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# ***************************************************************************
# * Copyright (c) 2022 sliptonic <shopinthewoods@gmail.com> *
# * *
# * This program is free software; you can redistribute it and/or modify *
# * it under the terms of the GNU Lesser General Public License (LGPL) *
# * as published by the Free Software Foundation; either version 2 of *
# * the License, or (at your option) any later version. *
# * for detail see the LICENCE text file. *
# * *
# * 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 Library General Public License for more details. *
# * *
# * You should have received a copy of the GNU Library General Public *
# * License along with this program; if not, write to the Free Software *
# * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 *
# * USA *
# * *
# ***************************************************************************
import FreeCAD
import Path
import Path.Base.Generator.dogboneII as dogboneII
import Path.Base.Language as PathLanguage
import CAMTests.PathTestUtils as PathTestUtils
import math
# Path.Log.setLevel(Path.Log.Level.DEBUG)
Path.Log.setLevel(Path.Log.Level.NOTICE)
PI = math.pi
DebugMode = Path.Log.getLevel(Path.Log.thisModule()) == Path.Log.Level.DEBUG
def createKinks(maneuver):
k = []
moves = maneuver.getMoves()
if moves:
move0 = moves[0]
prev = move0
for m in moves[1:]:
k.append(dogboneII.Kink(prev, m))
prev = m
if Path.Geom.pointsCoincide(move0.positionBegin(), prev.positionEnd()):
k.append(dogboneII.Kink(prev, move0))
return k
def findDogboneKinks(maneuver, threshold):
if threshold > 0:
return [k for k in createKinks(maneuver) if k.deflection() > threshold]
if threshold < 0:
return [k for k in createKinks(maneuver) if k.deflection() < threshold]
return createKinks(maneuver)
def MNVR(gcode, begin=None):
# 'turns out the replace() isn't really necessary
# leave it here anyway for clarity
return PathLanguage.Maneuver.FromGCode(gcode.replace("/", "\n"), begin)
def INSTR(gcode, begin=None):
return MNVR(gcode, begin).instr[0]
def KINK(gcode, begin=None):
maneuver = MNVR(gcode, begin)
if len(maneuver.instr) != 2:
return None
return dogboneII.Kink(maneuver.instr[0], maneuver.instr[1])
def GEN(generator, length):
return generator(lambda k, a, n, c: n, length, 1)
class TestGeneratorDogboneII(PathTestUtils.PathTestBase):
"""Unit tests for the dogboneII generator."""
def assertKinks(self, maneuver, s):
kinks = [f"{k.deflection():4.2f}" for k in createKinks(maneuver)]
self.assertEqual(f"[{', '.join(kinks)}]", s)
def assertBones(self, maneuver, threshold, s):
bones = [f"({int(b.x())},{int(b.y())})" for b in findDogboneKinks(maneuver, threshold)]
self.assertEqual(f"[{', '.join(bones)}]", s)
def assertBone(self, bone, s, digits=0):
if DebugMode and FreeCAD.GuiUp:
Path.show(dogboneII.kink_to_path(bone.kink))
FreeCAD.ActiveDocument.Objects[-1].Visibility = False
Path.show(dogboneII.bone_to_path(bone))
FreeCAD.ActiveDocument.Objects[-1].Visibility = False
