in self.absolute_params: self.values[name] = value elif name in self.relative_params: self.values[name] = value * factor else: raise ValueError("Unknown parameter for %s: %s" % ( self.__class__.__name__, name)) def __getattr__(self, name): return self.values[name] ############################################################################# ### Edges ############################################################################# class BaseEdge(object): """Abstract base class for all Edges""" char = None description = "Abstract Edge Class" def __init__(self, boxes, settings): self.boxes = boxes self.ctx = boxes.ctx self.settings = settings def __getattr__(self, name): """Hack for using unalter code form Boxes class""" return getattr(self.boxes, name) def __call__(self, length, **kw): """Draw edge of length mm""" self.ctx.move_to(0, 0) self.ctx.line_to(length, 0) self.ctx.translate(*self.ctx.get_current_point()) def startwidth(self): """Amount of space the beginning of the edge is set below the inner space of the part """ return 0.0 def endwidth(self): return self.startwidth() def margin(self): """Space needed right of the starting point""" return 0.0 def spacing(self): """Space the edge needs outside of the inner space of the part""" return self.startwidth() + self.margin() def startAngle(self): """Not yet supported""" return 0.0 def endAngle(self): """Not yet supported""" return 0.0 class Edge(BaseEdge): """Straight edge""" char = 'e' description = "Straight Edge" class OutSetEdge(BaseEdge): """Straight edge out set by one thickness""" char = 'E' description = "Straight Edge (outset by thickness)" def startwidth(self): return self.boxes.thickness ############################################################################# #### Gripping Edge ############################################################################# class GripSettings(Settings): """Settings for GrippingEdge Values: * absolute_params * style : A : "A" (wiggly line) or "B" (bumps) * outset : True : extend outward the straight edge * relative (in multiples of thickness) * depth : 0.3 : depth of the grooves """ absolute_params = { "style": "A", "outset": True, } relative_params = { "depth": 0.3, } class GrippingEdge(BaseEdge): description = """Corrugated edge useful as an gipping area""" char = 'g' def A(self, length): depth = self.settings.depth grooves = int(length // (depth * 2.0)) + 1 depth = length / grooves / 4.0 o = 1 if self.settings.outset else -1 for groove in range(grooves): self.corner(o * -90, depth) self.corner(o * 180, depth) self.corner(o * -90, depth) def B(self, length): depth = self.settings.depth grooves = int(length // (depth * 2.0)) + 1 depth = length / grooves / 2.0 o = 1 if self.settings.outset else -1 if self.settings.outset: self.corner(-90) else: self.corner(90) self.edge(depth) self.corner(-180) for groove in range(grooves): self.corner(180, depth) self.corner(-180, 0) if self.settings.outset: self.corner(90) else: self.edge(depth) self.corner(90) def margin(self): if self.settings.outset: return self.settings.depth else: return 0.0 def __call__(self, length, **kw): if length == 0.0: return getattr(self, self.settings.style)(length) class CompoundEdge(BaseEdge): """Edge composed of multiple different Edges""" description = "Compound Edge" def __init__(self, boxes, types, lengths): super(CompoundEdge, self).__init__(boxes, None) self.types = [self.edges.get(edge, edge) for edge in types] self.lengths = lengths self.length = sum(lengths) def startwidth(self): return self.types[0].startwidth() def endwidth(self): return self.types[-1].endwidth() def margin(self): return max((e.margin() for e in self.types)) def __call__(self, length, **kw): if length and abs(length - self.length) > 1E-5: raise ValueError("Wrong length for CompoundEdge") lastwidth = self.types[0].startwidth() for e, l in zip(self.types, self.lengths): diff = e.startwidth() - lastwidth if diff > 1E-5: self.boxes.corner(-90) self.boxes.edge(diff) self.boxes.corner(90) elif diff < -1E-5: self.boxes.corner(90) self.boxes.edge(-diff) self.boxes.corner(-90) e(l) lastwidth = e.endwidth() ############################################################################# #### Slots ############################################################################# class Slot(BaseEdge): """Edge with an slot to slid another pice through """ description = "Slot" def __init__(self, boxes, depth): super(Slot, self).