added method to get camera matrix

clarified interfaces
Merge pull request #182 from orange-cpp/feature/camera_upgrade
2026-04-19 11:03:27 +00:00 · 2026-04-18 15:40:38 +03:00 · 2026-04-18 12:54:37 +03:00 · 2026-04-15 18:59:18 +03:00 · 2026-04-15 03:48:03 +03:00 · 2026-04-15 03:38:02 +03:00
23 changed files with 2071 additions and 63 deletions
--- a/.claude/settings.local.json
+++ b/.claude/settings.local.json
@@ -1,7 +0,0 @@
 {
  "permissions": {
    "allow": [
      "Bash(ls:*)"
    ]
  }
 }
--- a/.idea/editor.xml
+++ b/.idea/editor.xml
@@ -17,7 +17,7 @@
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBoostFormatTooManyArgs/@EntryIndexedValue" value="WARNING" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCStyleCast/@EntryIndexedValue" value="SUGGESTION" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCVQualifierCanNotBeAppliedToReference/@EntryIndexedValue" value="WARNING" type="string" />
-    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassCanBeFinal/@EntryIndexedValue" value="WARNING" type="string" />
+    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassCanBeFinal/@EntryIndexedValue" value="DO_NOT_SHOW" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassIsIncomplete/@EntryIndexedValue" value="WARNING" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeedsConstructorBecauseOfUninitializedMember/@EntryIndexedValue" value="WARNING" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
@@ -110,7 +110,7 @@
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLambdaCaptureNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMayBeConst/@EntryIndexedValue" value="HINT" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMightNotBeInitialized/@EntryIndexedValue" value="WARNING" type="string" />
-    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableWithNonTrivialDtorIsNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
+    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableWithNonTrivialDtorIsNeverUsed/@EntryIndexedValue" value="DO_NOT_SHOW" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLongFloat/@EntryIndexedValue" value="WARNING" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeConst/@EntryIndexedValue" value="SUGGESTION" type="string" />
    <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeStatic/@EntryIndexedValue" value="SUGGESTION" type="string" />
--- a/CONTRIBUTING.md
+++ b/CONTRIBUTING.md
@@ -1,32 +1,36 @@
-## 🤝 Contributing to OMath or other Orange's Projects
+# Contributing
-### ❕ Prerequisites
+## Prerequisites
- A working up-to-date OMath installation
+- C++ compiler with C++23 support (Clang 18+, GCC 14+, MSVC 19.38+)
- C++ knowledge
+- CMake 3.25+
- Git knowledge
+- Git
- Ability to ask for help (Feel free to create empty pull-request or PM a maintainer
+- Familiarity with the codebase (see `INSTALL.md` for setup)
  in [Telegram](https://t.me/orange_cpp))
-### ⏬ Setting up OMath
+For questions, create a draft PR or reach out via [Telegram](https://t.me/orange_cpp).
-Please read INSTALL.md file in repository
+## Workflow
-### 🔀 Pull requests and Branches
+1. [Fork](https://docs.github.com/en/pull-requests/collaborating-with-pull-requests/working-with-forks/fork-a-repo) the repository.
 2. Create a feature branch from `main`.
 3. Make your changes, ensuring tests pass.
 4. Open a [pull request](https://docs.github.com/en/pull-requests/collaborating-with-pull-requests/proposing-changes-to-your-work-with-pull-requests/creating-a-pull-request-from-a-fork) against `main`.
-In order to send code back to the official OMath repository, you must first create a copy of OMath on your github
+## Code Style
 account ([fork](https://help.github.com/articles/creating-a-pull-request-from-a-fork/)) and
 then [create a pull request](https://help.github.com/articles/creating-a-pull-request-from-a-fork/) back to OMath.
-OMath development is performed on multiple branches. Changes are then pull requested into master. By default, changes
+Follow the project `.clang-format`. Run `clang-format` before committing.
 merged into master will not roll out to stable build users unless the `stable` tag is updated.
-### 📜 Code-Style
+## Building
-The orange code-style can be found in `.clang-format`.
+Use one of the CMake presets defined in `CMakePresets.json`:
-### 📦 Building
+```bash
 cmake --preset <preset-name> -DOMATH_BUILD_TESTS=ON
 cmake --build --preset <preset-name>
 ```
-OMath has already created the  `cmake-build` and `out` directories where cmake/bin files are located. By default, you
+Run `cmake --list-presets` to see available configurations.
-can build OMath by running `cmake --build cmake-build/build/windows-release --target omath -j 6` in the source
+
-directory.
+## Tests
 All new functionality must include unit tests. Run the test binary after building to verify nothing is broken.
--- a/examples/example_barycentric/example_barycentric.cpp
+++ b/examples/example_barycentric/example_barycentric.cpp
@@ -71,18 +71,18 @@ void drawChar(char c, float x, float y, float scale, const Color& color, std::ve
        lines.push_back(x + x1 * w);
        lines.push_back(y + y1 * h);
        lines.push_back(0.0f);
-        lines.push_back(color.x);
+        lines.push_back(color.value().x);
-        lines.push_back(color.y);
+        lines.push_back(color.value().y);
-        lines.push_back(color.z);
+        lines.push_back(color.value().z);
        lines.push_back(1.0f); // size
        lines.push_back(1.0f); // isLine
        lines.push_back(x + x2 * w);
        lines.push_back(y + y2 * h);
        lines.push_back(0.0f);
-        lines.push_back(color.x);
+        lines.push_back(color.value().x);
-        lines.push_back(color.y);
+        lines.push_back(color.value().y);
-        lines.push_back(color.z);
+        lines.push_back(color.value().z);
        lines.push_back(1.0f); // size
        lines.push_back(1.0f); // isLine
    };
--- a/examples/example_glfw3/example_glfw3.cpp
+++ b/examples/example_glfw3/example_glfw3.cpp
@@ -318,22 +318,22 @@ int main()
        glfwPollEvents();
        omath::Vector3<float> move_dir;
        if (glfwGetKey(window, GLFW_KEY_W))
-            move_dir += camera.get_forward();
+            move_dir += camera.get_abs_forward();
        if (glfwGetKey(window, GLFW_KEY_A))
-            move_dir -= camera.get_right();
+            move_dir -= camera.get_abs_right();
        if (glfwGetKey(window, GLFW_KEY_S))
-            move_dir -= camera.get_forward();
+            move_dir -= camera.get_abs_forward();
        if (glfwGetKey(window, GLFW_KEY_D))
-            move_dir += camera.get_right();
+            move_dir += camera.get_abs_right();
        if (glfwGetKey(window, GLFW_KEY_SPACE))
-            move_dir += camera.get_up();
+            move_dir += camera.get_abs_up();
        if (glfwGetKey(window, GLFW_KEY_LEFT_CONTROL))
-            move_dir -= camera.get_up();
+            move_dir -= camera.get_abs_up();
        auto delta = glfwGetTime() - old_mouse_time;
--- a/include/omath/3d_primitives/aabb.hpp
+++ b/include/omath/3d_primitives/aabb.hpp
@@ -0,0 +1,28 @@
 //
 // Created by Vladislav on 24.03.2026.