Path.Log.debug(f"{bone.kink} : {bone.angle / PI:.2f}")
b = [i.str(digits) for i in bone.instr]
self.assertEqual(f"[{', '.join(b)}]", s)
def test20(self):
"""Verify kinks of maneuvers"""
self.assertKinks(MNVR("G1X1/G1Y1"), "[1.57]")
self.assertKinks(MNVR("G1X1/G1Y-1"), "[-1.57]")
self.assertKinks(MNVR("G1X1/G1Y1/G1X0"), "[1.57, 1.57]")
self.assertKinks(MNVR("G1X1/G1Y1/G1X0/G1Y0"), "[1.57, 1.57, 1.57, 1.57]")
self.assertKinks(MNVR("G1Y1/G1X1"), "[-1.57]")
self.assertKinks(MNVR("G1Y1/G1X1/G1Y0"), "[-1.57, -1.57]")
self.assertKinks(MNVR("G1Y1/G1X1/G1Y0/G1X0"), "[-1.57, -1.57, -1.57, -1.57]")
# tangential arc moves
self.assertKinks(MNVR("G1X1/G3Y2J1"), "[0.00]")
self.assertKinks(MNVR("G1X1/G3Y2J1G1X0"), "[0.00, 0.00]")
# folding back arc moves
self.assertKinks(MNVR("G1X1/G2Y2J1"), "[-3.14]")
self.assertKinks(MNVR("G1X1/G2Y2J1G1X0"), "[-3.14, 3.14]")
def test30(self):
"""Verify dogbone detection"""
self.assertBones(MNVR("G1X1/G1Y1/G1X0/G1Y0"), PI / 4, "[(1,0), (1,1), (0,1), (0,0)]")
self.assertBones(MNVR("G1X1/G1Y1/G1X0/G1Y0"), -PI / 4, "[]")
# no bones on flat angle
self.assertBones(MNVR("G1X1/G1X3Y1/G1X0/G1Y0"), PI / 4, "[(3,1), (0,1), (0,0)]")
self.assertBones(MNVR("G1X1/G1X3Y1/G1X0/G1Y0"), -PI / 4, "[]")
# no bones on tangential arc
self.assertBones(MNVR("G1X1/G3Y2J1/G1X0/G1Y0"), PI / 4, "[(0,2), (0,0)]")
self.assertBones(MNVR("G1X1/G3Y2J1/G1X0/G1Y0"), -PI / 4, "[]")
# a bone on perpendicular arc
self.assertBones(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), PI / 4, "[(3,1), (0,1), (0,0)]")
self.assertBones(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), -PI / 4, "[(1,0)]")
def test40(self):
"""Verify horizontal t-bone creation"""
# Uses test data from test30, if that broke, this can't succeed
horizontal = GEN(dogboneII.GeneratorTBoneHorizontal, 1)
# single move right
maneuver = MNVR("G1X1/G1Y1")
kinks = findDogboneKinks(maneuver, PI / 4)
self.assertEqual(len(kinks), 1)
k = kinks[0]
p = k.position()
self.assertEqual(f"({int(p.x)}, {int(p.y)})", "(1, 0)")
bone = horizontal.generate(k)
self.assertBone(bone, "[G1{X: 2}, G1{X: 1}]")
# full loop CCW
kinks = findDogboneKinks(MNVR("G1X1/G1Y1/G1X0/G1Y0"), PI / 4)
bones = [horizontal.generate(k) for k in kinks]
self.assertEqual(len(bones), 4)
self.assertBone(bones[0], "[G1{X: 2}, G1{X: 1}]")
self.assertBone(bones[1], "[G1{X: 2}, G1{X: 1}]")
self.assertBone(bones[2], "[G1{X: -1}, G1{X: 0}]")
self.assertBone(bones[3], "[G1{X: -1}, G1{X: 0}]")
# single move left
maneuver = MNVR("G1X1/G1Y-1")
kinks = findDogboneKinks(maneuver, -PI / 4)
self.assertEqual(len(kinks), 1)
k = kinks[0]
p = k.position()
self.assertEqual(f"({int(p.x)}, {int(p.y)})", "(1, 0)")
bone = horizontal.generate(k)
self.assertBone(bone, "[G1{X: 2}, G1{X: 1}]")
# full loop CW
kinks = findDogboneKinks(MNVR("G1X1/G1Y-1/G1X0/G1Y0"), -PI / 4)
bones = [horizontal.generate(k) for k in kinks]
self.assertEqual(len(bones), 4)
self.assertBone(bones[0], "[G1{X: 2}, G1{X: 1}]")
self.assertBone(bones[1], "[G1{X: 2}, G1{X: 1}]")