__init__(boxes, None) self.depth = depth def __call__(self, length, **kw): if self.depth: self.boxes.corner(90) self.boxes.edge(self.depth) self.boxes.corner(-90) self.boxes.edge(length) self.boxes.corner(-90) self.boxes.edge(self.depth) self.boxes.corner(90) else: self.boxes.edge(self.length) class SlottedEdge(BaseEdge): """Edge with multiple slots""" description = "Straight Edge with slots" def __init__(self, boxes, sections, edge="e", slots=0): super(SlottedEdge, self).__init__(boxes, None) self.edge = self.edges.get(edge, edge) self.sections = sections self.slots = slots def startwidth(self): return self.edge.startwidth() def endwidth(self): return self.edge.endwidth() def margin(self): return self.edge.margin() def __call__(self, length, **kw): for l in self.sections[:-1]: self.edge(l) if self.slots: Slot(self.boxes, self.slots)(self.thickness) else: self.edge(self.thickness) self.edge(self.sections[-1]) ############################################################################# #### Finger Joints ############################################################################# class FingerJointSettings(Settings): """Settings for finger joints Values: * absolute * surroundingspaces : 2 : maximum space at the start and end in multiple of normal spaces * relative (in multiples of thickness) * space : 1.0 : space between fingers * finger : 1.0 : width of the fingers * height : 1.0 : length of the fingers * width : 1.0 : width of finger holes * edge_width : 1.0 : space below holes of FingerHoleEdge """ absolute_params = { "surroundingspaces": 2, } relative_params = { "space": 1.0, "finger": 1.0, "height": 1.0, "width": 1.0, "edge_width": 1.0, } class FingerJointEdge(BaseEdge): """Finger joint edge """ char = 'f' description = "Finger Joint" positive = True def __call__(self, length, bedBolts=None, bedBoltSettings=None, **kw): positive = self.positive space, finger = self.settings.space, self.settings.finger fingers = int((length - (self.settings.surroundingspaces - 1) * space) // (space + finger)) if bedBolts: fingers = bedBolts.numFingers(fingers) leftover = length - fingers * (space + finger) + space s, f, thickness = space, finger, self.thickness d, d_nut, h_nut, l, l1 = bedBoltSettings or self.boxes.bedBoltSettings p = 1 if positive else -1 if fingers <= 0: fingers = 0 leftover = length self.edge(leftover / 2.0) for i in range(fingers): if i != 0: if not positive and bedBolts and bedBolts.drawBolt(i): self.hole(0.5 * space, 0.5 * self.thickness, 0.5 * d) if positive and bedBolts and bedBolts.drawBolt(i): self.bedBoltHole(s, bedBoltSettings) else: self.edge(s) self.corner(-90 * p) self.edge(self.settings.height) self.corner(90 * p) self.edge(f) self.corner(90 * p) self.edge(self.settings.height) self.corner(-90 * p) self.edge(leftover / 2.0) def margin(self): """ """ return self.boxes.thickness class FingerJointEdgeCounterPart(FingerJointEdge): """Finger joint edge - other side""" char = 'F' description = "Finger Joint (opposing side)" positive = False def startwidth(self): """ """ return self.boxes.thickness def margin(self): """ """ return 0.0 class FingerHoles: """Hole matching a finger joint edge""" def __init__(self, boxes, settings): self.boxes = boxes self.ctx = boxes.ctx self.settings = settings def __call__(self, x, y, length, angle=90, bedBolts=None, bedBoltSettings=None): """ Draw holes for a matching finger joint edge :param x: position :param y: position :param length: length of matching edge :param angle: (Default value = 90) :param bedBolts: (Default value = None) :param bedBoltSettings: (Default value = None) """ self.boxes.ctx.save() self.boxes.moveTo(x, y, angle) s, f = self.settings.space, self.settings.finger fingers = int((length - (self.settings.surroundingspaces - 1) * s) // (s + f)) if bedBolts: fingers = bedBolts.numFingers(fingers) d, d_nut, h_nut, l, l1 = bedBoltSettings or self.boxes.bedBoltSettings leftover = length - fingers * (s + f) - f b = self.boxes.burn if self.boxes.debug: self.ctx.rectangle(0, -self.settings.width / 2 + b, length, self.settings.width - 2 * b) for i in range(fingers): pos = leftover / 2.0 + i * (s + f) if bedBolts and bedBolts.drawBolt(i): self.boxes.hole(pos + 0.5 * s, 0, d * 0.5) self.boxes.rectangularHole(pos + s + 0.5 * f, 0, f, self.settings.width) self.ctx.restore() class FingerHoleEdge(BaseEdge): """Edge with holes for a parallel finger joint""" char = 'h' description = "Edge (parallel Finger Joint Holes)" def __init__(self, boxes, fingerHoles=None, **kw): super(FingerHoleEdge, self).__init__(boxes, None, **kw) self.fingerHoles = fingerHoles or boxes.fingerHolesAt def __call__(self, length, bedBolts=None, bedBoltSettings=None, **kw): dist = self.fingerHoles.settings.edge_width self.ctx.save() self.fingerHoles(0, dist + self.thickness / 2, length, 0, bedBolts=bedBolts, bedBoltSettings=bedBoltSettings) self.ctx.restore() # XXX continue path self.ctx.move_to(0, 0) self.ctx.line_to(length, 0) self.ctx.translate(*self.ctx.get_current_point()) def startwidth(self): """ """ return self.fingerHoles.settings.edge_width + self.thickness class CrossingFingerHoleEdge(BaseEdge): """Edge with holes for finger joints 90° above""" description = "Edge (orthogonal Finger Joint Holes)" def __init__(self, boxes, height, fingerHoles=None, **kw): super(CrossingFingerHoleEdge, self).__init__(boxes, None, **kw) self.fingerHoles = fingerHoles or boxes.fingerHolesAt self.height = height def __call__(self, length, **kw): self.fingerHoles(length / 2.0, 0, self.height) super(CrossingFingerHoleEdge, self).__call__(length) ############################################################################# #### Stackable Joints ############################################################################# class StackableSettings(Settings): """Settings for StackableEdge classes Values: * absolute_params * angle : 60 : inside angle of the feet * relative (in multiples of thickness) * height : 2.0 : height of the feet * width : 4.0 : width of the feet * holedistance : 1.0 : distance from finger holes to bottom edge """ absolute_params = { "angle": 60, } relative_params = { "height": 2.0, "width": 4.0, "holedistance": 1.0, } class StackableEdge(BaseEdge): """Edge for having stackable Boxes. The Edge creates feet on the bottom and has matching recesses on the top corners.""" char = "s" description = "Stackable (bottom, finger joint holes)" bottom = True def __init__(self, boxes, settings, fingerjointsettings): super(StackableEdge, self).__init__(boxes, settings) self.fingerjointsettings = fingerjointsettings def __call__(self, length, **kw): s = self.settings r = s.height / 2.0 / (1 - math.cos(math.radians(s.angle))) l = r * math.sin(math.radians(s.angle)) p = 1 if self.bottom else -1 if self.bottom: self.boxes.fingerHolesAt(0, s.height + self.settings.holedistance + 0.5 * self.boxes.thickness, length, 0) self.boxes.edge(s.width) self.boxes.corner(p * s.angle, r) self.boxes.corner(-p * s.angle, r) self.boxes.edge(length - 2 * s.width - 4 * l) self.boxes.corner(-p * s.angle, r) self.boxes.corner(p * s.angle, r) self.boxes.edge(s.width) def _height(self): return self.settings.height + self.settings.holedistance + self.settings.thickness def startwidth(self): return self._height() if self.bottom else 0 def margin(self): return 0 if self.bottom else self._height() class StackableEdgeTop(StackableEdge): char = "S" description = "Stackable (top)" bottom = False ############################################################################# #### Hinges ############################################################################# class HingeSettings(Settings): """Settings for Hinge and HingePin classes