admin/omath
1
0
Fork 0
mirror of https://github.com/orange-cpp/omath.git synced 2026-04-18 22:23:26 +00:00
Code Issues Packages Projects Releases Wiki Activity

Compare commits

base: admin:9752accb1415b5e144627abb63ce997bf0c5fa98
Branches Tags
admin:main admin:feature/bvh_tree admin:feature/physx admin:feature/vmprotect-sdk-integration
admin:v5.1.1 admin:v5.1.0 admin:v5.1.0.rc6 admin:v5.1.0.rc5 admin:v5.1.0.rc4 admin:v5.1.0.rc3 admin:v5.1.0.rc2 admin:v5-ci-test admin:v5.1.0.rc1 admin:v5.0.0 admin:v4.7.0 admin:v4.6.1 admin:v4.6.0 admin:v4.5.1 admin:v4.5.0 admin:v4.4.0 admin:v4.3.0 admin:v4.2.0 admin:v4.1.0 admin:v4.0.1 admin:v3.10.1 admin:v3.9.4 admin:v3.9.3 admin:v3.9.0 admin:v3.8.2 admin:v3.8.1 admin:v3.6.1 admin:v3.5.1 admin:v3.2.3 admin:v3.0.3 admin:v2.3.2 admin:v2.3.1 admin:v2.3.0 admin:v2.2.1 admin:v2.2.0 admin:v2.1.1 admin:v2.1.0 admin:v2.0.2 admin:v2.0.1 admin:v2.0.0 admin:v1.3.0 admin:v1.2.0 admin:v1.1.3 admin:v1.1.2 admin:v1.1.1 admin:v1.1.0 admin:v1.0.1 admin:v1.0.0
...
compare: admin:feature/physx
Branches Tags
admin:main admin:feature/bvh_tree admin:feature/physx admin:feature/vmprotect-sdk-integration
admin:v5.1.1 admin:v5.1.0 admin:v5.1.0.rc6 admin:v5.1.0.rc5 admin:v5.1.0.rc4 admin:v5.1.0.rc3 admin:v5.1.0.rc2 admin:v5-ci-test admin:v5.1.0.rc1 admin:v5.0.0 admin:v4.7.0 admin:v4.6.1 admin:v4.6.0 admin:v4.5.1 admin:v4.5.0 admin:v4.4.0 admin:v4.3.0 admin:v4.2.0 admin:v4.1.0 admin:v4.0.1 admin:v3.10.1 admin:v3.9.4 admin:v3.9.3 admin:v3.9.0 admin:v3.8.2 admin:v3.8.1 admin:v3.6.1 admin:v3.5.1 admin:v3.2.3 admin:v3.0.3 admin:v2.3.2 admin:v2.3.1 admin:v2.3.0 admin:v2.2.1 admin:v2.2.0 admin:v2.1.1 admin:v2.1.0 admin:v2.0.2 admin:v2.0.1 admin:v2.0.0 admin:v1.3.0 admin:v1.2.0 admin:v1.1.3 admin:v1.1.2 admin:v1.1.1 admin:v1.1.0 admin:v1.0.1 admin:v1.0.0

32 Commits
9752accb14 ... feature/ph

Author SHA1 Message Date
orange
69e9735063 added more tests 2026-03-13 03:23:02 +03:00
orange
35b8510cf4 fixed tests 2026-03-13 03:18:13 +03:00
orange
ba662e44e2 added files 2026-03-13 03:16:32 +03:00
Orange++
2002bcca83 Merge pull request #163 from orange-cpp/feature/serailization 
Feature/serailization
 2026-03-11 14:47:23 +03:00
orange
ffacba71e2 changed to string view 2026-03-11 14:31:45 +03:00
orange
6081a9c426 added throw test 2026-03-11 14:30:01 +03:00
orange
8bbd504356 added check 2026-03-11 14:23:12 +03:00
orange
1d54039f57 added events 2026-03-11 14:19:58 +03:00
orange
93fc93d4f6 added more tests 2026-03-11 14:16:26 +03:00
Orange
b8a578774c improved serialization 2026-03-11 14:12:52 +03:00
Orange++
bfa6c77776 Merge pull request #162 from orange-cpp/feature/scanner_example 
Auto stash before checking out "origin/main"
 2026-03-10 21:39:20 +03:00
Orange
1341ef9925 Auto stash before checking out "origin/main" 2026-03-10 20:06:00 +03:00
Orange++
3ccbb0b25b Merge pull request #161 from orange-cpp/feature/lua-bindings 
Feature/lua bindings
 2026-03-10 19:41:34 +03:00
Orange
68993db48a updated read me 2026-03-10 19:22:39 +03:00
Orange
337204b3bf fixed missing source 2026-03-10 19:09:29 +03:00
Orange
1e601d2d8f android fix 2026-03-10 19:01:54 +03:00
Orange
2b4a75d011 added lua status to build logs 2026-03-10 19:00:36 +03:00
Orange
99a30e8fdf added pattern scan to lua 2026-03-10 18:55:55 +03:00
Orange
0cdd1d021f added triangle to lua 2026-03-10 18:39:20 +03:00
Orange
a79ac9743a added badge, added triangle 2026-03-10 18:39:10 +03:00
Orange
f26afb703b added bigobj for msvc and mingw 2026-03-10 18:29:13 +03:00
Orange
f237ee5f6a removed useless headers 2026-03-10 18:15:54 +03:00
Orange
9058ea9b39 refactored to class 2026-03-10 18:14:29 +03:00
Orange
f707ac1adb fixed forward decl 2026-03-10 18:04:31 +03:00
Orange
cbdabd3fc2 removed useless header 2026-03-10 17:57:11 +03:00
Orange
30e3feb4f8 fix 2026-03-10 16:38:00 +03:00
Orange
0726fdef32 webasm fix 2026-03-10 16:31:49 +03:00
Orange
0ffe0c2bdc potential fix 2026-03-10 16:24:21 +03:00
Orange
e9600ad42b splited lua into multiple sources 2026-03-10 16:15:02 +03:00
Orange
673835618c restructurized stuff 2026-03-10 15:57:22 +03:00
orange
afb2a13dd6 added color 2026-03-08 23:08:23 +03:00
orange
943472cf64 migrated to sol2 
decomposed method

added vector2, vector4

refactored tests

added opengl engine to lua

added other engines

added source tests

removed tons of lua files
 2026-03-08 12:55:35 +03:00
43 changed files with 3307 additions and 87 deletions
Expand all files Collapse all files

20
.github/workflows/cmake-multi-platform.yml vendored
View File

@@ -107,7 +107,7 @@ jobs:
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DOMATH_ENABLE_COVERAGE=${{ matrix.coverage == true && 'ON' || 'OFF' }} \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;lua"
- name: Build
shell: bash
@@ -193,7 +193,7 @@ jobs:
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DOMATH_ENABLE_COVERAGE=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;lua"
- name: Build
shell: bash
@@ -234,7 +234,7 @@ jobs:
-DOMATH_ENABLE_COVERAGE=ON \
-DOMATH_THREAT_WARNING_AS_ERROR=OFF \
-DCMAKE_BUILD_TYPE=Debug \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;lua"
cmake --build cmake-build/build/${{ matrix.preset }} --config Debug --target unit_tests omath
- name: Run Tests (Generates .profraw)
@@ -373,7 +373,7 @@ jobs:
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DOMATH_ENABLE_COVERAGE=${{ matrix.coverage == true && 'ON' || 'OFF' }} \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;lua"
- name: Build
shell: bash
@@ -450,7 +450,7 @@ jobs:
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;tests;lua"
- name: Build
shell: bash
@@ -509,7 +509,7 @@ jobs:
cmake --preset ${{ matrix.preset }} \
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests" \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;lua" \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported"
cmake --build cmake-build/build/${{ matrix.preset }} --target unit_tests omath
./out/Release/unit_tests
@@ -581,7 +581,7 @@ jobs:
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;tests;lua"
- name: Build
shell: bash
@@ -650,7 +650,7 @@ jobs:
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;tests;lua"
- name: Build
shell: bash
@@ -735,7 +735,7 @@ jobs:
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;tests"
-DVCPKG_MANIFEST_FEATURES="imgui;tests;lua"
- name: Build
run: |
@@ -800,7 +800,7 @@ jobs:
-DOMATH_BUILD_TESTS=ON \
-DOMATH_BUILD_BENCHMARK=ON \
-DOMATH_ENABLE_VALGRIND=ON \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;tests;benchmark"
-DVCPKG_MANIFEST_FEATURES="imgui;avx2;lua;tests;benchmark"
- name: Build All Targets
shell: bash

5
.luarc.json Normal file
View File

@@ -0,0 +1,5 @@
{
"diagnostics.globals": [
"omath"
]
}

35
CMakeLists.txt
View File

@@ -31,6 +31,11 @@ option(OMATH_SUPRESS_SAFETY_CHECKS
option(OMATH_ENABLE_COVERAGE "Enable coverage" OFF)
option(OMATH_ENABLE_FORCE_INLINE
"Will for compiler to make some functions to be force inlined no matter what" ON)
option(OMATH_ENABLE_LUA
"omath bindings for lua" OFF)
option(OMATH_ENABLE_PHYSX
"PhysX-backed collider implementations" OFF)
if(VCPKG_MANIFEST_FEATURES)
foreach(omath_feature IN LISTS VCPKG_MANIFEST_FEATURES)
if(omath_feature STREQUAL "imgui")
@@ -43,6 +48,10 @@ if(VCPKG_MANIFEST_FEATURES)
set(OMATH_BUILD_BENCHMARK ON)
elseif(omath_feature STREQUAL "examples")
set(OMATH_BUILD_EXAMPLES ON)
elseif(omath_feature STREQUAL "lua")
set(OMATH_ENABLE_LUA ON)
elseif(omath_feature STREQUAL "physx")
set(OMATH_ENABLE_PHYSX ON)
endif()
endforeach()
@@ -72,6 +81,8 @@ if(${PROJECT_IS_TOP_LEVEL})
message(STATUS "[${PROJECT_NAME}]: Building using vcpkg ${OMATH_BUILD_VIA_VCPKG}")
message(STATUS "[${PROJECT_NAME}]: Coverage feature status ${OMATH_ENABLE_COVERAGE}")
message(STATUS "[${PROJECT_NAME}]: Valgrind feature status ${OMATH_ENABLE_VALGRIND}")
message(STATUS "[${PROJECT_NAME}]: Lua feature status ${OMATH_ENABLE_LUA}")
message(STATUS "[${PROJECT_NAME}]: PhysX feature status ${OMATH_ENABLE_PHYSX}")
endif()
file(GLOB_RECURSE OMATH_SOURCES CONFIGURE_DEPENDS "${CMAKE_CURRENT_SOURCE_DIR}/source/*.cpp")
@@ -83,6 +94,24 @@ else()
add_library(${PROJECT_NAME} STATIC ${OMATH_SOURCES} ${OMATH_HEADERS})
endif()
if (OMATH_ENABLE_LUA)
target_compile_definitions(${PROJECT_NAME} PUBLIC OMATH_ENABLE_LUA)
find_package(Lua REQUIRED)
target_include_directories(${PROJECT_NAME} PRIVATE ${LUA_INCLUDE_DIR})
target_link_libraries(${PROJECT_NAME} PRIVATE ${LUA_LIBRARIES})
find_path(SOL2_INCLUDE_DIRS "sol/abort.hpp")
target_include_directories(${PROJECT_NAME} PRIVATE ${SOL2_INCLUDE_DIRS})
endif ()
if (OMATH_ENABLE_PHYSX)
target_compile_definitions(${PROJECT_NAME} PUBLIC OMATH_ENABLE_PHYSX)
find_package(unofficial-omniverse-physx-sdk CONFIG REQUIRED)
target_link_libraries(${PROJECT_NAME} PUBLIC unofficial::omniverse-physx-sdk::sdk)
endif ()
add_library(${PROJECT_NAME}::${PROJECT_NAME} ALIAS ${PROJECT_NAME})
target_compile_definitions(${PROJECT_NAME} PUBLIC OMATH_VERSION="${PROJECT_VERSION}")
@@ -174,6 +203,12 @@ elseif(OMATH_THREAT_WARNING_AS_ERROR)
target_compile_options(${PROJECT_NAME} PRIVATE -Wall -Wextra -Wpedantic -Werror)
endif()
if (CMAKE_CXX_COMPILER_ID STREQUAL "MSVC")
target_compile_options(${PROJECT_NAME} PRIVATE /bigobj)
endif()
if (CMAKE_CXX_COMPILER_ID STREQUAL "GNU" AND CMAKE_HOST_SYSTEM_NAME EQUAL "Windows")
target_compile_options(${PROJECT_NAME} PRIVATE -mbig-obj)
endif()
# Windows SDK redefine min/max via preprocessor and break std::min and std::max
if(CMAKE_CXX_COMPILER_ID STREQUAL "MSVC")
target_compile_definitions(${PROJECT_NAME} INTERFACE NOMINMAX)

4
CMakePresets.json
View File

@@ -145,7 +145,7 @@
"hidden": true,
"inherits": ["linux-base", "vcpkg-base"],
"cacheVariables": {
"VCPKG_MANIFEST_FEATURES": "tests;imgui;avx2"
"VCPKG_MANIFEST_FEATURES": "tests;imgui;avx2;lua;physx"
}
},
{
@@ -235,7 +235,7 @@
"hidden": true,
"inherits": ["darwin-base", "vcpkg-base"],
"cacheVariables": {
"VCPKG_MANIFEST_FEATURES": "tests;imgui;avx2;examples"
"VCPKG_MANIFEST_FEATURES": "tests;imgui;avx2;examples;lua"
}
},
{

2
README.md
View File

@@ -9,6 +9,7 @@
[![CodeFactor](https://www.codefactor.io/repository/github/orange-cpp/omath/badge)](https://www.codefactor.io/repository/github/orange-cpp/omath)
![GitHub Actions Workflow Status](https://img.shields.io/github/actions/workflow/status/orange-cpp/omath/cmake-multi-platform.yml)
[![Vcpkg package](https://repology.org/badge/version-for-repo/vcpkg/orange-math.svg)](https://repology.org/project/orange-math/versions)
![Conan Center](https://img.shields.io/conan/v/omath)
![GitHub forks](https://img.shields.io/github/forks/orange-cpp/omath)
[![discord badge](https://dcbadge.limes.pink/api/server/https://discord.gg/eDgdaWbqwZ?style=flat)](https://discord.gg/eDgdaWbqwZ)
[![telegram badge](https://img.shields.io/badge/Telegram-2CA5E0?style=flat-squeare&logo=telegram&logoColor=white)](https://t.me/orangennotes)
@@ -83,6 +84,7 @@ if (auto screen = camera.world_to_screen(world_position)) {
- **Engine support**: Supports coordinate systems of **Source, Unity, Unreal, Frostbite, IWEngine, CryEngine and canonical OpenGL**.
- **Cross platform**: Supports Windows, MacOS and Linux.
- **Algorithms**: Has ability to scan for byte pattern with wildcards in ELF/Mach-O/PE files/modules, binary slices, works even with Wine apps.
- **Scripting**: Supports to make scripts in Lua out of box
- **Battle tested**: It's already used by some big players on the market like wraith.su and bluedream.ltd
<div align = center>

59
include/omath/collision/physx_box_collider.hpp Normal file
View File

@@ -0,0 +1,59 @@
//
// Created by orange-cpp
//
#pragma once
#ifdef OMATH_ENABLE_PHYSX
#include "collider_interface.hpp"
#include <PxPhysicsAPI.h>
namespace omath::collision
{
/// Axis-aligned box collider backed by PhysX PxBoxGeometry.
/// Half-extents are stored in PhysX convention (positive values along each axis).
class PhysXBoxCollider final : public ColliderInterface<Vector3<float>>
{
public:
/// @param half_extents Half-widths along X, Y and Z axes (all must be > 0).
/// @param origin World-space centre of the box.
explicit PhysXBoxCollider(const VectorType& half_extents, const VectorType& origin = {})
: m_geometry(physx::PxVec3(half_extents.x, half_extents.y, half_extents.z))
, m_origin(origin)
{
}
/// Support function: returns the world-space point on the box furthest in @p direction.
/// For a box, the furthest point along d is origin + (sign(d.x)*hx, sign(d.y)*hy, sign(d.z)*hz).
[[nodiscard]]
VectorType find_abs_furthest_vertex_position(const VectorType& direction) const override
{
const auto& he = m_geometry.halfExtents;
return {
m_origin.x + (direction.x >= 0.f ? he.x : -he.x),
m_origin.y + (direction.y >= 0.f ? he.y : -he.y),
m_origin.z + (direction.z >= 0.f ? he.z : -he.z),
};
}
[[nodiscard]]
const VectorType& get_origin() const override { return m_origin; }
void set_origin(const VectorType& new_origin) override { m_origin = new_origin; }
[[nodiscard]]
const physx::PxBoxGeometry& get_geometry() const { return m_geometry; }
/// Update half-extents at runtime.
void set_half_extents(const VectorType& half_extents)
{
m_geometry = physx::PxBoxGeometry(physx::PxVec3(half_extents.x, half_extents.y, half_extents.z));
}
private:
physx::PxBoxGeometry m_geometry;
VectorType m_origin;
};
} // namespace omath::collision
#endif // OMATH_ENABLE_PHYSX