 //
 #pragma once
 #include "omath/linear_algebra/vector3.hpp"
 namespace omath::primitives
 {
    template<class Type>
    struct Aabb final
    {
        Vector3<Type> min;
        Vector3<Type> max;
        [[nodiscard]]
        constexpr Vector3<Type> center() const noexcept
        {
            return (min + max) / static_cast<Type>(2);
        }
        [[nodiscard]]
        constexpr Vector3<Type> extents() const noexcept
        {
            return (max - min) / static_cast<Type>(2);
        }
    };
 } // namespace omath::primitives
--- a/include/omath/collision/line_tracer.hpp
+++ b/include/omath/collision/line_tracer.hpp
@@ -3,6 +3,7 @@
 //
 #pragma once
 #include "omath/3d_primitives/aabb.hpp"
 #include "omath/linear_algebra/triangle.hpp"
 #include "omath/linear_algebra/vector3.hpp"
@@ -34,6 +35,7 @@ namespace omath::collision
    class LineTracer final
    {
        using TriangleType = Triangle<typename RayType::VectorType>;
        using AABBType = primitives::Aabb<typename RayType::VectorType::ContainedType>;
    public:
        LineTracer() = delete;
@@ -87,6 +89,54 @@ namespace omath::collision
            return ray.start + ray_dir * t_hit;
        }
        // Slab method ray-AABB intersection
        // Returns the hit point on the AABB surface, or ray.end if no intersection
        [[nodiscard]]
        constexpr static auto get_ray_hit_point(const RayType& ray, const AABBType& aabb) noexcept
        {
            using T = typename RayType::VectorType::ContainedType;
            const auto dir = ray.direction_vector();
            auto t_min = -std::numeric_limits<T>::infinity();
            auto t_max = std::numeric_limits<T>::infinity();
            const auto process_axis = [&](const T& d, const T& origin, const T& box_min,
                                          const T& box_max) -> bool
            {
                constexpr T k_epsilon = std::numeric_limits<T>::epsilon();
                if (std::abs(d) < k_epsilon)
                    return origin >= box_min && origin <= box_max;
                const T inv = T(1) / d;
                T t0 = (box_min - origin) * inv;
                T t1 = (box_max - origin) * inv;
                if (t0 > t1)
                    std::swap(t0, t1);
                t_min = std::max(t_min, t0);
                t_max = std::min(t_max, t1);
                return t_min <= t_max;
            };
            if (!process_axis(dir.x, ray.start.x, aabb.min.x, aabb.max.x))
                return ray.end;
            if (!process_axis(dir.y, ray.start.y, aabb.min.y, aabb.max.y))
                return ray.end;
            if (!process_axis(dir.z, ray.start.z, aabb.min.z, aabb.max.z))
                return ray.end;
            // t_hit: use entry point if in front of origin, otherwise 0 (started inside)
            const T t_hit = std::max(T(0), t_min);
            if (t_max < T(0))
                return ray.end; // box entirely behind origin
            if (!ray.infinite_length && t_hit > T(1))
                return ray.end; // box beyond ray endpoint
            return ray.start + dir * t_hit;
        }
        template<class MeshType>
        [[nodiscard]]
        constexpr static auto get_ray_hit_point(const RayType& ray, const MeshType& mesh) noexcept
--- a/include/omath/engines/cry_engine/camera.hpp
+++ b/include/omath/engines/cry_engine/camera.hpp
@@ -9,5 +9,5 @@
 namespace omath::cry_engine
 {
-    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE>;
 } // namespace omath::cry_engine
--- a/include/omath/engines/frostbite_engine/camera.hpp
+++ b/include/omath/engines/frostbite_engine/camera.hpp
@@ -9,5 +9,5 @@
 namespace omath::frostbite_engine
 {
-    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE>;
-} // namespace omath::unity_engine
+} // namespace omath::frostbite_engine
--- a/include/omath/engines/iw_engine/camera.hpp
+++ b/include/omath/engines/iw_engine/camera.hpp
@@ -9,5 +9,5 @@
 namespace omath::iw_engine
 {
-    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE>;
 } // namespace omath::iw_engine
--- a/include/omath/engines/opengl_engine/camera.hpp
+++ b/include/omath/engines/opengl_engine/camera.hpp
@@ -8,5 +8,5 @@
 namespace omath::opengl_engine
 {
-    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, true, NDCDepthRange::NEGATIVE_ONE_TO_ONE>;
+    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::NEGATIVE_ONE_TO_ONE, {.inverted_forward = true}>;
 } // namespace omath::opengl_engine
--- a/include/omath/engines/source_engine/camera.hpp
+++ b/include/omath/engines/source_engine/camera.hpp
@@ -7,5 +7,5 @@
 #include "traits/camera_trait.hpp"
 namespace omath::source_engine
 {
-    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera =  projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE>;
 } // namespace omath::source_engine
--- a/include/omath/engines/unity_engine/camera.hpp
+++ b/include/omath/engines/unity_engine/camera.hpp
@@ -9,5 +9,5 @@
 namespace omath::unity_engine
 {
-    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE, {.inverted_forward = true}>;
 } // namespace omath::unity_engine
--- a/include/omath/engines/unreal_engine/camera.hpp
+++ b/include/omath/engines/unreal_engine/camera.hpp
@@ -9,5 +9,5 @@
 namespace omath::unreal_engine
 {
-    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
+    using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE, {.inverted_right = true}>;
 } // namespace omath::unreal_engine
--- a/include/omath/pathfinding/walk_bot.hpp
+++ b/include/omath/pathfinding/walk_bot.hpp
@@ -0,0 +1,46 @@
 //
 // Created by orange on 4/12/2026.
 //
 #pragma once
 #include "navigation_mesh.hpp"
 #include "omath/linear_algebra/vector3.hpp"
 #include <functional>
 #include <memory>
 namespace omath::pathfinding
 {
    enum class WalkBotStatus
    {
        IDLE,
        PATHING,
        FINISHED
    };
    class WalkBot
    {
    public:
        WalkBot() = default;
        explicit WalkBot(const std::shared_ptr<NavigationMesh>& mesh, float min_node_distance = 1.f);
        void set_nav_mesh(const std::shared_ptr<NavigationMesh>& mesh);
        void set_min_node_distance(float distance);
        void set_target(const Vector3<float>& target);
        // Clear navigation state so the bot can be re-routed without stale
        // visited-node memory.
        void reset();
        // Call every game tick with the current bot world position.
        void update(const Vector3<float>& bot_position);
        void on_path(const std::function<void(const Vector3<float>&)>& callback);
        void on_status(const std::function<void(WalkBotStatus)>& callback);
    private:
        std::weak_ptr<NavigationMesh> m_nav_mesh;
        std::optional<std::function<void(const Vector3<float>&)>> m_on_next_path_node;
        std::optional<std::function<void(WalkBotStatus)>> m_on_status_update;
        std::optional<Vector3<float>> m_last_visited;
        std::optional<Vector3<float>> m_target;
        float m_min_node_distance{1.f};
    };
 } // namespace omath::pathfinding
--- a/include/omath/projection/camera.hpp
+++ b/include/omath/projection/camera.hpp
@@ -4,6 +4,7 @@
 #pragma once
 #include "omath/3d_primitives/aabb.hpp"
 #include "omath/linear_algebra/mat.hpp"
 #include "omath/linear_algebra/triangle.hpp"
 #include "omath/linear_algebra/vector3.hpp"
@@ -41,6 +42,12 @@ namespace omath::projection
        AUTO,
        MANUAL,
    };
    struct CameraAxes
    {
        bool inverted_forward = false;
        bool inverted_right   = false;
    };
    template<class T, class MatType, class ViewAnglesType>
    concept CameraEngineConcept =
            requires(const Vector3<float>& cam_origin, const Vector3<float>& look_at, const ViewAnglesType& angles,
@@ -57,8 +64,9 @@ namespace omath::projection
                requires noexcept(T::calc_projection_matrix(fov, viewport, znear, zfar, ndc_depth_range));
            };
-    template<class Mat4X4Type, class ViewAnglesType, class TraitClass, bool inverted_z = false,
+    template<class Mat4X4Type, class ViewAnglesType, class TraitClass,
-             NDCDepthRange depth_range = NDCDepthRange::NEGATIVE_ONE_TO_ONE>
+             NDCDepthRange depth_range = NDCDepthRange::NEGATIVE_ONE_TO_ONE,
             CameraAxes axes = {}>
    requires CameraEngineConcept<TraitClass, Mat4X4Type, ViewAnglesType>
    class Camera final
    {
@@ -82,6 +90,46 @@ namespace omath::projection
        {
        }
        struct ProjectionParams
        {
            FieldOfView fov;
            float aspect_ratio;
        };
        // Recovers vertical FOV and aspect ratio from a perspective projection matrix
        // built by any of the engine traits.  Both variants (ZERO_TO_ONE and
        // NEGATIVE_ONE_TO_ONE) share the same m[0,0]/m[1,1] layout, so this works
        // regardless of the NDC depth range.
        [[nodiscard]]
        static ProjectionParams extract_projection_params(const Mat4X4Type& proj_matrix) noexcept
        {
            // m[1,1] == 1 / tan(fov/2)  =>  fov = 2 * atan(1 / m[1,1])
            const float f = proj_matrix.at(1, 1);
            // m[0,0] == m[1,1] / aspect_ratio  =>  aspect = m[1,1] / m[0,0]
            return {FieldOfView::from_radians(2.f * std::atan(1.f / f)), f / proj_matrix.at(0, 0)};
        }
        [[nodiscard]]
        static ViewAnglesType calc_view_angles_from_view_matrix(const Mat4X4Type& view_matrix) noexcept
        {
            Vector3<float> forward_vector = {view_matrix[2, 0], view_matrix[2, 1], view_matrix[2, 2]};
            if constexpr (axes.inverted_forward)
                forward_vector = -forward_vector;
            return TraitClass::calc_look_at_angle({}, forward_vector);
        }
        [[nodiscard]]
        static Vector3<float> calc_origin_from_view_matrix(const Mat4X4Type& view_matrix) noexcept
        {
            // The view matrix is R * T(-origin), so the last column stores t = -R * origin.
            // Recovering origin: origin = -R^T * t
            return {
                -(view_matrix[0, 0] * view_matrix[0, 3] + view_matrix[1, 0] * view_matrix[1, 3] + view_matrix[2, 0] * view_matrix[2, 3]),
                -(view_matrix[0, 1] * view_matrix[0, 3] + view_matrix[1, 1] * view_matrix[1, 3] + view_matrix[2, 1] * view_matrix[2, 3]),
                -(view_matrix[0, 2] * view_matrix[0, 3] + view_matrix[1, 2] * view_matrix[1, 3] + view_matrix[2, 2] * view_matrix[2, 3]),
            };
        }
        void look_at(const Vector3<float>& target)
        {
            m_view_angles = TraitClass::calc_look_at_angle(m_origin, target);
@@ -98,9 +146,6 @@ namespace omath::projection
        Vector3<float> get_forward() const noexcept
        {
            const auto& view_matrix = get_view_matrix();
            if constexpr (inverted_z)
                return -Vector3<float>{view_matrix[2, 0], view_matrix[2, 1], view_matrix[2, 2]};
            return {view_matrix[2, 0], view_matrix[2, 1], view_matrix[2, 2]};
        }
@@ -117,6 +162,27 @@ namespace omath::projection
            const auto& view_matrix = get_view_matrix();
            return {view_matrix[1, 0], view_matrix[1, 1], view_matrix[1, 2]};
        }
        [[nodiscard]]
        Vector3<float> get_abs_forward() const noexcept
        {
            if constexpr (axes.inverted_forward)
                return -get_forward();
            return get_forward();
        }
        [[nodiscard]]
        Vector3<float> get_abs_right() const noexcept
        {
            if constexpr (axes.inverted_right)
                return -get_right();
            return get_right();
        }
        [[nodiscard]]
        Vector3<float> get_abs_up() const noexcept
        {
            return get_up();
        }
        [[nodiscard]] const Mat4X4Type& get_view_projection_matrix() const noexcept
        {
@@ -308,6 +374,63 @@ namespace omath::projection
            return false;
        }
        [[nodiscard]] bool is_aabb_culled_by_frustum(const primitives::Aabb<float>& aabb) const noexcept
        {
            const auto& m = get_view_projection_matrix();
            // Gribb-Hartmann: extract 6 frustum planes from the view-projection matrix.
