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base: admin:02d909f77df5da297abf8352b7d77384b6e39f2a
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

88 Commits
02d909f77d ... 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
Orange++
9752accb14 Merge pull request #160 from orange-cpp/feaure/gjk-epa-improvement 
Feaure/gjk epa improvement
 2026-03-03 18:25:37 +03:00
orange
7373e6d3df added std namspace to int64_t type 2026-03-03 10:00:46 +03:00
orange
68f4c8cc72 added nodiscard 2026-03-03 09:38:05 +03:00
orange
2dafc8a49d added additional method 2026-03-03 09:22:11 +03:00
orange
11fe49e801 added const 2026-03-03 08:51:13 +03:00
orange
dee705a391 improvement 2026-03-03 08:43:30 +03:00
orange
bfe147ef80 Merge remote-tracking branch 'orange-cpp/feaure/gjk-epa-improvement' into feaure/gjk-epa-improvement 2026-03-03 08:27:50 +03:00
orange
2c70288a8f added epa tests 2026-03-03 08:27:26 +03:00
Orange
529322fe34 decomposed method 2026-03-03 08:14:12 +03:00
orange
414b2af289 added gjk tests 2026-03-02 19:58:31 +03:00
orange
a79ad6948c optimized 2026-03-02 19:40:45 +03:00
orange
ea2c7c3d7f added benchmark 2026-03-02 19:40:37 +03:00
Orange++
91c2e0d74b Merge pull request #159 from orange-cpp/feature/color_update 
Feature/color update
 2026-03-01 13:53:18 +03:00
Orange
52e9b906ff added const 2026-03-01 13:32:13 +03:00
Orange
cc6d625c2d added more formaters 2026-03-01 13:30:32 +03:00
Orange
5eaec70846 fixed tests 2026-03-01 13:22:15 +03:00
Orange
2063c4d33a updated color 2026-03-01 13:15:09 +03:00
Orange
60bf8ca30f moved file 2026-03-01 13:00:24 +03:00
Orange++
6fca106edc Merge pull request #158 from orange-cpp/feature/quaternions 
added files
 2026-03-01 09:04:18 +03:00
orange
78cb644920 added files 2026-03-01 08:23:26 +03:00
orange
646a920e4c fixed potential deadlock 2026-02-27 08:47:46 +03:00
Orange
52687a70c7 fixed formating 2026-02-27 07:41:05 +03:00
Orange++
a9eff7d320 Merge pull request #157 from orange-cpp/feature/mesh_improvement 
Feature/mesh improvement
 2026-02-26 16:39:21 +03:00
orange
211e4c3d9b optimization 2026-02-26 16:19:54 +03:00
orange
74dc2234f7 fixed collider when rotated 2026-02-26 16:17:41 +03:00
Orange
7ebbed6763 added funding 
edit
 2026-02-23 07:18:25 +03:00
Orange
e271bccaf5 added codeowners 2026-02-23 06:45:43 +03:00
orange
50765f69c5 removed unused var 2026-02-23 04:36:48 +03:00
orange
1169534133 fix 2026-02-23 04:32:13 +03:00
Orange++
783501aab9 Enhance installation guide with prebuilt binaries section 
Updated vcpkg section and added instructions for using prebuilt binaries from GitHub Releases.
 2026-02-21 10:00:19 +03:00
Orange++
1a79566731 Merge pull request #156 from orange-cpp/copilot/add-automatic-binary-attach 
Add release workflow with binary uploads for all CI platforms
 2026-02-21 09:31:12 +03:00
copilot-swe-agent[bot]
9183406e7a Add all CI pipeline platforms to release workflow (Linux x86, iOS, FreeBSD, Android, WebAssembly, MinGW) 
Co-authored-by: orange-cpp <59374393+orange-cpp@users.noreply.github.com>
 2026-02-21 04:55:36 +00:00
copilot-swe-agent[bot]
b592af91a9 Add release workflow to automatically attach binaries to new releases 
Co-authored-by: orange-cpp <59374393+orange-cpp@users.noreply.github.com>
 2026-02-21 04:45:20 +00:00
copilot-swe-agent[bot]
af9c043e95 Initial plan 2026-02-21 04:41:46 +00:00
Orange
2aaa8633b9 updated tag 2026-02-20 09:07:33 +03:00
Orange++
0d1cc2088f Merge pull request #155 from orange-cpp/feaute/examples-folders 
retructurized examples
 2026-02-20 08:55:20 +03:00
Orange
260b3b97f9 fix 2026-02-20 08:53:03 +03:00
Orange
e0904690e6 fixed formating 2026-02-20 08:52:26 +03:00
Orange
7021d9d365 fixed formating 2026-02-20 08:46:43 +03:00
Orange
862d52593a retructurized examples 2026-02-20 07:48:19 +03:00
orange
97a3111791 fixed code style 2026-02-20 04:02:26 +03:00
Orange++
a9bec00973 Merge pull request #154 from luadebug/example1 
Example with opengl triangle
 2026-02-20 03:37:58 +03:00
Saikari
66debb46fa Refactor to use Color class and Triangle structure for better clarity in drawing functions 2026-02-20 03:01:34 +03:00
Saikari
b8323d3bc0 simplify complexity 2026-02-20 02:56:27 +03:00
Saikari
f363fa6f1a Fix text 2026-02-20 02:53:20 +03:00
Saikari
0546272493 Use dot not quad 2026-02-20 02:50:55 +03:00
Saikari
58801bfab3 Add one more example 2026-02-20 02:43:27 +03:00
Orange
4567cfa318 updated read me 2026-02-19 12:03:19 +03:00
Orange
1db9340dbf updated read me 2026-02-19 08:42:58 +03:00
Orange++
7b9a181b0e Merge pull request #153 from orange-cpp/feature/cryengine-support 
Feature/cryengine support
 2026-02-19 08:34:33 +03:00
Orange
0876af3c14 added warning back 2026-02-19 08:34:21 +03:00
Orange
e46a369ddc added more tests 2026-02-19 08:06:34 +03:00
Orange
630ffa69f6 clang format 2026-02-19 08:00:23 +03:00
Orange
609970cdfe fix 2026-02-19 07:57:04 +03:00
Orange
e935155022 improved tests 2026-02-19 07:47:23 +03:00
Orange
800082e4b3 added mesh 2026-02-19 06:35:08 +03:00
91 changed files with 7013 additions and 368 deletions
Expand all files Collapse all files

