openmw/apps/openmw_test_suite/nifloader/testbulletnifloader.cpp

#include "../nif/node.hpp"

#include <components/bullethelpers/processtrianglecallback.hpp>
#include <components/nif/data.hpp>
#include <components/nif/extra.hpp>
#include <components/nif/node.hpp>
#include <components/nifbullet/bulletnifloader.hpp>

#include <BulletCollision/CollisionShapes/btBoxShape.h>
#include <BulletCollision/CollisionShapes/btCompoundShape.h>
#include <BulletCollision/CollisionShapes/btTriangleMesh.h>

#include <gmock/gmock.h>
#include <gtest/gtest.h>

#include <algorithm>
#include <type_traits>

namespace
{
    template <class T>
    bool compareObjects(const T* lhs, const T* rhs)
    {
        return (!lhs && !rhs) || (lhs && rhs && *lhs == *rhs);
    }

    std::vector<btVector3> getTriangles(const btBvhTriangleMeshShape& shape)
    {
        std::vector<btVector3> result;
        auto callback = BulletHelpers::makeProcessTriangleCallback([&](btVector3* triangle, int, int) {
            for (std::size_t i = 0; i < 3; ++i)
                result.push_back(triangle[i]);
        });
        btVector3 aabbMin;
        btVector3 aabbMax;
        shape.getAabb(btTransform::getIdentity(), aabbMin, aabbMax);
        shape.processAllTriangles(&callback, aabbMin, aabbMax);
        return result;
    }

    bool isNear(btScalar lhs, btScalar rhs)
    {
        return std::abs(lhs - rhs) <= 1e-5;
    }

    bool isNear(const btVector3& lhs, const btVector3& rhs)
    {
        return std::equal(static_cast<const btScalar*>(lhs), static_cast<const btScalar*>(lhs) + 3,
            static_cast<const btScalar*>(rhs), [](btScalar lhs, btScalar rhs) { return isNear(lhs, rhs); });
    }

    bool isNear(const btMatrix3x3& lhs, const btMatrix3x3& rhs)
    {
        for (int i = 0; i < 3; ++i)
            if (!isNear(lhs[i], rhs[i]))
                return false;
        return true;
    }

    bool isNear(const btTransform& lhs, const btTransform& rhs)
    {
        return isNear(lhs.getOrigin(), rhs.getOrigin()) && isNear(lhs.getBasis(), rhs.getBasis());
    }

    struct WriteVec3f
    {
        osg::Vec3f mValue;

        friend std::ostream& operator<<(std::ostream& stream, const WriteVec3f& value)
        {
            return stream << "osg::Vec3f {" << std::setprecision(std::numeric_limits<float>::max_exponent10)
                          << value.mValue.x() << ", " << std::setprecision(std::numeric_limits<float>::max_exponent10)
                          << value.mValue.y() << ", " << std::setprecision(std::numeric_limits<float>::max_exponent10)
                          << value.mValue.z() << "}";
        }
    };
}

static std::ostream& operator<<(std::ostream& stream, const btVector3& value)
{
    return stream << "btVector3 {" << std::setprecision(std::numeric_limits<float>::max_exponent10) << value.getX()
                  << ", " << std::setprecision(std::numeric_limits<float>::max_exponent10) << value.getY() << ", "
                  << std::setprecision(std::numeric_limits<float>::max_exponent10) << value.getZ() << "}";
}

static std::ostream& operator<<(std::ostream& stream, const btMatrix3x3& value)
{
    stream << "btMatrix3x3 {";
    for (int i = 0; i < 3; ++i)
        stream << value.getRow(i) << ", ";
    return stream << "}";
}

static std::ostream& operator<<(std::ostream& stream, const btTransform& value)
{
    return stream << "btTransform {" << value.getBasis() << ", " << value.getOrigin() << "}";
}

static std::ostream& operator<<(std::ostream& stream, const btCollisionShape* value);

static std::ostream& operator<<(std::ostream& stream, const btCompoundShape& value)
{
    stream << "btCompoundShape {" << value.getLocalScaling() << ", ";
    stream << "{";
    for (int i = 0; i < value.getNumChildShapes(); ++i)
        stream << value.getChildShape(i) << ", ";
    stream << "},";
    stream << "{";
    for (int i = 0; i < value.getNumChildShapes(); ++i)
        stream << value.getChildTransform(i) << ", ";
    stream << "}";
    return stream << "}";
}