self.assertBone(bones[2], "[G1{X: -1}, G1{X: 0}]")
self.assertBone(bones[3], "[G1{X: -1}, G1{X: 0}]")
# bones on arcs
kinks = findDogboneKinks(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), PI / 4)
bones = [horizontal.generate(k) for k in kinks]
self.assertEqual(len(bones), 3)
self.assertBone(bones[0], "[G1{X: 4}, G1{X: 3}]")
self.assertBone(bones[1], "[G1{X: -1}, G1{X: 0}]")
self.assertBone(bones[2], "[G1{X: -1}, G1{X: 0}]")
# bones on arcs
kinks = findDogboneKinks(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), -PI / 4)
bones = [horizontal.generate(k) for k in kinks]
self.assertEqual(len(bones), 1)
self.assertBone(bones[0], "[G1{X: 2}, G1{X: 1}]")
def test50(self):
"""Verify vertical t-bone creation"""
# Uses test data from test30, if that broke, this can't succeed
vertical = GEN(dogboneII.GeneratorTBoneVertical, 1)
# single move right
maneuver = MNVR("G1X1/G1Y1")
kinks = findDogboneKinks(maneuver, PI / 4)
self.assertEqual(len(kinks), 1)
k = kinks[0]
p = k.position()
self.assertEqual(f"({int(p.x)}, {int(p.y)})", "(1, 0)")
bone = vertical.generate(k)
self.assertBone(bone, "[G1{Y: -1}, G1{Y: 0}]")
# full loop CCW
kinks = findDogboneKinks(MNVR("G1X1/G1Y1/G1X0/G1Y0"), PI / 4)
bones = [vertical.generate(k) for k in kinks]
self.assertEqual(len(bones), 4)
self.assertBone(bones[0], "[G1{Y: -1}, G1{Y: 0}]")
self.assertBone(bones[1], "[G1{Y: 2}, G1{Y: 1}]")
self.assertBone(bones[2], "[G1{Y: 2}, G1{Y: 1}]")
self.assertBone(bones[3], "[G1{Y: -1}, G1{Y: 0}]")
# single move left
maneuver = MNVR("G1X1/G1Y-1")
kinks = findDogboneKinks(maneuver, -PI / 4)
self.assertEqual(len(kinks), 1)
k = kinks[0]
p = k.position()
self.assertEqual(f"({int(p.x)}, {int(p.y)})", "(1, 0)")
bone = vertical.generate(k)
self.assertBone(bone, "[G1{Y: 1}, G1{Y: 0}]")
# full loop CW
kinks = findDogboneKinks(MNVR("G1X1/G1Y-1/G1X0/G1Y0"), -PI / 4)
bones = [vertical.generate(k) for k in kinks]
self.assertEqual(len(bones), 4)
self.assertBone(bones[0], "[G1{Y: 1}, G1{Y: 0}]")
self.assertBone(bones[1], "[G1{Y: -2}, G1{Y: -1}]")
self.assertBone(bones[2], "[G1{Y: -2}, G1{Y: -1}]")
self.assertBone(bones[3], "[G1{Y: 1}, G1{Y: 0}]")
# bones on arcs
kinks = findDogboneKinks(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), PI / 4)
bones = [vertical.generate(k) for k in kinks]
self.assertEqual(len(bones), 3)
self.assertBone(bones[0], "[G1{Y: 2}, G1{Y: 1}]")
self.assertBone(bones[1], "[G1{Y: 2}, G1{Y: 1}]")
self.assertBone(bones[2], "[G1{Y: -1}, G1{Y: 0}]")
# bones on arcs
kinks = findDogboneKinks(MNVR("G1X1/G3X3I1/G1Y1/G1X0/G1Y0"), -PI / 4)
bones = [vertical.generate(k) for k in kinks]
self.assertEqual(len(bones), 1)
self.assertBone(bones[0], "[G1{Y: 1}, G1{Y: 0}]")
def test60(self):
"""Verify t-bones on edges"""
on_short_1 = GEN(dogboneII.GeneratorTBoneOnShort, 1)
on_short_5 = GEN(dogboneII.GeneratorTBoneOnShort, 5)
# horizontal short edge
bone = on_short_1.generate(KINK("G1X1/G1Y2"))
self.assertBone(bone, "[G1{Y: -1}, G1{Y: 0}]")
bone = on_short_1.generate(KINK("G1X-1/G1Y2"))