4
.github/FUNDING.yml vendored Normal file
View File

@@ -0,0 +1,4 @@
# These are supported funding model platforms
open_collective: libomathorg
github: orange-cpp

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

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

618
.github/workflows/release.yml vendored Normal file
View File

@@ -0,0 +1,618 @@
name: Release
on:
release:
types: [published]
concurrency:
group: release-${{ github.ref }}
cancel-in-progress: true
permissions:
contents: write
jobs:
##############################################################################
# 1) Linux Clang / Ninja
##############################################################################
linux-release:
name: ${{ matrix.name }}
runs-on: ${{ matrix.runner }}
strategy:
matrix:
include:
- name: Linux (Clang) (x64-linux)
triplet: x64-linux
runner: ubuntu-latest
preset: linux-release-vcpkg
archive: omath-linux-x64
install_cmd: |
wget -qO- https://apt.llvm.org/llvm-snapshot.gpg.key | sudo tee /etc/apt/trusted.gpg.d/apt.llvm.org.asc
sudo add-apt-repository -y "deb http://apt.llvm.org/noble/ llvm-toolchain-noble-21 main"
sudo apt-get update
sudo apt-get install -y git build-essential cmake ninja-build \
zip unzip curl pkg-config ca-certificates \
clang-21 lld-21 libc++-21-dev libc++abi-21-dev
sudo update-alternatives --install /usr/bin/cc cc /usr/bin/clang-21 100
sudo update-alternatives --install /usr/bin/c++ c++ /usr/bin/clang++-21 100
sudo update-alternatives --install /usr/bin/lld lld /usr/bin/lld-21 100
- name: Linux (Clang) (x86-linux)
triplet: x86-linux
runner: ubuntu-latest
preset: linux-release-vcpkg-x86
archive: omath-linux-x86
install_cmd: |
# Add LLVM 21 repository
wget -qO- https://apt.llvm.org/llvm-snapshot.gpg.key | sudo tee /etc/apt/trusted.gpg.d/apt.llvm.org.asc
sudo add-apt-repository -y "deb http://apt.llvm.org/noble/ llvm-toolchain-noble-21 main"
# Add GCC Toolchain PPA
sudo add-apt-repository -y "deb http://archive.ubuntu.com/ubuntu plucky main universe"
# Enable i386 architecture
sudo dpkg --add-architecture i386
sudo apt-get update
# Install Clang 21
sudo apt-get install -y git build-essential cmake ninja-build \
zip unzip curl pkg-config ca-certificates \
clang-21 lld-21 libc++-21-dev libc++abi-21-dev
sudo apt-get install -y -t plucky binutils
# Install GCC 15 with multilib support
sudo apt-get install -y gcc-15-multilib g++-15-multilib
# Set up alternatives for Clang
sudo update-alternatives --install /usr/bin/cc cc /usr/bin/clang-21 100
sudo update-alternatives --install /usr/bin/c++ c++ /usr/bin/clang++-21 100
sudo update-alternatives --install /usr/bin/lld lld /usr/bin/lld-21 100
# Set up alternatives for GCC
sudo update-alternatives --install /usr/bin/gcc gcc /usr/bin/gcc-15 100
sudo update-alternatives --install /usr/bin/g++ g++ /usr/bin/g++-15 100
- name: Linux (Clang) (arm64-linux)
triplet: arm64-linux
runner: ubuntu-24.04-arm
preset: linux-release-vcpkg-arm64
archive: omath-linux-arm64
install_cmd: |
wget -qO- https://apt.llvm.org/llvm-snapshot.gpg.key | sudo tee /etc/apt/trusted.gpg.d/apt.llvm.org.asc
sudo add-apt-repository -y "deb http://apt.llvm.org/noble/ llvm-toolchain-noble-21 main"
sudo apt-get update
sudo apt-get install -y git build-essential cmake ninja-build \
zip unzip curl pkg-config ca-certificates \
clang-21 lld-21 libc++-21-dev libc++abi-21-dev
sudo update-alternatives --install /usr/bin/cc cc /usr/bin/clang-21 100
sudo update-alternatives --install /usr/bin/c++ c++ /usr/bin/clang++-21 100
sudo update-alternatives --install /usr/bin/lld lld /usr/bin/lld-21 100
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Install basic tool-chain
shell: bash
run: ${{ matrix.install_cmd }}
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Set up vcpkg
shell: bash
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2"
- name: Build
shell: bash
run: cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: bash
run: tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 2) Windows MSVC / Ninja
##############################################################################
windows-release:
name: ${{ matrix.name }}
runs-on: ${{ matrix.runner }}
strategy:
matrix:
include:
- name: Windows (MSVC) (x64-windows)
runner: windows-latest
arch: amd64
preset: windows-release-vcpkg
triplet: x64-windows
archive: omath-windows-x64
- name: Windows (MSVC) (x86-windows)
runner: windows-latest
arch: amd64_x86
preset: windows-release-vcpkg-x86
triplet: x86-windows
archive: omath-windows-x86
- name: Windows (MSVC) (arm64-windows)
runner: windows-11-arm
arch: arm64
preset: windows-release-vcpkg-arm64
triplet: arm64-windows
archive: omath-windows-arm64
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Install Ninja
uses: seanmiddleditch/gha-setup-ninja@v4
- name: Set up MSVC developer command-prompt
uses: ilammy/msvc-dev-cmd@v1
with:
arch: ${{ matrix.arch }}
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2"
- name: Build
shell: bash
run: cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: pwsh
run: Compress-Archive -Path staging\* -DestinationPath "${{ matrix.archive }}.zip"
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.zip" --clobber
##############################################################################
# 3) macOS AppleClang / Ninja
##############################################################################
macos-release:
name: ${{ matrix.name }}
runs-on: ${{ matrix.runner }}
strategy:
matrix:
include:
- name: macOS (AppleClang) (arm64-osx)
runner: macos-latest
preset: darwin-release-vcpkg
triplet: arm64-osx
archive: omath-macos-arm64
- name: macOS (AppleClang) (x64-osx)
runner: macos-15-intel
preset: darwin-release-vcpkg-x64
triplet: x64-osx
archive: omath-macos-x64
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Install basic tool-chain with Homebrew
shell: bash
run: |
brew install cmake ninja
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Set up vcpkg
shell: bash
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2"
- name: Build
shell: bash
run: cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: bash
run: tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 4) iOS AppleClang / Xcode / arm64-ios
##############################################################################
ios-release:
name: iOS (AppleClang) (${{ matrix.triplet }})
runs-on: macOS-latest
strategy:
matrix:
include:
- triplet: arm64-ios
preset: ios-release-vcpkg
archive: omath-ios-arm64