static std::ostream& operator<<(std::ostream& stream, const btBoxShape& value)
{
    return stream << "btBoxShape {" << value.getLocalScaling() << ", " << value.getHalfExtentsWithoutMargin() << "}";
}

namespace Resource
{

    static std::ostream& operator<<(std::ostream& stream, const TriangleMeshShape& value)
    {
        stream << "Resource::TriangleMeshShape {" << value.getLocalScaling() << ", "
               << value.usesQuantizedAabbCompression() << ", " << value.getOwnsBvh() << ", {";
        auto callback = BulletHelpers::makeProcessTriangleCallback([&](btVector3* triangle, int, int) {
            for (std::size_t i = 0; i < 3; ++i)
                stream << triangle[i] << ", ";
        });
        btVector3 aabbMin;
        btVector3 aabbMax;
        value.getAabb(btTransform::getIdentity(), aabbMin, aabbMax);
        value.processAllTriangles(&callback, aabbMin, aabbMax);
        return stream << "}}";
    }

    static bool operator==(const CollisionBox& l, const CollisionBox& r)
    {
        const auto tie = [](const CollisionBox& v) { return std::tie(v.mExtents, v.mCenter); };
        return tie(l) == tie(r);
    }

    static std::ostream& operator<<(std::ostream& stream, const CollisionBox& value)
    {
        return stream << "CollisionBox {" << WriteVec3f{ value.mExtents } << ", " << WriteVec3f{ value.mCenter } << "}";
    }

}

static std::ostream& operator<<(std::ostream& stream, const btCollisionShape& value)
{
    switch (value.getShapeType())
    {
        case COMPOUND_SHAPE_PROXYTYPE:
            return stream << static_cast<const btCompoundShape&>(value);
        case BOX_SHAPE_PROXYTYPE:
            return stream << static_cast<const btBoxShape&>(value);
        case TRIANGLE_MESH_SHAPE_PROXYTYPE:
            if (const auto casted = dynamic_cast<const Resource::TriangleMeshShape*>(&value))
                return stream << *casted;
            break;
    }
    return stream << "btCollisionShape {" << value.getShapeType() << "}";
}

static std::ostream& operator<<(std::ostream& stream, const btCollisionShape* value)
{
    return value ? stream << "&" << *value : stream << "nullptr";
}

namespace std
{
    static std::ostream& operator<<(std::ostream& stream, const map<int, int>& value)
    {
        stream << "std::map<int, int> {";
        for (const auto& v : value)
            stream << "{" << v.first << ", " << v.second << "},";
        return stream << "}";
    }
}

namespace Resource
{
    static bool operator==(const Resource::BulletShape& lhs, const Resource::BulletShape& rhs)
    {
        return compareObjects(lhs.mCollisionShape.get(), rhs.mCollisionShape.get())
            && compareObjects(lhs.mAvoidCollisionShape.get(), rhs.mAvoidCollisionShape.get())
            && lhs.mCollisionBox == rhs.mCollisionBox && lhs.mVisualCollisionType == rhs.mVisualCollisionType
            && lhs.mAnimatedShapes == rhs.mAnimatedShapes;
    }

    static std::ostream& operator<<(std::ostream& stream, Resource::VisualCollisionType value)
    {
        switch (value)
        {
            case Resource::VisualCollisionType::None:
                return stream << "Resource::VisualCollisionType::None";
            case Resource::VisualCollisionType::Default:
                return stream << "Resource::VisualCollisionType::Default";
            case Resource::VisualCollisionType::Camera:
                return stream << "Resource::VisualCollisionType::Camera";
        }
        return stream << static_cast<std::underlying_type_t<Resource::VisualCollisionType>>(value);
    }

    static std::ostream& operator<<(std::ostream& stream, const Resource::BulletShape& value)
    {
        return stream << "Resource::BulletShape {" << value.mCollisionShape.get() << ", "
                      << value.mAvoidCollisionShape.get() << ", " << value.mCollisionBox << ", "
                      << value.mAnimatedShapes << ", " << value.mVisualCollisionType << "}";
    }
}