137
include/omath/collision/physx_rigid_body.hpp Normal file
View File

@@ -0,0 +1,137 @@
//
// Created by orange-cpp
//
#pragma once
#ifdef OMATH_ENABLE_PHYSX
#include "collider_interface.hpp"
#include "physx_world.hpp"
#include <PxPhysicsAPI.h>
#include <extensions/PxRigidBodyExt.h>
#include <cmath>
namespace omath::collision
{
/// Dynamic rigid body backed by a PhysX PxRigidDynamic actor.
/// Implements ColliderInterface so it can participate in both omath GJK
/// and PhysX simulation-based collision resolution.
///
/// Ownership: the actor is added to the world's scene on construction
/// and removed + released on destruction.
class PhysXRigidBody final : public ColliderInterface<Vector3<float>>
{
public:
/// @param world PhysXWorld that owns the scene.
/// @param geometry Shape geometry (PxBoxGeometry, PxSphereGeometry, …).
/// @param origin Initial world-space position.
/// @param density Mass density used to compute mass and inertia.
PhysXRigidBody(PhysXWorld& world, const physx::PxGeometry& geometry,
const VectorType& origin = {}, float density = 1.f)
: m_world(world)
, m_geometry(geometry)
{
const physx::PxTransform pose(physx::PxVec3(origin.x, origin.y, origin.z));
m_actor = world.get_physics().createRigidDynamic(pose);
physx::PxShape* shape = world.get_physics().createShape(
geometry, world.get_default_material(), true);
m_actor->attachShape(*shape);
shape->release();
physx::PxRigidBodyExt::updateMassAndInertia(*m_actor, density);
world.get_scene().addActor(*m_actor);
}
~PhysXRigidBody() override
{
m_world.get_scene().removeActor(*m_actor);
m_actor->release();
}
PhysXRigidBody(const PhysXRigidBody&) = delete;
PhysXRigidBody& operator=(const PhysXRigidBody&) = delete;
// ── ColliderInterface ────────────────────────────────────────────────
/// Support function — delegates to the stored geometry type so the body
/// can be used with omath GJK alongside the non-simulated colliders.
[[nodiscard]]
VectorType find_abs_furthest_vertex_position(const VectorType& direction) const override
{
const VectorType o = get_origin();
switch (m_geometry.getType())
{
case physx::PxGeometryType::eBOX:
{
const auto& he = m_geometry.box().halfExtents;
return {
o.x + (direction.x >= 0.f ? he.x : -he.x),
o.y + (direction.y >= 0.f ? he.y : -he.y),
o.z + (direction.z >= 0.f ? he.z : -he.z),
};
}
case physx::PxGeometryType::eSPHERE:
{
const float r = m_geometry.sphere().radius;
const float len = std::sqrt(direction.x * direction.x +
direction.y * direction.y +
direction.z * direction.z);
if (len == 0.f)
return o;
const float inv = r / len;
return { o.x + direction.x * inv,
o.y + direction.y * inv,
o.z + direction.z * inv };
}
default:
return o; // unsupported geometry — return centre
}
}
[[nodiscard]]
const VectorType& get_origin() const override
{
const auto& p = m_actor->getGlobalPose().p;
m_cached_origin = { p.x, p.y, p.z };
return m_cached_origin;
}
void set_origin(const VectorType& new_origin) override
{
physx::PxTransform pose = m_actor->getGlobalPose();
pose.p = physx::PxVec3(new_origin.x, new_origin.y, new_origin.z);
m_actor->setGlobalPose(pose);
}
// ── PhysX-specific API ───────────────────────────────────────────────
[[nodiscard]] physx::PxRigidDynamic& get_actor() { return *m_actor; }
[[nodiscard]] const physx::PxRigidDynamic& get_actor() const { return *m_actor; }
void set_linear_velocity(const VectorType& v)
{
m_actor->setLinearVelocity(physx::PxVec3(v.x, v.y, v.z));
}
[[nodiscard]]
VectorType get_linear_velocity() const
{
const auto& v = m_actor->getLinearVelocity();
return { v.x, v.y, v.z };
}
void set_kinematic(bool enabled)
{
m_actor->setRigidBodyFlag(physx::PxRigidBodyFlag::eKINEMATIC, enabled);
}
private:
PhysXWorld& m_world;
physx::PxGeometryHolder m_geometry;
physx::PxRigidDynamic* m_actor{nullptr};
mutable VectorType m_cached_origin{};
};
} // namespace omath::collision
#endif // OMATH_ENABLE_PHYSX

64
include/omath/collision/physx_sphere_collider.hpp Normal file
View File

@@ -0,0 +1,64 @@
//
// Created by orange-cpp
//
#pragma once
#ifdef OMATH_ENABLE_PHYSX
#include "collider_interface.hpp"
#include <PxPhysicsAPI.h>
#include <cmath>
namespace omath::collision
{
/// Sphere collider backed by PhysX PxSphereGeometry.
class PhysXSphereCollider final : public ColliderInterface<Vector3<float>>
{
public:
/// @param radius Sphere radius (must be > 0).
/// @param origin World-space centre of the sphere.
explicit PhysXSphereCollider(float radius, const VectorType& origin = {})
: m_geometry(radius)
, m_origin(origin)
{
}
/// Support function: returns the world-space point on the sphere furthest in @p direction.
/// For a sphere that is simply origin + normalize(direction) * radius.
[[nodiscard]]
VectorType find_abs_furthest_vertex_position(const VectorType& direction) const override
{
const float len = std::sqrt(direction.x * direction.x +
direction.y * direction.y +
direction.z * direction.z);
if (len == 0.f)
return m_origin;
const float inv = m_geometry.radius / len;
return {
m_origin.x + direction.x * inv,
m_origin.y + direction.y * inv,
m_origin.z + direction.z * inv,
};
}
[[nodiscard]]
const VectorType& get_origin() const override { return m_origin; }
void set_origin(const VectorType& new_origin) override { m_origin = new_origin; }
[[nodiscard]]
const physx::PxSphereGeometry& get_geometry() const { return m_geometry; }
[[nodiscard]]
float get_radius() const { return m_geometry.radius; }
void set_radius(float radius) { m_geometry = physx::PxSphereGeometry(radius); }
private:
physx::PxSphereGeometry m_geometry;
VectorType m_origin;
};
} // namespace omath::collision
#endif // OMATH_ENABLE_PHYSX

82
include/omath/collision/physx_world.hpp Normal file
View File

@@ -0,0 +1,82 @@
//
// Created by orange-cpp
//
#pragma once
#ifdef OMATH_ENABLE_PHYSX
#include <PxPhysicsAPI.h>
namespace omath::collision
{
/// RAII owner of a PhysX Foundation + Physics + Scene.
/// One world per simulation context; not copyable or movable.
class PhysXWorld final
{
public:
explicit PhysXWorld(physx::PxVec3 gravity = {0.f, -9.81f, 0.f},
physx::PxU32 cpu_threads = 2)
{
m_foundation = PxCreateFoundation(PX_PHYSICS_VERSION, m_allocator, m_error_callback);
m_physics = PxCreatePhysics(PX_PHYSICS_VERSION, *m_foundation,
physx::PxTolerancesScale{});
physx::PxSceneDesc desc(m_physics->getTolerancesScale());
desc.gravity = gravity;
desc.cpuDispatcher = physx::PxDefaultCpuDispatcherCreate(cpu_threads);
m_dispatcher = static_cast<physx::PxDefaultCpuDispatcher*>(desc.cpuDispatcher);
desc.filterShader = physx::PxDefaultSimulationFilterShader;
m_scene = m_physics->createScene(desc);
// Default material: static friction 0.5, dynamic friction 0.5, restitution 0.
m_default_material = m_physics->createMaterial(0.5f, 0.5f, 0.f);
}
~PhysXWorld()
{
m_scene->release();
m_dispatcher->release();
m_default_material->release();
m_physics->release();
m_foundation->release();
}
PhysXWorld(const PhysXWorld&) = delete;
PhysXWorld& operator=(const PhysXWorld&) = delete;
/// Advance the simulation by @p dt seconds and block until results are ready.
void step(float dt)
{
m_scene->simulate(dt);
m_scene->fetchResults(true);
}
[[nodiscard]] physx::PxPhysics& get_physics() { return *m_physics; }
[[nodiscard]] physx::PxScene& get_scene() { return *m_scene; }
[[nodiscard]] physx::PxMaterial& get_default_material() { return *m_default_material; }
/// Add an infinite static ground plane at y = @p y_level facing +Y.
physx::PxRigidStatic* add_ground_plane(float y_level = 0.f)
{
physx::PxRigidStatic* plane = PxCreatePlane(
*m_physics,
physx::PxPlane(0.f, 1.f, 0.f, -y_level),
*m_default_material);
m_scene->addActor(*plane);
return plane;
}
private:
physx::PxDefaultAllocator m_allocator{};
physx::PxDefaultErrorCallback m_error_callback{};
physx::PxFoundation* m_foundation{nullptr};
physx::PxPhysics* m_physics{nullptr};
physx::PxDefaultCpuDispatcher* m_dispatcher{nullptr};
physx::PxScene* m_scene{nullptr};
physx::PxMaterial* m_default_material{nullptr};
};
} // namespace omath::collision
#endif // OMATH_ENABLE_PHYSX

25
include/omath/lua/lua.hpp Normal file
View File

@@ -0,0 +1,25 @@
//
// Created by orange on 07.03.2026.
//
#pragma once
#ifdef OMATH_ENABLE_LUA
#include <sol/forward.hpp>
namespace omath::lua
{
class LuaInterpreter final
{
public:
static void register_lib(lua_State* lua_state);
private:
static void register_vec2(sol::table& omath_table);
static void register_vec3(sol::table& omath_table);
static void register_vec4(sol::table& omath_table);
static void register_color(sol::table& omath_table);
static void register_triangle(sol::table& omath_table);
static void register_shared_types(sol::table& omath_table);
static void register_engines(sol::table& omath_table);
static void register_pattern_scan(sol::table& omath_table);
};
}
#endif

16
include/omath/pathfinding/navigation_mesh.hpp
View File

@@ -6,7 +6,9 @@
#include "omath/linear_algebra/vector3.hpp"
#include <expected>
#include <optional>
#include <string>
#include <unordered_map>
#include <vector>
namespace omath::pathfinding
@@ -28,10 +30,20 @@ namespace omath::pathfinding
[[nodiscard]]
bool empty() const;
[[nodiscard]] std::vector<uint8_t> serialize() const noexcept;
// Events -- per-vertex optional tag (e.g. "jump", "teleport")
void set_event(const Vector3<float>& vertex, const std::string_view& event_id);
void clear_event(const Vector3<float>& vertex);
void deserialize(const std::vector<uint8_t>& raw) noexcept;
[[nodiscard]]
std::optional<std::string> get_event(const Vector3<float>& vertex) const noexcept;
[[nodiscard]] std::string serialize() const noexcept;
void deserialize(const std::string& raw);
std::unordered_map<Vector3<float>, std::vector<Vector3<float>>> m_vertex_map;
private:
std::unordered_map<Vector3<float>, std::string> m_vertex_events;
};
} // namespace omath::pathfinding

27
source/lua/lua.cpp Normal file
View File

@@ -0,0 +1,27 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "lua.hpp"
#include <sol/sol.hpp>
#include "omath/lua/lua.hpp"
namespace omath::lua
{
void LuaInterpreter::register_lib(lua_State* lua_state)
{
sol::state_view lua(lua_state);
auto omath_table = lua["omath"].get_or_create<sol::table>();
register_vec2(omath_table);
register_vec3(omath_table);
register_vec4(omath_table);
register_color(omath_table);
register_triangle(omath_table);
register_shared_types(omath_table);
register_engines(omath_table);
register_pattern_scan(omath_table);
}
} // namespace omath::lua
#endif

46
source/lua/lua_color.cpp Normal file
View File

@@ -0,0 +1,46 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <sol/sol.hpp>
#include <omath/utility/color.hpp>
namespace omath::lua
{
void LuaInterpreter::register_color(sol::table& omath_table)
{
omath_table.new_usertype<omath::Color>(
"Color",
sol::factories([](float r, float g, float b, float a) { return omath::Color(r, g, b, a); },
[]() { return omath::Color(); }),
"from_rgba", [](uint8_t r, uint8_t g, uint8_t b, uint8_t a)
{ return omath::Color::from_rgba(r, g, b, a); }, "from_hsv",
sol::overload([](float h, float s, float v) { return omath::Color::from_hsv(h, s, v); },
[](const omath::Hsv& hsv) { return omath::Color::from_hsv(hsv); }),
"red", []() { return omath::Color::red(); }, "green", []() { return omath::Color::green(); }, "blue",
[]() { return omath::Color::blue(); },
"r", sol::property([](const omath::Color& c) { return c.value().x; }), "g",
sol::property([](const omath::Color& c) { return c.value().y; }), "b",
sol::property([](const omath::Color& c) { return c.value().z; }), "a",
sol::property([](const omath::Color& c) { return c.value().w; }),
"to_hsv", &omath::Color::to_hsv, "set_hue", &omath::Color::set_hue, "set_saturation",
&omath::Color::set_saturation, "set_value", &omath::Color::set_value, "blend", &omath::Color::blend,
sol::meta_function::to_string, &omath::Color::to_string);
omath_table.new_usertype<omath::Hsv>(
"Hsv", sol::constructors<omath::Hsv()>(), "hue",
sol::property([](const omath::Hsv& h) { return h.hue; }, [](omath::Hsv& h, float val) { h.hue = val; }),
"saturation",
sol::property([](const omath::Hsv& h) { return h.saturation; },
[](omath::Hsv& h, float val) { h.saturation = val; }),
"value",
sol::property([](const omath::Hsv& h) { return h.value; },
[](omath::Hsv& h, float val) { h.value = val; }));
}
} // namespace omath::lua::detail
#endif

227
source/lua/lua_engines.cpp Normal file
View File

@@ -0,0 +1,227 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.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/unity_engine/camera.hpp>
#include <omath/engines/unreal_engine/camera.hpp>
#include <sol/sol.hpp>
#include <string_view>
namespace
{
// ---- Canonical shared C++ type aliases ----------------------------------
// Each unique template instantiation must be registered exactly once.
using PitchAngle90 = omath::Angle<float, -90.f, 90.f, omath::AngleFlags::Clamped>;
using PitchAngle89 = omath::Angle<float, -89.f, 89.f, omath::AngleFlags::Clamped>;
using SharedYawRoll = omath::Angle<float, -180.f, 180.f, omath::AngleFlags::Normalized>;
using SharedFoV = omath::Angle<float, 0.f, 180.f, omath::AngleFlags::Clamped>;
using ViewAngles90 = omath::ViewAngles<PitchAngle90, SharedYawRoll, SharedYawRoll>;
using ViewAngles89 = omath::ViewAngles<PitchAngle89, SharedYawRoll, SharedYawRoll>;
std::string projection_error_to_string(omath::projection::Error e)
{
switch (e)
{
case omath::projection::Error::WORLD_POSITION_IS_OUT_OF_SCREEN_BOUNDS:
return "world position is out of screen bounds";
case omath::projection::Error::INV_VIEW_PROJ_MAT_DET_EQ_ZERO:
return "inverse view-projection matrix determinant is zero";
}
return "unknown error";
}
template<class AngleType>
void register_angle(sol::table& table, const char* name)
{
table.new_usertype<AngleType>(
name, sol::no_constructor, "from_degrees", &AngleType::from_degrees, "from_radians",
&AngleType::from_radians, "as_degrees", &AngleType::as_degrees, "as_radians", &AngleType::as_radians,
"sin", &AngleType::sin, "cos", &AngleType::cos, "tan", &AngleType::tan, "cot", &AngleType::cot,
sol::meta_function::addition, [](const AngleType& a, const AngleType& b)
{ return AngleType::from_degrees(a.as_degrees() + b.as_degrees()); }, sol::meta_function::subtraction,
[](const AngleType& a, const AngleType& b)
{ return AngleType::from_degrees(a.as_degrees() - b.as_degrees()); }, sol::meta_function::unary_minus,
[](const AngleType& a) { return AngleType::from_degrees(-a.as_degrees()); },
sol::meta_function::equal_to, [](const AngleType& a, const AngleType& b) { return a == b; },
sol::meta_function::to_string, [](const AngleType& a) { return std::format("{}deg", a.as_degrees()); });
}
// Set aliases in an engine subtable pointing to the already-registered shared types
template<class PitchAngleType, class ViewAnglesType>
void set_engine_aliases(sol::table& engine_table, sol::table& types)
{
if constexpr (std::is_same_v<PitchAngleType, PitchAngle90>)
engine_table["PitchAngle"] = types["PitchAngle90"];
else
engine_table["PitchAngle"] = types["PitchAngle89"];
engine_table["YawAngle"] = types["YawRoll"];
engine_table["RollAngle"] = types["YawRoll"];
engine_table["FieldOfView"] = types["FieldOfView"];
engine_table["ViewPort"] = types["ViewPort"];
if constexpr (std::is_same_v<ViewAnglesType, ViewAngles90>)
engine_table["ViewAngles"] = types["ViewAngles90"];
else
engine_table["ViewAngles"] = types["ViewAngles89"];
}
// Register an engine: alias shared types, register unique Camera
template<class EngineTraits>
void register_engine(sol::table& omath_table, const char* subtable_name)
{
using PitchAngle = typename EngineTraits::PitchAngle;
using ViewAngles = typename EngineTraits::ViewAngles;
using Camera = typename EngineTraits::Camera;
auto engine_table = omath_table[subtable_name].get_or_create<sol::table>();
auto types = omath_table["_types"].get<sol::table>();
set_engine_aliases<PitchAngle, ViewAngles>(engine_table, types);
engine_table.new_usertype<Camera>(
"Camera",
sol::constructors<Camera(const omath::Vector3<float>&, const ViewAngles&,
const omath::projection::ViewPort&, const omath::projection::FieldOfView&,
float, float)>(),
"look_at", &Camera::look_at, "get_forward", &Camera::get_forward, "get_right", &Camera::get_right,
"get_up", &Camera::get_up, "get_origin", &Camera::get_origin, "get_view_angles",
&Camera::get_view_angles, "get_near_plane", &Camera::get_near_plane, "get_far_plane",
&Camera::get_far_plane, "get_field_of_view", &Camera::get_field_of_view, "set_origin",
&Camera::set_origin, "set_view_angles", &Camera::set_view_angles, "set_view_port",
&Camera::set_view_port, "set_field_of_view", &Camera::set_field_of_view, "set_near_plane",
&Camera::set_near_plane, "set_far_plane", &Camera::set_far_plane,
"world_to_screen",
[](const Camera& cam, const omath::Vector3<float>& pos)
-> std::tuple<sol::optional<omath::Vector3<float>>, sol::optional<std::string>>
{
auto result = cam.world_to_screen(pos);
if (result)
return {*result, sol::nullopt};
return {sol::nullopt, projection_error_to_string(result.error())};
},
"screen_to_world",
[](const Camera& cam, const omath::Vector3<float>& pos)
-> std::tuple<sol::optional<omath::Vector3<float>>, sol::optional<std::string>>
{
auto result = cam.screen_to_world(pos);
if (result)
return {*result, sol::nullopt};
return {sol::nullopt, projection_error_to_string(result.error())};
});
}
// ---- Engine trait structs -----------------------------------------------
struct OpenGLEngineTraits
{
using PitchAngle = omath::opengl_engine::PitchAngle;
using ViewAngles = omath::opengl_engine::ViewAngles;
using Camera = omath::opengl_engine::Camera;
};
struct FrostbiteEngineTraits
{
using PitchAngle = omath::frostbite_engine::PitchAngle;
using ViewAngles = omath::frostbite_engine::ViewAngles;
using Camera = omath::frostbite_engine::Camera;
};
struct IWEngineTraits
{
using PitchAngle = omath::iw_engine::PitchAngle;
using ViewAngles = omath::iw_engine::ViewAngles;
using Camera = omath::iw_engine::Camera;
};
struct SourceEngineTraits
{
using PitchAngle = omath::source_engine::PitchAngle;
using ViewAngles = omath::source_engine::ViewAngles;
using Camera = omath::source_engine::Camera;
};
struct UnityEngineTraits
{
using PitchAngle = omath::unity_engine::PitchAngle;
using ViewAngles = omath::unity_engine::ViewAngles;
using Camera = omath::unity_engine::Camera;
};
struct UnrealEngineTraits
{
using PitchAngle = omath::unreal_engine::PitchAngle;
using ViewAngles = omath::unreal_engine::ViewAngles;
using Camera = omath::unreal_engine::Camera;
};
struct CryEngineTraits
{
using PitchAngle = omath::cry_engine::PitchAngle;
using ViewAngles = omath::cry_engine::ViewAngles;
using Camera = omath::cry_engine::Camera;
};
} // namespace
namespace omath::lua
{
void LuaInterpreter::register_shared_types(sol::table& omath_table)
{
auto t = omath_table["_types"].get_or_create<sol::table>();
register_angle<PitchAngle90>(t, "PitchAngle90");
register_angle<PitchAngle89>(t, "PitchAngle89");
register_angle<SharedYawRoll>(t, "YawRoll");
register_angle<SharedFoV>(t, "FieldOfView");
t.new_usertype<omath::projection::ViewPort>(
"ViewPort", sol::factories([](float w, float h) { return omath::projection::ViewPort{w, h}; }), "width",
sol::property([](const omath::projection::ViewPort& vp) { return vp.m_width; },
[](omath::projection::ViewPort& vp, float val) { vp.m_width = val; }),
"height",
sol::property([](const omath::projection::ViewPort& vp) { return vp.m_height; },
[](omath::projection::ViewPort& vp, float val) { vp.m_height = val; }),
"aspect_ratio", &omath::projection::ViewPort::aspect_ratio);
t.new_usertype<ViewAngles90>(
"ViewAngles90",
sol::factories([](PitchAngle90 p, SharedYawRoll y, SharedYawRoll r) { return ViewAngles90{p, y, r}; }),
"pitch",
sol::property([](const ViewAngles90& va) { return va.pitch; },
[](ViewAngles90& va, const PitchAngle90& val) { va.pitch = val; }),
"yaw",
sol::property([](const ViewAngles90& va) { return va.yaw; },
[](ViewAngles90& va, const SharedYawRoll& val) { va.yaw = val; }),
"roll",
sol::property([](const ViewAngles90& va) { return va.roll; },
[](ViewAngles90& va, const SharedYawRoll& val) { va.roll = val; }));
t.new_usertype<ViewAngles89>(
"ViewAngles89",
sol::factories([](PitchAngle89 p, SharedYawRoll y, SharedYawRoll r) { return ViewAngles89{p, y, r}; }),
"pitch",
sol::property([](const ViewAngles89& va) { return va.pitch; },
[](ViewAngles89& va, const PitchAngle89& val) { va.pitch = val; }),
"yaw",
sol::property([](const ViewAngles89& va) { return va.yaw; },
[](ViewAngles89& va, const SharedYawRoll& val) { va.yaw = val; }),
"roll",
sol::property([](const ViewAngles89& va) { return va.roll; },
[](ViewAngles89& va, const SharedYawRoll& val) { va.roll = val; }));
}
void LuaInterpreter::register_engines(sol::table& omath_table)
{
register_engine<OpenGLEngineTraits>(omath_table, "opengl");
register_engine<FrostbiteEngineTraits>(omath_table, "frostbite");
register_engine<IWEngineTraits>(omath_table, "iw");
register_engine<SourceEngineTraits>(omath_table, "source");
register_engine<UnityEngineTraits>(omath_table, "unity");
register_engine<UnrealEngineTraits>(omath_table, "unreal");
register_engine<CryEngineTraits>(omath_table, "cry");
}
} // namespace omath::lua::detail
#endif