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Install CMake tooling
shell: bash
run: |
brew install cmake ninja
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Set up vcpkg
shell: bash
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui"
- name: Build
shell: bash
run: |
cmake --build cmake-build/build/${{ matrix.preset }} --config Release --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: bash
run: tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 5) FreeBSD Clang / Ninja
##############################################################################
freebsd-release:
name: FreeBSD (Clang) (${{ matrix.triplet }})
runs-on: ubuntu-latest
strategy:
matrix:
include:
- triplet: x64-freebsd
preset: freebsd-release-vcpkg
arch: x86-64
archive: omath-freebsd-x64
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/tmp/vcpkg
steps:
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Build and Package
uses: cross-platform-actions/action@v0.31.0
with:
operating_system: freebsd
architecture: ${{ matrix.arch }}
version: '15.0'
memory: '12G'
cpu_count: 4
run: |
sudo pkg install -y git curl zip unzip gmake llvm gsed bash perl5 openssl 7-zip coreutils cmake ninja pkgconf patchelf
git config --global --add safe.directory `pwd`
# Build vcpkg in /tmp to avoid sshfs timestamp sync issues
export VCPKG_ROOT=/tmp/vcpkg
rm -rf "$VCPKG_ROOT"
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
cd -
export VCPKG_FORCE_SYSTEM_BINARIES=0
cmake --preset ${{ matrix.preset }} \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui;avx2" \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported"
cmake --build cmake-build/build/${{ matrix.preset }} --target omath
cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 6) Android NDK Clang / Ninja
##############################################################################
android-release:
name: Android NDK (${{ matrix.triplet }})
runs-on: ubuntu-latest
strategy:
matrix:
include:
- triplet: arm-neon-android
preset: android-arm-neon-release-vcpkg
archive: omath-android-arm-neon
- triplet: arm64-android
preset: android-arm64-release-vcpkg
archive: omath-android-arm64
- triplet: x64-android
preset: android-x64-release-vcpkg
archive: omath-android-x64
- triplet: x86-android
preset: android-x86-release-vcpkg
archive: omath-android-x86
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
ANDROID_NDK_HOME: ${{ github.workspace }}/android-ndk
steps:
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Install Android NDK
shell: bash
run: |
NDK_VERSION="r28b"
NDK_ZIP="android-ndk-${NDK_VERSION}-linux.zip"
wget -q "https://dl.google.com/android/repository/${NDK_ZIP}"
unzip -q "${NDK_ZIP}" -d "${{ github.workspace }}"
mv "${{ github.workspace }}/android-ndk-${NDK_VERSION}" "$ANDROID_NDK_HOME"
rm "${NDK_ZIP}"
echo "ANDROID_NDK_HOME=${ANDROID_NDK_HOME}" >> $GITHUB_ENV
- name: Install basic tool-chain
shell: bash
run: |
sudo apt-get update
sudo apt-get install -y ninja-build cmake
- name: Set up vcpkg
shell: bash
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui"
- name: Build
shell: bash
run: |
cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: bash
run: tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 7) WebAssembly (Emscripten) Clang / Ninja / wasm32-emscripten
##############################################################################
wasm-release:
name: WebAssembly (Emscripten) (${{ matrix.triplet }})
runs-on: ubuntu-latest
strategy:
matrix:
include:
- triplet: wasm32-emscripten
preset: wasm-release-vcpkg
archive: omath-wasm32
fail-fast: false
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Install basic tool-chain
shell: bash
run: |
sudo apt-get update
sudo apt-get install -y ninja-build
- name: Setup Emscripten
uses: mymindstorm/setup-emsdk@v14
with:
version: 'latest'
- name: Verify Emscripten
shell: bash
run: |
echo "EMSDK=$EMSDK"
emcc --version
ls -la "$EMSDK/upstream/emscripten/cmake/Modules/Platform/Emscripten.cmake"
- name: Set up vcpkg
shell: bash
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
- name: Configure (cmake --preset)
shell: bash
run: |
cmake --preset ${{ matrix.preset }} \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui"
- name: Build
shell: bash
run: |
cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
shell: bash
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: bash
run: tar -czf ${{ matrix.archive }}.tar.gz -C staging .
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.tar.gz" --clobber
##############################################################################
# 8) Windows MSYS2 MinGW GCC / Ninja
##############################################################################
mingw-release:
name: ${{ matrix.name }}
runs-on: windows-latest
strategy:
matrix:
include:
- name: MINGW64 (MSYS2) (x64-mingw-dynamic)
msystem: MINGW64
pkg_prefix: mingw-w64-x86_64
preset: mingw-release-vcpkg
archive: omath-mingw64-x64
- name: UCRT64 (MSYS2) (x64-mingw-dynamic)
msystem: UCRT64
pkg_prefix: mingw-w64-ucrt-x86_64
preset: mingw-release-vcpkg
archive: omath-ucrt64-x64
- name: MINGW32 (MSYS2) (x86-mingw-dynamic)
msystem: MINGW32
pkg_prefix: mingw-w64-i686
preset: mingw32-release-vcpkg
archive: omath-mingw32-x86
fail-fast: false
defaults:
run:
shell: msys2 {0}
env:
VCPKG_ROOT: ${{ github.workspace }}/vcpkg
steps:
- name: Setup MSYS2
uses: msys2/setup-msys2@v2
with:
msystem: ${{ matrix.msystem }}
update: true
install: >-
${{ matrix.pkg_prefix }}-toolchain
${{ matrix.pkg_prefix }}-cmake
${{ matrix.pkg_prefix }}-ninja
${{ matrix.pkg_prefix }}-pkg-config
git
base-devel
- name: Checkout repository (with sub-modules)
uses: actions/checkout@v4
with:
submodules: recursive
- name: Set up vcpkg
run: |
git clone https://github.com/microsoft/vcpkg "$VCPKG_ROOT"
cd "$VCPKG_ROOT"
./bootstrap-vcpkg.sh
- name: Configure (cmake --preset)
run: |
cmake --preset ${{ matrix.preset }} \
-DVCPKG_INSTALL_OPTIONS="--allow-unsupported" \
-DOMATH_BUILD_TESTS=OFF \
-DOMATH_BUILD_BENCHMARK=OFF \
-DVCPKG_MANIFEST_FEATURES="imgui"
- name: Build
run: |
cmake --build cmake-build/build/${{ matrix.preset }} --target omath
- name: Install
run: cmake --install cmake-build/build/${{ matrix.preset }} --prefix staging
- name: Package
shell: pwsh
run: Compress-Archive -Path staging\* -DestinationPath "${{ matrix.archive }}.zip"
- name: Upload release asset
env:
GH_TOKEN: ${{ github.token }}
shell: bash
run: gh release upload "${{ github.event.release.tag_name }}" "${{ matrix.archive }}.zip" --clobber