            // Each plane is (a, b, c, d) such that ax + by + cz + d >= 0 means inside.
            // For a 4x4 matrix with rows r0..r3:
            //   Left   = r3 + r0
            //   Right  = r3 - r0
            //   Bottom = r3 + r1
            //   Top    = r3 - r1
            //   Near   = r3 + r2  ([-1,1]) or r2 ([0,1])
            //   Far    = r3 - r2
            struct Plane final
            {
                float a, b, c, d;
            };
            const auto extract_plane = [&m](const int sign, const int row) -> Plane
            {
                return {
                        m.at(3, 0) + static_cast<float>(sign) * m.at(row, 0),
                        m.at(3, 1) + static_cast<float>(sign) * m.at(row, 1),
                        m.at(3, 2) + static_cast<float>(sign) * m.at(row, 2),
                        m.at(3, 3) + static_cast<float>(sign) * m.at(row, 3),
                };
            };
            std::array<Plane, 6> planes = {
                    extract_plane(1, 0), // left
                    extract_plane(-1, 0), // right
                    extract_plane(1, 1), // bottom
                    extract_plane(-1, 1), // top
                    extract_plane(-1, 2), // far
            };
            // Near plane depends on NDC depth range
            if constexpr (depth_range == NDCDepthRange::ZERO_TO_ONE)
                planes[5] = {m.at(2, 0), m.at(2, 1), m.at(2, 2), m.at(2, 3)};
            else
                planes[5] = extract_plane(1, 2);
            // For each plane, find the AABB corner most in the direction of the plane normal
            // (the "positive vertex"). If it's outside, the entire AABB is outside.
            for (const auto& [a, b, c, d] : planes)
            {
                const float px = a >= 0.f ? aabb.max.x : aabb.min.x;
                const float py = b >= 0.f ? aabb.max.y : aabb.min.y;
                const float pz = c >= 0.f ? aabb.max.z : aabb.min.z;
                if (a * px + b * py + c * pz + d < 0.f)
                    return true;
            }
            return false;
        }
        [[nodiscard]] std::expected<Vector3<float>, Error>
        world_to_view_port(const Vector3<float>& world_position,
                           const ViewPortClipping& clipping = ViewPortClipping::AUTO) const noexcept
--- a/source/pathfinding/a_star.cpp
+++ b/source/pathfinding/a_star.cpp
@@ -87,11 +87,11 @@ namespace omath::pathfinding
            const auto current_node = current_node_it->second;
            closed_list.emplace(current, current_node);
            if (current == end_vertex)
                return reconstruct_final_path(closed_list, current);
            closed_list.emplace(current, current_node);
            for (const auto& neighbor: nav_mesh.get_neighbors(current))
            {
                if (closed_list.contains(neighbor))
--- a/source/pathfinding/walk_bot.cpp
+++ b/source/pathfinding/walk_bot.cpp
@@ -0,0 +1,92 @@
 //
 // Created by orange on 4/12/2026.
 //
 #include "omath/pathfinding/walk_bot.hpp"
 #include "omath/pathfinding/a_star.hpp"
 namespace omath::pathfinding
 {
    WalkBot::WalkBot(const std::shared_ptr<NavigationMesh>& mesh, const float min_node_distance)
        : m_nav_mesh(mesh), m_min_node_distance(min_node_distance) {}
    void WalkBot::set_nav_mesh(const std::shared_ptr<NavigationMesh>& mesh)
    {
        m_nav_mesh = mesh;
    }
    void WalkBot::set_min_node_distance(const float distance)
    {
        m_min_node_distance = distance;
    }
    void WalkBot::set_target(const Vector3<float>& target)
    {
        m_target = target;
    }
    void WalkBot::reset()
    {
        m_last_visited.reset();
    }
    void WalkBot::update(const Vector3<float>& bot_position)
    {
        if (!m_target.has_value())
            return;
        if (m_target->distance_to(bot_position) <= m_min_node_distance)
        {
            if (m_on_status_update.has_value())
                m_on_status_update->operator()(WalkBotStatus::FINISHED);
            return;
        }
        if (!m_on_next_path_node.has_value())
            return;
        const auto nav_mesh = m_nav_mesh.lock();
        if (!nav_mesh)
        {
            if (m_on_status_update.has_value())
                m_on_status_update->operator()(WalkBotStatus::IDLE);
            return;
        }
        const auto path = Astar::find_path(bot_position, *m_target, *nav_mesh);
        if (path.empty())
        {
            if (m_on_status_update.has_value())
                m_on_status_update->operator()(WalkBotStatus::IDLE);
            return;
        }
        const auto& nearest = path.front();
        // Record the nearest node as visited once we are close enough to it.
        if (nearest.distance_to(bot_position) <= m_min_node_distance)
            m_last_visited = nearest;
        // If the nearest node was already visited, advance to the next one so
        // we never oscillate back to a node we just left.
        // If the bot was displaced (blown back), nearest will be an unvisited
        // node, so we route to it first before continuing forward.
        if (m_last_visited.has_value() && *m_last_visited == nearest && path.size() > 1)
            m_on_next_path_node->operator()(path[1]);
        else
            m_on_next_path_node->operator()(nearest);
        if (m_on_status_update.has_value())
            m_on_status_update->operator()(WalkBotStatus::PATHING);
    }
    void WalkBot::on_path(const std::function<void(const Vector3<float>&)>& callback)
    {
        m_on_next_path_node = callback;
    }
    void WalkBot::on_status(const std::function<void(WalkBotStatus)>& callback)
    {
        m_on_status_update = callback;
    }
 } // namespace omath::pathfinding
--- a/tests/engines/unit_test_frostbite_engine.cpp
+++ b/tests/engines/unit_test_frostbite_engine.cpp
@@ -453,3 +453,184 @@ TEST(unit_test_frostbite_engine, ViewAnglesAsVector3NormalizedYaw)
    EXPECT_NEAR(vec.y, -90.f, 0.01f);
 }
 // ---------------------------------------------------------------------------
 // extract_projection_params
 // ---------------------------------------------------------------------------
 // Tolerance: tan/atan round-trip in single precision introduces ~1e-5 rad
 // error, which is ~5.7e-4 degrees.
 static constexpr float k_fov_tolerance_deg  = 0.001f;
 static constexpr float k_aspect_tolerance   = 1e-5f;
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_BasicRoundTrip)
 {
    // Build a matrix with known inputs and verify both outputs are recovered.
    constexpr float fov_deg    = 60.f;
    constexpr float aspect     = 16.f / 9.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.1f, 1000.f, omath::NDCDepthRange::ZERO_TO_ONE);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_NegOneToOneDepthRange)
 {
    // The FOV/aspect encoding in rows 0 and 1 is identical for both NDC
    // depth ranges, so extraction must work the same way.
    constexpr float fov_deg = 75.f;
    constexpr float aspect  = 4.f / 3.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.1f, 500.f, omath::NDCDepthRange::NEGATIVE_ONE_TO_ONE);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_Fov45)
 {
    constexpr float fov_deg = 45.f;
    constexpr float aspect  = 16.f / 9.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.01f, 1000.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_Fov90)
 {
    constexpr float fov_deg = 90.f;
    constexpr float aspect  = 16.f / 9.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.01f, 1000.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_Fov120)
 {
    constexpr float fov_deg = 120.f;
    constexpr float aspect  = 16.f / 9.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.01f, 1000.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_AspectRatio_4by3)
 {
    constexpr float fov_deg = 60.f;
    constexpr float aspect  = 4.f / 3.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.1f, 500.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_AspectRatio_Ultrawide)
 {
    constexpr float fov_deg = 90.f;
    constexpr float aspect  = 21.f / 9.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.1f, 500.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_AspectRatio_Square)
 {
    constexpr float fov_deg = 90.f;
    constexpr float aspect  = 1.f;
    const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
        fov_deg, aspect, 0.1f, 500.f);
    const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
    EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_FovAndAspectAreIndependent)
 {
    // Changing only FOV must not affect recovered aspect ratio, and vice versa.
    constexpr float aspect = 16.f / 9.f;
    for (const float fov_deg : {45.f, 60.f, 90.f, 110.f})
    {
        const auto mat = omath::frostbite_engine::calc_perspective_projection_matrix(
            fov_deg, aspect, 0.1f, 1000.f);
        const auto [fov, ar] = omath::frostbite_engine::Camera::extract_projection_params(mat);
        EXPECT_NEAR(fov.as_degrees(), fov_deg, k_fov_tolerance_deg);
        EXPECT_NEAR(ar, aspect, k_aspect_tolerance);
    }
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_ViaCamera_RoundTrip)
 {
    // End-to-end: construct a Camera, retrieve its projection matrix, then
    // recover the FOV and aspect ratio and compare against the original inputs.