static bool operator==(const btCollisionShape& lhs, const btCollisionShape& rhs);

static bool operator==(const btCompoundShape& lhs, const btCompoundShape& rhs)
{
    if (lhs.getNumChildShapes() != rhs.getNumChildShapes() || lhs.getLocalScaling() != rhs.getLocalScaling())
        return false;
    for (int i = 0; i < lhs.getNumChildShapes(); ++i)
    {
        if (!compareObjects(lhs.getChildShape(i), rhs.getChildShape(i))
            || !isNear(lhs.getChildTransform(i), rhs.getChildTransform(i)))
            return false;
    }
    return true;
}

static bool operator==(const btBoxShape& lhs, const btBoxShape& rhs)
{
    return isNear(lhs.getLocalScaling(), rhs.getLocalScaling())
        && lhs.getHalfExtentsWithoutMargin() == rhs.getHalfExtentsWithoutMargin();
}

static bool operator==(const btBvhTriangleMeshShape& lhs, const btBvhTriangleMeshShape& rhs)
{
    return isNear(lhs.getLocalScaling(), rhs.getLocalScaling())
        && lhs.usesQuantizedAabbCompression() == rhs.usesQuantizedAabbCompression()
        && lhs.getOwnsBvh() == rhs.getOwnsBvh() && getTriangles(lhs) == getTriangles(rhs);
}

static bool operator==(const btCollisionShape& lhs, const btCollisionShape& rhs)
{
    if (lhs.getShapeType() != rhs.getShapeType())
        return false;
    switch (lhs.getShapeType())
    {
        case COMPOUND_SHAPE_PROXYTYPE:
            return static_cast<const btCompoundShape&>(lhs) == static_cast<const btCompoundShape&>(rhs);
        case BOX_SHAPE_PROXYTYPE:
            return static_cast<const btBoxShape&>(lhs) == static_cast<const btBoxShape&>(rhs);
        case TRIANGLE_MESH_SHAPE_PROXYTYPE:
            if (const auto lhsCasted = dynamic_cast<const Resource::TriangleMeshShape*>(&lhs))
                if (const auto rhsCasted = dynamic_cast<const Resource::TriangleMeshShape*>(&rhs))
                    return *lhsCasted == *rhsCasted;
            return false;
    }
    return false;
}

namespace
{
    using namespace testing;
    using namespace Nif::Testing;
    using NifBullet::BulletNifLoader;

    void copy(const btTransform& src, Nif::Transformation& dst)
    {
        dst.pos = osg::Vec3f(src.getOrigin().x(), src.getOrigin().y(), src.getOrigin().z());
        for (int row = 0; row < 3; ++row)
            for (int column = 0; column < 3; ++column)
                dst.rotation.mValues[column][row] = src.getBasis().getRow(row)[column];
    }

    struct TestBulletNifLoader : Test
    {
        BulletNifLoader mLoader;
        Nif::Node mNode;
        Nif::Node mNode2;
        Nif::NiNode mNiNode;
        Nif::NiNode mNiNode2;
        Nif::NiNode mNiNode3;
        Nif::NiTriShapeData mNiTriShapeData;
        Nif::NiTriShape mNiTriShape;
        Nif::NiTriShapeData mNiTriShapeData2;
        Nif::NiTriShape mNiTriShape2;
        Nif::NiTriStripsData mNiTriStripsData;
        Nif::NiTriStrips mNiTriStrips;
        Nif::NiSkinInstance mNiSkinInstance;
        Nif::NiStringExtraData mNiStringExtraData;
        Nif::NiStringExtraData mNiStringExtraData2;
        Nif::Controller mController;
        btTransform mTransform{ btMatrix3x3(btQuaternion(btVector3(1, 0, 0), 0.5f)), btVector3(1, 2, 3) };
        btTransform mResultTransform{ btMatrix3x3(1, 0, 0, 0, 0.82417738437652587890625, 0.56633174419403076171875, 0,
                                          -0.56633174419403076171875, 0.82417738437652587890625),
            btVector3(1, 2, 3) };
        btTransform mResultTransform2{ btMatrix3x3(1, 0, 0, 0, 0.7951543331146240234375, 0.606407105922698974609375, 0,
                                           -0.606407105922698974609375, 0.7951543331146240234375),
            btVector3(4, 8, 12) };
        const std::string mHash = "hash";