4
.idea/editor.xml generated
View File

@@ -17,7 +17,7 @@
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBoostFormatTooManyArgs/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBoostFormatTooManyArgs/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCStyleCast/@EntryIndexedValue" value="SUGGESTION" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCStyleCast/@EntryIndexedValue" value="SUGGESTION" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCVQualifierCanNotBeAppliedToReference/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppCVQualifierCanNotBeAppliedToReference/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassCanBeFinal/@EntryIndexedValue" value="DO_NOT_SHOW" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassCanBeFinal/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassIsIncomplete/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassIsIncomplete/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeedsConstructorBecauseOfUninitializedMember/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeedsConstructorBecauseOfUninitializedMember/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeverUsed/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClassNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
@@ -110,7 +110,7 @@
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLambdaCaptureNeverUsed/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLambdaCaptureNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMayBeConst/@EntryIndexedValue" value="HINT" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMayBeConst/@EntryIndexedValue" value="HINT" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMightNotBeInitialized/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMightNotBeInitialized/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableWithNonTrivialDtorIsNeverUsed/@EntryIndexedValue" value="DO_NOT_SHOW" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableWithNonTrivialDtorIsNeverUsed/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLongFloat/@EntryIndexedValue" value="WARNING" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLongFloat/@EntryIndexedValue" value="WARNING" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeConst/@EntryIndexedValue" value="SUGGESTION" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeConst/@EntryIndexedValue" value="SUGGESTION" type="string" />
<option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeStatic/@EntryIndexedValue" value="SUGGESTION" type="string" /> <option name="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMemberFunctionMayBeStatic/@EntryIndexedValue" value="SUGGESTION" type="string" />

5
.luarc.json Normal file
View File

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

44
CMakeLists.txt
View File

@@ -31,6 +31,11 @@ option(OMATH_SUPRESS_SAFETY_CHECKS
option(OMATH_ENABLE_COVERAGE "Enable coverage" OFF) option(OMATH_ENABLE_COVERAGE "Enable coverage" OFF)
option(OMATH_ENABLE_FORCE_INLINE option(OMATH_ENABLE_FORCE_INLINE
"Will for compiler to make some functions to be force inlined no matter what" ON) "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) if(VCPKG_MANIFEST_FEATURES)
foreach(omath_feature IN LISTS VCPKG_MANIFEST_FEATURES) foreach(omath_feature IN LISTS VCPKG_MANIFEST_FEATURES)
if(omath_feature STREQUAL "imgui") if(omath_feature STREQUAL "imgui")
@@ -43,6 +48,10 @@ if(VCPKG_MANIFEST_FEATURES)
set(OMATH_BUILD_BENCHMARK ON) set(OMATH_BUILD_BENCHMARK ON)
elseif(omath_feature STREQUAL "examples") elseif(omath_feature STREQUAL "examples")
set(OMATH_BUILD_EXAMPLES ON) 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() endif()
endforeach() 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}]: Building using vcpkg ${OMATH_BUILD_VIA_VCPKG}")
message(STATUS "[${PROJECT_NAME}]: Coverage feature status ${OMATH_ENABLE_COVERAGE}") message(STATUS "[${PROJECT_NAME}]: Coverage feature status ${OMATH_ENABLE_COVERAGE}")
message(STATUS "[${PROJECT_NAME}]: Valgrind feature status ${OMATH_ENABLE_VALGRIND}") message(STATUS "[${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 ${OMATH_ENABLE_PHYSX}")
endif() endif()
file(GLOB_RECURSE OMATH_SOURCES CONFIGURE_DEPENDS "${CMAKE_CURRENT_SOURCE_DIR}/source/*.cpp") 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} ${OMATH_HEADERS}) add_library(${PROJECT_NAME} STATIC ${OMATH_SOURCES} ${OMATH_HEADERS})
endif() endif()
if (OMATH_ENABLE_LUA)
target_compile_definitions(${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 ${PROJECT_NAME}) add_library(${PROJECT_NAME}::${PROJECT_NAME} ALIAS ${PROJECT_NAME})
target_compile_definitions(${PROJECT_NAME} PUBLIC OMATH_VERSION="${PROJECT_VERSION}") target_compile_definitions(${PROJECT_NAME} PUBLIC OMATH_VERSION="${PROJECT_VERSION}")
@@ -130,11 +159,10 @@ set_target_properties(
CXX_STANDARD 23 CXX_STANDARD 23
CXX_STANDARD_REQUIRED ON) CXX_STANDARD_REQUIRED ON)
if (OMATH_STATIC_MSVC_RUNTIME_LIBRARY) if(OMATH_STATIC_MSVC_RUNTIME_LIBRARY)
set_target_properties(${PROJECT_NAME} PROPERTIES set_target_properties(${PROJECT_NAME} PROPERTIES MSVC_RUNTIME_LIBRARY
MSVC_RUNTIME_LIBRARY "MultiThreaded$<$<CONFIG:Debug>:Debug>" "MultiThreaded$<$<CONFIG:Debug>:Debug>")
) endif()
endif ()
if(OMATH_USE_AVX2) if(OMATH_USE_AVX2)
if(MSVC) if(MSVC)
@@ -175,6 +203,12 @@ elseif(OMATH_THREAT_WARNING_AS_ERROR)
target_compile_options(${PROJECT_NAME} PRIVATE -Wall -Wextra -Wpedantic -Werror) target_compile_options(${PROJECT_NAME} PRIVATE -Wall -Wextra -Wpedantic -Werror)
endif() endif()
if (CMAKE_CXX_COMPILER_ID STREQUAL "MSVC")
target_compile_options(${PROJECT_NAME} PRIVATE /bigobj)
endif()
if (CMAKE_CXX_COMPILER_ID STREQUAL "GNU" AND CMAKE_HOST_SYSTEM_NAME EQUAL "Windows")
target_compile_options(${PROJECT_NAME} PRIVATE -mbig-obj)
endif()
# Windows SDK redefine min/max via preprocessor and break std::min and std::max # Windows SDK redefine min/max via preprocessor and break std::min and std::max
if(CMAKE_CXX_COMPILER_ID STREQUAL "MSVC") if(CMAKE_CXX_COMPILER_ID STREQUAL "MSVC")
target_compile_definitions(${PROJECT_NAME} INTERFACE NOMINMAX) target_compile_definitions(${PROJECT_NAME} INTERFACE NOMINMAX)