    constexpr auto fov_in  = omath::projection::FieldOfView::from_degrees(90.f);
    constexpr float aspect = 1920.f / 1080.f;
    const auto cam = omath::frostbite_engine::Camera(
        {0.f, 0.f, 0.f}, {}, {1920.f, 1080.f}, fov_in, 0.01f, 1000.f);
    const auto [fov_out, ar_out] =
        omath::frostbite_engine::Camera::extract_projection_params(cam.get_projection_matrix());
    EXPECT_NEAR(fov_out.as_degrees(), fov_in.as_degrees(), k_fov_tolerance_deg);
    EXPECT_NEAR(ar_out, aspect, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_ViaCamera_AfterFovChange)
 {
    // Verify that the extracted FOV tracks the camera's FOV after set_field_of_view().
    auto cam = omath::frostbite_engine::Camera(
        {0.f, 0.f, 0.f}, {}, {1920.f, 1080.f},
        omath::projection::FieldOfView::from_degrees(60.f), 0.01f, 1000.f);
    cam.set_field_of_view(omath::projection::FieldOfView::from_degrees(110.f));
    const auto [fov, ar] =
        omath::frostbite_engine::Camera::extract_projection_params(cam.get_projection_matrix());
    EXPECT_NEAR(fov.as_degrees(), 110.f, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, 1920.f / 1080.f, k_aspect_tolerance);
 }
 TEST(unit_test_frostbite_engine, ExtractProjectionParams_ViaCamera_AfterViewportChange)
 {
    // Verify that the extracted aspect ratio tracks the viewport after set_view_port().
    auto cam = omath::frostbite_engine::Camera(
        {0.f, 0.f, 0.f}, {}, {1920.f, 1080.f},
        omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    cam.set_view_port({1280.f, 720.f});
    const auto [fov, ar] =
        omath::frostbite_engine::Camera::extract_projection_params(cam.get_projection_matrix());
    EXPECT_NEAR(fov.as_degrees(), 90.f, k_fov_tolerance_deg);
    EXPECT_NEAR(ar, 1280.f / 720.f, k_aspect_tolerance);
 }
--- a/tests/general/unit_test_a_star.cpp
+++ b/tests/general/unit_test_a_star.cpp
@@ -40,8 +40,9 @@ TEST(AStarExtra, TrivialNeighbor)
    nav.m_vertex_map[v2] = {v1};
    const auto path = Astar::find_path(v1, v2, nav);
-    ASSERT_EQ(path.size(), 1u);
+    ASSERT_EQ(path.size(), 2u);
-    EXPECT_EQ(path.front(), v2);
+    EXPECT_EQ(path.front(), v1);
    EXPECT_EQ(path.back(), v2);
 }
 TEST(AStarExtra, StartEqualsGoal)
@@ -101,7 +102,7 @@ TEST(AStarExtra, LongerPathAvoidsBlock)
    constexpr Vector3<float> goal = idx(2, 1);
    const auto path = Astar::find_path(start, goal, nav);
    ASSERT_FALSE(path.empty());
-    EXPECT_EQ(path.front(), goal);
+    EXPECT_EQ(path.back(), goal);
 }
 TEST(AstarTests, TrivialDirectNeighborPath)
@@ -114,8 +115,9 @@ TEST(AstarTests, TrivialDirectNeighborPath)
    nav.m_vertex_map.emplace(v2, std::vector<Vector3<float>>{v1});
    const auto path = Astar::find_path(v1, v2, nav);
-    ASSERT_EQ(path.size(), 1u);
+    ASSERT_EQ(path.size(), 2u);
-    EXPECT_EQ(path.front(), v2);
+    EXPECT_EQ(path.front(), v1);
    EXPECT_EQ(path.back(), v2);
 }
 TEST(AstarTests, NoPathWhenDisconnected)
--- a/tests/general/unit_test_line_tracer_aabb.cpp
+++ b/tests/general/unit_test_line_tracer_aabb.cpp
@@ -0,0 +1,125 @@
 //
 // Created by Vlad on 3/25/2025.
 //
 #include "omath/collision/line_tracer.hpp"
 #include "omath/3d_primitives/aabb.hpp"
 #include <gtest/gtest.h>
 using Vec3 = omath::Vector3<float>;
 using Ray = omath::collision::Ray<>;
 using LineTracer = omath::collision::LineTracer<>;
 using AABB = omath::primitives::Aabb<float>;
 static Ray make_ray(Vec3 start, Vec3 end, bool infinite = false)
 {
    Ray r;
    r.start = start;
    r.end = end;
    r.infinite_length = infinite;
    return r;
 }
 // Ray passing straight through the center along Z axis
 TEST(LineTracerAABBTests, HitCenterAlongZ)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    const auto ray = make_ray({0.f, 0.f, -5.f}, {0.f, 0.f, 5.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    EXPECT_NEAR(hit.z, -1.f, 1e-4f);
    EXPECT_NEAR(hit.x, 0.f, 1e-4f);
    EXPECT_NEAR(hit.y, 0.f, 1e-4f);
 }
 // Ray passing straight through the center along X axis
 TEST(LineTracerAABBTests, HitCenterAlongX)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    const auto ray = make_ray({-5.f, 0.f, 0.f}, {5.f, 0.f, 0.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    EXPECT_NEAR(hit.x, -1.f, 1e-4f);
 }
 // Ray that misses entirely (too far in Y)
 TEST(LineTracerAABBTests, MissReturnsEnd)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    const auto ray = make_ray({0.f, 5.f, -5.f}, {0.f, 5.f, 5.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_EQ(hit, ray.end);
 }
 // Ray that stops short before reaching the box
 TEST(LineTracerAABBTests, RayTooShortReturnsEnd)
 {
    const AABB box{{3.f, -1.f, -1.f}, {5.f, 1.f, 1.f}};
    const auto ray = make_ray({0.f, 0.f, 0.f}, {2.f, 0.f, 0.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_EQ(hit, ray.end);
 }
 // Infinite ray that starts before the box should hit
 TEST(LineTracerAABBTests, InfiniteRayHits)
 {
    const AABB box{{3.f, -1.f, -1.f}, {5.f, 1.f, 1.f}};
    const auto ray = make_ray({0.f, 0.f, 0.f}, {2.f, 0.f, 0.f}, true);
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    EXPECT_NEAR(hit.x, 3.f, 1e-4f);
 }
 // Ray starting inside the box — t_min=0, so hit point equals ray.start
 TEST(LineTracerAABBTests, RayStartsInsideBox)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    const auto ray = make_ray({0.f, 0.f, 0.f}, {0.f, 0.f, 5.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    // t_min is clamped to 0, so hit == start
    EXPECT_NEAR(hit.x, 0.f, 1e-4f);
    EXPECT_NEAR(hit.y, 0.f, 1e-4f);
    EXPECT_NEAR(hit.z, 0.f, 1e-4f);
 }
 // Ray parallel to XY plane, pointing along X, at Z outside the box
 TEST(LineTracerAABBTests, ParallelRayOutsideSlabMisses)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    // Z component of ray is 3.0 — outside box's Z slab
    const auto ray = make_ray({-5.f, 0.f, 3.f}, {5.f, 0.f, 3.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_EQ(hit, ray.end);
 }
 // Ray parallel to XY plane, pointing along X, at Z inside the box
 TEST(LineTracerAABBTests, ParallelRayInsideSlabHits)
 {
    const AABB box{{-1.f, -1.f, -1.f}, {1.f, 1.f, 1.f}};
    const auto ray = make_ray({-5.f, 0.f, 0.f}, {5.f, 0.f, 0.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    EXPECT_NEAR(hit.x, -1.f, 1e-4f);
 }
 // Diagonal ray hitting a corner region
 TEST(LineTracerAABBTests, DiagonalRayHits)
 {
    const AABB box{{0.f, 0.f, 0.f}, {2.f, 2.f, 2.f}};
    const auto ray = make_ray({-1.f, -1.f, -1.f}, {3.f, 3.f, 3.f});
    const auto hit = LineTracer::get_ray_hit_point(ray, box);
    EXPECT_NE(hit, ray.end);
    // Entry point should be at (0,0,0)
    EXPECT_NEAR(hit.x, 0.f, 1e-4f);
    EXPECT_NEAR(hit.y, 0.f, 1e-4f);
    EXPECT_NEAR(hit.z, 0.f, 1e-4f);
 }
--- a/tests/general/unit_test_projection.cpp
+++ b/tests/general/unit_test_projection.cpp
@@ -4,7 +4,13 @@
 #include "omath/engines/unity_engine/camera.hpp"
 #include <complex>
 #include <gtest/gtest.h>
 #include <omath/3d_primitives/aabb.hpp>
 #include <omath/engines/cry_engine/camera.hpp>
 #include <omath/engines/frostbite_engine/camera.hpp>
 #include <omath/engines/iw_engine/camera.hpp>
 #include <omath/engines/opengl_engine/camera.hpp>
 #include <omath/engines/source_engine/camera.hpp>
 #include <omath/engines/unreal_engine/camera.hpp>
 #include <omath/projection/camera.hpp>
 #include <print>
 #include <random>
@@ -217,3 +223,721 @@ TEST(UnitTestProjection, ScreenToWorldBottomLeftCorner)
        EXPECT_NEAR(screen_cords->y, initial_screen_cords.y, 0.001f);
    }
 }
 TEST(UnitTestProjection, AabbInsideFrustumNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Small box directly in front of camera (Source Engine: +X forward, +Y left, +Z up)
    const omath::primitives::Aabb<float> aabb{{90.f, -1.f, -1.f}, {110.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbBehindCameraCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box entirely behind the camera
    const omath::primitives::Aabb<float> aabb{{-200.f, -1.f, -1.f}, {-100.f, 1.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbBeyondFarPlaneCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box beyond far plane (1000)
    const omath::primitives::Aabb<float> aabb{{1500.f, -1.f, -1.f}, {2000.f, 1.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbFarLeftCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box far to the side, outside the frustum
    const omath::primitives::Aabb<float> aabb{{90.f, 4000.f, -1.f}, {110.f, 5000.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbFarRightCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box far to the other side, outside the frustum
    const omath::primitives::Aabb<float> aabb{{90.f, -5000.f, -1.f}, {110.f, -4000.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbAboveCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box far above the frustum
    const omath::primitives::Aabb<float> aabb{{90.f, -1.f, 5000.f}, {110.f, 1.f, 6000.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbPartiallyInsideNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Large box that straddles the frustum boundary — partially inside
    const omath::primitives::Aabb<float> aabb{{50.f, -5000.f, -5000.f}, {500.f, 5000.f, 5000.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbStraddlesNearPlaneNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box that straddles the near plane — partially in front
    const omath::primitives::Aabb<float> aabb{{-5.f, -1.f, -1.f}, {5.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbStraddlesFarPlaneNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box that straddles the far plane
    const omath::primitives::Aabb<float> aabb{{900.f, -1.f, -1.f}, {1100.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbCulledUnityEngine)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    // Box in front — not culled
    const omath::primitives::Aabb<float> inside{{-1.f, -1.f, 50.f}, {1.f, 1.f, 100.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(inside));