104
source/lua/lua_pattern_scan.cpp Normal file
View File

@@ -0,0 +1,104 @@
//
// Created by orange on 10.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <format>
#include <omath/utility/elf_pattern_scan.hpp>
#include <omath/utility/macho_pattern_scan.hpp>
#include <omath/utility/pattern_scan.hpp>
#include <omath/utility/pe_pattern_scan.hpp>
#include <omath/utility/section_scan_result.hpp>
#include <sol/sol.hpp>
namespace omath::lua
{
void LuaInterpreter::register_pattern_scan(sol::table& omath_table)
{
omath_table.new_usertype<SectionScanResult>(
"SectionScanResult", sol::no_constructor,
"virtual_base_addr",
sol::property([](const SectionScanResult& r) { return r.virtual_base_addr; }),
"raw_base_addr",
sol::property([](const SectionScanResult& r) { return r.raw_base_addr; }),
"target_offset",
sol::property([](const SectionScanResult& r) { return r.target_offset; }),
sol::meta_function::to_string,
[](const SectionScanResult& r)
{
return std::format("SectionScanResult(vbase=0x{:X}, raw_base=0x{:X}, offset={})",
r.virtual_base_addr, r.raw_base_addr, r.target_offset);
});
// Generic scanner: accepts a Lua string as a byte buffer
auto ps_table = omath_table["PatternScanner"].get_or_create<sol::table>();
ps_table["scan"] = [](const std::string& data, const std::string& pattern) -> sol::optional<std::ptrdiff_t>
{
const auto* begin = reinterpret_cast<const std::byte*>(data.data());
const auto* end = begin + data.size();
const auto* result = PatternScanner::scan_for_pattern(begin, end, pattern);
if (result == end)
return sol::nullopt;
return std::distance(begin, result);
};
auto pe_table = omath_table["PePatternScanner"].get_or_create<sol::table>();
pe_table["scan_in_module"] = [](std::uintptr_t base_addr, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<std::uintptr_t>
{
auto result = PePatternScanner::scan_for_pattern_in_loaded_module(reinterpret_cast<const void*>(base_addr),
pattern, section.value_or(".text"));
if (!result)
return sol::nullopt;
return *result;
};
pe_table["scan_in_file"] = [](const std::string& path, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<SectionScanResult>
{
auto result = PePatternScanner::scan_for_pattern_in_file(std::filesystem::path(path), pattern,
section.value_or(".text"));
if (!result)
return sol::nullopt;
return *result;
};
auto elf_table = omath_table["ElfPatternScanner"].get_or_create<sol::table>();
elf_table["scan_in_module"] = [](std::uintptr_t base_addr, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<std::uintptr_t>
{
auto result = ElfPatternScanner::scan_for_pattern_in_loaded_module(reinterpret_cast<const void*>(base_addr),
pattern, section.value_or(".text"));
if (!result)
return sol::nullopt;
return *result;
};
elf_table["scan_in_file"] = [](const std::string& path, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<SectionScanResult>
{
auto result = ElfPatternScanner::scan_for_pattern_in_file(std::filesystem::path(path), pattern,
section.value_or(".text"));
if (!result)
return sol::nullopt;
return *result;
};
auto macho_table = omath_table["MachOPatternScanner"].get_or_create<sol::table>();
macho_table["scan_in_module"] = [](std::uintptr_t base_addr, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<std::uintptr_t>
{
auto result = MachOPatternScanner::scan_for_pattern_in_loaded_module(
reinterpret_cast<const void*>(base_addr), pattern, section.value_or("__text"));
if (!result)
return sol::nullopt;
return *result;
};
macho_table["scan_in_file"] = [](const std::string& path, const std::string& pattern,
sol::optional<std::string> section) -> sol::optional<SectionScanResult>
{
auto result = MachOPatternScanner::scan_for_pattern_in_file(std::filesystem::path(path), pattern,
section.value_or("__text"));
if (!result)
return sol::nullopt;
return *result;
};
}
} // namespace omath::lua
#endif

48
source/lua/lua_triangle.cpp Normal file
View File

@@ -0,0 +1,48 @@
//
// Created by orange on 10.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <sol/sol.hpp>
#include <omath/linear_algebra/triangle.hpp>
namespace omath::lua
{
void LuaInterpreter::register_triangle(sol::table& omath_table)
{
using Vec3f = omath::Vector3<float>;
using Tri3f = omath::Triangle<Vec3f>;
omath_table.new_usertype<Tri3f>(
"Triangle", sol::constructors<Tri3f(), Tri3f(const Vec3f&, const Vec3f&, const Vec3f&)>(),
"vertex1",
sol::property([](const Tri3f& t) { return t.m_vertex1; },
[](Tri3f& t, const Vec3f& v) { t.m_vertex1 = v; }),
"vertex2",
sol::property([](const Tri3f& t) { return t.m_vertex2; },
[](Tri3f& t, const Vec3f& v) { t.m_vertex2 = v; }),
"vertex3",
sol::property([](const Tri3f& t) { return t.m_vertex3; },
[](Tri3f& t, const Vec3f& v) { t.m_vertex3 = v; }),
"calculate_normal", &Tri3f::calculate_normal,
"side_a_length", &Tri3f::side_a_length,
"side_b_length", &Tri3f::side_b_length,
"side_a_vector", &Tri3f::side_a_vector,
"side_b_vector", &Tri3f::side_b_vector,
"hypot", &Tri3f::hypot,
"is_rectangular", &Tri3f::is_rectangular,
"mid_point", &Tri3f::mid_point,
sol::meta_function::to_string,
[](const Tri3f& t)
{
return std::format("Triangle(({}, {}, {}), ({}, {}, {}), ({}, {}, {}))",
t.m_vertex1.x, t.m_vertex1.y, t.m_vertex1.z,
t.m_vertex2.x, t.m_vertex2.y, t.m_vertex2.z,
t.m_vertex3.x, t.m_vertex3.y, t.m_vertex3.z);
});
}
} // namespace omath::lua
#endif

54
source/lua/lua_vec2.cpp Normal file
View File

@@ -0,0 +1,54 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <omath/linear_algebra/vector2.hpp>
#include <sol/sol.hpp>
namespace omath::lua
{
void LuaInterpreter::register_vec2(sol::table& omath_table)
{
using Vec2f = omath::Vector2<float>;
omath_table.new_usertype<Vec2f>(
"Vec2", sol::constructors<Vec2f(), Vec2f(float, float)>(),
"x", sol::property([](const Vec2f& v) { return v.x; }, [](Vec2f& v, const float val) { v.x = val; }),
"y", sol::property([](const Vec2f& v) { return v.y; }, [](Vec2f& v, const float val) { v.y = val; }),
sol::meta_function::addition, sol::resolve<Vec2f(const Vec2f&) const>(&Vec2f::operator+),
sol::meta_function::subtraction, sol::resolve<Vec2f(const Vec2f&) const>(&Vec2f::operator-),
sol::meta_function::unary_minus, sol::resolve<Vec2f() const>(&Vec2f::operator-),
sol::meta_function::equal_to, &Vec2f::operator==,
sol::meta_function::less_than, sol::resolve<bool(const Vec2f&) const>(&Vec2f::operator<),
sol::meta_function::less_than_or_equal_to, sol::resolve<bool(const Vec2f&) const>(&Vec2f::operator<=),
sol::meta_function::to_string,
[](const Vec2f& v) { return std::format("Vec2({}, {})", v.x, v.y); },
sol::meta_function::multiplication,
sol::overload(sol::resolve<Vec2f(const float&) const>(&Vec2f::operator*),
[](const float s, const Vec2f& v) { return v * s; }),
sol::meta_function::division,
sol::resolve<Vec2f(const float&) const>(&Vec2f::operator/),
"length", &Vec2f::length,
"length_sqr", &Vec2f::length_sqr,
"normalized", &Vec2f::normalized,
"dot", &Vec2f::dot,
"distance_to", &Vec2f::distance_to,
"distance_to_sqr", &Vec2f::distance_to_sqr,
"sum", &Vec2f::sum,
"abs",
[](const Vec2f& v)
{
Vec2f copy = v;
copy.abs();
return copy;
});
}
} // namespace omath::lua::detail
#endif

81
source/lua/lua_vec3.cpp Normal file
View File

@@ -0,0 +1,81 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <sol/sol.hpp>
#include <omath/linear_algebra/vector3.hpp>
namespace omath::lua
{
void LuaInterpreter::register_vec3(sol::table& omath_table)
{
using Vec3f = omath::Vector3<float>;
omath_table.new_usertype<Vec3f>(
"Vec3", sol::constructors<Vec3f(), Vec3f(float, float, float)>(),
"x", sol::property([](const Vec3f& v) { return v.x; }, [](Vec3f& v, float val) { v.x = val; }),
"y", sol::property([](const Vec3f& v) { return v.y; }, [](Vec3f& v, float val) { v.y = val; }),
"z", sol::property([](const Vec3f& v) { return v.z; }, [](Vec3f& v, float val) { v.z = val; }),
sol::meta_function::addition, sol::resolve<Vec3f(const Vec3f&) const>(&Vec3f::operator+),
sol::meta_function::subtraction, sol::resolve<Vec3f(const Vec3f&) const>(&Vec3f::operator-),
sol::meta_function::unary_minus, sol::resolve<Vec3f() const>(&Vec3f::operator-),
sol::meta_function::equal_to, &Vec3f::operator==, sol::meta_function::less_than,
sol::resolve<bool(const Vec3f&) const>(&Vec3f::operator<), sol::meta_function::less_than_or_equal_to,
sol::resolve<bool(const Vec3f&) const>(&Vec3f::operator<=), sol::meta_function::to_string,
[](const Vec3f& v) { return std::format("Vec3({}, {}, {})", v.x, v.y, v.z); },
sol::meta_function::multiplication,
sol::overload(sol::resolve<Vec3f(const float&) const>(&Vec3f::operator*),
sol::resolve<Vec3f(const Vec3f&) const>(&Vec3f::operator*),
[](const float s, const Vec3f& v) { return v * s; }),
sol::meta_function::division,
sol::overload(sol::resolve<Vec3f(const float&) const>(&Vec3f::operator/),
sol::resolve<Vec3f(const Vec3f&) const>(&Vec3f::operator/)),
"length", &Vec3f::length, "length_2d", &Vec3f::length_2d, "length_sqr", &Vec3f::length_sqr,
"normalized", &Vec3f::normalized, "dot", &Vec3f::dot, "cross", &Vec3f::cross, "distance_to",
&Vec3f::distance_to, "distance_to_sqr", &Vec3f::distance_to_sqr, "sum",
sol::resolve<float() const>(&Vec3f::sum), "sum_2d", &Vec3f::sum_2d, "point_to_same_direction",
&Vec3f::point_to_same_direction, "as_array", &Vec3f::as_array,
"abs",
[](const Vec3f& v)
{
Vec3f copy = v;
copy.abs();
return copy;
},
"angle_between",
[](const Vec3f& self,
const Vec3f& other) -> std::tuple<sol::optional<float>, sol::optional<std::string>>
{
auto result = self.angle_between(other);
if (result)
return std::make_tuple(sol::optional<float>(result->as_degrees()),
sol::optional<std::string>(sol::nullopt));
return std::make_tuple(sol::optional<float>(sol::nullopt),
sol::optional<std::string>("impossible angle (zero-length vector)"));
},
"is_perpendicular",
[](const Vec3f& self, const Vec3f& other, sol::optional<float> eps)
{ return self.is_perpendicular(other, eps.value_or(0.0001f)); },
"as_table",
[](const Vec3f& v, sol::this_state s) -> sol::table
{
sol::state_view lua(s);
sol::table t = lua.create_table();
t["x"] = v.x;
t["y"] = v.y;
t["z"] = v.z;
return t;
});
}
} // namespace omath::lua::detail
#endif

62
source/lua/lua_vec4.cpp Normal file
View File

@@ -0,0 +1,62 @@
//
// Created by orange on 07.03.2026.
//
#ifdef OMATH_ENABLE_LUA
#include "omath/lua/lua.hpp"
#include <sol/sol.hpp>
#include <omath/linear_algebra/vector4.hpp>
namespace omath::lua
{
void LuaInterpreter::register_vec4(sol::table& omath_table)
{
using Vec4f = omath::Vector4<float>;
omath_table.new_usertype<Vec4f>(
"Vec4", sol::constructors<Vec4f(), Vec4f(float, float, float, float)>(),
"x", sol::property([](const Vec4f& v) { return v.x; }, [](Vec4f& v, float val) { v.x = val; }),
"y", sol::property([](const Vec4f& v) { return v.y; }, [](Vec4f& v, float val) { v.y = val; }),
"z", sol::property([](const Vec4f& v) { return v.z; }, [](Vec4f& v, float val) { v.z = val; }),
"w", sol::property([](const Vec4f& v) { return v.w; }, [](Vec4f& v, float val) { v.w = val; }),
sol::meta_function::addition, sol::resolve<Vec4f(const Vec4f&) const>(&Vec4f::operator+),
sol::meta_function::subtraction, sol::resolve<Vec4f(const Vec4f&) const>(&Vec4f::operator-),
sol::meta_function::unary_minus, sol::resolve<Vec4f() const>(&Vec4f::operator-),
sol::meta_function::equal_to, &Vec4f::operator==,
sol::meta_function::less_than, sol::resolve<bool(const Vec4f&) const>(&Vec4f::operator<),
sol::meta_function::less_than_or_equal_to, sol::resolve<bool(const Vec4f&) const>(&Vec4f::operator<=),
sol::meta_function::to_string,
[](const Vec4f& v) { return std::format("Vec4({}, {}, {}, {})", v.x, v.y, v.z, v.w); },
sol::meta_function::multiplication,
sol::overload(sol::resolve<Vec4f(const float&) const>(&Vec4f::operator*),
sol::resolve<Vec4f(const Vec4f&) const>(&Vec4f::operator*),
[](const float s, const Vec4f& v) { return v * s; }),
sol::meta_function::division,
sol::overload(sol::resolve<Vec4f(const float&) const>(&Vec4f::operator/),
sol::resolve<Vec4f(const Vec4f&) const>(&Vec4f::operator/)),
"length", &Vec4f::length,
"length_sqr", &Vec4f::length_sqr,
"dot", &Vec4f::dot,
"sum", &Vec4f::sum,
"abs",
[](const Vec4f& v)
{
Vec4f copy = v;
copy.abs();
return copy;
},
"clamp",
[](Vec4f& v, float mn, float mx)
{
v.clamp(mn, mx);
return v;
});
}
} // namespace omath::lua::detail
#endif