4
CMakePresets.json
View File

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

37
CODEOWNERS Normal file
View File

@@ -0,0 +1,37 @@
## List of maintainers for the omath library
## This file purpose is to give newcomers to the project the responsible
## developers when submitting a pull request on GitHub, or opening a bug
## report in issues.
## This file will notably establish who is responsible for a specific
## area of omath. Being a maintainer means the following:
## - that person has good knownledge in the area
## - that person is able to enforce consistency in the area
## - that person may be available for giving help in the area
## - that person has push access on the repository
## Being a maintainer does not mean the following:
## - that person is dedicated to the area
## - that person is working full-time on the area/on omath
## - that person is paid
## - that person is always available
# omath core source code
/source @orange-cpp
/include @orange-cpp
# Tests and becnchmarks
/benchmark @orange-cpp
/tests @orange-cpp @luadebug
# Examples and documentation
/examples @luadebug @orange-cpp
/docs @orange-cpp
# Misc like formating
/scripts @luadebug
/pixi @luadebug
# CI/CD
/.github/workflows @luadbg @orange-cpp

42
INSTALL.md
View File

@@ -1,6 +1,6 @@
# 📥Installation Guide # 📥Installation Guide
## <img width="28px" src="https://vcpkg.io/assets/mark/mark.svg" /> Using vcpkg ## <img width="28px" src="https://vcpkg.io/assets/mark/mark.svg" /> Using vcpkg (recomended)
**Note**: Support vcpkg for package management **Note**: Support vcpkg for package management
1. Install [vcpkg](https://github.com/microsoft/vcpkg) 1. Install [vcpkg](https://github.com/microsoft/vcpkg)
2. Run the following command to install the orange-math package: 2. Run the following command to install the orange-math package:
@@ -28,6 +28,46 @@ target("...")
add_packages("omath") add_packages("omath")
``` ```
## <img width="28px" src="https://github.githubassets.com/favicons/favicon.svg" /> Using prebuilt binaries (GitHub Releases)
**Note**: This is the fastest option if you dont want to build from source.
1. **Go to the Releases page**
- Open the projects GitHub **Releases** page and choose the latest version.
2. **Download the correct asset for your platform**
- Pick the archive that matches your OS and architecture (for example: Windows x64 / Linux x64 / macOS arm64).
3. **Extract the archive**
- You should end up with something like:
- `include/` (headers)
- `lib/` or `bin/` (library files / DLLs)
- sometimes `cmake/` (CMake package config)
4. **Use it in your project**
### Option A: CMake package (recommended if the release includes CMake config files)
If the extracted folder contains something like `lib/cmake/omath` or `cmake/omath`, you can point CMake to it:
```cmake
# Example: set this to the extracted prebuilt folder
list(APPEND CMAKE_PREFIX_PATH "path/to/omath-prebuilt")
find_package(omath CONFIG REQUIRED)
target_link_libraries(main PRIVATE omath::omath)
```
### Option B: Manual include + link (works with any layout)
If theres no CMake package config, link it manually:
```cmake
target_include_directories(main PRIVATE "path/to/omath-prebuilt/include")
# Choose ONE depending on what you downloaded:
# - Static library: .lib / .a
# - Shared library: .dll + .lib import (Windows), .so (Linux), .dylib (macOS)
target_link_directories(main PRIVATE "path/to/omath-prebuilt/lib")
target_link_libraries(main PRIVATE omath) # or the actual library filename
```
## <img width="28px" src="https://upload.wikimedia.org/wikipedia/commons/e/ef/CMake_logo.svg?" /> Build from source using CMake ## <img width="28px" src="https://upload.wikimedia.org/wikipedia/commons/e/ef/CMake_logo.svg?" /> Build from source using CMake
1. **Preparation** 1. **Preparation**

7
README.md
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@@ -9,6 +9,7 @@
[![CodeFactor](https://www.codefactor.io/repository/github/orange-cpp/omath/badge)](https://www.codefactor.io/repository/github/orange-cpp/omath) [![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) ![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) [![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) ![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) [![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) [![telegram badge](https://img.shields.io/badge/Telegram-2CA5E0?style=flat-squeare&logo=telegram&logoColor=white)](https://t.me/orangennotes)
@@ -80,9 +81,11 @@ if (auto screen = camera.world_to_screen(world_position)) {
- **Collision Detection**: Production ready code to handle collision detection by using simple interfaces. - **Collision Detection**: Production ready code to handle collision detection by using simple interfaces.