    // Box behind — culled
    const omath::primitives::Aabb<float> behind{{-1.f, -1.f, -200.f}, {1.f, 1.f, -100.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(behind));
 }
 TEST(UnitTestProjection, AabbBelowCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box far below the frustum (Source Engine: +Z up)
    const omath::primitives::Aabb<float> aabb{{90.f, -1.f, -6000.f}, {110.f, 1.f, -5000.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbEnclosesCameraNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Huge box that fully encloses the camera
    const omath::primitives::Aabb<float> aabb{{-500.f, -500.f, -500.f}, {500.f, 500.f, 500.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbExactlyAtNearPlaneNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box starting exactly at the near plane distance
    const omath::primitives::Aabb<float> aabb{{0.01f, -1.f, -1.f}, {10.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbExactlyAtFarPlaneNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Box ending exactly at the far plane distance
    const omath::primitives::Aabb<float> aabb{{990.f, -1.f, -1.f}, {1000.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbNarrowFovCulledAtEdge)
 {
    // Narrow FOV — box that would be visible at 90 is culled at 30
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(30.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    const omath::primitives::Aabb<float> aabb{{100.f, 200.f, -1.f}, {110.f, 210.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbWideFovNotCulledAtEdge)
 {
    // Wide FOV — same box is visible
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(120.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    const omath::primitives::Aabb<float> aabb{{100.f, 200.f, -1.f}, {110.f, 210.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbCameraOffOrigin)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({500.f, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f},
                                                  fov, 0.01f, 1000.f);
    // Box in front of shifted camera
    const omath::primitives::Aabb<float> in_front{{600.f, -1.f, -1.f}, {700.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(in_front));
    // Box behind shifted camera
    const omath::primitives::Aabb<float> behind{{0.f, -1.f, -1.f}, {100.f, 1.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(behind));
 }
 TEST(UnitTestProjection, AabbShortFarPlaneCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    // Very short far plane
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 50.f);
    // Box at distance 100 — beyond the 50-unit far plane
    const omath::primitives::Aabb<float> aabb{{90.f, -1.f, -1.f}, {110.f, 1.f, 1.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
    // Box at distance 30 — within range
    const omath::primitives::Aabb<float> near_box{{25.f, -1.f, -1.f}, {35.f, 1.f, 1.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(near_box));
 }
 TEST(UnitTestProjection, AabbPointSizedInsideNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, omath::source_engine::ViewAngles{}, {1920.f, 1080.f}, fov,
                                                  0.01f, 1000.f);
    // Degenerate zero-volume AABB (a point) inside the frustum
    const omath::primitives::Aabb<float> aabb{{100.f, 0.f, 0.f}, {100.f, 0.f, 0.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbOpenGlEngineInsideNotCulled)
 {
    // OpenGL: COLUMN_MAJOR, NEGATIVE_ONE_TO_ONE, inverted_z, forward = -Z
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::opengl_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    // Box in front of camera (OpenGL: -Z forward)
    const omath::primitives::Aabb<float> aabb{{-1.f, -1.f, -110.f}, {1.f, 1.f, -90.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbOpenGlEngineBehindCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::opengl_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    // Box behind (OpenGL: +Z is behind the camera)
    const omath::primitives::Aabb<float> aabb{{-1.f, -1.f, 100.f}, {1.f, 1.f, 200.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbOpenGlEngineBeyondFarCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::opengl_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    // Box beyond far plane along -Z
    const omath::primitives::Aabb<float> aabb{{-1.f, -1.f, -2000.f}, {1.f, 1.f, -1500.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbOpenGlEngineSideCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::opengl_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    // Box far to the right (OpenGL: +X right)
    const omath::primitives::Aabb<float> aabb{{4000.f, -1.f, -110.f}, {5000.f, 1.f, -90.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbUnityEngineBeyondFarCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 500.f);
    // Box beyond 500-unit far plane (Unity: +Z forward)
    const omath::primitives::Aabb<float> aabb{{-1.f, -1.f, 600.f}, {1.f, 1.f, 700.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbUnityEngineSideCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    // Box far above (Unity: +Y up)
    const omath::primitives::Aabb<float> aabb{{-1.f, 5000.f, 50.f}, {1.f, 6000.f, 100.f}};
    EXPECT_TRUE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, AabbUnityEngineStraddlesNearNotCulled)
 {
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    // Box straddles near plane (Unity: +Z forward)
    const omath::primitives::Aabb<float> aabb{{-1.f, -1.f, -5.f}, {1.f, 1.f, 5.f}};
    EXPECT_FALSE(cam.is_aabb_culled_by_frustum(aabb));
 }
 TEST(UnitTestProjection, CalcViewAnglesFromViewMatrix_LookingForward)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(0.f),
        omath::source_engine::YawAngle::from_degrees(0.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({0, 0, 0}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto result = omath::source_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), 0.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), 0.f, k_eps);
 }
 TEST(UnitTestProjection, CalcViewAnglesFromViewMatrix_PositivePitchAndYaw)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(30.f),
        omath::source_engine::YawAngle::from_degrees(45.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({0, 0, 0}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto result = omath::source_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), 30.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), 45.f, k_eps);
 }
 TEST(UnitTestProjection, CalcViewAnglesFromViewMatrix_NegativePitchAndYaw)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(-45.f),
        omath::source_engine::YawAngle::from_degrees(-90.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({0, 0, 0}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto result = omath::source_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), -45.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), -90.f, k_eps);
 }
 TEST(UnitTestProjection, CalcViewAnglesFromViewMatrix_OffOriginCameraIgnored)
 {
    // The forward vector from the view matrix does not depend on camera origin,
    // so the same angles should be recovered regardless of position.
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(20.f),
        omath::source_engine::YawAngle::from_degrees(60.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({100.f, 200.f, -50.f}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto result = omath::source_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), 20.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), 60.f, k_eps);
 }
 TEST(UnitTestProjection, CalcViewAnglesFromViewMatrix_RollAlwaysZero)
 {
    // Roll cannot be encoded in the forward vector, so it is always 0 in the result.
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(10.f),
        omath::source_engine::YawAngle::from_degrees(30.f),
        omath::source_engine::RollAngle::from_degrees(15.f)
    };
    const auto cam = omath::source_engine::Camera({0, 0, 0}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto result = omath::source_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_FLOAT_EQ(result.roll.as_degrees(), 0.f);
 }
 TEST(UnitTestProjection, CalcOriginFromViewMatrix_AtOrigin)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const auto cam = omath::source_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto origin = omath::source_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 0.f, k_eps);
    EXPECT_NEAR(origin.y, 0.f, k_eps);
    EXPECT_NEAR(origin.z, 0.f, k_eps);
 }
 TEST(UnitTestProjection, CalcOriginFromViewMatrix_ArbitraryPosition)
 {
    constexpr float k_eps = 1e-3f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(0.f),
        omath::source_engine::YawAngle::from_degrees(0.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({100.f, 200.f, -50.f}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto origin = omath::source_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 100.f, k_eps);
    EXPECT_NEAR(origin.y, 200.f, k_eps);
    EXPECT_NEAR(origin.z, -50.f, k_eps);
 }
 TEST(UnitTestProjection, CalcOriginFromViewMatrix_WithRotation)
 {
    // Origin recovery must work even when the camera is rotated.
    constexpr float k_eps = 1e-3f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    const omath::source_engine::ViewAngles angles{
        omath::source_engine::PitchAngle::from_degrees(30.f),
        omath::source_engine::YawAngle::from_degrees(45.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::source_engine::Camera({300.f, -100.f, 75.f}, angles, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto origin = omath::source_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 300.f, k_eps);
    EXPECT_NEAR(origin.y, -100.f, k_eps);
    EXPECT_NEAR(origin.z, 75.f, k_eps);
 }
 TEST(UnitTestProjection, CalcOriginFromViewMatrix_IndependentOfAngles)
 {
    // Same position, different orientations — should always recover the same origin.