        TestBulletNifLoader()
        {
            init(mNode);
            init(mNode2);
            init(mNiNode);
            init(mNiNode2);
            init(mNiNode3);
            init(mNiTriShape);
            init(mNiTriShape2);
            init(mNiTriStrips);
            init(mNiSkinInstance);
            init(mNiStringExtraData);
            init(mNiStringExtraData2);
            init(mController);

            mNiTriShapeData.recType = Nif::RC_NiTriShapeData;
            mNiTriShapeData.vertices = { osg::Vec3f(0, 0, 0), osg::Vec3f(1, 0, 0), osg::Vec3f(1, 1, 0) };
            mNiTriShapeData.triangles = { 0, 1, 2 };
            mNiTriShape.data = Nif::NiGeometryDataPtr(&mNiTriShapeData);

            mNiTriShapeData2.recType = Nif::RC_NiTriShapeData;
            mNiTriShapeData2.vertices = { osg::Vec3f(0, 0, 1), osg::Vec3f(1, 0, 1), osg::Vec3f(1, 1, 1) };
            mNiTriShapeData2.triangles = { 0, 1, 2 };
            mNiTriShape2.data = Nif::NiGeometryDataPtr(&mNiTriShapeData2);

            mNiTriStripsData.recType = Nif::RC_NiTriStripsData;
            mNiTriStripsData.vertices
                = { osg::Vec3f(0, 0, 0), osg::Vec3f(1, 0, 0), osg::Vec3f(1, 1, 0), osg::Vec3f(0, 1, 0) };
            mNiTriStripsData.strips = { { 0, 1, 2, 3 } };
            mNiTriStrips.data = Nif::NiGeometryDataPtr(&mNiTriStripsData);
        }
    };

    TEST_F(TestBulletNifLoader, for_zero_num_roots_should_return_default)
    {
        Nif::NIFFile file("test.nif");
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
        EXPECT_EQ(result->mFileName, "test.nif");
        EXPECT_EQ(result->mFileHash, mHash);
    }

    TEST_F(TestBulletNifLoader, should_ignore_nullptr_root)
    {
        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(nullptr);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_default_root_nif_node_should_return_default)
    {
        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_default_root_collision_node_nif_node_should_return_default)
    {
        mNode.recType = Nif::RC_RootCollisionNode;

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_default_root_nif_node_and_filename_starting_with_x_should_return_default)
    {
        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(
        TestBulletNifLoader, for_root_nif_node_with_bounding_box_should_return_shape_with_compound_shape_and_box_inside)
    {
        mNode.hasBounds = true;
        mNode.flags |= Nif::Node::Flag_BBoxCollision;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);
        std::unique_ptr<btBoxShape> box(new btBoxShape(btVector3(1, 2, 3)));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(btTransform(btMatrix3x3::getIdentity(), btVector3(-1, -2, -3)), box.release());
        expected.mCollisionShape.reset(shape.release());

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_child_nif_node_with_bounding_box)
    {
        mNode.hasBounds = true;
        mNode.flags |= Nif::Node::Flag_BBoxCollision;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);
        mNode.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNode) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);
        std::unique_ptr<btBoxShape> box(new btBoxShape(btVector3(1, 2, 3)));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(btTransform(btMatrix3x3::getIdentity(), btVector3(-1, -2, -3)), box.release());
        expected.mCollisionShape.reset(shape.release());

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_root_and_child_nif_node_with_bounding_box_but_root_without_flag_should_use_child_bounds)
    {
        mNode.hasBounds = true;
        mNode.flags |= Nif::Node::Flag_BBoxCollision;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);
        mNode.parents.push_back(&mNiNode);

        mNiNode.hasBounds = true;
        mNiNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNiNode.bounds.box.extents = osg::Vec3f(4, 5, 6);
        mNiNode.bounds.box.center = osg::Vec3f(-4, -5, -6);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNode) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);
        std::unique_ptr<btBoxShape> box(new btBoxShape(btVector3(1, 2, 3)));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(btTransform(btMatrix3x3::getIdentity(), btVector3(-1, -2, -3)), box.release());
        expected.mCollisionShape.reset(shape.release());