107
source/pathfinding/navigation_mesh.cpp
View File

@@ -3,9 +3,9 @@
//
#include "omath/pathfinding/navigation_mesh.hpp"
#include <algorithm>
#include <cstring>
#include <limits>
#include <sstream>
#include <stdexcept>
namespace omath::pathfinding
{
std::expected<Vector3<float>, std::string>
@@ -30,77 +30,72 @@ namespace omath::pathfinding
return m_vertex_map.empty();
}
std::vector<uint8_t> NavigationMesh::serialize() const noexcept
void NavigationMesh::set_event(const Vector3<float>& vertex, const std::string_view& event_id)
{
std::vector<std::uint8_t> raw;
if (!m_vertex_map.contains(vertex))
throw std::invalid_argument(std::format("Vertex '{}' not found", vertex));
// Pre-calculate total size for better performance
std::size_t total_size = 0;
for (const auto& [vertex, neighbors] : m_vertex_map)
{
total_size += sizeof(vertex) + sizeof(std::uint16_t) + sizeof(Vector3<float>) * neighbors.size();
}
raw.reserve(total_size);
auto dump_to_vector = [&raw]<typename T>(const T& t)
{
const auto* byte_ptr = reinterpret_cast<const std::uint8_t*>(&t);
raw.insert(raw.end(), byte_ptr, byte_ptr + sizeof(T));
};
for (const auto& [vertex, neighbors] : m_vertex_map)
{
// Clamp neighbors count to fit in uint16_t (prevents silent data corruption)
// NOTE: If neighbors.size() > 65535, only the first 65535 neighbors will be serialized.
// This is a limitation of the current serialization format using uint16_t for count.
const auto clamped_count =
std::min<std::size_t>(neighbors.size(), std::numeric_limits<std::uint16_t>::max());
const auto neighbors_count = static_cast<std::uint16_t>(clamped_count);
dump_to_vector(vertex);
dump_to_vector(neighbors_count);
// Only serialize up to the clamped count
for (std::size_t i = 0; i < clamped_count; ++i)
dump_to_vector(neighbors[i]);
}
return raw;
m_vertex_events[vertex] = event_id;
}
void NavigationMesh::deserialize(const std::vector<uint8_t>& raw) noexcept
void NavigationMesh::clear_event(const Vector3<float>& vertex)
{
auto load_from_vector = [](const std::vector<uint8_t>& vec, std::size_t& offset, auto& value)
m_vertex_events.erase(vertex);
}
std::optional<std::string> NavigationMesh::get_event(const Vector3<float>& vertex) const noexcept
{
const auto it = m_vertex_events.find(vertex);
if (it == m_vertex_events.end())
return std::nullopt;
return it->second;
}
// Serialization format per vertex line:
// x y z neighbor_count event_id
// where event_id is "-" when no event is set.
// Neighbor lines follow: nx ny nz
std::string NavigationMesh::serialize() const noexcept
{
std::ostringstream oss;
for (const auto& [vertex, neighbors] : m_vertex_map)
{
if (offset + sizeof(value) > vec.size())
throw std::runtime_error("Deserialize: Invalid input data size.");
const auto event_it = m_vertex_events.find(vertex);
const std::string& event = (event_it != m_vertex_events.end()) ? event_it->second : "-";
std::copy_n(vec.data() + offset, sizeof(value), reinterpret_cast<uint8_t*>(&value));
offset += sizeof(value);
};
oss << vertex.x << ' ' << vertex.y << ' ' << vertex.z << ' ' << neighbors.size() << ' ' << event << '\n';
for (const auto& n : neighbors)
oss << n.x << ' ' << n.y << ' ' << n.z << '\n';
}
return oss.str();
}
void NavigationMesh::deserialize(const std::string& raw)
{
m_vertex_map.clear();
m_vertex_events.clear();
std::istringstream iss(raw);
std::size_t offset = 0;
while (offset < raw.size())
Vector3<float> vertex;
std::size_t neighbors_count;
std::string event;
while (iss >> vertex.x >> vertex.y >> vertex.z >> neighbors_count >> event)
{
Vector3<float> vertex;
load_from_vector(raw, offset, vertex);
std::uint16_t neighbors_count;
load_from_vector(raw, offset, neighbors_count);
std::vector<Vector3<float>> neighbors;
neighbors.reserve(neighbors_count);
for (std::size_t i = 0; i < neighbors_count; ++i)
{
Vector3<float> neighbor;
load_from_vector(raw, offset, neighbor);
neighbors.push_back(neighbor);
Vector3<float> n;
if (!(iss >> n.x >> n.y >> n.z))
throw std::runtime_error("Deserialize: Unexpected end of data.");
neighbors.push_back(n);
}
m_vertex_map.emplace(vertex, std::move(neighbors));
if (event != "-")
m_vertex_events.emplace(vertex, std::move(event));
}
}
} // namespace omath::pathfinding

15
tests/CMakeLists.txt
View File

@@ -4,8 +4,8 @@ project(unit_tests)
include(GoogleTest)
file(GLOB_RECURSE UNIT_TESTS_SOURCES CONFIGURE_DEPENDS "${CMAKE_CURRENT_SOURCE_DIR}/*.cpp")
add_executable(${PROJECT_NAME} ${UNIT_TESTS_SOURCES})
file(GLOB_RECURSE UNIT_TESTS_SOURCES CONFIGURE_DEPENDS "${CMAKE_CURRENT_SOURCE_DIR}/general/*.cpp" "${CMAKE_CURRENT_SOURCE_DIR}/engines/*.cpp")
add_executable(${PROJECT_NAME} ${UNIT_TESTS_SOURCES} main.cpp)
set_target_properties(
${PROJECT_NAME}
@@ -22,6 +22,16 @@ else() # GTest is being linked as vcpkg package
target_link_libraries(${PROJECT_NAME} PRIVATE GTest::gtest GTest::gtest_main omath::omath)
endif()
if (OMATH_ENABLE_LUA)
file(GLOB_RECURSE UNIT_TESTS_SOURCES_LUA CONFIGURE_DEPENDS "${CMAKE_CURRENT_SOURCE_DIR}/lua/*.cpp")
target_compile_definitions(${PROJECT_NAME} PRIVATE LUA_SCRIPTS_DIR="${CMAKE_CURRENT_SOURCE_DIR}/lua")
target_sources(${PROJECT_NAME} PRIVATE ${UNIT_TESTS_SOURCES_LUA})
if (EMSCRIPTEN)
target_link_options(${PROJECT_NAME} PRIVATE
"SHELL:--embed-file ${CMAKE_CURRENT_SOURCE_DIR}/lua@${CMAKE_CURRENT_SOURCE_DIR}/lua")
endif()
endif()
if(OMATH_ENABLE_COVERAGE)
include(${CMAKE_SOURCE_DIR}/cmake/Coverage.cmake)
omath_setup_coverage(${PROJECT_NAME})
@@ -36,3 +46,4 @@ endif()
if(NOT (ANDROID OR IOS OR EMSCRIPTEN))
gtest_discover_tests(${PROJECT_NAME})
endif()

181
tests/general/unit_test_a_star.cpp
View File

@@ -8,6 +8,29 @@
using namespace omath;
using namespace omath::pathfinding;
// ---------------------------------------------------------------------------
// Helpers
// ---------------------------------------------------------------------------
static NavigationMesh make_linear_chain(int length)
{
// 0 -> 1 -> 2 -> ... -> length-1 (directed)
NavigationMesh nav;
for (int i = 0; i < length; ++i)
{
const Vector3<float> v{static_cast<float>(i), 0.f, 0.f};
if (i + 1 < length)
nav.m_vertex_map[v] = {Vector3<float>{static_cast<float>(i + 1), 0.f, 0.f}};
else
nav.m_vertex_map[v] = {};
}
return nav;
}
// ---------------------------------------------------------------------------
// Basic reachability
// ---------------------------------------------------------------------------
TEST(AStarExtra, TrivialNeighbor)
{
NavigationMesh nav;
@@ -78,7 +101,7 @@ 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); // Astar convention: single-element or endpoint present
EXPECT_EQ(path.front(), goal);
}
TEST(AstarTests, TrivialDirectNeighborPath)
@@ -91,9 +114,6 @@ TEST(AstarTests, TrivialDirectNeighborPath)
nav.m_vertex_map.emplace(v2, std::vector<Vector3<float>>{v1});
const auto path = Astar::find_path(v1, v2, nav);
// Current A* implementation returns the end vertex as the reconstructed
// path (single-element) in the simple neighbor scenario. Assert that the
// endpoint is present and reachable.
ASSERT_EQ(path.size(), 1u);
EXPECT_EQ(path.front(), v2);
}
@@ -133,4 +153,155 @@ TEST(unit_test_a_star, finding_right_path)
mesh.m_vertex_map[{0.f, 2.f, 0.f}] = {{0.f, 3.f, 0.f}};
mesh.m_vertex_map[{0.f, 3.f, 0.f}] = {};
std::ignore = omath::pathfinding::Astar::find_path({}, {0.f, 3.f, 0.f}, mesh);
}
}
// ---------------------------------------------------------------------------
// Directed edges
// ---------------------------------------------------------------------------
TEST(AstarTests, DirectedEdge_ForwardPathExists)
{
// A -> B only; path from A to B should succeed
NavigationMesh nav;
constexpr Vector3<float> a{0.f, 0.f, 0.f};
constexpr Vector3<float> b{1.f, 0.f, 0.f};
nav.m_vertex_map[a] = {b};
nav.m_vertex_map[b] = {}; // no edge back
const auto path = Astar::find_path(a, b, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), b);
}
TEST(AstarTests, DirectedEdge_ReversePathMissing)
{
// A -> B only; path from B to A should fail
NavigationMesh nav;
constexpr Vector3<float> a{0.f, 0.f, 0.f};
constexpr Vector3<float> b{1.f, 0.f, 0.f};
nav.m_vertex_map[a] = {b};
nav.m_vertex_map[b] = {};
const auto path = Astar::find_path(b, a, nav);
EXPECT_TRUE(path.empty());
}
// ---------------------------------------------------------------------------
// Vertex snapping
// ---------------------------------------------------------------------------
TEST(AstarTests, OffMeshStart_SnapsToNearestVertex)
{
NavigationMesh nav;
constexpr Vector3<float> v1{0.f, 0.f, 0.f};
constexpr Vector3<float> v2{10.f, 0.f, 0.f};
nav.m_vertex_map[v1] = {v2};
nav.m_vertex_map[v2] = {v1};
// Start is slightly off v1 but closer to it than to v2
constexpr Vector3<float> off_start{0.1f, 0.f, 0.f};
const auto path = Astar::find_path(off_start, v2, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), v2);
}
TEST(AstarTests, OffMeshEnd_SnapsToNearestVertex)
{
NavigationMesh nav;
constexpr Vector3<float> v1{0.f, 0.f, 0.f};
constexpr Vector3<float> v2{10.f, 0.f, 0.f};
nav.m_vertex_map[v1] = {v2};
nav.m_vertex_map[v2] = {v1};
// Goal is slightly off v2 but closer to it than to v1
constexpr Vector3<float> off_goal{9.9f, 0.f, 0.f};
const auto path = Astar::find_path(v1, off_goal, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), v2);
}
// ---------------------------------------------------------------------------
// Cycle handling
// ---------------------------------------------------------------------------
TEST(AstarTests, CyclicGraph_FindsPathWithoutLooping)
{
// Triangle: A <-> B <-> C <-> A
NavigationMesh nav;
constexpr Vector3<float> a{0.f, 0.f, 0.f};
constexpr Vector3<float> b{1.f, 0.f, 0.f};
constexpr Vector3<float> c{0.5f, 1.f, 0.f};
nav.m_vertex_map[a] = {b, c};
nav.m_vertex_map[b] = {a, c};
nav.m_vertex_map[c] = {a, b};
const auto path = Astar::find_path(a, c, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), c);
}
TEST(AstarTests, SelfLoopVertex_DoesNotBreakSearch)
{
// Vertex with itself as a neighbor
NavigationMesh nav;
constexpr Vector3<float> a{0.f, 0.f, 0.f};
constexpr Vector3<float> b{1.f, 0.f, 0.f};
nav.m_vertex_map[a] = {a, b}; // self-loop on a
nav.m_vertex_map[b] = {a};
const auto path = Astar::find_path(a, b, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), b);
}
// ---------------------------------------------------------------------------
// Longer chains
// ---------------------------------------------------------------------------
TEST(AstarTests, LinearChain_ReachesEnd)
{
constexpr int kLength = 10;
const NavigationMesh nav = make_linear_chain(kLength);
const Vector3<float> start{0.f, 0.f, 0.f};
const Vector3<float> goal{static_cast<float>(kLength - 1), 0.f, 0.f};
const auto path = Astar::find_path(start, goal, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), goal);
}
TEST(AstarTests, LinearChain_MidpointReachable)
{
constexpr int kLength = 6;
const NavigationMesh nav = make_linear_chain(kLength);
const Vector3<float> start{0.f, 0.f, 0.f};
const Vector3<float> mid{3.f, 0.f, 0.f};
const auto path = Astar::find_path(start, mid, nav);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), mid);
}
// ---------------------------------------------------------------------------
// Serialize -> pathfind integration
// ---------------------------------------------------------------------------
TEST(AstarTests, PathfindAfterSerializeDeserialize)
{
NavigationMesh nav;
constexpr Vector3<float> a{0.f, 0.f, 0.f};
constexpr Vector3<float> b{1.f, 0.f, 0.f};
constexpr Vector3<float> c{2.f, 0.f, 0.f};
nav.m_vertex_map[a] = {b};
nav.m_vertex_map[b] = {a, c};
nav.m_vertex_map[c] = {b};
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
const auto path = Astar::find_path(a, c, nav2);
ASSERT_FALSE(path.empty());
EXPECT_EQ(path.back(), c);
}

229
tests/general/unit_test_navigation_mesh.cpp
View File

@@ -7,19 +7,18 @@ using namespace omath::pathfinding;
TEST(NavigationMeshTests, SerializeDeserializeRoundTrip)
{
NavigationMesh nav;
Vector3<float> a{0.f,0.f,0.f};
Vector3<float> b{1.f,0.f,0.f};
Vector3<float> c{0.f,1.f,0.f};
Vector3<float> a{0.f, 0.f, 0.f};
Vector3<float> b{1.f, 0.f, 0.f};
Vector3<float> c{0.f, 1.f, 0.f};
nav.m_vertex_map.emplace(a, std::vector<Vector3<float>>{b,c});
nav.m_vertex_map.emplace(a, std::vector<Vector3<float>>{b, c});
nav.m_vertex_map.emplace(b, std::vector<Vector3<float>>{a});
nav.m_vertex_map.emplace(c, std::vector<Vector3<float>>{a});
auto data = nav.serialize();
std::string data = nav.serialize();
NavigationMesh nav2;
EXPECT_NO_THROW(nav2.deserialize(data));
// verify neighbors preserved
EXPECT_EQ(nav2.m_vertex_map.size(), nav.m_vertex_map.size());
EXPECT_EQ(nav2.get_neighbors(a).size(), 2u);
}
@@ -27,7 +26,223 @@ TEST(NavigationMeshTests, SerializeDeserializeRoundTrip)
TEST(NavigationMeshTests, GetClosestVertexWhenEmpty)
{
const NavigationMesh nav;
constexpr Vector3<float> p{5.f,5.f,5.f};
constexpr Vector3<float> p{5.f, 5.f, 5.f};
const auto res = nav.get_closest_vertex(p);
EXPECT_FALSE(res.has_value());
}
TEST(NavigationMeshTests, SerializeEmptyMesh)
{
const NavigationMesh nav;
const std::string data = nav.serialize();
EXPECT_TRUE(data.empty());
}
TEST(NavigationMeshTests, DeserializeEmptyString)
{
NavigationMesh nav;
EXPECT_NO_THROW(nav.deserialize(""));
EXPECT_TRUE(nav.empty());
}
TEST(NavigationMeshTests, SerializeProducesHumanReadableText)
{
NavigationMesh nav;
nav.m_vertex_map.emplace(Vector3<float>{1.f, 2.f, 3.f}, std::vector<Vector3<float>>{{4.f, 5.f, 6.f}});
const std::string data = nav.serialize();
// Must contain the vertex and neighbor coords as plain text
EXPECT_NE(data.find("1"), std::string::npos);
EXPECT_NE(data.find("2"), std::string::npos);
EXPECT_NE(data.find("3"), std::string::npos);
EXPECT_NE(data.find("4"), std::string::npos);
EXPECT_NE(data.find("5"), std::string::npos);
EXPECT_NE(data.find("6"), std::string::npos);
}
TEST(NavigationMeshTests, DeserializeRestoresNeighborValues)
{
NavigationMesh nav;
const Vector3<float> v{1.f, 2.f, 3.f};
const Vector3<float> n1{4.f, 5.f, 6.f};
const Vector3<float> n2{7.f, 8.f, 9.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{n1, n2});
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
ASSERT_EQ(nav2.m_vertex_map.count(v), 1u);
const auto& neighbors = nav2.get_neighbors(v);
ASSERT_EQ(neighbors.size(), 2u);
EXPECT_EQ(neighbors[0], n1);
EXPECT_EQ(neighbors[1], n2);
}
TEST(NavigationMeshTests, DeserializeOverwritesPreviousData)
{
NavigationMesh nav;
const Vector3<float> v{1.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
// Load a different mesh into the same object
NavigationMesh other;
const Vector3<float> a{10.f, 20.f, 30.f};
other.m_vertex_map.emplace(a, std::vector<Vector3<float>>{});
nav.deserialize(other.serialize());
EXPECT_EQ(nav.m_vertex_map.size(), 1u);
EXPECT_EQ(nav.m_vertex_map.count(v), 0u);
EXPECT_EQ(nav.m_vertex_map.count(a), 1u);
}
TEST(NavigationMeshTests, RoundTripNegativeAndFractionalCoords)
{
NavigationMesh nav;
const Vector3<float> v{-1.5f, 0.25f, -3.75f};
const Vector3<float> n{100.f, -200.f, 0.001f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{n});
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
ASSERT_EQ(nav2.m_vertex_map.count(v), 1u);
const auto& neighbors = nav2.get_neighbors(v);
ASSERT_EQ(neighbors.size(), 1u);
EXPECT_NEAR(neighbors[0].x, n.x, 1e-3f);
EXPECT_NEAR(neighbors[0].y, n.y, 1e-3f);
EXPECT_NEAR(neighbors[0].z, n.z, 1e-3f);
}
TEST(NavigationMeshTests, GetClosestVertexReturnsNearest)
{
NavigationMesh nav;
const Vector3<float> a{0.f, 0.f, 0.f};
const Vector3<float> b{10.f, 0.f, 0.f};
nav.m_vertex_map.emplace(a, std::vector<Vector3<float>>{});
nav.m_vertex_map.emplace(b, std::vector<Vector3<float>>{});
const auto res = nav.get_closest_vertex({1.f, 0.f, 0.f});
ASSERT_TRUE(res.has_value());
EXPECT_EQ(res.value(), a);
}
TEST(NavigationMeshTests, VertexWithNoNeighborsRoundTrip)
{
NavigationMesh nav;
const Vector3<float> v{5.f, 5.f, 5.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
ASSERT_EQ(nav2.m_vertex_map.count(v), 1u);
EXPECT_TRUE(nav2.get_neighbors(v).empty());
}
// ---------------------------------------------------------------------------
// Vertex events
// ---------------------------------------------------------------------------
TEST(NavigationMeshTests, SetEventOnNonExistentVertexThrows)
{
NavigationMesh nav;
const Vector3<float> v{99.f, 99.f, 99.f};
EXPECT_THROW(nav.set_event(v, "jump"), std::invalid_argument);
}
TEST(NavigationMeshTests, EventNotSetByDefault)
{
NavigationMesh nav;
const Vector3<float> v{0.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
EXPECT_FALSE(nav.get_event(v).has_value());
}
TEST(NavigationMeshTests, SetAndGetEvent)
{
NavigationMesh nav;
const Vector3<float> v{1.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
nav.set_event(v, "jump");
const auto event = nav.get_event(v);
ASSERT_TRUE(event.has_value());
EXPECT_EQ(event.value(), "jump");
}
TEST(NavigationMeshTests, OverwriteEvent)
{
NavigationMesh nav;
const Vector3<float> v{1.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
nav.set_event(v, "jump");
nav.set_event(v, "teleport");
EXPECT_EQ(nav.get_event(v).value(), "teleport");
}
TEST(NavigationMeshTests, ClearEvent)
{
NavigationMesh nav;
const Vector3<float> v{1.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
nav.set_event(v, "jump");
nav.clear_event(v);
EXPECT_FALSE(nav.get_event(v).has_value());
}
TEST(NavigationMeshTests, EventRoundTripSerialization)
{
NavigationMesh nav;
const Vector3<float> a{0.f, 0.f, 0.f};
const Vector3<float> b{1.f, 0.f, 0.f};
nav.m_vertex_map.emplace(a, std::vector<Vector3<float>>{b});
nav.m_vertex_map.emplace(b, std::vector<Vector3<float>>{});
nav.set_event(b, "jump");
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
ASSERT_FALSE(nav2.get_event(a).has_value());
ASSERT_TRUE(nav2.get_event(b).has_value());
EXPECT_EQ(nav2.get_event(b).value(), "jump");
}
TEST(NavigationMeshTests, MultipleEventsRoundTrip)
{
NavigationMesh nav;
const Vector3<float> a{0.f, 0.f, 0.f};
const Vector3<float> b{1.f, 0.f, 0.f};
const Vector3<float> c{2.f, 0.f, 0.f};
nav.m_vertex_map.emplace(a, std::vector<Vector3<float>>{});
nav.m_vertex_map.emplace(b, std::vector<Vector3<float>>{});
nav.m_vertex_map.emplace(c, std::vector<Vector3<float>>{});
nav.set_event(a, "spawn");
nav.set_event(c, "teleport");
NavigationMesh nav2;
nav2.deserialize(nav.serialize());
EXPECT_EQ(nav2.get_event(a).value(), "spawn");
EXPECT_FALSE(nav2.get_event(b).has_value());
EXPECT_EQ(nav2.get_event(c).value(), "teleport");
}
TEST(NavigationMeshTests, DeserializeClearsOldEvents)
{
NavigationMesh nav;
const Vector3<float> v{0.f, 0.f, 0.f};
nav.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
nav.set_event(v, "jump");
// Deserialize a mesh that has no events
NavigationMesh empty_events;
empty_events.m_vertex_map.emplace(v, std::vector<Vector3<float>>{});
nav.deserialize(empty_events.serialize());
EXPECT_FALSE(nav.get_event(v).has_value());
}