    constexpr float k_eps = 1e-3f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
    constexpr omath::Vector3<float> expected_origin{50.f, 50.f, 50.f};
    const omath::source_engine::ViewAngles angles_a{
        omath::source_engine::PitchAngle::from_degrees(0.f),
        omath::source_engine::YawAngle::from_degrees(0.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const omath::source_engine::ViewAngles angles_b{
        omath::source_engine::PitchAngle::from_degrees(-60.f),
        omath::source_engine::YawAngle::from_degrees(135.f),
        omath::source_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam_a = omath::source_engine::Camera(expected_origin, angles_a, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto cam_b = omath::source_engine::Camera(expected_origin, angles_b, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
    const auto origin_a = omath::source_engine::Camera::calc_origin_from_view_matrix(cam_a.get_view_matrix());
    const auto origin_b = omath::source_engine::Camera::calc_origin_from_view_matrix(cam_b.get_view_matrix());
    EXPECT_NEAR(origin_a.x, expected_origin.x, k_eps);
    EXPECT_NEAR(origin_a.y, expected_origin.y, k_eps);
    EXPECT_NEAR(origin_a.z, expected_origin.z, k_eps);
    EXPECT_NEAR(origin_b.x, expected_origin.x, k_eps);
    EXPECT_NEAR(origin_b.y, expected_origin.y, k_eps);
    EXPECT_NEAR(origin_b.z, expected_origin.z, k_eps);
 }
 // ---- Unity engine camera tests ----
 TEST(UnitTestProjection, Unity_CalcViewAnglesFromViewMatrix_LookingForward)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const omath::unity_engine::ViewAngles angles{
        omath::unity_engine::PitchAngle::from_degrees(0.f),
        omath::unity_engine::YawAngle::from_degrees(0.f),
        omath::unity_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, angles, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto result = omath::unity_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), 0.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), 0.f, k_eps);
 }
 TEST(UnitTestProjection, Unity_CalcViewAnglesFromViewMatrix_PositivePitchAndYaw)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const omath::unity_engine::ViewAngles angles{
        omath::unity_engine::PitchAngle::from_degrees(30.f),
        omath::unity_engine::YawAngle::from_degrees(45.f),
        omath::unity_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, angles, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto result = omath::unity_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), 30.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), 45.f, k_eps);
 }
 TEST(UnitTestProjection, Unity_CalcViewAnglesFromViewMatrix_NegativePitchAndYaw)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const omath::unity_engine::ViewAngles angles{
        omath::unity_engine::PitchAngle::from_degrees(-45.f),
        omath::unity_engine::YawAngle::from_degrees(-90.f),
        omath::unity_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, angles, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto result = omath::unity_engine::Camera::calc_view_angles_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(result.pitch.as_degrees(), -45.f, k_eps);
    EXPECT_NEAR(result.yaw.as_degrees(), -90.f, k_eps);
 }
 TEST(UnitTestProjection, Unity_CalcOriginFromViewMatrix_AtOrigin)
 {
    constexpr float k_eps = 1e-4f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto origin = omath::unity_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 0.f, k_eps);
    EXPECT_NEAR(origin.y, 0.f, k_eps);
    EXPECT_NEAR(origin.z, 0.f, k_eps);
 }
 TEST(UnitTestProjection, Unity_CalcOriginFromViewMatrix_ArbitraryPosition)
 {
    constexpr float k_eps = 1e-3f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const omath::unity_engine::ViewAngles angles{
        omath::unity_engine::PitchAngle::from_degrees(0.f),
        omath::unity_engine::YawAngle::from_degrees(0.f),
        omath::unity_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::unity_engine::Camera({100.f, 200.f, -50.f}, angles, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto origin = omath::unity_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 100.f, k_eps);
    EXPECT_NEAR(origin.y, 200.f, k_eps);
    EXPECT_NEAR(origin.z, -50.f, k_eps);
 }
 TEST(UnitTestProjection, Unity_CalcOriginFromViewMatrix_WithRotation)
 {
    constexpr float k_eps = 1e-3f;
    constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
    const omath::unity_engine::ViewAngles angles{
        omath::unity_engine::PitchAngle::from_degrees(30.f),
        omath::unity_engine::YawAngle::from_degrees(45.f),
        omath::unity_engine::RollAngle::from_degrees(0.f)
    };
    const auto cam = omath::unity_engine::Camera({300.f, -100.f, 75.f}, angles, {1280.f, 720.f}, fov, 0.03f, 1000.f);
    const auto origin = omath::unity_engine::Camera::calc_origin_from_view_matrix(cam.get_view_matrix());
    EXPECT_NEAR(origin.x, 300.f, k_eps);
    EXPECT_NEAR(origin.y, -100.f, k_eps);
    EXPECT_NEAR(origin.z, 75.f, k_eps);
 }
 // ---- Camera basis vectors at zero angles ----
 TEST(UnitTestProjection, SourceEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::source_engine::Camera({}, {}, {1920.f, 1080.f},
                                                  omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::source_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::source_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::source_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::source_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::source_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::source_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::source_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::source_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::source_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, UnityEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::unity_engine::Camera({}, {}, {1280.f, 720.f},
                                                 omath::projection::FieldOfView::from_degrees(60.f), 0.03f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::unity_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::unity_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::unity_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::unity_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::unity_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::unity_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::unity_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::unity_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::unity_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, OpenGLEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::opengl_engine::Camera({}, {}, {1920.f, 1080.f},
                                                  omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::opengl_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::opengl_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::opengl_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::opengl_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::opengl_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::opengl_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::opengl_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::opengl_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::opengl_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, UnrealEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::unreal_engine::Camera({}, {}, {1920.f, 1080.f},
                                                  omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::unreal_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::unreal_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::unreal_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::unreal_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::unreal_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::unreal_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::unreal_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::unreal_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::unreal_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, FrostbiteEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::frostbite_engine::Camera({}, {}, {1920.f, 1080.f},
                                                     omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::frostbite_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::frostbite_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::frostbite_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::frostbite_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::frostbite_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::frostbite_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::frostbite_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::frostbite_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::frostbite_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, CryEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::cry_engine::Camera({}, {}, {1920.f, 1080.f},
                                               omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::cry_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::cry_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::cry_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::cry_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::cry_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::cry_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::cry_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::cry_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::cry_engine::k_abs_up.z, k_eps);
 }
 TEST(UnitTestProjection, IWEngine_ZeroAngles_BasisVectors)
 {
    constexpr float k_eps = 1e-5f;
    const auto cam = omath::iw_engine::Camera({}, {}, {1920.f, 1080.f},
                                              omath::projection::FieldOfView::from_degrees(90.f), 0.01f, 1000.f);
    const auto fwd   = cam.get_abs_forward();
    const auto right = cam.get_abs_right();
    const auto up    = cam.get_abs_up();
    EXPECT_NEAR(fwd.x,   omath::iw_engine::k_abs_forward.x, k_eps);
    EXPECT_NEAR(fwd.y,   omath::iw_engine::k_abs_forward.y, k_eps);
    EXPECT_NEAR(fwd.z,   omath::iw_engine::k_abs_forward.z, k_eps);
    EXPECT_NEAR(right.x, omath::iw_engine::k_abs_right.x, k_eps);
    EXPECT_NEAR(right.y, omath::iw_engine::k_abs_right.y, k_eps);
    EXPECT_NEAR(right.z, omath::iw_engine::k_abs_right.z, k_eps);
    EXPECT_NEAR(up.x,    omath::iw_engine::k_abs_up.x, k_eps);
    EXPECT_NEAR(up.y,    omath::iw_engine::k_abs_up.y, k_eps);
    EXPECT_NEAR(up.z,    omath::iw_engine::k_abs_up.z, k_eps);
 }
--- a/tests/general/unit_test_walk_bot.cpp
+++ b/tests/general/unit_test_walk_bot.cpp
@@ -0,0 +1,640 @@
 // Unit tests for omath::pathfinding::WalkBot
 // Covers all status transitions, callback behaviour, and a full walk simulation.
 #include <gtest/gtest.h>
 #include "omath/pathfinding/walk_bot.hpp"
 #include "omath/pathfinding/navigation_mesh.hpp"
 using namespace omath;
 using namespace omath::pathfinding;
 // ---------------------------------------------------------------------------
 // Helpers
 // ---------------------------------------------------------------------------
 // Build a simple bidirectional linear chain:
 //   (0,0,0) <-> (1,0,0) <-> (2,0,0) <-> ... <-> (n-1,0,0)
 static std::shared_ptr<NavigationMesh> make_linear_mesh(int n)
 {
    auto mesh = std::make_shared<NavigationMesh>();
    for (int i = 0; i < n; ++i)
    {
        const Vector3<float> v{static_cast<float>(i), 0.f, 0.f};
        std::vector<Vector3<float>> neighbors;
        if (i > 0)
            neighbors.push_back(Vector3<float>{static_cast<float>(i - 1), 0.f, 0.f});
        if (i + 1 < n)
            neighbors.push_back(Vector3<float>{static_cast<float>(i + 1), 0.f, 0.f});
        mesh->m_vertex_map[v] = neighbors;
    }
    return mesh;
 }
 // Collect every status update fired during one update() call.
 static auto make_status_recorder(std::vector<WalkBotStatus>& out)
 {
    return [&out](WalkBotStatus s) { out.push_back(s); };
 }
 // Collect every "next node" hint fired during one update() call.
 static auto make_node_recorder(std::vector<Vector3<float>>& out)
 {
    return [&out](const Vector3<float>& v) { out.push_back(v); };
 }
 // ---------------------------------------------------------------------------
 // Construction
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, DefaultConstructedBotIsInert)
 {
    // A default-constructed bot with no mesh, no target, and no callbacks must
    // not crash.