self.assertBone(bone, "[G1{Y: -1}, G1{Y: 0}]")
# vertical short edge
bone = on_short_1.generate(KINK("G1Y1/G1X2"))
self.assertBone(bone, "[G1{X: -1}, G1{X: 0}]")
bone = on_short_1.generate(KINK("G1Y1/G1X-2"))
self.assertBone(bone, "[G1{X: 1}, G1{X: 0}]")
# some other angle
bone = on_short_5.generate(KINK("G1X1Y1/G1Y-1"))
self.assertBone(bone, "[G1{X: -2.5, Y: 4.5}, G1{X: 1.0, Y: 1.0}]", 2)
bone = on_short_5.generate(KINK("G1X-1Y-1/G1Y1"))
self.assertBone(bone, "[G1{X: 2.5, Y: -4.5}, G1{X: -1.0, Y: -1.0}]", 2)
# some other angle
bone = on_short_5.generate(KINK("G1X2Y1/G1Y-3"))
self.assertBone(bone, "[G1{X: -0.24, Y: 5.5}, G1{X: 2.0, Y: 1.0}]", 2)
bone = on_short_5.generate(KINK("G1X-2Y-1/G1Y3"))
self.assertBone(bone, "[G1{X: 0.24, Y: -5.5}, G1{X: -2.0, Y: -1.0}]", 2)
# short edge - the 2nd
bone = on_short_1.generate(KINK("G1Y2/G1X1"))
self.assertBone(bone, "[G1{Y: 3}, G1{Y: 2}]")
bone = on_short_1.generate(KINK("G1Y2/G1X-1"))
self.assertBone(bone, "[G1{Y: 3}, G1{Y: 2}]")
bone = on_short_5.generate(KINK("G1Y-3/G1X2Y-2"))
self.assertBone(bone, "[G1{X: 2.2, Y: -7.5}, G1{X: 0.0, Y: -3.0}]", 2)
bone = on_short_5.generate(KINK("G1Y3/G1X-2Y2"))
self.assertBone(bone, "[G1{X: -2.2, Y: 7.5}, G1{X: 0.0, Y: 3.0}]", 2)
# long edge
on_long_1 = GEN(dogboneII.GeneratorTBoneOnLong, 1)
on_long_5 = GEN(dogboneII.GeneratorTBoneOnLong, 5)
bone = on_long_1.generate(
KINK("G1X2/G1Y1"),
)
self.assertBone(bone, "[G1{Y: -1}, G1{Y: 0}]")
bone = on_long_1.generate(KINK("G1X-2/G1Y1"))
self.assertBone(bone, "[G1{Y: -1}, G1{Y: 0}]")
bone = on_long_5.generate(KINK("G1Y-1/G1X2Y0"))
self.assertBone(bone, "[G1{X: 2.2, Y: -5.5}, G1{X: 0.0, Y: -1.0}]", 2)
bone = on_long_5.generate(KINK("G1Y1/G1X-2Y0"))
self.assertBone(bone, "[G1{X: -2.2, Y: 5.5}, G1{X: 0.0, Y: 1.0}]", 2)
def test70(self):
"""Verify dogbone angles"""
self.assertRoughly(180 * KINK("G1X1/G1Y+1").normAngle() / PI, -45)
self.assertRoughly(180 * KINK("G1X1/G1Y-1").normAngle() / PI, 45)
self.assertRoughly(180 * KINK("G1X1/G1X2Y1").normAngle() / PI, -67.5)
self.assertRoughly(180 * KINK("G1X1/G1X2Y-1").normAngle() / PI, 67.5)
self.assertRoughly(180 * KINK("G1Y1/G1X+1").normAngle() / PI, 135)
self.assertRoughly(180 * KINK("G1Y1/G1X-1").normAngle() / PI, 45)
self.assertRoughly(180 * KINK("G1X-1/G1Y+1").normAngle() / PI, -135)
self.assertRoughly(180 * KINK("G1X-1/G1Y-1").normAngle() / PI, 135)
self.assertRoughly(180 * KINK("G1Y-1/G1X-1").normAngle() / PI, -45)
self.assertRoughly(180 * KINK("G1Y-1/G1X+1").normAngle() / PI, -135)
def test71(self):
"""Verify dogbones"""
dogbone = GEN(dogboneII.GeneratorDogbone, 1)
bone = dogbone.generate(KINK("G1X1/G1Y1"))
self.assertBone(bone, "[G1{X: 1.7, Y: -0.71}, G1{X: 1.0, Y: 0.0}]", 2)
bone = dogbone.generate(KINK("G1X1/G1X3Y-1"))
self.assertBone(bone, "[G1{X: 1.2, Y: 0.97}, G1{X: 1.0, Y: 0.0}]", 2)
bone = dogbone.generate(KINK("G1X1Y1/G1X2"))
self.assertBone(bone, "[G1{X: 0.62, Y: 1.9}, G1{X: 1.0, Y: 1.0}]", 2)
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