341
tests/general/unit_test_physx_colliders.cpp Normal file
View File

@@ -0,0 +1,341 @@
//
// Created by orange-cpp
//
#ifdef OMATH_ENABLE_PHYSX
#include <gtest/gtest.h>
#include <omath/collision/gjk_algorithm.hpp>
#include <omath/collision/physx_box_collider.hpp>
#include <omath/collision/physx_rigid_body.hpp>
#include <omath/collision/physx_sphere_collider.hpp>
#include <omath/collision/physx_world.hpp>
using namespace omath::collision;
using omath::Vector3;
// ─── PhysXBoxCollider ────────────────────────────────────────────────────────
TEST(PhysXBoxCollider, DefaultOriginIsZero)
{
PhysXBoxCollider box({1.f, 1.f, 1.f});
EXPECT_EQ(box.get_origin(), Vector3<float>(0.f, 0.f, 0.f));
}
TEST(PhysXBoxCollider, SetAndGetOrigin)
{
PhysXBoxCollider box({1.f, 1.f, 1.f}, {3.f, 4.f, 5.f});
EXPECT_EQ(box.get_origin(), Vector3<float>(3.f, 4.f, 5.f));
box.set_origin({-1.f, 0.f, 2.f});
EXPECT_EQ(box.get_origin(), Vector3<float>(-1.f, 0.f, 2.f));
}
TEST(PhysXBoxCollider, FurthestPointPositiveDirection)
{
// Box centred at origin with half-extents (2, 3, 4).
// Direction (+x, +y, +z) → furthest corner is (+2, +3, +4).
PhysXBoxCollider box({2.f, 3.f, 4.f});
const auto p = box.find_abs_furthest_vertex_position({1.f, 1.f, 1.f});
EXPECT_FLOAT_EQ(p.x, 2.f);
EXPECT_FLOAT_EQ(p.y, 3.f);
EXPECT_FLOAT_EQ(p.z, 4.f);
}
TEST(PhysXBoxCollider, FurthestPointNegativeDirection)
{
// Direction (-x, -y, -z) → furthest corner is (-2, -3, -4).
PhysXBoxCollider box({2.f, 3.f, 4.f});
const auto p = box.find_abs_furthest_vertex_position({-1.f, -1.f, -1.f});
EXPECT_FLOAT_EQ(p.x, -2.f);
EXPECT_FLOAT_EQ(p.y, -3.f);
EXPECT_FLOAT_EQ(p.z, -4.f);
}
TEST(PhysXBoxCollider, FurthestPointMixedDirection)
{
// Direction (+x, -y, +z) → furthest corner is (+2, -3, +4).
PhysXBoxCollider box({2.f, 3.f, 4.f});
const auto p = box.find_abs_furthest_vertex_position({1.f, -1.f, 1.f});
EXPECT_FLOAT_EQ(p.x, 2.f);
EXPECT_FLOAT_EQ(p.y, -3.f);
EXPECT_FLOAT_EQ(p.z, 4.f);
}
TEST(PhysXBoxCollider, FurthestPointWithNonZeroOrigin)
{
// Box at (10, 0, 0), half-extents (1, 1, 1). Direction +x → (11, 1, 1).
PhysXBoxCollider box({1.f, 1.f, 1.f}, {10.f, 0.f, 0.f});
const auto p = box.find_abs_furthest_vertex_position({1.f, 1.f, 1.f});
EXPECT_FLOAT_EQ(p.x, 11.f);
EXPECT_FLOAT_EQ(p.y, 1.f);
EXPECT_FLOAT_EQ(p.z, 1.f);
}
TEST(PhysXBoxCollider, SetHalfExtentsUpdatesGeometry)
{
PhysXBoxCollider box({1.f, 1.f, 1.f});
box.set_half_extents({5.f, 6.f, 7.f});
const auto& he = box.get_geometry().halfExtents;
EXPECT_FLOAT_EQ(he.x, 5.f);
EXPECT_FLOAT_EQ(he.y, 6.f);
EXPECT_FLOAT_EQ(he.z, 7.f);
// Furthest vertex must reflect the new extents.
const auto p = box.find_abs_furthest_vertex_position({1.f, 1.f, 1.f});
EXPECT_FLOAT_EQ(p.x, 5.f);
EXPECT_FLOAT_EQ(p.y, 6.f);
EXPECT_FLOAT_EQ(p.z, 7.f);
}
// ─── PhysXSphereCollider ─────────────────────────────────────────────────────
TEST(PhysXSphereCollider, DefaultOriginIsZero)
{
PhysXSphereCollider sphere(1.f);
EXPECT_EQ(sphere.get_origin(), Vector3<float>(0.f, 0.f, 0.f));
}
TEST(PhysXSphereCollider, SetAndGetOrigin)
{
PhysXSphereCollider sphere(1.f, {1.f, 2.f, 3.f});
EXPECT_EQ(sphere.get_origin(), Vector3<float>(1.f, 2.f, 3.f));
sphere.set_origin({-5.f, 0.f, 0.f});
EXPECT_EQ(sphere.get_origin(), Vector3<float>(-5.f, 0.f, 0.f));
}
TEST(PhysXSphereCollider, FurthestPointAlongPureXAxis)
{
// Direction (1,0,0), radius 3 → furthest point is (3, 0, 0).
PhysXSphereCollider sphere(3.f);
const auto p = sphere.find_abs_furthest_vertex_position({1.f, 0.f, 0.f});
EXPECT_FLOAT_EQ(p.x, 3.f);
EXPECT_FLOAT_EQ(p.y, 0.f);
EXPECT_FLOAT_EQ(p.z, 0.f);
}
TEST(PhysXSphereCollider, FurthestPointAlongDiagonal)
{
// Direction (1,1,0), radius 1 → furthest point at distance 1 from origin.
PhysXSphereCollider sphere(1.f);
const auto p = sphere.find_abs_furthest_vertex_position({1.f, 1.f, 0.f});
const float dist = std::sqrt(p.x * p.x + p.y * p.y + p.z * p.z);
EXPECT_NEAR(dist, 1.f, 1e-5f);
}
TEST(PhysXSphereCollider, FurthestPointWithNonZeroOrigin)
{
// Sphere at (5, 0, 0), radius 2. Direction +x → (7, 0, 0).
PhysXSphereCollider sphere(2.f, {5.f, 0.f, 0.f});
const auto p = sphere.find_abs_furthest_vertex_position({1.f, 0.f, 0.f});
EXPECT_FLOAT_EQ(p.x, 7.f);
EXPECT_FLOAT_EQ(p.y, 0.f);
EXPECT_FLOAT_EQ(p.z, 0.f);
}
TEST(PhysXSphereCollider, ZeroDirectionReturnsOrigin)
{
PhysXSphereCollider sphere(5.f, {1.f, 2.f, 3.f});
const auto p = sphere.find_abs_furthest_vertex_position({0.f, 0.f, 0.f});
EXPECT_EQ(p, sphere.get_origin());
}
TEST(PhysXSphereCollider, SetRadiusUpdatesGeometry)
{
PhysXSphereCollider sphere(1.f);
sphere.set_radius(10.f);
EXPECT_FLOAT_EQ(sphere.get_radius(), 10.f);
// Furthest point along +x should now be at x = 10.
const auto p = sphere.find_abs_furthest_vertex_position({1.f, 0.f, 0.f});
EXPECT_FLOAT_EQ(p.x, 10.f);
}
// ─── GJK: Box vs Box ─────────────────────────────────────────────────────────
using GjkBox = omath::collision::GjkAlgorithm<PhysXBoxCollider>;
using GjkSphere = omath::collision::GjkAlgorithm<PhysXSphereCollider>;
TEST(PhysXBoxGjk, CollidingOverlap)
{
// Two unit boxes: A at origin, B shifted by 0.5 — clearly overlapping.
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f}, {0.5f, 0.f, 0.f});
EXPECT_TRUE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, NotCollidingTouching)
{
// Boxes exactly touching on the +X face: A[-1,1] and B[1,3] along X.
// GJK treats boundary contact (Minkowski difference passes through origin) as non-collision.
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f}, {2.f, 0.f, 0.f});
EXPECT_FALSE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, CollidingSlightOverlap)
{
// Boxes overlapping by 0.1 along X: A[-1,1] and B[0.9,2.9].
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f}, {1.9f, 0.f, 0.f});
EXPECT_TRUE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, NotCollidingSeparated)
{
// Boxes separated by a gap: A[-1,1] and B[3,5] along X.
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f}, {4.f, 0.f, 0.f});
EXPECT_FALSE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, CollidingSameOrigin)
{
// Same position — fully overlapping.
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f});
EXPECT_TRUE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, NotCollidingDiagonalSeparation)
{
// Boxes separated along a diagonal so no axis-aligned faces overlap.
const PhysXBoxCollider a({1.f, 1.f, 1.f});
const PhysXBoxCollider b({1.f, 1.f, 1.f}, {3.f, 3.f, 3.f});
EXPECT_FALSE(GjkBox::is_collide(a, b));
}
TEST(PhysXBoxGjk, DifferentSizesColliding)
{
// Large box vs small box inside it.
const PhysXBoxCollider large({5.f, 5.f, 5.f});
const PhysXBoxCollider small_box({1.f, 1.f, 1.f}, {2.f, 0.f, 0.f});
EXPECT_TRUE(GjkBox::is_collide(large, small_box));
}
// ─── GJK: Sphere vs Sphere ───────────────────────────────────────────────────
TEST(PhysXSphereGjk, CollidingOverlap)
{
// Radii 1 each, centres 1 apart — overlapping.
const PhysXSphereCollider a(1.f);
const PhysXSphereCollider b(1.f, {1.f, 0.f, 0.f});
EXPECT_TRUE(GjkSphere::is_collide(a, b));
}
TEST(PhysXSphereGjk, CollidingSameOrigin)
{
const PhysXSphereCollider a(1.f);
const PhysXSphereCollider b(1.f);
EXPECT_TRUE(GjkSphere::is_collide(a, b));
}
TEST(PhysXSphereGjk, NotCollidingSeparated)
{
// Radii 1 each, centres 3 apart — gap of 1.
const PhysXSphereCollider a(1.f);
const PhysXSphereCollider b(1.f, {3.f, 0.f, 0.f});
EXPECT_FALSE(GjkSphere::is_collide(a, b));
}
TEST(PhysXSphereGjk, DifferentRadiiColliding)
{
// r=2 and r=1, centres 2.5 apart — still overlapping.
const PhysXSphereCollider a(2.f);
const PhysXSphereCollider b(1.f, {2.5f, 0.f, 0.f});
EXPECT_TRUE(GjkSphere::is_collide(a, b));
}
TEST(PhysXSphereGjk, DifferentRadiiNotColliding)
{
// r=1 and r=1, centres 5 apart — separated.
const PhysXSphereCollider a(1.f);
const PhysXSphereCollider b(1.f, {5.f, 0.f, 0.f});
EXPECT_FALSE(GjkSphere::is_collide(a, b));
}
// ─── PhysX simulation-based collision resolution ─────────────────────────────
// Helper: step the world N times with a fixed dt.
static void step_n(omath::collision::PhysXWorld& world, int n, float dt = 1.f / 60.f)
{
for (int i = 0; i < n; ++i)
world.step(dt);
}
TEST(PhysXSimulation, BoxFallsAndStopsOnGround)
{
// A box dropped from y=5 should come to rest at y≈0.5 (half-extent) above the ground plane.
omath::collision::PhysXWorld world;
world.add_ground_plane(0.f);
omath::collision::PhysXRigidBody box(world, physx::PxBoxGeometry(0.5f, 0.5f, 0.5f),
{0.f, 5.f, 0.f});
step_n(world, 300); // ~5 simulated seconds
EXPECT_NEAR(box.get_origin().y, 0.5f, 0.05f);
}
TEST(PhysXSimulation, SphereFallsAndStopsOnGround)
{
// A sphere of radius 1 dropped from y=5 should rest at y≈1.
omath::collision::PhysXWorld world;
world.add_ground_plane(0.f);
omath::collision::PhysXRigidBody sphere(world, physx::PxSphereGeometry(1.f),
{0.f, 5.f, 0.f});
step_n(world, 300);
EXPECT_NEAR(sphere.get_origin().y, 1.f, 0.05f);
}
TEST(PhysXSimulation, TwoBoxesCollideSeparate)
{
// Two boxes launched toward each other — after collision they must be
// further apart than their combined half-extents (no overlap).
omath::collision::PhysXWorld world({0.f, 0.f, 0.f}); // no gravity
omath::collision::PhysXRigidBody left (world, physx::PxBoxGeometry(0.5f, 0.5f, 0.5f), {-3.f, 0.f, 0.f});
omath::collision::PhysXRigidBody right(world, physx::PxBoxGeometry(0.5f, 0.5f, 0.5f), { 3.f, 0.f, 0.f});
left.set_linear_velocity({ 5.f, 0.f, 0.f});
right.set_linear_velocity({-5.f, 0.f, 0.f});
step_n(world, 120); // 2 simulated seconds
const float distance = right.get_origin().x - left.get_origin().x;
// Boxes must not be overlapping (combined extents = 1.0).
EXPECT_GE(distance, 1.0f);
}
TEST(PhysXSimulation, BoxGetOriginMatchesSetOrigin)
{
// Kinematic teleport — set_origin must immediately reflect in get_origin.
omath::collision::PhysXWorld world;
omath::collision::PhysXRigidBody box(world, physx::PxBoxGeometry(1.f, 1.f, 1.f));
box.set_kinematic(true);
box.set_origin({7.f, 3.f, -2.f});
EXPECT_NEAR(box.get_origin().x, 7.f, 1e-4f);
EXPECT_NEAR(box.get_origin().y, 3.f, 1e-4f);
EXPECT_NEAR(box.get_origin().z, -2.f, 1e-4f);
}
TEST(PhysXSimulation, BoxFallsUnderGravity)
{
// Without a floor, a box should be lower after simulation than its start.
omath::collision::PhysXWorld world; // default gravity -9.81 Y
omath::collision::PhysXRigidBody box(world, physx::PxBoxGeometry(0.5f, 0.5f, 0.5f),
{0.f, 10.f, 0.f});
const float y_start = box.get_origin().y;
step_n(world, 60); // 1 simulated second
EXPECT_LT(box.get_origin().y, y_start);
}
#endif // OMATH_ENABLE_PHYSX