    WalkBot bot;
    EXPECT_NO_THROW(bot.update({0.f, 0.f, 0.f}));
 }
 TEST(WalkBotTests, ConstructWithMeshAndDistance)
 {
    auto mesh = make_linear_mesh(3);
    EXPECT_NO_THROW(WalkBot bot(mesh, 0.5f));
 }
 // ---------------------------------------------------------------------------
 // Status: FINISHED
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, FiresFinishedWhenBotIsAtTarget)
 {
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({2.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // bot_position == target_position -> distance == 0, well within threshold
    bot.update({2.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.front(), WalkBotStatus::FINISHED);
 }
 TEST(WalkBotTests, FiresFinishedWhenBotIsWithinMinDistance)
 {
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({0.4f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // distance between (0,0,0) and (0.4,0,0) is 0.4 < 0.5 threshold
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.front(), WalkBotStatus::FINISHED);
 }
 TEST(WalkBotTests, NoFinishedWhenOutsideMinDistance)
 {
    auto mesh = make_linear_mesh(5);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({4.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // Attach path callback so we get further status updates
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    // FINISHED must NOT appear in the status list
    for (auto s : statuses)
        EXPECT_NE(s, WalkBotStatus::FINISHED);
 }
 TEST(WalkBotTests, FinishedFiredEvenWithoutPathCallback)
 {
    // FINISHED is emitted before the on_path guard, so it fires regardless.
    auto mesh = make_linear_mesh(2);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({1.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // Intentionally do NOT register on_path callback.
    bot.update({1.f, 0.f, 0.f});
    ASSERT_EQ(statuses.size(), 1u);
    EXPECT_EQ(statuses[0], WalkBotStatus::FINISHED);
 }
 TEST(WalkBotTests, FinishedDoesNotFallThroughToPathing)
 {
    // update() must return after FINISHED — PATHING must not fire on the same tick.
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({1.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({1.f, 0.f, 0.f}); // bot is at target
    ASSERT_EQ(statuses.size(), 1u);
    EXPECT_EQ(statuses[0], WalkBotStatus::FINISHED);
    EXPECT_TRUE(nodes.empty());
 }
 // ---------------------------------------------------------------------------
 // No target set
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, NoUpdateWithoutTarget)
 {
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    // Intentionally do NOT call set_target()
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    EXPECT_TRUE(statuses.empty());
    EXPECT_TRUE(nodes.empty());
 }
 // ---------------------------------------------------------------------------
 // Status: IDLE — no path callback registered
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, NoPathCallbackMeansNoPathingStatus)
 {
    auto mesh = make_linear_mesh(4);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({3.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // No on_path registered -> update returns early after FINISHED check
    bot.update({0.f, 0.f, 0.f});
    EXPECT_TRUE(statuses.empty());
 }
 // ---------------------------------------------------------------------------
 // Status: IDLE — null/expired navigation mesh
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, FiresIdleWhenNavMeshIsNull)
 {
    WalkBot bot; // no mesh assigned
    bot.set_target({5.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.back(), WalkBotStatus::IDLE);
    EXPECT_TRUE(nodes.empty());
 }
 TEST(WalkBotTests, FiresIdleWhenNavMeshExpires)
 {
    auto mesh = make_linear_mesh(4);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({3.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    // Let the shared_ptr expire — WalkBot holds only a weak_ptr.
    mesh.reset();
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.back(), WalkBotStatus::IDLE);
    EXPECT_TRUE(nodes.empty());
 }
 TEST(WalkBotTests, SetNavMeshRestoresPathing)
 {
    WalkBot bot; // starts with no mesh
    bot.set_target({3.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    // First call — no mesh -> IDLE
    bot.update({0.f, 0.f, 0.f});
    ASSERT_EQ(statuses.back(), WalkBotStatus::IDLE);
    // Assign a mesh and call again. Keep the shared_ptr alive so the
    // weak_ptr inside WalkBot does not expire before update() is called.
    statuses.clear();
    nodes.clear();
    auto new_mesh = make_linear_mesh(4);
    bot.set_nav_mesh(new_mesh);
    bot.set_min_node_distance(0.5f);
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.back(), WalkBotStatus::PATHING);
    EXPECT_FALSE(nodes.empty());
 }
 // ---------------------------------------------------------------------------
 // Status: IDLE — A* finds no path
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, FiresIdleWhenNoPathExists)
 {
    // Disconnected graph: two isolated vertices
    auto mesh = std::make_shared<NavigationMesh>();
    mesh->m_vertex_map[{0.f, 0.f, 0.f}] = {};
    mesh->m_vertex_map[{10.f, 0.f, 0.f}] = {};
    WalkBot bot(mesh, 0.5f);
    bot.set_target({10.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.back(), WalkBotStatus::IDLE);
    EXPECT_TRUE(nodes.empty());
 }
 // ---------------------------------------------------------------------------
 // Status: PATHING — normal routing
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, FiresPathingAndProvidesNextNode)
 {
    auto mesh = make_linear_mesh(4);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({3.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.back(), WalkBotStatus::PATHING);
    ASSERT_FALSE(nodes.empty());
 }
 TEST(WalkBotTests, NextNodeIsOnThePath)
 {
    auto mesh = make_linear_mesh(5);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({4.f, 0.f, 0.f});
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    bot.update({0.f, 0.f, 0.f});
    // The suggested node must be a mesh vertex (x in [0..4], y=0, z=0)
    ASSERT_FALSE(nodes.empty());
    const auto& hint = nodes.front();
    EXPECT_GE(hint.x, 0.f);
    EXPECT_LE(hint.x, 4.f);
    EXPECT_FLOAT_EQ(hint.y, 0.f);
    EXPECT_FLOAT_EQ(hint.z, 0.f);
 }
 // ---------------------------------------------------------------------------
 // set_min_node_distance
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, MinNodeDistanceAffectsFinishedThreshold)
 {
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.1f); // very tight threshold
    bot.set_target({1.f, 0.f, 0.f});
    std::vector<WalkBotStatus> statuses;
    bot.on_status(make_status_recorder(statuses));
    // distance 0.4 — outside 0.1 threshold
    bot.update({0.6f, 0.f, 0.f});
    EXPECT_TRUE(statuses.empty() ||
                std::find(statuses.begin(), statuses.end(), WalkBotStatus::FINISHED) == statuses.end());
    statuses.clear();
    bot.set_min_node_distance(0.5f); // widen threshold
    bot.update({0.6f, 0.f, 0.f});   // now 0.4 < 0.5 -> FINISHED
    ASSERT_FALSE(statuses.empty());
    EXPECT_EQ(statuses.front(), WalkBotStatus::FINISHED);
 }
 // ---------------------------------------------------------------------------
 // reset()
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, ResetClearsLastVisited)
 {
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({2.f, 0.f, 0.f});
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    // Tick 1: mark node 0 visited -> hint is node 1
    bot.update({0.05f, 0.f, 0.f});
    ASSERT_FALSE(nodes.empty());
    EXPECT_FLOAT_EQ(nodes.back().x, 1.f);
    // Without reset, a second tick from the same position also gives node 1.
    nodes.clear();
    bot.reset();
    // After reset, m_last_visited is cleared. The nearest node is 0 again,
    // it is within threshold so it gets marked visited and we advance to 1.
    // The hint should still be node 1 (same outcome, but state was cleanly reset).
    bot.update({0.05f, 0.f, 0.f});
    ASSERT_FALSE(nodes.empty());
    // Confirm the bot still routes correctly after reset.
    EXPECT_GE(nodes.back().x, 0.f);
 }
 // ---------------------------------------------------------------------------
 // Node advancement — visited node causes skip to next
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, AdvancesWhenNearestNodeAlreadyVisited)
 {
    // Chain: (0,0,0) -> (1,0,0) -> (2,0,0)
    auto mesh = make_linear_mesh(3);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({2.f, 0.f, 0.f});
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    // Tick 1: bot is very close to node 0 -> node 0 marked visited -> hint is node 1.
    bot.update({0.05f, 0.f, 0.f});
    ASSERT_FALSE(nodes.empty());
    EXPECT_FLOAT_EQ(nodes.back().x, 1.f);
    nodes.clear();
    // Tick 2: bot has moved to near node 1 -> node 1 marked visited -> hint advances to node 2.
    bot.update({1.05f, 0.f, 0.f});
    ASSERT_FALSE(nodes.empty());
    EXPECT_GT(nodes.back().x, 1.f);
 }
 // ---------------------------------------------------------------------------
 // Displacement recovery — bot knocked back to unvisited node
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, RecoverAfterDisplacementToUnvisitedNode)
 {
    // Chain: 0 -> 1 -> 2 -> 3 -> 4
    auto mesh = make_linear_mesh(5);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({4.f, 0.f, 0.f});
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    // Walk forward through nodes 0-3 to build visited state.
    for (int i = 0; i <= 3; ++i)
    {
        nodes.clear();
        bot.update(Vector3<float>{static_cast<float>(i) + 0.1f, 0.f, 0.f});
    }
    // Displace the bot back to near node 1. The bot should route toward node 1
    // first rather than skipping ahead to node 4.