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_root_and_two_children_where_both_with_bounds_but_only_first_with_flag_should_use_first_bounds)
    {
        mNode.hasBounds = true;
        mNode.flags |= Nif::Node::Flag_BBoxCollision;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);
        mNode.parents.push_back(&mNiNode);

        mNode2.hasBounds = true;
        mNode2.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode2.bounds.box.extents = osg::Vec3f(4, 5, 6);
        mNode2.bounds.box.center = osg::Vec3f(-4, -5, -6);
        mNode2.parents.push_back(&mNiNode);

        mNiNode.hasBounds = true;
        mNiNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNiNode.bounds.box.extents = osg::Vec3f(7, 8, 9);
        mNiNode.bounds.box.center = osg::Vec3f(-7, -8, -9);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNode), Nif::NodePtr(&mNode2) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);
        std::unique_ptr<btBoxShape> box(new btBoxShape(btVector3(1, 2, 3)));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(btTransform(btMatrix3x3::getIdentity(), btVector3(-1, -2, -3)), box.release());
        expected.mCollisionShape.reset(shape.release());

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_root_and_two_children_where_both_with_bounds_but_only_second_with_flag_should_use_second_bounds)
    {
        mNode.hasBounds = true;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);
        mNode.parents.push_back(&mNiNode);

        mNode2.hasBounds = true;
        mNode2.flags |= Nif::Node::Flag_BBoxCollision;
        mNode2.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode2.bounds.box.extents = osg::Vec3f(4, 5, 6);
        mNode2.bounds.box.center = osg::Vec3f(-4, -5, -6);
        mNode2.parents.push_back(&mNiNode);

        mNiNode.hasBounds = true;
        mNiNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNiNode.bounds.box.extents = osg::Vec3f(7, 8, 9);
        mNiNode.bounds.box.center = osg::Vec3f(-7, -8, -9);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNode), Nif::NodePtr(&mNode2) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(4, 5, 6);
        expected.mCollisionBox.mCenter = osg::Vec3f(-4, -5, -6);
        std::unique_ptr<btBoxShape> box(new btBoxShape(btVector3(4, 5, 6)));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(btTransform(btMatrix3x3::getIdentity(), btVector3(-4, -5, -6)), box.release());
        expected.mCollisionShape.reset(shape.release());

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_root_nif_node_with_bounds_but_without_flag_should_return_shape_with_bounds_but_with_null_collision_shape)
    {
        mNode.hasBounds = true;
        mNode.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNode.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNode.bounds.box.center = osg::Vec3f(-1, -2, -3);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_tri_shape_root_node_should_return_shape_with_triangle_mesh_shape)
    {
        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriShape);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_root_node_with_bounds_should_return_shape_with_bounds_but_with_null_collision_shape)
    {
        mNiTriShape.hasBounds = true;
        mNiTriShape.bounds.type = Nif::NiBoundingVolume::Type::BOX_BV;
        mNiTriShape.bounds.box.extents = osg::Vec3f(1, 2, 3);
        mNiTriShape.bounds.box.center = osg::Vec3f(-1, -2, -3);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriShape);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;
        expected.mCollisionBox.mExtents = osg::Vec3f(1, 2, 3);
        expected.mCollisionBox.mCenter = osg::Vec3f(-1, -2, -3);

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_tri_shape_child_node_should_return_shape_with_triangle_mesh_shape)
    {
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_nested_tri_shape_child_should_return_shape_with_triangle_mesh_shape)
    {
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiNode2) }));
        mNiNode2.parents.push_back(&mNiNode);
        mNiNode2.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiTriShape.parents.push_back(&mNiNode2);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_two_tri_shape_children_should_return_shape_with_triangle_mesh_shape_with_all_meshes)
    {
        mNiTriShape.parents.push_back(&mNiNode);
        mNiTriShape2.parents.push_back(&mNiNode);
        mNiNode.children
            = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape), Nif::NodePtr(&mNiTriShape2) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 1), btVector3(1, 0, 1), btVector3(1, 1, 1));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_and_filename_starting_with_x_and_not_empty_skin_should_return_shape_with_triangle_mesh_shape)
    {
        mNiTriShape.skin = Nif::NiSkinInstancePtr(&mNiSkinInstance);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_root_node_and_filename_starting_with_x_should_return_shape_with_compound_shape)
    {
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 3;