96
tests/lua/color_tests.lua Normal file
View File

@@ -0,0 +1,96 @@
local function approx(a, b, eps) return math.abs(a - b) < (eps or 1e-4) end
function Color_Constructor_float()
local c = omath.Color.new(1, 0.5, 0.25, 1)
assert(approx(c.r, 1) and approx(c.g, 0.5) and approx(c.b, 0.25) and approx(c.a, 1))
end
function Color_Constructor_default()
local c = omath.Color.new()
assert(c ~= nil)
end
function Color_Constructor_clamping()
local c = omath.Color.new(2, -1, 0.5, 1)
assert(approx(c.r, 1) and approx(c.g, 0) and approx(c.b, 0.5))
end
function Color_from_rgba()
local c = omath.Color.from_rgba(255, 128, 0, 255)
assert(approx(c.r, 1) and approx(c.g, 128/255) and approx(c.b, 0) and approx(c.a, 1))
end
function Color_from_hsv_components()
local c = omath.Color.from_hsv(0, 1, 1)
assert(approx(c.r, 1) and approx(c.g, 0) and approx(c.b, 0))
end
function Color_from_hsv_struct()
local hsv = omath.Hsv.new()
hsv.hue = 0
hsv.saturation = 1
hsv.value = 1
local c = omath.Color.from_hsv(hsv)
assert(approx(c.r, 1) and approx(c.g, 0) and approx(c.b, 0))
end
function Color_red()
local c = omath.Color.red()
assert(approx(c.r, 1) and approx(c.g, 0) and approx(c.b, 0) and approx(c.a, 1))
end
function Color_green()
local c = omath.Color.green()
assert(approx(c.r, 0) and approx(c.g, 1) and approx(c.b, 0) and approx(c.a, 1))
end
function Color_blue()
local c = omath.Color.blue()
assert(approx(c.r, 0) and approx(c.g, 0) and approx(c.b, 1) and approx(c.a, 1))
end
function Color_to_hsv()
local hsv = omath.Color.red():to_hsv()
assert(approx(hsv.hue, 0) and approx(hsv.saturation, 1) and approx(hsv.value, 1))
end
function Color_set_hue()
local c = omath.Color.red()
c:set_hue(1/3)
assert(approx(c.g, 1, 1e-3))
end
function Color_set_saturation()
local c = omath.Color.red()
c:set_saturation(0)
assert(approx(c.r, c.g) and approx(c.g, c.b))
end
function Color_set_value()
local c = omath.Color.red()
c:set_value(0)
assert(approx(c.r, 0) and approx(c.g, 0) and approx(c.b, 0))
end
function Color_blend()
local c = omath.Color.red():blend(omath.Color.blue(), 0.5)
assert(approx(c.r, 0.5) and approx(c.b, 0.5))
end
function Color_blend_clamped_ratio()
local c = omath.Color.red():blend(omath.Color.blue(), 2.0)
assert(approx(c.r, 0) and approx(c.b, 1))
end
function Color_to_string()
local s = tostring(omath.Color.red())
assert(s == "[r:255, g:0, b:0, a:255]")
end
function Hsv_fields()
local hsv = omath.Hsv.new()
hsv.hue = 0.5
hsv.saturation = 0.8
hsv.value = 0.9
assert(approx(hsv.hue, 0.5) and approx(hsv.saturation, 0.8) and approx(hsv.value, 0.9))
end

66
tests/lua/pe_scanner_tests.lua Normal file
View File

@@ -0,0 +1,66 @@
-- PatternScanner tests: generic scan over a Lua string buffer
function PatternScanner_FindsExactPattern()
local buf = "\x90\x01\x02\x03\x04"
local offset = omath.PatternScanner.scan(buf, "90 01 02")
assert(offset ~= nil, "expected pattern to be found")
assert(offset == 0, "expected offset 0, got " .. tostring(offset))
end
function PatternScanner_FindsPatternAtNonZeroOffset()
local buf = "\x00\x00\xAB\xCD\xEF"
local offset = omath.PatternScanner.scan(buf, "AB CD EF")
assert(offset ~= nil, "expected pattern to be found")
assert(offset == 2, "expected offset 2, got " .. tostring(offset))
end
function PatternScanner_WildcardMatches()
local buf = "\xDE\xAD\xBE\xEF"
local offset = omath.PatternScanner.scan(buf, "DE ?? BE")
assert(offset ~= nil, "expected wildcard match")
assert(offset == 0)
end
function PatternScanner_ReturnsNilWhenNotFound()
local buf = "\x01\x02\x03"
local offset = omath.PatternScanner.scan(buf, "AA BB CC")
assert(offset == nil, "expected nil for not-found pattern")
end
function PatternScanner_ReturnsNilForEmptyBuffer()
local offset = omath.PatternScanner.scan("", "90 01")
assert(offset == nil)
end
-- PePatternScanner tests: scan_in_module uses FAKE_MODULE_BASE injected from C++
-- The fake module contains {0x90, 0x01, 0x02, 0x03, 0x04} placed at raw offset 0x200
function PeScanner_FindsExactPattern()
local addr = omath.PePatternScanner.scan_in_module(FAKE_MODULE_BASE, "90 01 02")
assert(addr ~= nil, "expected pattern to be found in module")
local offset = addr - FAKE_MODULE_BASE
assert(offset == 0x200, string.format("expected offset 0x200, got 0x%X", offset))
end
function PeScanner_WildcardMatches()
local addr = omath.PePatternScanner.scan_in_module(FAKE_MODULE_BASE, "90 ?? 02")
assert(addr ~= nil, "expected wildcard match in module")
local offset = addr - FAKE_MODULE_BASE
assert(offset == 0x200, string.format("expected offset 0x200, got 0x%X", offset))
end
function PeScanner_ReturnsNilWhenNotFound()
local addr = omath.PePatternScanner.scan_in_module(FAKE_MODULE_BASE, "AA BB CC DD")
assert(addr == nil, "expected nil for not-found pattern")
end
function PeScanner_CustomSectionFallsBackToNil()
-- Request a section that doesn't exist in our fake module
local addr = omath.PePatternScanner.scan_in_module(FAKE_MODULE_BASE, "90 01 02", ".rdata")
assert(addr == nil, "expected nil for wrong section name")
end
-- SectionScanResult: verify the type is registered and tostring works on a C++-returned value
function SectionScanResult_TypeIsRegistered()
assert(omath.SectionScanResult ~= nil, "SectionScanResult type should be registered")
end

197
tests/lua/source_engine_tests.lua Normal file
View File

@@ -0,0 +1,197 @@
local function approx(a, b, eps) return math.abs(a - b) < (eps or 1e-4) end
local function make_camera()
local pos = omath.Vec3.new(0, 0, 0)
local pitch = omath.source.PitchAngle.from_degrees(0)
local yaw = omath.source.YawAngle.from_degrees(0)
local roll = omath.source.RollAngle.from_degrees(0)
local angles = omath.source.ViewAngles.new(pitch, yaw, roll)
local vp = omath.opengl.ViewPort.new(1920, 1080)
local fov = omath.source.FieldOfView.from_degrees(90)
return omath.source.Camera.new(pos, angles, vp, fov, 0.1, 1000)
end
-- PitchAngle
function Source_PitchAngle_from_degrees()
assert(omath.source.PitchAngle.from_degrees(45):as_degrees() == 45)
end
function Source_PitchAngle_clamping_max()
assert(omath.source.PitchAngle.from_degrees(100):as_degrees() == 89)
end
function Source_PitchAngle_clamping_min()
assert(omath.source.PitchAngle.from_degrees(-100):as_degrees() == -89)
end
function Source_PitchAngle_from_radians()
assert(approx(omath.source.PitchAngle.from_radians(math.pi / 4):as_degrees(), 45))
end
function Source_PitchAngle_as_radians()
assert(approx(omath.source.PitchAngle.from_degrees(0):as_radians(), 0))
end
function Source_PitchAngle_sin()
assert(approx(omath.source.PitchAngle.from_degrees(30):sin(), 0.5))
end
function Source_PitchAngle_cos()
assert(approx(omath.source.PitchAngle.from_degrees(60):cos(), 0.5))
end
function Source_PitchAngle_tan()
assert(approx(omath.source.PitchAngle.from_degrees(45):tan(), 1.0))
end
function Source_PitchAngle_addition()
local c = omath.source.PitchAngle.from_degrees(20) + omath.source.PitchAngle.from_degrees(15)
assert(c:as_degrees() == 35)
end
function Source_PitchAngle_addition_clamped()
local c = omath.source.PitchAngle.from_degrees(80) + omath.source.PitchAngle.from_degrees(20)
assert(c:as_degrees() == 89)
end
function Source_PitchAngle_subtraction()
local c = omath.source.PitchAngle.from_degrees(50) - omath.source.PitchAngle.from_degrees(20)
assert(c:as_degrees() == 30)
end
function Source_PitchAngle_unary_minus()
assert((-omath.source.PitchAngle.from_degrees(45)):as_degrees() == -45)
end
function Source_PitchAngle_equal_to()
local a = omath.source.PitchAngle.from_degrees(45)
assert(a == omath.source.PitchAngle.from_degrees(45))
assert(not (a == omath.source.PitchAngle.from_degrees(30)))
end
function Source_PitchAngle_to_string()
assert(tostring(omath.source.PitchAngle.from_degrees(45)) == "45deg")
end
-- YawAngle
function Source_YawAngle_from_degrees()
assert(omath.source.YawAngle.from_degrees(90):as_degrees() == 90)
end
function Source_YawAngle_normalization()
assert(approx(omath.source.YawAngle.from_degrees(200):as_degrees(), -160))
end
-- RollAngle
function Source_RollAngle_from_degrees()
assert(omath.source.RollAngle.from_degrees(45):as_degrees() == 45)
end
-- FieldOfView
function Source_FieldOfView_from_degrees()
assert(omath.source.FieldOfView.from_degrees(90):as_degrees() == 90)
end
function Source_FieldOfView_clamping()
assert(omath.source.FieldOfView.from_degrees(200):as_degrees() == 180)
end
-- ViewAngles
function Source_ViewAngles_new()
local angles = omath.source.ViewAngles.new(
omath.source.PitchAngle.from_degrees(30),
omath.source.YawAngle.from_degrees(90),
omath.source.RollAngle.from_degrees(0))
assert(angles.pitch:as_degrees() == 30)
assert(angles.yaw:as_degrees() == 90)
assert(angles.roll:as_degrees() == 0)
end
function Source_ViewAngles_field_mutation()
local angles = omath.source.ViewAngles.new(
omath.source.PitchAngle.from_degrees(0),
omath.source.YawAngle.from_degrees(0),
omath.source.RollAngle.from_degrees(0))
angles.pitch = omath.source.PitchAngle.from_degrees(45)
assert(angles.pitch:as_degrees() == 45)
end
-- Camera
function Source_Camera_constructor()
assert(make_camera() ~= nil)
end
function Source_Camera_get_set_origin()
local cam = make_camera()
cam:set_origin(omath.Vec3.new(1, 2, 3))
local o = cam:get_origin()
assert(approx(o.x, 1) and approx(o.y, 2) and approx(o.z, 3))
end
function Source_Camera_get_set_near_plane()
local cam = make_camera()
cam:set_near_plane(0.5)
assert(approx(cam:get_near_plane(), 0.5))
end
function Source_Camera_get_set_far_plane()
local cam = make_camera()
cam:set_far_plane(500)
assert(approx(cam:get_far_plane(), 500))
end
function Source_Camera_get_set_fov()
local cam = make_camera()
cam:set_field_of_view(omath.source.FieldOfView.from_degrees(60))
assert(approx(cam:get_field_of_view():as_degrees(), 60))
end
function Source_Camera_get_set_view_angles()
local cam = make_camera()
cam:set_view_angles(omath.source.ViewAngles.new(
omath.source.PitchAngle.from_degrees(30),
omath.source.YawAngle.from_degrees(90),
omath.source.RollAngle.from_degrees(0)))
assert(approx(cam:get_view_angles().pitch:as_degrees(), 30))
assert(approx(cam:get_view_angles().yaw:as_degrees(), 90))
end
function Source_Camera_look_at()
local cam = make_camera()
cam:look_at(omath.Vec3.new(10, 0, 0))
assert(cam:get_view_angles() ~= nil)
end
function Source_Camera_get_forward()
local fwd = make_camera():get_forward()
assert(approx(fwd:length(), 1.0))
end
function Source_Camera_get_right()
assert(approx(make_camera():get_right():length(), 1.0))
end
function Source_Camera_get_up()
assert(approx(make_camera():get_up():length(), 1.0))
end
function Source_Camera_world_to_screen_success()
local cam = make_camera()
cam:look_at(omath.Vec3.new(1, 0, 0))
local screen, err = cam:world_to_screen(omath.Vec3.new(5, 0, 0))
assert(screen ~= nil, "expected screen pos, got: " .. tostring(err))
end
function Source_Camera_world_to_screen_error()
local cam = make_camera()
cam:look_at(omath.Vec3.new(1, 0, 0))
local screen, err = cam:world_to_screen(omath.Vec3.new(-100, 0, 0))
assert(screen == nil and err ~= nil)
end
function Source_Camera_screen_to_world()
local cam = make_camera()
cam:look_at(omath.Vec3.new(1, 0, 0))
local world, err = cam:screen_to_world(omath.Vec3.new(960, 540, 1))
assert(world ~= nil, "expected world pos, got: " .. tostring(err))
end

82
tests/lua/triangle_tests.lua Normal file
View File

@@ -0,0 +1,82 @@
local function approx(a, b, eps) return math.abs(a - b) < (eps or 1e-5) end
function Triangle_Constructor_default()
local t = omath.Triangle.new()
assert(t.vertex1.x == 0 and t.vertex1.y == 0 and t.vertex1.z == 0)
assert(t.vertex2.x == 0 and t.vertex2.y == 0 and t.vertex2.z == 0)
assert(t.vertex3.x == 0 and t.vertex3.y == 0 and t.vertex3.z == 0)
end
function Triangle_Constructor_vertices()
local v1 = omath.Vec3.new(1, 0, 0)
local v2 = omath.Vec3.new(0, 1, 0)
local v3 = omath.Vec3.new(0, 0, 1)
local t = omath.Triangle.new(v1, v2, v3)
assert(t.vertex1.x == 1 and t.vertex1.y == 0 and t.vertex1.z == 0)
assert(t.vertex2.x == 0 and t.vertex2.y == 1 and t.vertex2.z == 0)
assert(t.vertex3.x == 0 and t.vertex3.y == 0 and t.vertex3.z == 1)
end
function Triangle_Vertex_mutation()
local t = omath.Triangle.new()
t.vertex1 = omath.Vec3.new(5, 6, 7)
assert(t.vertex1.x == 5 and t.vertex1.y == 6 and t.vertex1.z == 7)
end
-- Right triangle: v1=(0,3,0), v2=(0,0,0), v3=(4,0,0) — sides 3, 4, hypot 5
function Triangle_SideALength()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
assert(approx(t:side_a_length(), 3.0))
end
function Triangle_SideBLength()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
assert(approx(t:side_b_length(), 4.0))
end
function Triangle_Hypot()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
assert(approx(t:hypot(), 5.0))
end
function Triangle_SideAVector()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
local a = t:side_a_vector()
assert(approx(a.x, 0) and approx(a.y, 3) and approx(a.z, 0))
end
function Triangle_SideBVector()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
local b = t:side_b_vector()
assert(approx(b.x, 4) and approx(b.y, 0) and approx(b.z, 0))
end
function Triangle_IsRectangular_true()
local t = omath.Triangle.new(omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(4, 0, 0))
assert(t:is_rectangular() == true)
end
function Triangle_IsRectangular_false()
-- equilateral-ish triangle, not rectangular
local t = omath.Triangle.new(omath.Vec3.new(0, 1, 0), omath.Vec3.new(-1, 0, 0), omath.Vec3.new(1, 0, 0))
assert(t:is_rectangular() == false)
end
function Triangle_MidPoint()
local t = omath.Triangle.new(omath.Vec3.new(3, 0, 0), omath.Vec3.new(0, 3, 0), omath.Vec3.new(0, 0, 3))
local m = t:mid_point()
assert(approx(m.x, 1.0) and approx(m.y, 1.0) and approx(m.z, 1.0))
end
function Triangle_CalculateNormal()
-- flat triangle in XY plane — normal should be (0, 0, 1)
local t = omath.Triangle.new(omath.Vec3.new(0, 1, 0), omath.Vec3.new(0, 0, 0), omath.Vec3.new(1, 0, 0))
local n = t:calculate_normal()
assert(approx(n.x, 0) and approx(n.y, 0) and approx(n.z, 1))
end
function Triangle_ToString()
local t = omath.Triangle.new(omath.Vec3.new(1, 0, 0), omath.Vec3.new(0, 1, 0), omath.Vec3.new(0, 0, 1))
local s = tostring(t)
assert(s == "Triangle((1, 0, 0), (0, 1, 0), (0, 0, 1))")
end

51
tests/lua/unit_test_lua_color.cpp Normal file
View File

@@ -0,0 +1,51 @@
//
// Created by orange on 08.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaColor : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/color_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaColor, Constructor_float) { check("Color_Constructor_float"); }
TEST_F(LuaColor, Constructor_default) { check("Color_Constructor_default"); }
TEST_F(LuaColor, Constructor_clamping) { check("Color_Constructor_clamping"); }
TEST_F(LuaColor, from_rgba) { check("Color_from_rgba"); }
TEST_F(LuaColor, from_hsv_components) { check("Color_from_hsv_components"); }
TEST_F(LuaColor, from_hsv_struct) { check("Color_from_hsv_struct"); }
TEST_F(LuaColor, red) { check("Color_red"); }
TEST_F(LuaColor, green) { check("Color_green"); }
TEST_F(LuaColor, blue) { check("Color_blue"); }
TEST_F(LuaColor, to_hsv) { check("Color_to_hsv"); }
TEST_F(LuaColor, set_hue) { check("Color_set_hue"); }
TEST_F(LuaColor, set_saturation) { check("Color_set_saturation"); }
TEST_F(LuaColor, set_value) { check("Color_set_value"); }
TEST_F(LuaColor, blend) { check("Color_blend"); }
TEST_F(LuaColor, blend_clamped_ratio) { check("Color_blend_clamped_ratio"); }
TEST_F(LuaColor, to_string) { check("Color_to_string"); }
TEST_F(LuaColor, Hsv_fields) { check("Hsv_fields"); }