- **No Additional Dependencies**: No additional dependencies need to use OMath except unit test execution - **No Additional Dependencies**: No additional dependencies need to use OMath except unit test execution
- **Ready for meta-programming**: Omath use templates for common types like Vectors, Matrixes etc, to handle all types! - **Ready for meta-programming**: Omath use templates for common types like Vectors, Matrixes etc, to handle all types!
- **Engine support**: Supports coordinate systems of **Source, Unity, Unreal, Frostbite, IWEngine and canonical OpenGL**. - **Engine support**: Supports coordinate systems of **Source, Unity, Unreal, Frostbite, IWEngine, CryEngine and canonical OpenGL**.
- **Cross platform**: Supports Windows, MacOS and Linux. - **Cross platform**: Supports Windows, MacOS and Linux.
- **Algorithms**: Has ability to scan for byte pattern with wildcards in PE files/modules, binary slices, works even with Wine apps. - **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> <div align = center>
# Gallery # Gallery

2
VERSION
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@@ -1 +1 @@
4.7.1 5.0.0

161
benchmark/benchmark_collision.cpp Normal file
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@@ -0,0 +1,161 @@
//
// Created by Vlad on 3/2/2026.
//
#include <benchmark/benchmark.h>
#include <memory_resource>
#include <omath/collision/epa_algorithm.hpp>
#include <omath/collision/gjk_algorithm.hpp>
#include <omath/engines/source_engine/collider.hpp>
#include <omath/engines/source_engine/mesh.hpp>
using Mesh = omath::source_engine::Mesh;
using Collider = omath::source_engine::MeshCollider;
using Gjk = omath::collision::GjkAlgorithm<Collider>;
using Epa = omath::collision::Epa<Collider>;
namespace
{
// Unit cube with half-extent 1 — 8 vertices in [-1,1]^3.
const std::vector<omath::primitives::Vertex<>> k_cube_vbo = {
{ { -1.f, -1.f, -1.f }, {}, {} },
{ { -1.f, -1.f, 1.f }, {}, {} },
{ { -1.f, 1.f, -1.f }, {}, {} },
{ { -1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, -1.f }, {}, {} },
{ { 1.f, -1.f, 1.f }, {}, {} },
{ { 1.f, -1.f, -1.f }, {}, {} },
};
const std::vector<omath::Vector3<std::uint32_t>> k_empty_vao{};
} // namespace
// ---------------------------------------------------------------------------
// GJK benchmarks
// ---------------------------------------------------------------------------
// Separated cubes — origin distance 2.1, no overlap.
// Exercises the early-exit path and the centroid-based initial direction.
static void BM_Gjk_Separated(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
Mesh mesh_b{k_cube_vbo, k_empty_vao};
mesh_b.set_origin({0.f, 2.1f, 0.f});
const Collider b{mesh_b};
for ([[maybe_unused]] auto _ : state)
benchmark::DoNotOptimize(Gjk::is_collide(a, b));
}
// Overlapping cubes — B offset by 0.5 along X, ~1.5 units penetration depth.
static void BM_Gjk_Overlapping(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
Mesh mesh_b{k_cube_vbo, k_empty_vao};
mesh_b.set_origin({0.5f, 0.f, 0.f});
const Collider b{mesh_b};
for ([[maybe_unused]] auto _ : state)
benchmark::DoNotOptimize(Gjk::is_collide(a, b));
}
// Identical cubes at the same origin — deep overlap / worst case for GJK.
static void BM_Gjk_SameOrigin(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
const Collider b{Mesh{k_cube_vbo, k_empty_vao}};
for ([[maybe_unused]] auto _ : state)
benchmark::DoNotOptimize(Gjk::is_collide(a, b));
}
// ---------------------------------------------------------------------------
// EPA benchmarks
// ---------------------------------------------------------------------------
// EPA with a pre-allocated monotonic buffer (reset each iteration).
// Isolates algorithmic cost from allocator overhead.
static void BM_Epa_MonotonicBuffer(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
Mesh mesh_b{k_cube_vbo, k_empty_vao};
mesh_b.set_origin({0.5f, 0.f, 0.f});
const Collider b{mesh_b};
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
if (!hit)
return; // shouldn't happen, but guard for safety
constexpr Epa::Params params{.max_iterations = 64, .tolerance = 1e-4f};
// Pre-allocate a 32 KiB stack buffer — enough for typical polytope growth.
constexpr std::size_t k_buf_size = 32768;
alignas(std::max_align_t) char buf[k_buf_size];
std::pmr::monotonic_buffer_resource mr{buf, k_buf_size, std::pmr::null_memory_resource()};
for ([[maybe_unused]] auto _ : state)
{
mr.release(); // reset the buffer without touching the upstream resource
benchmark::DoNotOptimize(Epa::solve(a, b, simplex, params, mr));
}
}
// EPA with the default (malloc-backed) memory resource.
// Shows total cost including allocator pressure.
static void BM_Epa_DefaultResource(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
Mesh mesh_b{k_cube_vbo, k_empty_vao};
mesh_b.set_origin({0.5f, 0.f, 0.f});
const Collider b{mesh_b};