    nodes.clear();
    bot.update({1.1f, 0.f, 0.f});
    ASSERT_FALSE(nodes.empty());
    EXPECT_LE(nodes.back().x, 3.f);
 }
 // ---------------------------------------------------------------------------
 // Callback wiring
 // ---------------------------------------------------------------------------
 TEST(WalkBotTests, ReplacingPathCallbackTakesEffect)
 {
    auto mesh = make_linear_mesh(4);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({3.f, 0.f, 0.f});
    int first_cb_calls = 0;
    int second_cb_calls = 0;
    bot.on_path([&](const Vector3<float>&) { ++first_cb_calls; });
    bot.update({0.f, 0.f, 0.f});
    bot.on_path([&](const Vector3<float>&) { ++second_cb_calls; });
    bot.update({0.f, 0.f, 0.f});
    EXPECT_EQ(first_cb_calls, 1);
    EXPECT_EQ(second_cb_calls, 1);
 }
 TEST(WalkBotTests, ReplacingStatusCallbackTakesEffect)
 {
    auto mesh = make_linear_mesh(4);
    WalkBot bot(mesh, 0.5f);
    bot.set_target({3.f, 0.f, 0.f});
    std::vector<Vector3<float>> nodes;
    bot.on_path(make_node_recorder(nodes));
    int cb1 = 0, cb2 = 0;
    bot.on_status([&](WalkBotStatus) { ++cb1; });
    bot.update({0.f, 0.f, 0.f});
    bot.on_status([&](WalkBotStatus) { ++cb2; });
    bot.update({0.f, 0.f, 0.f});
    EXPECT_EQ(cb1, 1);
    EXPECT_EQ(cb2, 1);
 }
 // ---------------------------------------------------------------------------
 // Full walk simulation — bot traverses a linear mesh step by step
 // ---------------------------------------------------------------------------
 // Simulates one game-loop tick and immediately "teleports" the bot to the
 // suggested node so the next tick starts from there.
 struct WalkSimulator
 {
    WalkBot bot;
    Vector3<float> position;
    std::vector<Vector3<float>> visited_nodes;
    std::vector<WalkBotStatus> status_history;
    bool finished{false};
    WalkSimulator(const std::shared_ptr<NavigationMesh>& mesh,
                  const Vector3<float>& start,
                  const Vector3<float>& goal,
                  float threshold)
        : position(start)
    {
        bot = WalkBot(mesh, threshold);
        bot.set_target(goal);
        bot.on_path([this](const Vector3<float>& next) {
            visited_nodes.push_back(next);
            position = next; // teleport to the suggested node
        });
        bot.on_status([this](WalkBotStatus s) {
            status_history.push_back(s);
            if (s == WalkBotStatus::FINISHED)
                finished = true;
        });
    }
    void run(int max_ticks = 100)
    {
        for (int tick = 0; tick < max_ticks && !finished; ++tick)
            bot.update(position);
    }
 };
 TEST(WalkBotSimulation, BotReachesTargetOnLinearMesh)
 {
    auto mesh = make_linear_mesh(5);
    WalkSimulator sim(mesh, {0.f, 0.f, 0.f}, {4.f, 0.f, 0.f}, 0.5f);
    sim.run(50);
    EXPECT_TRUE(sim.finished);
 }
 TEST(WalkBotSimulation, StatusTransitionSequenceIsCorrect)
 {
    // Expect: one or more PATHING updates, then exactly FINISHED at the end.
    auto mesh = make_linear_mesh(4);
    WalkSimulator sim(mesh, {0.f, 0.f, 0.f}, {3.f, 0.f, 0.f}, 0.5f);
    sim.run(50);
    ASSERT_TRUE(sim.finished);
    ASSERT_FALSE(sim.status_history.empty());
    // All entries before the last must be PATHING
    for (std::size_t i = 0; i + 1 < sim.status_history.size(); ++i)
        EXPECT_EQ(sim.status_history[i], WalkBotStatus::PATHING);
    EXPECT_EQ(sim.status_history.back(), WalkBotStatus::FINISHED);
 }
 TEST(WalkBotSimulation, BotVisitsNodesInForwardOrder)
 {
    auto mesh = make_linear_mesh(5);
    WalkSimulator sim(mesh, {0.f, 0.f, 0.f}, {4.f, 0.f, 0.f}, 0.5f);
    sim.run(50);
    ASSERT_FALSE(sim.visited_nodes.empty());
    // Verify that x-coordinates are non-decreasing (forward progress only).
    for (std::size_t i = 1; i < sim.visited_nodes.size(); ++i)
        EXPECT_GE(sim.visited_nodes[i].x, sim.visited_nodes[i - 1].x - 1e-3f);
 }
 TEST(WalkBotSimulation, TwoNodePathReachesGoal)
 {
    auto mesh = make_linear_mesh(2); // (0,0,0) <-> (1,0,0)
    WalkSimulator sim(mesh, {0.f, 0.f, 0.f}, {1.f, 0.f, 0.f}, 0.5f);
    sim.run(10);
    EXPECT_TRUE(sim.finished);
 }
 TEST(WalkBotSimulation, LongChainEventuallyFinishes)
 {
    constexpr int kLength = 20;
    auto mesh = make_linear_mesh(kLength);
    WalkSimulator sim(mesh,
                      {0.f, 0.f, 0.f},
                      {static_cast<float>(kLength - 1), 0.f, 0.f},
                      0.5f);
    sim.run(200);
    EXPECT_TRUE(sim.finished);
 }
 TEST(WalkBotSimulation, StartAlreadyAtTargetFinishesImmediately)
 {
    auto mesh = make_linear_mesh(3);
    WalkSimulator sim(mesh, {1.f, 0.f, 0.f}, {1.f, 0.f, 0.f}, 0.5f);
    sim.run(5);
    EXPECT_TRUE(sim.finished);
    EXPECT_EQ(sim.status_history.front(), WalkBotStatus::FINISHED);
    EXPECT_EQ(sim.status_history.size(), 1u);
 }
 TEST(WalkBotSimulation, NoIdleEmittedDuringSuccessfulWalk)
 {
    auto mesh = make_linear_mesh(4);
    WalkSimulator sim(mesh, {0.f, 0.f, 0.f}, {3.f, 0.f, 0.f}, 0.5f);
    sim.run(50);
    for (auto s : sim.status_history)
        EXPECT_NE(s, WalkBotStatus::IDLE);
 }
 // ---------------------------------------------------------------------------
 // Walk simulation on a branching mesh
 // ---------------------------------------------------------------------------
 TEST(WalkBotSimulation, BotNavigatesBranchingMesh)
 {
    // Diamond topology:
    //        (1,1,0)
    //       /       \
    // (0,0,0)       (2,0,0)
    //       \       /
    //        (1,-1,0)
    auto mesh = std::make_shared<NavigationMesh>();
    const Vector3<float> start{0.f, 0.f, 0.f};
    const Vector3<float> top{1.f, 1.f, 0.f};
    const Vector3<float> bot_node{1.f, -1.f, 0.f};
    const Vector3<float> goal{2.f, 0.f, 0.f};
    mesh->m_vertex_map[start]    = {top, bot_node};
    mesh->m_vertex_map[top]      = {start, goal};
    mesh->m_vertex_map[bot_node] = {start, goal};
    mesh->m_vertex_map[goal]     = {top, bot_node};
    WalkSimulator sim(mesh, start, goal, 0.5f);
    sim.run(20);
    EXPECT_TRUE(sim.finished);
 }
Author	SHA1	Message	Date
Orange	20930c629a	added method to get camera matrix	2026-04-18 15:40:38 +03:00
Orange	0845a2e863	clarified interfaces	2026-04-18 12:54:37 +03:00
Orange++	f3f454b02e	Merge pull request #182 from orange-cpp/feature/camera_upgrade Feature/camera upgrade	2026-04-15 18:59:18 +03:00
Orange++	0419043720	Update include/omath/engines/frostbite_engine/camera.hpp Co-authored-by: Copilot <175728472+Copilot@users.noreply.github.com>	2026-04-15 03:48:03 +03:00
Orange	79f64d9679	fixed unreal bug, improved interface	2026-04-15 03:38:02 +03:00
Orange	dbe29926dc	fixed unity bug	2026-04-15 03:25:53 +03:00
Orange	9d30446c55	added ability to get view angles from view matrix	2026-04-15 03:08:06 +03:00
Orange++	ba80aebfae	Merge pull request #181 from orange-cpp/feature/walk-bot Feature/walk bot	2026-04-14 15:23:49 +03:00
Orange	9c1b6d0ba3	added tests improved API	2026-04-12 21:21:23 +03:00
Orange	ea07d17dbb	improved walkbot	2026-04-12 12:05:40 +03:00
Orange	bb974da0e2	improvement	2026-04-12 11:16:39 +03:00
Orange	fde764c1fa	added code	2026-04-12 11:12:17 +03:00
va_alpatov	28e86fc355	tests hotfix	2026-04-11 20:23:08 +03:00
va_alpatov	93e7a9457a	fixed pathfinding bug	2026-04-11 20:06:39 +03:00
Orange	8f65183882	fixed tests	2026-04-08 15:34:10 +03:00
Orange	327db8d441	updated contributing	2026-04-03 20:59:34 +03:00
Orange	d8188de736	keeping 1 AABB type	2026-03-28 14:22:36 +03:00
Orange++	33cd3f64e4	Merge pull request #180 from orange-cpp/feature/aabb-linetrace added aabb line trace	2026-03-25 03:37:35 +03:00
Orange	67a07eed45	added aabb line trace	2026-03-25 03:14:22 +03:00
Orange++	0b52b2847b	Merge pull request #179 from orange-cpp/feature/aabb_check added AABB check	2026-03-24 10:45:00 +03:00
Orange	d38895e4d7	added AABB check	2026-03-24 10:20:50 +03:00