113
tests/lua/unit_test_lua_pe_scanner.cpp Normal file
View File

@@ -0,0 +1,113 @@
//
// Created by orange on 10.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
#include <cstdint>
#include <cstring>
#include <vector>
namespace
{
std::vector<std::uint8_t> make_fake_pe_module(std::uint32_t base_of_code, std::uint32_t size_code,
const std::vector<std::uint8_t>& code_bytes)
{
constexpr std::uint32_t e_lfanew = 0x80;
constexpr std::uint32_t nt_sig = 0x4550;
constexpr std::uint16_t opt_magic = 0x020B; // PE32+
constexpr std::uint16_t num_sections = 1;
constexpr std::uint16_t opt_hdr_size = 0xF0;
constexpr std::uint32_t section_table_off = e_lfanew + 4 + 20 + opt_hdr_size;
constexpr std::uint32_t section_hdr_size = 40;
constexpr std::uint32_t text_chars = 0x60000020;
const std::uint32_t headers_end = section_table_off + section_hdr_size;
const std::uint32_t code_end = base_of_code + size_code;
const std::uint32_t total_size = std::max(headers_end, code_end) + 0x100;
std::vector<std::uint8_t> buf(total_size, 0);
auto w16 = [&](std::size_t off, std::uint16_t v) { std::memcpy(buf.data() + off, &v, 2); };
auto w32 = [&](std::size_t off, std::uint32_t v) { std::memcpy(buf.data() + off, &v, 4); };
auto w64 = [&](std::size_t off, std::uint64_t v) { std::memcpy(buf.data() + off, &v, 8); };
w16(0x00, 0x5A4D);
w32(0x3C, e_lfanew);
w32(e_lfanew, nt_sig);
const std::size_t fh = e_lfanew + 4;
w16(fh + 2, num_sections);
w16(fh + 16, opt_hdr_size);
const std::size_t opt = fh + 20;
w16(opt + 0, opt_magic);
w32(opt + 4, size_code);
w32(opt + 20, base_of_code);
w64(opt + 24, 0);
w32(opt + 32, 0x1000);
w32(opt + 36, 0x200);
w32(opt + 56, code_end);
w32(opt + 60, headers_end);
w32(opt + 108, 0);
const std::size_t sh = section_table_off;
std::memcpy(buf.data() + sh, ".text", 5);
w32(sh + 8, size_code);
w32(sh + 12, base_of_code);
w32(sh + 16, size_code);
w32(sh + 20, base_of_code);
w32(sh + 36, text_chars);
if (base_of_code + code_bytes.size() <= buf.size())
std::memcpy(buf.data() + base_of_code, code_bytes.data(), code_bytes.size());
return buf;
}
} // namespace
class LuaPeScanner : public ::testing::Test
{
protected:
lua_State* L = nullptr;
std::vector<std::uint8_t> m_fake_module;
void SetUp() override
{
const std::vector<std::uint8_t> code = {0x90, 0x01, 0x02, 0x03, 0x04};
m_fake_module = make_fake_pe_module(0x200, static_cast<std::uint32_t>(code.size()), code);
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
lua_pushinteger(L, static_cast<lua_Integer>(
reinterpret_cast<std::uintptr_t>(m_fake_module.data())));
lua_setglobal(L, "FAKE_MODULE_BASE");
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/pe_scanner_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaPeScanner, PatternScanner_FindsExactPattern) { check("PatternScanner_FindsExactPattern"); }
TEST_F(LuaPeScanner, PatternScanner_FindsPatternAtOffset) { check("PatternScanner_FindsPatternAtNonZeroOffset"); }
TEST_F(LuaPeScanner, PatternScanner_WildcardMatches) { check("PatternScanner_WildcardMatches"); }
TEST_F(LuaPeScanner, PatternScanner_ReturnsNilWhenNotFound) { check("PatternScanner_ReturnsNilWhenNotFound"); }
TEST_F(LuaPeScanner, PatternScanner_ReturnsNilForEmptyBuffer){ check("PatternScanner_ReturnsNilForEmptyBuffer"); }
TEST_F(LuaPeScanner, PeScanner_FindsExactPattern) { check("PeScanner_FindsExactPattern"); }
TEST_F(LuaPeScanner, PeScanner_WildcardMatches) { check("PeScanner_WildcardMatches"); }
TEST_F(LuaPeScanner, PeScanner_ReturnsNilWhenNotFound) { check("PeScanner_ReturnsNilWhenNotFound"); }
TEST_F(LuaPeScanner, PeScanner_CustomSectionFallsBackToNil) { check("PeScanner_CustomSectionFallsBackToNil"); }
TEST_F(LuaPeScanner, SectionScanResult_TypeIsRegistered) { check("SectionScanResult_TypeIsRegistered"); }

79
tests/lua/unit_test_lua_source_engine.cpp Normal file
View File

@@ -0,0 +1,79 @@
//
// Created by orange on 07.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaSourceEngine : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/source_engine_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
// PitchAngle
TEST_F(LuaSourceEngine, PitchAngle_from_degrees) { check("Source_PitchAngle_from_degrees"); }
TEST_F(LuaSourceEngine, PitchAngle_clamping_max) { check("Source_PitchAngle_clamping_max"); }
TEST_F(LuaSourceEngine, PitchAngle_clamping_min) { check("Source_PitchAngle_clamping_min"); }
TEST_F(LuaSourceEngine, PitchAngle_from_radians) { check("Source_PitchAngle_from_radians"); }
TEST_F(LuaSourceEngine, PitchAngle_as_radians) { check("Source_PitchAngle_as_radians"); }
TEST_F(LuaSourceEngine, PitchAngle_sin) { check("Source_PitchAngle_sin"); }
TEST_F(LuaSourceEngine, PitchAngle_cos) { check("Source_PitchAngle_cos"); }
TEST_F(LuaSourceEngine, PitchAngle_tan) { check("Source_PitchAngle_tan"); }
TEST_F(LuaSourceEngine, PitchAngle_addition) { check("Source_PitchAngle_addition"); }
TEST_F(LuaSourceEngine, PitchAngle_addition_clamped) { check("Source_PitchAngle_addition_clamped"); }
TEST_F(LuaSourceEngine, PitchAngle_subtraction) { check("Source_PitchAngle_subtraction"); }
TEST_F(LuaSourceEngine, PitchAngle_unary_minus) { check("Source_PitchAngle_unary_minus"); }
TEST_F(LuaSourceEngine, PitchAngle_equal_to) { check("Source_PitchAngle_equal_to"); }
TEST_F(LuaSourceEngine, PitchAngle_to_string) { check("Source_PitchAngle_to_string"); }
// YawAngle
TEST_F(LuaSourceEngine, YawAngle_from_degrees) { check("Source_YawAngle_from_degrees"); }
TEST_F(LuaSourceEngine, YawAngle_normalization) { check("Source_YawAngle_normalization"); }
// RollAngle
TEST_F(LuaSourceEngine, RollAngle_from_degrees) { check("Source_RollAngle_from_degrees"); }
// FieldOfView
TEST_F(LuaSourceEngine, FieldOfView_from_degrees) { check("Source_FieldOfView_from_degrees"); }
TEST_F(LuaSourceEngine, FieldOfView_clamping) { check("Source_FieldOfView_clamping"); }
// ViewAngles
TEST_F(LuaSourceEngine, ViewAngles_new) { check("Source_ViewAngles_new"); }
TEST_F(LuaSourceEngine, ViewAngles_field_mutation) { check("Source_ViewAngles_field_mutation"); }
// Camera
TEST_F(LuaSourceEngine, Camera_constructor) { check("Source_Camera_constructor"); }
TEST_F(LuaSourceEngine, Camera_get_set_origin) { check("Source_Camera_get_set_origin"); }
TEST_F(LuaSourceEngine, Camera_get_set_near_plane) { check("Source_Camera_get_set_near_plane"); }
TEST_F(LuaSourceEngine, Camera_get_set_far_plane) { check("Source_Camera_get_set_far_plane"); }
TEST_F(LuaSourceEngine, Camera_get_set_fov) { check("Source_Camera_get_set_fov"); }
TEST_F(LuaSourceEngine, Camera_get_set_view_angles) { check("Source_Camera_get_set_view_angles"); }
TEST_F(LuaSourceEngine, Camera_look_at) { check("Source_Camera_look_at"); }
TEST_F(LuaSourceEngine, Camera_get_forward) { check("Source_Camera_get_forward"); }
TEST_F(LuaSourceEngine, Camera_get_right) { check("Source_Camera_get_right"); }
TEST_F(LuaSourceEngine, Camera_get_up) { check("Source_Camera_get_up"); }
TEST_F(LuaSourceEngine, Camera_world_to_screen_success) { check("Source_Camera_world_to_screen_success"); }
TEST_F(LuaSourceEngine, Camera_world_to_screen_error) { check("Source_Camera_world_to_screen_error"); }
TEST_F(LuaSourceEngine, Camera_screen_to_world) { check("Source_Camera_screen_to_world"); }

47
tests/lua/unit_test_lua_triangle.cpp Normal file
View File

@@ -0,0 +1,47 @@
//
// Created by orange on 10.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaTriangle : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/triangle_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaTriangle, Constructor_default) { check("Triangle_Constructor_default"); }
TEST_F(LuaTriangle, Constructor_vertices) { check("Triangle_Constructor_vertices"); }
TEST_F(LuaTriangle, Vertex_mutation) { check("Triangle_Vertex_mutation"); }
TEST_F(LuaTriangle, SideALength) { check("Triangle_SideALength"); }
TEST_F(LuaTriangle, SideBLength) { check("Triangle_SideBLength"); }
TEST_F(LuaTriangle, Hypot) { check("Triangle_Hypot"); }
TEST_F(LuaTriangle, SideAVector) { check("Triangle_SideAVector"); }
TEST_F(LuaTriangle, SideBVector) { check("Triangle_SideBVector"); }
TEST_F(LuaTriangle, IsRectangular_true) { check("Triangle_IsRectangular_true"); }
TEST_F(LuaTriangle, IsRectangular_false) { check("Triangle_IsRectangular_false"); }
TEST_F(LuaTriangle, MidPoint) { check("Triangle_MidPoint"); }
TEST_F(LuaTriangle, CalculateNormal) { check("Triangle_CalculateNormal"); }
TEST_F(LuaTriangle, ToString) { check("Triangle_ToString"); }

56
tests/lua/unit_test_lua_vector2.cpp Normal file
View File

@@ -0,0 +1,56 @@
//
// Created by orange on 07.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaVec2 : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/vec2_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaVec2, Constructor_default) { check("Vec2_Constructor_default"); }
TEST_F(LuaVec2, Constructor_xy) { check("Vec2_Constructor_xy"); }
TEST_F(LuaVec2, Field_mutation) { check("Vec2_Field_mutation"); }
TEST_F(LuaVec2, Addition) { check("Vec2_Addition"); }
TEST_F(LuaVec2, Subtraction) { check("Vec2_Subtraction"); }
TEST_F(LuaVec2, UnaryMinus) { check("Vec2_UnaryMinus"); }
TEST_F(LuaVec2, Multiplication_scalar) { check("Vec2_Multiplication_scalar"); }
TEST_F(LuaVec2, Multiplication_scalar_reversed) { check("Vec2_Multiplication_scalar_reversed"); }
TEST_F(LuaVec2, Division_scalar) { check("Vec2_Division_scalar"); }
TEST_F(LuaVec2, EqualTo_true) { check("Vec2_EqualTo_true"); }
TEST_F(LuaVec2, EqualTo_false) { check("Vec2_EqualTo_false"); }
TEST_F(LuaVec2, LessThan) { check("Vec2_LessThan"); }
TEST_F(LuaVec2, LessThanOrEqual) { check("Vec2_LessThanOrEqual"); }
TEST_F(LuaVec2, ToString) { check("Vec2_ToString"); }
TEST_F(LuaVec2, Length) { check("Vec2_Length"); }
TEST_F(LuaVec2, LengthSqr) { check("Vec2_LengthSqr"); }
TEST_F(LuaVec2, Normalized) { check("Vec2_Normalized"); }
TEST_F(LuaVec2, Dot) { check("Vec2_Dot"); }
TEST_F(LuaVec2, DistanceTo) { check("Vec2_DistanceTo"); }
TEST_F(LuaVec2, DistanceToSqr) { check("Vec2_DistanceToSqr"); }
TEST_F(LuaVec2, Sum) { check("Vec2_Sum"); }
TEST_F(LuaVec2, Abs) { check("Vec2_Abs"); }

69
tests/lua/unit_test_lua_vector3.cpp Normal file
View File

@@ -0,0 +1,69 @@
//
// Created by orange on 07.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaVec3 : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/vec3_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaVec3, Constructor_default) { check("Vec3_Constructor_default"); }
TEST_F(LuaVec3, Constructor_xyz) { check("Vec3_Constructor_xyz"); }
TEST_F(LuaVec3, Field_mutation) { check("Vec3_Field_mutation"); }
TEST_F(LuaVec3, Addition) { check("Vec3_Addition"); }
TEST_F(LuaVec3, Subtraction) { check("Vec3_Subtraction"); }
TEST_F(LuaVec3, UnaryMinus) { check("Vec3_UnaryMinus"); }
TEST_F(LuaVec3, Multiplication_scalar) { check("Vec3_Multiplication_scalar"); }
TEST_F(LuaVec3, Multiplication_scalar_reversed) { check("Vec3_Multiplication_scalar_reversed"); }
TEST_F(LuaVec3, Multiplication_vec) { check("Vec3_Multiplication_vec"); }
TEST_F(LuaVec3, Division_scalar) { check("Vec3_Division_scalar"); }
TEST_F(LuaVec3, Division_vec) { check("Vec3_Division_vec"); }
TEST_F(LuaVec3, EqualTo_true) { check("Vec3_EqualTo_true"); }
TEST_F(LuaVec3, EqualTo_false) { check("Vec3_EqualTo_false"); }
TEST_F(LuaVec3, LessThan) { check("Vec3_LessThan"); }
TEST_F(LuaVec3, LessThanOrEqual) { check("Vec3_LessThanOrEqual"); }
TEST_F(LuaVec3, ToString) { check("Vec3_ToString"); }
TEST_F(LuaVec3, Length) { check("Vec3_Length"); }
TEST_F(LuaVec3, Length2d) { check("Vec3_Length2d"); }
TEST_F(LuaVec3, LengthSqr) { check("Vec3_LengthSqr"); }
TEST_F(LuaVec3, Normalized) { check("Vec3_Normalized"); }
TEST_F(LuaVec3, Dot_perpendicular) { check("Vec3_Dot_perpendicular"); }
TEST_F(LuaVec3, Dot_parallel) { check("Vec3_Dot_parallel"); }
TEST_F(LuaVec3, Cross) { check("Vec3_Cross"); }
TEST_F(LuaVec3, DistanceTo) { check("Vec3_DistanceTo"); }
TEST_F(LuaVec3, DistanceToSqr) { check("Vec3_DistanceToSqr"); }
TEST_F(LuaVec3, Sum) { check("Vec3_Sum"); }
TEST_F(LuaVec3, Sum2d) { check("Vec3_Sum2d"); }
TEST_F(LuaVec3, Abs) { check("Vec3_Abs"); }
TEST_F(LuaVec3, PointToSameDirection_true) { check("Vec3_PointToSameDirection_true"); }
TEST_F(LuaVec3, PointToSameDirection_false) { check("Vec3_PointToSameDirection_false"); }
TEST_F(LuaVec3, IsPerpendicular_true) { check("Vec3_IsPerpendicular_true"); }
TEST_F(LuaVec3, IsPerpendicular_false) { check("Vec3_IsPerpendicular_false"); }
TEST_F(LuaVec3, AngleBetween_90deg) { check("Vec3_AngleBetween_90deg"); }
TEST_F(LuaVec3, AngleBetween_zero_vector_error) { check("Vec3_AngleBetween_zero_vector_error"); }
TEST_F(LuaVec3, AsTable) { check("Vec3_AsTable"); }

57
tests/lua/unit_test_lua_vector4.cpp Normal file
View File

@@ -0,0 +1,57 @@
//
// Created by orange on 07.03.2026.
//
#include <gtest/gtest.h>
#include <lua.hpp>
#include <omath/lua/lua.hpp>
class LuaVec4 : public ::testing::Test
{
protected:
lua_State* L = nullptr;
void SetUp() override
{
L = luaL_newstate();
luaL_openlibs(L);
omath::lua::LuaInterpreter::register_lib(L);
if (luaL_dofile(L, LUA_SCRIPTS_DIR "/vec4_tests.lua") != LUA_OK)
FAIL() << lua_tostring(L, -1);
}
void TearDown() override { lua_close(L); }
void check(const char* func_name)
{
lua_getglobal(L, func_name);
if (lua_pcall(L, 0, 0, 0) != LUA_OK)
{
FAIL() << lua_tostring(L, -1);
lua_pop(L, 1);
}
}
};
TEST_F(LuaVec4, Constructor_default) { check("Vec4_Constructor_default"); }
TEST_F(LuaVec4, Constructor_xyzw) { check("Vec4_Constructor_xyzw"); }
TEST_F(LuaVec4, Field_mutation) { check("Vec4_Field_mutation"); }
TEST_F(LuaVec4, Addition) { check("Vec4_Addition"); }
TEST_F(LuaVec4, Subtraction) { check("Vec4_Subtraction"); }
TEST_F(LuaVec4, UnaryMinus) { check("Vec4_UnaryMinus"); }
TEST_F(LuaVec4, Multiplication_scalar) { check("Vec4_Multiplication_scalar"); }
TEST_F(LuaVec4, Multiplication_scalar_reversed) { check("Vec4_Multiplication_scalar_reversed"); }
TEST_F(LuaVec4, Multiplication_vec) { check("Vec4_Multiplication_vec"); }
TEST_F(LuaVec4, Division_scalar) { check("Vec4_Division_scalar"); }
TEST_F(LuaVec4, Division_vec) { check("Vec4_Division_vec"); }
TEST_F(LuaVec4, EqualTo_true) { check("Vec4_EqualTo_true"); }
TEST_F(LuaVec4, EqualTo_false) { check("Vec4_EqualTo_false"); }
TEST_F(LuaVec4, LessThan) { check("Vec4_LessThan"); }
TEST_F(LuaVec4, LessThanOrEqual) { check("Vec4_LessThanOrEqual"); }
TEST_F(LuaVec4, ToString) { check("Vec4_ToString"); }
TEST_F(LuaVec4, Length) { check("Vec4_Length"); }
TEST_F(LuaVec4, LengthSqr) { check("Vec4_LengthSqr"); }
TEST_F(LuaVec4, Dot) { check("Vec4_Dot"); }
TEST_F(LuaVec4, Dot_perpendicular) { check("Vec4_Dot_perpendicular"); }
TEST_F(LuaVec4, Sum) { check("Vec4_Sum"); }
TEST_F(LuaVec4, Abs) { check("Vec4_Abs"); }
TEST_F(LuaVec4, Clamp) { check("Vec4_Clamp"); }