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
if (!hit)
return;
constexpr Epa::Params params{.max_iterations = 64, .tolerance = 1e-4f};
for ([[maybe_unused]] auto _ : state)
benchmark::DoNotOptimize(Epa::solve(a, b, simplex, params));
}
// ---------------------------------------------------------------------------
// Combined GJK + EPA pipeline
// ---------------------------------------------------------------------------
// Full collision pipeline: GJK detects contact, EPA resolves penetration.
// This is the hot path in a physics engine tick.
static void BM_GjkEpa_Pipeline(benchmark::State& state)
{
const Collider a{Mesh{k_cube_vbo, k_empty_vao}};
Mesh mesh_b{k_cube_vbo, k_empty_vao};
mesh_b.set_origin({0.5f, 0.f, 0.f});
const Collider b{mesh_b};
constexpr Epa::Params params{.max_iterations = 64, .tolerance = 1e-4f};
constexpr std::size_t k_buf_size = 32768;
alignas(std::max_align_t) char buf[k_buf_size];
std::pmr::monotonic_buffer_resource mr{buf, k_buf_size, std::pmr::null_memory_resource()};
for ([[maybe_unused]] auto _ : state)
{
mr.release();
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
if (hit)
benchmark::DoNotOptimize(Epa::solve(a, b, simplex, params, mr));
}
}
BENCHMARK(BM_Gjk_Separated)->Iterations(100'000);
BENCHMARK(BM_Gjk_Overlapping)->Iterations(100'000);
BENCHMARK(BM_Gjk_SameOrigin)->Iterations(100'000);
BENCHMARK(BM_Epa_MonotonicBuffer)->Iterations(100'000);
BENCHMARK(BM_Epa_DefaultResource)->Iterations(100'000);
BENCHMARK(BM_GjkEpa_Pipeline)->Iterations(100'000);

36
examples/CMakeLists.txt
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@@ -1,35 +1,7 @@
project(examples) add_subdirectory(example_barycentric)
add_subdirectory(example_glfw3)
add_executable(example_projection_matrix_builder example_proj_mat_builder.cpp) add_subdirectory(example_proj_mat_builder)
set_target_properties( add_subdirectory(example_signature_scan)
example_projection_matrix_builder
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
target_link_libraries(example_projection_matrix_builder PRIVATE omath::omath)
add_executable(example_signature_scan example_signature_scan.cpp)
set_target_properties(
example_signature_scan
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
target_link_libraries(example_signature_scan PRIVATE omath::omath)
add_executable(example_glfw3 example_glfw3.cpp)
set_target_properties(
example_glfw3
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
find_package(OpenGL)
find_package(GLEW REQUIRED)
find_package(glfw3 CONFIG REQUIRED)
target_link_libraries(example_glfw3 PRIVATE omath::omath GLEW::GLEW glfw OpenGL::GL)
if(OMATH_ENABLE_VALGRIND) if(OMATH_ENABLE_VALGRIND)
omath_setup_valgrind(example_projection_matrix_builder) omath_setup_valgrind(example_projection_matrix_builder)

14
examples/example_barycentric/CMakeLists.txt Normal file
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@@ -0,0 +1,14 @@
project(example_barycentric)
add_executable(${PROJECT_NAME} example_barycentric.cpp)
set_target_properties(
${PROJECT_NAME}
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
find_package(OpenGL)
find_package(GLEW REQUIRED)
find_package(glfw3 CONFIG REQUIRED)
target_link_libraries(${PROJECT_NAME} PRIVATE omath::omath GLEW::GLEW glfw OpenGL::GL)

427
examples/example_barycentric/example_barycentric.cpp Normal file
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@@ -0,0 +1,427 @@
#include <GL/glew.h>
#include <GLFW/glfw3.h>
#include <cmath>
#include <iostream>
#include <omath/omath.hpp>
#include <vector>
using omath::Color;
using omath::Triangle;
using omath::Vector3;
static const char* vertexShaderSource = R"(
#version 330 core
layout (location = 0) in vec3 aPos;
layout (location = 1) in vec3 aColor;
layout (location = 2) in float aPointSize;
layout (location = 3) in float aIsLine;
out vec3 vColor;
out float vIsLine;
void main() {
gl_Position = vec4(aPos, 1.0);
vColor = aColor;
gl_PointSize = aPointSize;
vIsLine = aIsLine;
}
)";
static const char* fragmentShaderSource = R"(
#version 330 core
in vec3 vColor;
in float vIsLine;
out vec4 FragColor;
void main() {
if (vIsLine < 0.5) {
// Calculate distance from center of the point
vec2 coord = gl_PointCoord - vec2(0.5);
if(length(coord) > 0.5)
discard;
}
FragColor = vec4(vColor, 1.0);
}
)";
GLuint compileShader(GLenum type, const char* src)
{
GLuint shader = glCreateShader(type);
glShaderSource(shader, 1, &src, nullptr);
glCompileShader(shader);
GLint ok;
glGetShaderiv(shader, GL_COMPILE_STATUS, &ok);
if (!ok)
{
char log[1024];
glGetShaderInfoLog(shader, sizeof(log), nullptr, log);
std::cerr << "Shader error: " << log << std::endl;
}
return shader;
}
void drawChar(char c, float x, float y, float scale, const Color& color, std::vector<float>& lines)
{
float w = 0.5f * scale;
float h = 1.0f * scale;