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiTriShape);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh(new Resource::TriangleMeshShape(triangles.release(), true));
        mesh->setLocalScaling(btVector3(3, 3, 3));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(mResultTransform, mesh.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_and_filename_starting_with_x_should_return_shape_with_compound_shape)
    {
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 3;
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode.trafo.scale = 4;

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh(new Resource::TriangleMeshShape(triangles.release(), true));
        mesh->setLocalScaling(btVector3(12, 12, 12));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(mResultTransform2, mesh.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_two_tri_shape_children_nodes_and_filename_starting_with_x_should_return_shape_with_compound_shape)
    {
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 3;
        mNiTriShape.parents.push_back(&mNiNode);

        copy(mTransform, mNiTriShape2.trafo);
        mNiTriShape2.trafo.scale = 3;
        mNiTriShape2.parents.push_back(&mNiNode);

        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({
            Nif::NodePtr(&mNiTriShape),
            Nif::NodePtr(&mNiTriShape2),
        }));

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh(new Resource::TriangleMeshShape(triangles.release(), true));
        mesh->setLocalScaling(btVector3(3, 3, 3));

        std::unique_ptr<btTriangleMesh> triangles2(new btTriangleMesh(false));
        triangles2->addTriangle(btVector3(0, 0, 1), btVector3(1, 0, 1), btVector3(1, 1, 1));
        std::unique_ptr<Resource::TriangleMeshShape> mesh2(new Resource::TriangleMeshShape(triangles2.release(), true));
        mesh2->setLocalScaling(btVector3(3, 3, 3));

        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(mResultTransform, mesh.release());
        shape->addChildShape(mResultTransform, mesh2.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_tri_shape_child_node_with_controller_should_return_shape_with_compound_shape)
    {
        mController.recType = Nif::RC_NiKeyframeController;
        mController.flags |= Nif::Controller::Flag_Active;
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 3;
        mNiTriShape.parents.push_back(&mNiNode);
        mNiTriShape.controller = Nif::ControllerPtr(&mController);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode.trafo.scale = 4;

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh(new Resource::TriangleMeshShape(triangles.release(), true));
        mesh->setLocalScaling(btVector3(12, 12, 12));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(mResultTransform2, mesh.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_two_tri_shape_children_nodes_where_one_with_controller_should_return_shape_with_compound_shape)
    {
        mController.recType = Nif::RC_NiKeyframeController;
        mController.flags |= Nif::Controller::Flag_Active;
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 3;
        mNiTriShape.parents.push_back(&mNiNode);
        copy(mTransform, mNiTriShape2.trafo);
        mNiTriShape2.trafo.scale = 3;
        mNiTriShape2.parents.push_back(&mNiNode);
        mNiTriShape2.controller = Nif::ControllerPtr(&mController);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({
            Nif::NodePtr(&mNiTriShape),
            Nif::NodePtr(&mNiTriShape2),
        }));
        mNiNode.trafo.scale = 4;

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(
            btVector3(4, 8, 12), btVector3(16, 8, 12), btVector3(16, 18.5309906005859375, 6.246893405914306640625));
        std::unique_ptr<Resource::TriangleMeshShape> mesh(new Resource::TriangleMeshShape(triangles.release(), true));
        mesh->setLocalScaling(btVector3(1, 1, 1));

        std::unique_ptr<btTriangleMesh> triangles2(new btTriangleMesh(false));
        triangles2->addTriangle(btVector3(0, 0, 1), btVector3(1, 0, 1), btVector3(1, 1, 1));
        std::unique_ptr<Resource::TriangleMeshShape> mesh2(new Resource::TriangleMeshShape(triangles2.release(), true));
        mesh2->setLocalScaling(btVector3(12, 12, 12));