102
tests/lua/vec2_tests.lua Normal file
View File

@@ -0,0 +1,102 @@
local function approx(a, b) return math.abs(a - b) < 1e-5 end
function Vec2_Constructor_default()
local v = omath.Vec2.new()
assert(v.x == 0 and v.y == 0)
end
function Vec2_Constructor_xy()
local v = omath.Vec2.new(3, 4)
assert(v.x == 3 and v.y == 4)
end
function Vec2_Field_mutation()
local v = omath.Vec2.new(1, 2)
v.x = 9; v.y = 8
assert(v.x == 9 and v.y == 8)
end
function Vec2_Addition()
local c = omath.Vec2.new(1, 2) + omath.Vec2.new(3, 4)
assert(c.x == 4 and c.y == 6)
end
function Vec2_Subtraction()
local c = omath.Vec2.new(5, 7) - omath.Vec2.new(2, 3)
assert(c.x == 3 and c.y == 4)
end
function Vec2_UnaryMinus()
local b = -omath.Vec2.new(1, 2)
assert(b.x == -1 and b.y == -2)
end
function Vec2_Multiplication_scalar()
local b = omath.Vec2.new(2, 3) * 2.0
assert(b.x == 4 and b.y == 6)
end
function Vec2_Multiplication_scalar_reversed()
local b = 2.0 * omath.Vec2.new(2, 3)
assert(b.x == 4 and b.y == 6)
end
function Vec2_Division_scalar()
local b = omath.Vec2.new(4, 6) / 2.0
assert(b.x == 2 and b.y == 3)
end
function Vec2_EqualTo_true()
assert(omath.Vec2.new(1, 2) == omath.Vec2.new(1, 2))
end
function Vec2_EqualTo_false()
assert(not (omath.Vec2.new(1, 2) == omath.Vec2.new(9, 9)))
end
function Vec2_LessThan()
assert(omath.Vec2.new(1, 0) < omath.Vec2.new(3, 4))
end
function Vec2_LessThanOrEqual()
-- (3,4) and (4,3) both have length 5
assert(omath.Vec2.new(3, 4) <= omath.Vec2.new(4, 3))
end
function Vec2_ToString()
assert(tostring(omath.Vec2.new(1, 2)) == "Vec2(1, 2)")
end
function Vec2_Length()
assert(approx(omath.Vec2.new(3, 4):length(), 5.0))
end
function Vec2_LengthSqr()
assert(omath.Vec2.new(3, 4):length_sqr() == 25.0)
end
function Vec2_Normalized()
local n = omath.Vec2.new(3, 4):normalized()
assert(approx(n.x, 0.6) and approx(n.y, 0.8))
end
function Vec2_Dot()
assert(omath.Vec2.new(1, 2):dot(omath.Vec2.new(3, 4)) == 11.0)
end
function Vec2_DistanceTo()
assert(approx(omath.Vec2.new(0, 0):distance_to(omath.Vec2.new(3, 4)), 5.0))
end
function Vec2_DistanceToSqr()
assert(omath.Vec2.new(0, 0):distance_to_sqr(omath.Vec2.new(3, 4)) == 25.0)
end
function Vec2_Sum()
assert(omath.Vec2.new(3, 4):sum() == 7.0)
end
function Vec2_Abs()
local a = omath.Vec2.new(-3, -4):abs()
assert(a.x == 3 and a.y == 4)
end

163
tests/lua/vec3_tests.lua Normal file
View File

@@ -0,0 +1,163 @@
local function approx(a, b, eps) return math.abs(a - b) < (eps or 1e-5) end
function Vec3_Constructor_default()
local v = omath.Vec3.new()
assert(v.x == 0 and v.y == 0 and v.z == 0)
end
function Vec3_Constructor_xyz()
local v = omath.Vec3.new(1, 2, 3)
assert(v.x == 1 and v.y == 2 and v.z == 3)
end
function Vec3_Field_mutation()
local v = omath.Vec3.new(1, 2, 3)
v.x = 9; v.y = 8; v.z = 7
assert(v.x == 9 and v.y == 8 and v.z == 7)
end
function Vec3_Addition()
local c = omath.Vec3.new(1, 2, 3) + omath.Vec3.new(4, 5, 6)
assert(c.x == 5 and c.y == 7 and c.z == 9)
end
function Vec3_Subtraction()
local c = omath.Vec3.new(4, 5, 6) - omath.Vec3.new(1, 2, 3)
assert(c.x == 3 and c.y == 3 and c.z == 3)
end
function Vec3_UnaryMinus()
local b = -omath.Vec3.new(1, 2, 3)
assert(b.x == -1 and b.y == -2 and b.z == -3)
end
function Vec3_Multiplication_scalar()
local b = omath.Vec3.new(1, 2, 3) * 2.0
assert(b.x == 2 and b.y == 4 and b.z == 6)
end
function Vec3_Multiplication_scalar_reversed()
local b = 2.0 * omath.Vec3.new(1, 2, 3)
assert(b.x == 2 and b.y == 4 and b.z == 6)
end
function Vec3_Multiplication_vec()
local c = omath.Vec3.new(2, 3, 4) * omath.Vec3.new(2, 2, 2)
assert(c.x == 4 and c.y == 6 and c.z == 8)
end
function Vec3_Division_scalar()
local b = omath.Vec3.new(2, 4, 6) / 2.0
assert(b.x == 1 and b.y == 2 and b.z == 3)
end
function Vec3_Division_vec()
local c = omath.Vec3.new(4, 6, 8) / omath.Vec3.new(2, 2, 2)
assert(c.x == 2 and c.y == 3 and c.z == 4)
end
function Vec3_EqualTo_true()
assert(omath.Vec3.new(1, 2, 3) == omath.Vec3.new(1, 2, 3))
end
function Vec3_EqualTo_false()
assert(not (omath.Vec3.new(1, 2, 3) == omath.Vec3.new(9, 9, 9)))
end
function Vec3_LessThan()
assert(omath.Vec3.new(1, 0, 0) < omath.Vec3.new(3, 4, 0))
end
function Vec3_LessThanOrEqual()
-- (0,3,4) and (0,4,3) both have length 5
assert(omath.Vec3.new(0, 3, 4) <= omath.Vec3.new(0, 4, 3))
end
function Vec3_ToString()
assert(tostring(omath.Vec3.new(1, 2, 3)) == "Vec3(1, 2, 3)")
end
function Vec3_Length()
assert(approx(omath.Vec3.new(1, 2, 2):length(), 3.0))
end
function Vec3_Length2d()
assert(approx(omath.Vec3.new(3, 4, 99):length_2d(), 5.0))
end
function Vec3_LengthSqr()
assert(omath.Vec3.new(1, 2, 2):length_sqr() == 9.0)
end
function Vec3_Normalized()
local n = omath.Vec3.new(3, 0, 0):normalized()
assert(approx(n.x, 1.0) and approx(n.y, 0.0) and approx(n.z, 0.0))
end
function Vec3_Dot_perpendicular()
assert(omath.Vec3.new(1, 0, 0):dot(omath.Vec3.new(0, 1, 0)) == 0.0)
end
function Vec3_Dot_parallel()
local a = omath.Vec3.new(1, 2, 3)
assert(a:dot(a) == 14.0)
end
function Vec3_Cross()
local c = omath.Vec3.new(1, 0, 0):cross(omath.Vec3.new(0, 1, 0))
assert(approx(c.x, 0) and approx(c.y, 0) and approx(c.z, 1))
end
function Vec3_DistanceTo()
assert(approx(omath.Vec3.new(0, 0, 0):distance_to(omath.Vec3.new(1, 2, 2)), 3.0))
end
function Vec3_DistanceToSqr()
assert(omath.Vec3.new(0, 0, 0):distance_to_sqr(omath.Vec3.new(1, 2, 2)) == 9.0)
end
function Vec3_Sum()
assert(omath.Vec3.new(1, 2, 3):sum() == 6.0)
end
function Vec3_Sum2d()
assert(omath.Vec3.new(1, 2, 3):sum_2d() == 3.0)
end
function Vec3_Abs()
local a = omath.Vec3.new(-1, -2, -3):abs()
assert(a.x == 1 and a.y == 2 and a.z == 3)
end
function Vec3_PointToSameDirection_true()
assert(omath.Vec3.new(1, 1, 0):point_to_same_direction(omath.Vec3.new(2, 2, 0)) == true)
end
function Vec3_PointToSameDirection_false()
assert(omath.Vec3.new(1, 0, 0):point_to_same_direction(omath.Vec3.new(-1, 0, 0)) == false)
end
function Vec3_IsPerpendicular_true()
assert(omath.Vec3.new(1, 0, 0):is_perpendicular(omath.Vec3.new(0, 1, 0)) == true)
end
function Vec3_IsPerpendicular_false()
local a = omath.Vec3.new(1, 0, 0)
assert(a:is_perpendicular(a) == false)
end
function Vec3_AngleBetween_90deg()
local angle, err = omath.Vec3.new(1, 0, 0):angle_between(omath.Vec3.new(0, 1, 0))
assert(angle ~= nil, err)
assert(math.abs(angle - 90.0) < 1e-3)
end
function Vec3_AngleBetween_zero_vector_error()
local angle, err = omath.Vec3.new(0, 0, 0):angle_between(omath.Vec3.new(1, 0, 0))
assert(angle == nil and err ~= nil)
end
function Vec3_AsTable()
local t = omath.Vec3.new(1, 2, 3):as_table()
assert(t.x == 1 and t.y == 2 and t.z == 3)
end

110
tests/lua/vec4_tests.lua Normal file
View File

@@ -0,0 +1,110 @@
local function approx(a, b) return math.abs(a - b) < 1e-5 end
function Vec4_Constructor_default()
local v = omath.Vec4.new()
assert(v.x == 0 and v.y == 0 and v.z == 0 and v.w == 0)
end
function Vec4_Constructor_xyzw()
local v = omath.Vec4.new(1, 2, 3, 4)
assert(v.x == 1 and v.y == 2 and v.z == 3 and v.w == 4)
end
function Vec4_Field_mutation()
local v = omath.Vec4.new(1, 2, 3, 4)
v.w = 99
assert(v.w == 99)
end
function Vec4_Addition()
local c = omath.Vec4.new(1, 2, 3, 4) + omath.Vec4.new(4, 3, 2, 1)
assert(c.x == 5 and c.y == 5 and c.z == 5 and c.w == 5)
end
function Vec4_Subtraction()
local c = omath.Vec4.new(5, 5, 5, 5) - omath.Vec4.new(1, 2, 3, 4)
assert(c.x == 4 and c.y == 3 and c.z == 2 and c.w == 1)
end
function Vec4_UnaryMinus()
local b = -omath.Vec4.new(1, 2, 3, 4)
assert(b.x == -1 and b.y == -2 and b.z == -3 and b.w == -4)
end
function Vec4_Multiplication_scalar()
local b = omath.Vec4.new(1, 2, 3, 4) * 2.0
assert(b.x == 2 and b.y == 4 and b.z == 6 and b.w == 8)
end
function Vec4_Multiplication_scalar_reversed()
local b = 2.0 * omath.Vec4.new(1, 2, 3, 4)
assert(b.x == 2 and b.y == 4 and b.z == 6 and b.w == 8)
end
function Vec4_Multiplication_vec()
local c = omath.Vec4.new(2, 3, 4, 5) * omath.Vec4.new(2, 2, 2, 2)
assert(c.x == 4 and c.y == 6 and c.z == 8 and c.w == 10)
end
function Vec4_Division_scalar()
local b = omath.Vec4.new(2, 4, 6, 8) / 2.0
assert(b.x == 1 and b.y == 2 and b.z == 3 and b.w == 4)
end
function Vec4_Division_vec()
local c = omath.Vec4.new(4, 6, 8, 10) / omath.Vec4.new(2, 2, 2, 2)
assert(c.x == 2 and c.y == 3 and c.z == 4 and c.w == 5)
end
function Vec4_EqualTo_true()
assert(omath.Vec4.new(1, 2, 3, 4) == omath.Vec4.new(1, 2, 3, 4))
end
function Vec4_EqualTo_false()
assert(not (omath.Vec4.new(1, 2, 3, 4) == omath.Vec4.new(9, 9, 9, 9)))
end
function Vec4_LessThan()
assert(omath.Vec4.new(1, 0, 0, 0) < omath.Vec4.new(0, 0, 3, 4))
end
function Vec4_LessThanOrEqual()
-- (0,0,3,4) and (0,0,4,3) both have length 5
assert(omath.Vec4.new(0, 0, 3, 4) <= omath.Vec4.new(0, 0, 4, 3))
end
function Vec4_ToString()
assert(tostring(omath.Vec4.new(1, 2, 3, 4)) == "Vec4(1, 2, 3, 4)")
end
function Vec4_Length()
assert(approx(omath.Vec4.new(0, 0, 3, 4):length(), 5.0))
end
function Vec4_LengthSqr()
assert(omath.Vec4.new(0, 0, 3, 4):length_sqr() == 25.0)
end
function Vec4_Dot()
local a = omath.Vec4.new(1, 2, 3, 4)
assert(a:dot(a) == 30.0)
end
function Vec4_Dot_perpendicular()
assert(omath.Vec4.new(1, 0, 0, 0):dot(omath.Vec4.new(0, 1, 0, 0)) == 0.0)
end
function Vec4_Sum()
assert(omath.Vec4.new(1, 2, 3, 4):sum() == 10.0)
end
function Vec4_Abs()
local a = omath.Vec4.new(-1, -2, -3, -4):abs()
assert(a.x == 1 and a.y == 2 and a.z == 3 and a.w == 4)
end
function Vec4_Clamp()
local v = omath.Vec4.new(5, -3, 10, 99)
v:clamp(0, 7)
assert(v.x == 5 and v.y == 0 and v.z == 7)
end

29
tests/lua/vector2_test.lua Normal file
View File

@@ -0,0 +1,29 @@
local a = omath.Vec2.new(1, 2)
local b = omath.Vec2.new(10, 20)
-- Operators
local c = a + b
local d = a - b
local e = a * 2.0
local f = -a
print("a + b = " .. tostring(c))
print("a - b = " .. tostring(d))
print("a * 2 = " .. tostring(e))
print("-a = " .. tostring(f))
print("a == Vec2(1,2): " .. tostring(a == omath.Vec2.new(1, 2)))
print("a < b: " .. tostring(a < b))
-- Field access + mutation
print("c.x = " .. c.x .. ", c.y = " .. c.y)
c.x = 99
print("c.x after mutation = " .. c.x)
-- Methods
print("a:length() = " .. a:length())
print("a:length_sqr() = " .. a:length_sqr())
print("a:normalized() = " .. tostring(a:normalized()))
print("a:dot(b) = " .. a:dot(b))
print("a:distance_to(b) = " .. a:distance_to(b))
print("a:distance_to_sqr(b) = " .. a:distance_to_sqr(b))
print("a:sum() = " .. a:sum())
print("a:abs() = " .. tostring(a:abs()))

55
tests/lua/vector3_test.lua Normal file
View File

@@ -0,0 +1,55 @@
local a = omath.Vec3.new(1, 0, 0)
local b = omath.Vec3.new(0, 1, 0)
-- Operators
local c = a + b
local d = a - b
local e = a * 2.0
local f = -a
print("a + b = " .. tostring(c))
print("a - b = " .. tostring(d))
print("a * 2 = " .. tostring(e))
print("-a = " .. tostring(f))
print("a == Vec3(1,2,3): " .. tostring(a == omath.Vec3.new(1, 2, 3)))
print("a < b: " .. tostring(a < b))
-- Field access + mutation
print("c.x = " .. c.x .. ", c.y = " .. c.y .. ", c.z = " .. c.z)
c.x = 99
print("c.x after mutation = " .. c.x)
-- Methods
print("a:length() = " .. a:length())
print("a:length_2d() = " .. a:length_2d())
print("a:length_sqr() = " .. a:length_sqr())
print("a:normalized() = " .. tostring(a:normalized()))
print("a:dot(b) = " .. a:dot(b))
print("a:cross(b) = " .. tostring(a:cross(b)))
print("a:distance_to(b) = " .. a:distance_to(b))
print("a:distance_to_sqr(b) = " .. a:distance_to_sqr(b))
print("a:abs() = " .. tostring(a:abs()))
print("a:sum() = " .. a:sum())
print("a:sum_2d() = " .. a:sum_2d())
print("a:point_to_same_direction(b) = " .. tostring(a:point_to_same_direction(b)))
print("a:is_perpendicular(b) = " .. tostring(a:is_perpendicular(b)))
-- angle_between
local angle, err = a:angle_between(b)
if angle then
print("angle_between = " .. angle .. " degrees")
else
print("angle_between error: " .. err)
end
-- Zero vector edge case
local zero = omath.Vec3.new(0, 0, 0)
local ang2, err2 = zero:angle_between(a)
if ang2 then
print("zero angle = " .. ang2)
else
print("zero angle error: " .. err2)
end
-- as_table
local t = a:as_table()
print("as_table: x=" .. t.x .. " y=" .. t.y .. " z=" .. t.z)

31
tests/lua/vector4_test.lua Normal file
View File

@@ -0,0 +1,31 @@
local a = omath.Vec4.new(1, 2, 3, 4)
local b = omath.Vec4.new(10, 20, 30, 40)
-- Operators
local c = a + b
local d = a - b
local e = a * 2.0
local f = -a
print("a + b = " .. tostring(c))
print("a - b = " .. tostring(d))
print("a * 2 = " .. tostring(e))
print("-a = " .. tostring(f))
print("a == Vec4(1,2,3,4): " .. tostring(a == omath.Vec4.new(1, 2, 3, 4)))
print("a < b: " .. tostring(a < b))
-- Field access + mutation
print("c.x=" .. c.x .. " c.y=" .. c.y .. " c.z=" .. c.z .. " c.w=" .. c.w)
c.w = 99
print("c.w after mutation = " .. c.w)
-- Methods
print("a:length() = " .. a:length())
print("a:length_sqr() = " .. a:length_sqr())
print("a:dot(b) = " .. a:dot(b))
print("a:sum() = " .. a:sum())
print("a:abs() = " .. tostring(a:abs()))
-- clamp
local clamped = omath.Vec4.new(5, -3, 10, 1)
clamped:clamp(0, 7)
print("clamp([5,-3,10,1], 0, 7).x=" .. clamped.x .. " .y=" .. clamped.y .. " .z=" .. clamped.z)

2
vcpkg-configuration.json
View File

@@ -1,7 +1,7 @@
{
"default-registry": {
"kind": "git",
"baseline": "b1b19307e2d2ec1eefbdb7ea069de7d4bcd31f01",
"baseline": "efa4634bd526b87559684607d2cbbdeeec0f07d8",
"repository": "https://github.com/microsoft/vcpkg"
},
"registries": [

18
vcpkg.json
View File

@@ -17,7 +17,7 @@
],
"features": {
"avx2": {
"description": "Omath will use AVX2 to boost performance",
"description": "omath will use AVX2 to boost performance",
"supports": "!arm"
},
"benchmark": {
@@ -35,7 +35,7 @@
]
},
"imgui": {
"description": "Omath will define method to convert omath types to imgui types",
"description": "omath will define method to convert omath types to imgui types",
"dependencies": [
"imgui"
]
@@ -45,6 +45,20 @@
"dependencies": [
"gtest"
]
},
"lua": {
"description": "lua support for omath",
"dependencies": [
"lua",
"sol2"
]
},
"physx": {
"description": "PhysX-backed collider implementations",
"dependencies": [
"physx"
],
"supports": "(windows & x64 & !mingw & !uwp) | (linux & x64) | (linux & arm64)"
}
}
}