create/src/Mod/Assembly/AssemblyTests/TestSolverIntegration.py

# SPDX-License-Identifier: LGPL-2.1-or-later
# /****************************************************************************
#                                                                           *
#    Copyright (c) 2025 Kindred Systems <development@kindred-systems.com>   *
#                                                                           *
#    This file is part of FreeCAD.                                          *
#                                                                           *
#    FreeCAD is free software: you can redistribute it and/or modify it     *
#    under the terms of the GNU Lesser General Public License as            *
#    published by the Free Software Foundation, either version 2.1 of the   *
#    License, or (at your option) any later version.                        *
#                                                                           *
#    FreeCAD 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       *
#    Lesser General Public License for more details.                        *
#                                                                           *
#    You should have received a copy of the GNU Lesser General Public       *
#    License along with FreeCAD. If not, see                                *
#    <https://www.gnu.org/licenses/>.                                       *
#                                                                           *
# ***************************************************************************/

"""
Solver integration tests for Phase 1e (KCSolve refactor).

These tests verify that the AssemblyObject → IKCSolver → OndselAdapter pipeline
produces correct results via the full FreeCAD stack. They complement the C++
unit tests in tests/src/Mod/Assembly/Solver/.
"""

import os
import tempfile
import unittest

import FreeCAD as App
import JointObject


class TestSolverIntegration(unittest.TestCase):
    """Full-stack solver regression tests exercising AssemblyObject.solve()."""

    def setUp(self):
        doc_name = self.__class__.__name__
        if App.ActiveDocument:
            if App.ActiveDocument.Name != doc_name:
                App.newDocument(doc_name)
        else:
            App.newDocument(doc_name)
        App.setActiveDocument(doc_name)
        self.doc = App.ActiveDocument

        self.assembly = self.doc.addObject("Assembly::AssemblyObject", "Assembly")
        self.jointgroup = self.assembly.newObject("Assembly::JointGroup", "Joints")

    def tearDown(self):
        App.closeDocument(self.doc.Name)

    # ── Helpers ─────────────────────────────────────────────────────

    def _make_box(self, x=0, y=0, z=0, size=10):
        """Create a Part::Box inside the assembly with a given offset."""
        box = self.assembly.newObject("Part::Box", "Box")
        box.Length = size
        box.Width = size
        box.Height = size
        box.Placement = App.Placement(App.Vector(x, y, z), App.Rotation())
        return box

    def _ground(self, obj):
        """Create a grounded joint for the given object."""
        gnd = self.jointgroup.newObject("App::FeaturePython", "GroundedJoint")
        JointObject.GroundedJoint(gnd, obj)
        return gnd

    def _make_joint(self, joint_type, ref1, ref2):
        """Create a joint of the given type connecting two (obj, subelements) pairs.

        joint_type: integer JointType enum value (0=Fixed, 1=Revolute, etc.)
        ref1, ref2: tuples of (obj, [sub_element, sub_element])
        """
        joint = self.jointgroup.newObject("App::FeaturePython", "Joint")
        JointObject.Joint(joint, joint_type)

        refs = [
            [ref1[0], ref1[1]],
            [ref2[0], ref2[1]],
        ]
        joint.Proxy.setJointConnectors(joint, refs)
        return joint

    # ── Tests ───────────────────────────────────────────────────────

    def test_solve_fixed_joint(self):
        """Two boxes + grounded + fixed joint → placements match."""
        box1 = self._make_box(10, 20, 30)
        box2 = self._make_box(40, 50, 60)
        self._ground(box2)

        # Fixed joint (type 0) connecting Face6+Vertex7 on each box.
        self._make_joint(
            0,
            [box2, ["Face6", "Vertex7"]],
            [box1, ["Face6", "Vertex7"]],
        )

        # After setJointConnectors, solve() was already called internally.
        # Verify that box1 moved to match box2.
        self.assertTrue(
            box1.Placement.isSame(box2.Placement, 1e-6),
            "Fixed joint: box1 should match box2 placement",
        )

    def test_solve_revolute_joint(self):
        """Two boxes + grounded + revolute joint → solve succeeds (return 0)."""
        box1 = self._make_box(0, 0, 0)
        box2 = self._make_box(100, 0, 0)
        self._ground(box1)

        # Revolute joint (type 1) connecting Face6+Vertex7.
        self._make_joint(
            1,
            [box1, ["Face6", "Vertex7"]],
            [box2, ["Face6", "Vertex7"]],
        )

        result = self.assembly.solve()
        self.assertEqual(result, 0, "Revolute joint solve should succeed")

    def test_solve_returns_code_for_no_ground(self):
        """Assembly with no grounded parts → solve returns -6."""
        box1 = self._make_box(0, 0, 0)
        box2 = self._make_box(50, 0, 0)

        # Fixed joint but no ground.
        joint = self.jointgroup.newObject("App::FeaturePython", "Joint")
        JointObject.Joint(joint, 0)
        refs = [
            [box1, ["Face6", "Vertex7"]],
            [box2, ["Face6", "Vertex7"]],
        ]
        joint.Proxy.setJointConnectors(joint, refs)

        result = self.assembly.solve()
        self.assertEqual(result, -6, "No grounded parts should return -6")

    def test_solve_returns_redundancy(self):
        """Over-constrained assembly → solve returns -2 (redundant)."""
        box1 = self._make_box(0, 0, 0)
        box2 = self._make_box(50, 0, 0)
        self._ground(box1)

        # Two fixed joints between the same faces → redundant.
        self._make_joint(
            0,
            [box1, ["Face6", "Vertex7"]],
            [box2, ["Face6", "Vertex7"]],
        )
        self._make_joint(
            0,
            [box1, ["Face5", "Vertex5"]],
            [box2, ["Face5", "Vertex5"]],
        )

        result = self.assembly.solve()
        self.assertEqual(result, -2, "Redundant constraints should return -2")

    def test_export_asmt(self):
        """exportAsASMT() produces a non-empty file."""
        box1 = self._make_box(0, 0, 0)
        box2 = self._make_box(50, 0, 0)
        self._ground(box1)

        self._make_joint(
            0,
            [box1, ["Face6", "Vertex7"]],
            [box2, ["Face6", "Vertex7"]],
        )

        self.assembly.solve()

        with tempfile.NamedTemporaryFile(suffix=".asmt", delete=False) as f:
            path = f.name

        try:
            self.assembly.exportAsASMT(path)
            self.assertTrue(os.path.exists(path), "ASMT file should exist")
            self.assertGreater(
                os.path.getsize(path), 0, "ASMT file should be non-empty"
            )
        finally:
            if os.path.exists(path):
                os.unlink(path)

    def test_solve_multiple_times_stable(self):
        """Solving the same assembly twice produces identical placements."""
        box1 = self._make_box(10, 20, 30)
        box2 = self._make_box(40, 50, 60)
        self._ground(box2)

        self._make_joint(
            0,
            [box2, ["Face6", "Vertex7"]],
            [box1, ["Face6", "Vertex7"]],
        )

        self.assembly.solve()
        plc_first = App.Placement(box1.Placement)

        self.assembly.solve()
        plc_second = box1.Placement

        self.assertTrue(
            plc_first.isSame(plc_second, 1e-6),
            "Deterministic solver should produce identical results",
        )