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24 Commits
3b0470cc11 ... main

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
Orange
04203d46ff patch 2026-03-24 06:44:10 +03:00
Orange
bcbb5c1a8d fixed index 2026-03-24 06:05:56 +03:00
Orange
ba46c86664 simplified method 2026-03-24 06:03:35 +03:00
23 changed files with 2082 additions and 75 deletions
Expand all files Collapse all files

7
.claude/settings.local.json
View File

@@ -1,7 +0,0 @@
{
"permissions": {
"allow": [
"Bash(ls:*)"
]
}
}

4
.idea/editor.xml generated
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@@ -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" />

46
CONTRIBUTING.md
View File

@@ -1,32 +1,36 @@
## 🤝 Contributing to OMath or other Orange's Projects
# Contributing
### ❕ Prerequisites
## Prerequisites
- A working up-to-date OMath installation
- C++ knowledge
- Git knowledge
- Ability to ask for help (Feel free to create empty pull-request or PM a maintainer
in [Telegram](https://t.me/orange_cpp))
- C++ compiler with C++23 support (Clang 18+, GCC 14+, MSVC 19.38+)
- CMake 3.25+
- Git
- Familiarity with the codebase (see `INSTALL.md` for setup)
### ⏬ 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
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.
## Code Style
OMath development is performed on multiple branches. Changes are then pull requested into master. By default, changes
merged into master will not roll out to stable build users unless the `stable` tag is updated.
Follow the project `.clang-format`. Run `clang-format` before committing.
### 📜 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
can build OMath by running `cmake --build cmake-build/build/windows-release --target omath -j 6` in the source
directory.
Run `cmake --list-presets` to see available configurations.
## Tests
All new functionality must include unit tests. Run the test binary after building to verify nothing is broken.

12
examples/example_barycentric/example_barycentric.cpp
View File

@@ -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.y);
lines.push_back(color.z);
lines.push_back(color.value().x);
lines.push_back(color.value().y);
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.y);
lines.push_back(color.z);
lines.push_back(color.value().x);
lines.push_back(color.value().y);
lines.push_back(color.value().z);
lines.push_back(1.0f); // size
lines.push_back(1.0f); // isLine
};

12
examples/example_glfw3/example_glfw3.cpp
View File

@@ -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;

28
include/omath/3d_primitives/aabb.hpp Normal file
View File

@@ -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

50
include/omath/collision/line_tracer.hpp
View File

@@ -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

2
include/omath/engines/cry_engine/camera.hpp
View File

@@ -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

4
include/omath/engines/frostbite_engine/camera.hpp
View File

@@ -9,5 +9,5 @@
namespace omath::frostbite_engine
{
using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, false, NDCDepthRange::ZERO_TO_ONE>;
} // namespace omath::unity_engine
using Camera = projection::Camera<Mat4X4, ViewAngles, CameraTrait, NDCDepthRange::ZERO_TO_ONE>;
} // namespace omath::frostbite_engine

2
include/omath/engines/iw_engine/camera.hpp
View File

@@ -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

2
include/omath/engines/opengl_engine/camera.hpp
View File

@@ -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

2
include/omath/engines/source_engine/camera.hpp
View File

@@ -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

2
include/omath/engines/unity_engine/camera.hpp
View File

@@ -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

2
include/omath/engines/unreal_engine/camera.hpp
View File

@@ -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

46
include/omath/pathfinding/walk_bot.hpp Normal file
View File

@@ -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

156
include/omath/projection/camera.hpp
View File

@@ -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,
NDCDepthRange depth_range = NDCDepthRange::NEGATIVE_ONE_TO_ONE>
template<class Mat4X4Type, class ViewAnglesType, class TraitClass,
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
@@ -398,20 +521,19 @@ namespace omath::projection
return true;
if (data[1] < -1.0f - eps || data[1] > 1.0f + eps)
return true;
// z range depends on the NDC depth convention
return is_ndc_z_value_out_of_bounds(data[2]);
}
template<class ZType>
[[nodiscard]]
constexpr static bool is_ndc_z_value_out_of_bounds(const ZType& z_ndc) noexcept
{
constexpr auto eps = std::numeric_limits<float>::epsilon();
if constexpr (depth_range == NDCDepthRange::NEGATIVE_ONE_TO_ONE)
return z_ndc < -1.0f - eps || z_ndc > 1.0f + eps;
if constexpr (depth_range == NDCDepthRange::ZERO_TO_ONE)
{
if (data[2] < 0.0f - eps || data[2] > 1.0f + eps)
return true;
}
else
{
if (data[2] < -1.0f - eps || data[2] > 1.0f + eps)
return true;
}
return z_ndc < 0.0f - eps || z_ndc > 1.0f + eps;
return false;
std::unreachable();
}
// NDC REPRESENTATION:

4
source/pathfinding/a_star.cpp
View File

@@ -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))

92
source/pathfinding/walk_bot.cpp Normal file
View File

@@ -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

181
tests/engines/unit_test_frostbite_engine.cpp
View File

@@ -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);
}

12
tests/general/unit_test_a_star.cpp
View File

@@ -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);
EXPECT_EQ(path.front(), v2);
ASSERT_EQ(path.size(), 2u);
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);
EXPECT_EQ(path.front(), v2);
ASSERT_EQ(path.size(), 2u);
EXPECT_EQ(path.front(), v1);
EXPECT_EQ(path.back(), v2);
}
TEST(AstarTests, NoPathWhenDisconnected)

125
tests/general/unit_test_line_tracer_aabb.cpp Normal file
View File

@@ -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);
}

726
tests/general/unit_test_projection.cpp
View File

@@ -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>
@@ -216,4 +222,722 @@ TEST(UnitTestProjection, ScreenToWorldBottomLeftCorner)
EXPECT_NEAR(screen_cords->x, initial_screen_cords.x, 0.001f);
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);
}

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// 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);
}