        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        shape->addChildShape(mResultTransform2, mesh2.release());
        shape->addChildShape(btTransform::getIdentity(), mesh.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_add_static_mesh_to_existing_compound_mesh)
    {
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mRoots.push_back(&mNiTriShape2);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));

        std::unique_ptr<btTriangleMesh> triangles2(new btTriangleMesh(false));
        triangles2->addTriangle(btVector3(0, 0, 1), btVector3(1, 0, 1), btVector3(1, 1, 1));

        std::unique_ptr<btCompoundShape> compound(new btCompoundShape);
        compound->addChildShape(btTransform::getIdentity(), new Resource::TriangleMeshShape(triangles.release(), true));
        compound->addChildShape(
            btTransform::getIdentity(), new Resource::TriangleMeshShape(triangles2.release(), true));

        Resource::BulletShape expected;
        expected.mCollisionShape.reset(compound.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(
        TestBulletNifLoader, for_root_avoid_node_and_tri_shape_child_node_should_return_shape_with_null_collision_shape)
    {
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode.recType = Nif::RC_AvoidNode;

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mAvoidCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), false));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_tri_shape_child_node_with_empty_data_should_return_shape_with_null_collision_shape)
    {
        mNiTriShape.data = Nif::NiGeometryDataPtr(nullptr);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_empty_data_triangles_should_return_shape_with_null_collision_shape)
    {
        auto data = static_cast<Nif::NiTriShapeData*>(mNiTriShape.data.getPtr());
        data->triangles.clear();
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_extra_data_string_equal_ncc_should_return_shape_with_cameraonly_collision)
    {
        mNiStringExtraData.string = "NCC__";
        mNiStringExtraData.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));
        expected.mVisualCollisionType = Resource::VisualCollisionType::Camera;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_not_first_extra_data_string_equal_ncc_should_return_shape_with_cameraonly_collision)
    {
        mNiStringExtraData.next = Nif::ExtraPtr(&mNiStringExtraData2);
        mNiStringExtraData2.string = "NCC__";
        mNiStringExtraData2.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));
        expected.mVisualCollisionType = Resource::VisualCollisionType::Camera;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_extra_data_string_starting_with_nc_should_return_shape_with_nocollision)
    {
        mNiStringExtraData.string = "NC___";
        mNiStringExtraData.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));
        expected.mVisualCollisionType = Resource::VisualCollisionType::Default;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_not_first_extra_data_string_starting_with_nc_should_return_shape_with_nocollision)
    {
        mNiStringExtraData.next = Nif::ExtraPtr(&mNiStringExtraData2);
        mNiStringExtraData2.string = "NC___";
        mNiStringExtraData2.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));
        expected.mVisualCollisionType = Resource::VisualCollisionType::Default;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_empty_root_collision_node_without_nc_should_return_shape_with_cameraonly_collision)
    {
        Nif::NiTriShape niTriShape;
        Nif::NiNode emptyCollisionNode;
        init(niTriShape);
        init(emptyCollisionNode);

        niTriShape.data = Nif::NiGeometryDataPtr(&mNiTriShapeData);
        niTriShape.parents.push_back(&mNiNode);

        emptyCollisionNode.recType = Nif::RC_RootCollisionNode;
        emptyCollisionNode.parents.push_back(&mNiNode);

        mNiNode.children = Nif::NodeList(
            std::vector<Nif::NodePtr>({ Nif::NodePtr(&niTriShape), Nif::NodePtr(&emptyCollisionNode) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));
        expected.mVisualCollisionType = Resource::VisualCollisionType::Camera;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_extra_data_string_mrk_should_return_shape_with_null_collision_shape)
    {
        mNiStringExtraData.string = "MRK";
        mNiStringExtraData.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader,
        for_tri_shape_child_node_with_extra_data_string_mrk_and_other_collision_node_should_return_shape_with_triangle_mesh_shape_with_all_meshes)
    {
        mNiStringExtraData.string = "MRK";
        mNiStringExtraData.recType = Nif::RC_NiStringExtraData;
        mNiTriShape.extra = Nif::ExtraPtr(&mNiStringExtraData);
        mNiTriShape.parents.push_back(&mNiNode2);
        mNiNode2.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode2.recType = Nif::RC_RootCollisionNode;
        mNiNode2.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiNode2) }));
        mNiNode.recType = Nif::RC_NiNode;

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_ignore_tri_shape_data_with_mismatching_data_rec_type)
    {
        mNiTriShape.data = Nif::NiGeometryDataPtr(&mNiTriStripsData);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriShape);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_tri_strips_root_node_should_return_shape_with_triangle_mesh_shape)
    {
        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        triangles->addTriangle(btVector3(1, 0, 0), btVector3(0, 1, 0), btVector3(1, 1, 0));
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(new Resource::TriangleMeshShape(triangles.release(), true));