Values: * absolute_params * style : B : currently "A" or "B" * outset : False : have lid overlap at the sides (similar to OutSetEdge) * pinwidth : 1.0 : set to lower value to get disks surrounding the pins * grip_percentage" : 0 : percentage of the lid that should get grips * relative (in multiples of thickness) * hingestrength : 1 : thickness of the arc holding the pin in place * axle : 2 : diameter of the pin hole * grip_length : 0 : fixed length of the grips on he lids """ absolute_params = { "style": "A", "outset": False, "pinwidth": 0.5, "grip_percentage": 0, } relative_params = { "hingestrength": 1, # 1.5-0.5*2**0.5, "axle": 2, "grip_length": 0, } class Hinge(BaseEdge): char = 'i' description = "Straight edge with hinge eye" def __init__(self, boxes, settings=None, layout=1): super(Hinge, self).__init__(boxes, settings) if not (0 < layout <= 3): raise ValueError("layout must be 1, 2 or 3 (got %i)" % layout) self.layout = layout self.char = "eijk"[layout] self.description = self.description + ('', ' (start)', ' (end)', ' (both ends)')[layout] def margin(self): return 3 * self.thickness def A(self, _reversed=False): t = self.thickness r = 0.5 * self.settings.axle alpha = math.degrees(math.asin(0.5 * t / r)) pinl = (self.settings.axle ** 2 - self.thickness ** 2) ** 0.5 * self.settings.pinwidth pos = math.cos(math.radians(alpha)) * r hinge = ( 0, 90 - alpha, 0, (-360, r), 0, 90 + alpha, t, 90, 0.5 * t, (180, t + pos), 0, (-90, 0.5 * t), 0 ) if _reversed: hinge = reversed(hinge) self.polyline(*hinge) self.boxes.rectangularHole(-pos, -0.5 * t, pinl, self.thickness) else: self.boxes.rectangularHole(pos, -0.5 * t, pinl, self.thickness) self.polyline(*hinge) def Alen(self): t = self.thickness r = 0.5 * self.settings.axle alpha = math.degrees(math.asin(0.5 * t / r)) pos = math.cos(math.radians(alpha)) * r return 2 * pos + 1.5 * t def B(self, _reversed=False): t = self.thickness hinge = ( 0, -90, 0.5 * t, (180, 0.5 * self.settings.axle + self.settings.hingestrength), 0, (-90, 0.5 * t), 0 ) pos = 0.5 * self.settings.axle + self.settings.hingestrength pinl = (self.settings.axle ** 2 - self.thickness ** 2) ** 0.5 * self.settings.pinwidth if _reversed: hinge = reversed(hinge) self.hole(0.5 * t + pos, -0.5 * t, 0.5 * self.settings.axle) self.boxes.rectangularHole(0.5 * t + pos, -0.5 * t, pinl, self.thickness) else: self.hole(pos, -0.5 * t, 0.5 * self.settings.axle) self.boxes.rectangularHole(pos, -0.5 * t, pinl, self.thickness) self.polyline(*hinge) def Blen(self): return self.settings.axle + 2 * self.settings.hingestrength + 0.5 * self.thickness def __call__(self, l, **kw): hlen = getattr(self, self.settings.style + 'len')() if self.layout & 1: getattr(self, self.settings.style)() self.edge(l - (self.layout & 1) * hlen - bool(self.layout & 2) * hlen) if self.layout & 2: getattr(self, self.settings.style)(True) class HingePin(BaseEdge): char = 'I' description = "Edge with hinge pin" def __init__(self, boxes, settings=None, layout=1): super(HingePin, self).__init__(boxes, settings) if not (0 < layout <= 3): raise ValueError("layout must be 1, 2 or 3 (got %i)" % layout) self.layout = layout self.char = "EIJK"[layout] self.description = self.description + ('', ' (start)', ' (end)', ' (both ends)')[layout] def startwidth(self): if self.layout & 1: return 0 else: return self.settings.outset * self.boxes.thickness def endwidth(self): if self.layout & 2: return 0 else: return self.settings.outset * self.boxes.thickness def margin(self): return self.thickness def A(self, _reversed=False): t = self.thickness r = 0.5 * self.settings.axle alpha = math.degrees(math.asin(0.5 * t / r)) pos = math.cos(math.radians(alpha)) * r pinl = (self.settings.axle ** 2 - self.thickness ** 2) ** 0.5 * self.settings.pinwidth pin = (pos - 0.5 * pinl, -90, t, 90, pinl, 90, t, -90) if self.settings.outset: pin += ( pos - 0.5 * pinl + 1.5 * t, -90, t, 90, 0, ) else: pin += (pos - 0.5 * pinl,) if _reversed: pin = reversed(pin) self.polyline(*pin) def Alen(self): t = self.thickness r = 0.5 * self.settings.axle alpha = math.degrees(math.asin(0.5 * t / r)) pos = math.cos(math.radians(alpha)) * r if self.settings.outset: return 2 * pos + 1.5 * self.thickness else: return 2 * pos def B(self, _reversed=False): t = self.thickness pinl = (self.settings.axle ** 2 - t ** 2) ** 0.5 * self.settings.pinwidth d = (self.settings.axle - pinl) / 2.0 pin = (self.settings.hingestrength + d, -90, t, 90, pinl, 90, t, -90, d) if self.settings.outset: pin += ( 0, self.settings.hingestrength + 0.5 * t, -90, t, 90, 0, ) if _reversed: pin = reversed(pin) self.polyline(*pin) def Blen(self): l = self.settings.hingestrength + self.settings.axle if self.settings.outset: l += self.settings.hingestrength + 0.5 * self.thickness return l def __call__(self, l, **kw): plen = getattr(self, self.settings.style + 'len')() glen = l * self.settings.grip_percentage + \ self.settings.grip_length if not self.settings.outset: glen = 0.0 glen = min(glen, l - plen) if self.layout & 1 and self.layout & 2: getattr(self, self.settings.style)() self.edge(l - 2 * plen) getattr(self, self.settings.style)(True) elif self.layout & 1: getattr(self, self.settings.style)() self.edge(l - plen - glen) self.edges['g'](glen) else: self.edges['g'](glen) self.edge(l - plen - glen) getattr(self, self.settings.style)(True) ############################################################################# #### Click Joints ############################################################################# class ClickSettings(Settings): absolute_params = { "angle": 5, } relative_params = { "depth": 3.0, "bottom_radius": 0.1, } class ClickConnector(BaseEdge): char = "c" description = "Click on (bottom side)" def hook(self, reverse=False): t = self.thickness a = self.settings.angle d = self.settings.depth r = self.settings.bottom_radius c = math.cos(math.radians(a)) s = math.sin(math.radians(a)) p1 = (0, 90 - a, c * d) p2 = ( d + t, -90, t * 0.5, 135, t * 2 ** 0.5, 135, d + 2 * t + s * 0.5 * t) p3 = (c * d - s * c * 0.2 * t, -a, 0) if not reverse: self.polyline(*p1) self.corner(-180, r) self.polyline(*p2) self.corner(-180 + 2 * a, r) self.polyline(*p3) else: self.polyline(*reversed(p3)) self.corner(-180 + 2 * a, r) self.polyline(*reversed(p2)) self.corner(-180, r) self.polyline(*reversed(p1)) def hookWidth(self): t = self.thickness a = self.settings.angle d = self.settings.depth r = self.settings.bottom_radius c = math.cos(math.radians(a)) s = math.sin(math.radians(a)) return 2 * s * d * c + 0.5 * c * t + c * 4 * r def hookOffset(self): a = self.settings.angle d = self.settings.depth r = self.settings.bottom_radius c = math.cos(math.radians(a)) s = math.sin(math.radians(a)) return s * d * c + 2 * r def finger(self, length): t = self.thickness self.polyline( 2 * t, 90, length, 90, 2 * t, ) def __call__(self, length, **kw): t = self.thickness self.edge(4 * t) self.hook() self.finger(2 * t) self.hook(reverse=True) self.edge(length - 2 * (6 * t + 2 * self.hookWidth())) self.hook() self.finger(2 * t) self.hook(reverse=True) self.edge(4 * t) def margin(self): return 2 * self.thickness class ClickEdge(ClickConnector): char = "C" description = "Click on (top)" def startwidth(self): return self.boxes.thickness def margin(self): return 0.0 def __call__(self, length, **kw): t = self.thickness o = self.hookOffset() w = self.hookWidth() p1 = ( 4 * t + o, 90, t, -90, 2 * (t + w - o), -90, t, 90, 0) self.polyline(*p1) self.edge(length - 2 * (6 * t + 2 * w) + 2 * o) self.polyline(*reversed(p1)) ############################################################################# #### Dove Tail Joints ############################################################################# class DoveTailSettings(Settings): """Settings used for dove tail joints Values: * absolute * angle : 50 : how much should fingers widen (-80 to 80) * relative (in multiples of thickness) * size : 3 : from one middle of a dove tail to another * depth : 1.5 : how far the dove tails stick out of/into the edge * radius : 0.2 : radius used on all four corners """ absolute_params = { "angle": 50, } relative_params = { "size": 3, "depth": 1.5, "radius": 0.2, } class DoveTailJoint(BaseEdge): """Edge with dove tail joints """ char = 'd' description = "Dove Tail Joint" positive = True def __call__(self, length, **kw): s = self.settings radius = max(s.radius, self.boxes.burn) # no smaller than burn positive = self.positive a = s.angle + 90 alpha = 0.5 * math.pi - math.pi * s.angle / 180.0 l1 = radius / math.tan(alpha / 2.0) diffx = 0.5 * s.depth / math.tan(alpha) l2 = 0.5 * s.depth / math.sin(alpha) sections = int((length) // (s.size * 2)) leftover = length - sections * s.size * 2 p = 1 if positive else -1 self.edge((s.size + leftover) / 2.0 + diffx - l1) for i in range(sections): self.corner(-1 * p * a, radius) self.edge(2 * (l2 - l1)) self.corner(p * a, radius) self.edge(2 * (diffx - l1) + s.size) self.corner(p * a, radius) self.edge(2 * (l2 - l1)) self.corner(-1 * p * a, radius) if i < sections - 1: # all but the last self.edge(2 * (diffx - l1) + s.size) self.edge((s.size + leftover) / 2.0 + diffx - l1) self.ctx.translate(*self.ctx.get_current_point()) def margin(self): """ """ return self.settings.depth class DoveTailJointCounterPart(DoveTailJoint): """Edge for other side of dove joints """ char = 'D' description = "Dove Tail Joint (opposing side)" positive = False def margin(self): return 0.0 class FlexSettings(Settings): """Settings for one directional flex cuts Values: * absolute * stretch : 1.05 : Hint of how much the flex part should be shortend * relative (in multiples of thickness) * distance : 0.5 : width of the pattern perpendicular to the cuts * connection : 1.0 : width of the gaps in the cuts * width" : 5.0 : width of the pattern in direction of the cuts """ relative_params = { "distance": 0.5, "connection": 1.0, "width": 5.0, } absolute_params = { "stretch": 1.05, } class FlexEdge(BaseEdge): """Edge with flex cuts - use straight edge for the opposing side""" char = 'X' description = "Flex cut" def __call__(self, x, h, **kw): dist = self.settings.distance connection = self.settings.connection width = self.settings.width burn = self.boxes.burn h += 2 * burn lines = int(x // dist) leftover = x - lines * dist sections = int((h - connection) // width) sheight = ((h - connection) / sections) - connection for i in range(1, lines): pos = i * dist + leftover / 2 if i % 2: self.ctx.move_to(pos, 0) self.ctx.line_to(pos, connection + sheight) for j in range((sections - 1) // 2): self.ctx.move_to(pos, (2 * j + 1) * sheight + (2 * j + 2) * connection) self.ctx.line_to(pos, (2 * j + 3) * (sheight + connection)) if not sections % 2: self.ctx.move_to(pos, h - sheight - connection) self.ctx.line_to(pos, h) else: if sections % 2: self.ctx.move_to(pos, h) self.ctx.line_to(pos, h - connection - sheight) for j in range((sections - 1) // 2): self.ctx.move_to( pos, h - ((2 * j + 1) * sheight + (2 * j + 2) * connection)) self.ctx.line_to( pos, h - (2 * j + 3) * (sheight + connection)) else: for j in range(sections // 2): self.ctx.move_to(pos, h - connection - 2 * j * (sheight + connection)) self.ctx.line_to(pos, h - 2 * (j + 1) * (sheight + connection)) self.ctx.move_to(0, 0) self.ctx.line_to(x, 0) self.ctx.translate(*self.ctx.get_current_point()) class GearSettings(Settings): absolute_params = { "dimension" : 3.0, "angle" : 20.0, "profile_shift" : 20.0, "clearance" : 0.0, } relative_params = {} class RackEdge(BaseEdge): char = "R" def __init__(self, boxes, settings): super(RackEdge, self).__init__(boxes, settings) self.gear = gears.Gears(boxes) def __call__(self, length, **kw): params = self.settings.values.copy() params["draw_rack"] = True params["rack_base_height"] = -1E-36 params["rack_teeth_length"] = int(length // params["dimension"]) params["rack_base_tab"] = (length - (params["rack_teeth_length"]) * params["dimension"]) / 2.0 s_tmp = self.boxes.spacing self.boxes.spacing = 0 self.moveTo(length, 0, 180) self.gear(move="", **params) self.moveTo(0, 0, 180) self.boxes.spacing = s_tmp def margin(self): return self.settings.dimension * 1.1