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_ignore_tri_strips_data_with_mismatching_data_rec_type)
    {
        mNiTriStrips.data = Nif::NiGeometryDataPtr(&mNiTriShapeData);

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_ignore_tri_strips_data_with_empty_strips)
    {
        mNiTriStripsData.strips.clear();

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_static_mesh_should_ignore_tri_strips_data_with_less_than_3_strips)
    {
        mNiTriStripsData.strips.front() = { 0, 1 };

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_avoid_collision_mesh_should_ignore_tri_strips_data_with_less_than_3_strips)
    {
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode.recType = Nif::RC_AvoidNode;
        mNiTriStripsData.strips.front() = { 0, 1 };

        Nif::NIFFile file("test.nif");
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, for_animated_mesh_should_ignore_tri_strips_data_with_less_than_3_strips)
    {
        mNiTriStripsData.strips.front() = { 0, 1 };
        mNiTriStrips.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriStrips) }));

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        const Resource::BulletShape expected;

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_not_add_static_mesh_with_no_triangles_to_compound_shape)
    {
        mNiTriStripsData.strips.front() = { 0, 1 };
        mNiTriShape.parents.push_back(&mNiNode);
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mRoots.push_back(&mNiTriStrips);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles(new btTriangleMesh(false));
        triangles->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));

        std::unique_ptr<btCompoundShape> compound(new btCompoundShape);
        compound->addChildShape(btTransform::getIdentity(), new Resource::TriangleMeshShape(triangles.release(), true));

        Resource::BulletShape expected;
        expected.mCollisionShape.reset(compound.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }

    TEST_F(TestBulletNifLoader, should_handle_node_with_multiple_parents)
    {
        copy(mTransform, mNiTriShape.trafo);
        mNiTriShape.trafo.scale = 4;
        mNiTriShape.parents = { &mNiNode, &mNiNode2 };
        mNiNode.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode.trafo.scale = 2;
        mNiNode2.children = Nif::NodeList(std::vector<Nif::NodePtr>({ Nif::NodePtr(&mNiTriShape) }));
        mNiNode2.trafo.scale = 3;

        Nif::NIFFile file("xtest.nif");
        file.mRoots.push_back(&mNiNode);
        file.mRoots.push_back(&mNiNode2);
        file.mHash = mHash;

        const auto result = mLoader.load(file);

        std::unique_ptr<btTriangleMesh> triangles1(new btTriangleMesh(false));
        triangles1->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh1(new Resource::TriangleMeshShape(triangles1.release(), true));
        mesh1->setLocalScaling(btVector3(8, 8, 8));
        std::unique_ptr<btTriangleMesh> triangles2(new btTriangleMesh(false));
        triangles2->addTriangle(btVector3(0, 0, 0), btVector3(1, 0, 0), btVector3(1, 1, 0));
        std::unique_ptr<Resource::TriangleMeshShape> mesh2(new Resource::TriangleMeshShape(triangles2.release(), true));
        mesh2->setLocalScaling(btVector3(12, 12, 12));
        std::unique_ptr<btCompoundShape> shape(new btCompoundShape);
        const btTransform transform1{
            btMatrix3x3(1, 0, 0, 0, 0.8004512795493964327775415767973754555, 0.59939782204119995689950428641168400645,
                0, -0.59939782204119995689950428641168400645, 0.8004512795493964327775415767973754555),
            btVector3(2, 4, 6)
        };
        const btTransform transform2{
            btMatrix3x3(1, 0, 0, 0, 0.79515431915808965079861536651151254773, 0.60640713116208888600056070572463795543,
                0, -0.60640713116208888600056070572463795543, 0.79515431915808965079861536651151254773),
            btVector3(3, 6, 9)
        };
        shape->addChildShape(transform1, mesh1.release());
        shape->addChildShape(transform2, mesh2.release());
        Resource::BulletShape expected;
        expected.mCollisionShape.reset(shape.release());
        expected.mAnimatedShapes = { { -1, 0 } };

        EXPECT_EQ(*result, expected);
    }
}