auto add = [&](float x1, float y1, float x2, float y2)
{
lines.push_back(x + x1 * w);
lines.push_back(y + y1 * h);
lines.push_back(0.0f);
lines.push_back(color.x);
lines.push_back(color.y);
lines.push_back(color.z);
lines.push_back(1.0f); // size
lines.push_back(1.0f); // isLine
lines.push_back(x + x2 * w);
lines.push_back(y + y2 * h);
lines.push_back(0.0f);
lines.push_back(color.x);
lines.push_back(color.y);
lines.push_back(color.z);
lines.push_back(1.0f); // size
lines.push_back(1.0f); // isLine
};
switch (c)
{
case '0':
add(0, 0, 1, 0);
add(1, 0, 1, 1);
add(1, 1, 0, 1);
add(0, 1, 0, 0);
break;
case '1':
add(0.5f, 0, 0.5f, 1);
add(0.25f, 0.75f, 0.5f, 1);
add(0.25f, 0, 0.75f, 0);
break;
case '2':
add(0, 1, 1, 1);
add(1, 1, 1, 0.5f);
add(1, 0.5f, 0, 0.5f);
add(0, 0.5f, 0, 0);
add(0, 0, 1, 0);
break;
case '3':
add(0, 1, 1, 1);
add(1, 1, 1, 0);
add(1, 0, 0, 0);
add(0, 0.5f, 1, 0.5f);
break;
case '4':
add(0, 1, 0, 0.5f);
add(0, 0.5f, 1, 0.5f);
add(1, 1, 1, 0);
break;
case '5':
add(1, 1, 0, 1);
add(0, 1, 0, 0.5f);
add(0, 0.5f, 1, 0.5f);
add(1, 0.5f, 1, 0);
add(1, 0, 0, 0);
break;
case '6':
add(1, 1, 0, 1);
add(0, 1, 0, 0);
add(0, 0, 1, 0);
add(1, 0, 1, 0.5f);
add(1, 0.5f, 0, 0.5f);
break;
case '7':
add(0, 1, 1, 1);
add(1, 1, 0.5f, 0);
break;
case '8':
add(0, 0, 1, 0);
add(1, 0, 1, 1);
add(1, 1, 0, 1);
add(0, 1, 0, 0);
add(0, 0.5f, 1, 0.5f);
break;
case '9':
add(1, 0.5f, 0, 0.5f);
add(0, 0.5f, 0, 1);
add(0, 1, 1, 1);
add(1, 1, 1, 0);
add(1, 0, 0, 0);
break;
case '.':
add(0.4f, 0, 0.6f, 0);
add(0.6f, 0, 0.6f, 0.2f);
add(0.6f, 0.2f, 0.4f, 0.2f);
add(0.4f, 0.2f, 0.4f, 0);
break;
}
}
void drawText(const std::string& text, float x, float y, float scale, const Color& color, std::vector<float>& lines)
{
float cursor = x;
for (char c : text)
{
drawChar(c, cursor, y, scale, color, lines);
cursor += (c == '.' ? 0.3f : 0.7f) * scale;
}
}
GLFWwindow* initWindow(int width, int height, const char* title)
{
if (!glfwInit())
{
std::cerr << "Failed to initialize GLFW\n";
return nullptr;
}
glfwWindowHint(GLFW_CONTEXT_VERSION_MAJOR, 3);
glfwWindowHint(GLFW_CONTEXT_VERSION_MINOR, 3);
glfwWindowHint(GLFW_OPENGL_PROFILE, GLFW_OPENGL_CORE_PROFILE);
GLFWwindow* window = glfwCreateWindow(width, height, title, NULL, NULL);
if (!window)
{
std::cerr << "Failed to create GLFW window\n";
glfwTerminate();
return nullptr;
}
glfwMakeContextCurrent(window);
// Check if context is valid using standard GL
const GLubyte* renderer = glGetString(GL_RENDERER);
const GLubyte* version = glGetString(GL_VERSION);
if (renderer && version)
{
std::cout << "Renderer: " << renderer << "\n";
std::cout << "OpenGL version supported: " << version << "\n";
}
else
{
std::cerr << "Failed to get GL_RENDERER or GL_VERSION. Context might be invalid.\n";
}
glewExperimental = GL_TRUE;
GLenum glewErr = glewInit();
if (glewErr != GLEW_OK)
{
// Ignore GLEW_ERROR_NO_GLX_DISPLAY if we have a valid context (e.g. Wayland)
if (glewErr == GLEW_ERROR_NO_GLX_DISPLAY && renderer)
{
std::cerr << "GLEW warning: " << glewGetErrorString(glewErr) << " (Ignored because context seems valid)\n";
}
else
{
std::cerr << "Failed to initialize GLEW: " << glewGetErrorString(glewErr) << "\n";
glfwTerminate();
return nullptr;
}
}
return window;
}
GLuint createShaderProgram()
{
GLuint vs = compileShader(GL_VERTEX_SHADER, vertexShaderSource);
GLuint fs = compileShader(GL_FRAGMENT_SHADER, fragmentShaderSource);
GLuint shaderProgram = glCreateProgram();
glAttachShader(shaderProgram, vs);
glAttachShader(shaderProgram, fs);
glLinkProgram(shaderProgram);
return shaderProgram;
}
void generatePointCloud(std::vector<float>& pointCloud, const Triangle<Vector3<float>>& triangle)
{
const auto& A = triangle.m_vertex1;
const auto& B = triangle.m_vertex2;
const auto& C = triangle.m_vertex3;
// Iterating over barycentric coordinates (u, v, w) from 0.0 to 1.0
for (float u = 0.0f; u <= 1.0f; u += 0.015f)
{
for (float v = 0.0f; v <= 1.0f - u; v += 0.015f)
{
float w = 1.0f - u - v;
if (w >= 0.0f && w <= 1.0f)
{
Vector3<float> P = A * u + B * v + C * w;
pointCloud.push_back(P.x);
pointCloud.push_back(P.y);
pointCloud.push_back(P.z);
pointCloud.push_back(u);
pointCloud.push_back(v);
pointCloud.push_back(w);
pointCloud.push_back(2.0f); // size
pointCloud.push_back(0.0f); // isLine
}
}
}
}
void setupBuffers(GLuint& VAO_cloud, GLuint& VBO_cloud, const std::vector<float>& pointCloud, GLuint& VAO_dyn,
GLuint& VBO_dyn)
{
glGenVertexArrays(1, &VAO_cloud);
glGenBuffers(1, &VBO_cloud);
glBindVertexArray(VAO_cloud);
glBindBuffer(GL_ARRAY_BUFFER, VBO_cloud);
glBufferData(GL_ARRAY_BUFFER, pointCloud.size() * sizeof(float), pointCloud.data(), GL_STATIC_DRAW);
glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)0);
glEnableVertexAttribArray(0);
glVertexAttribPointer(1, 3, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(3 * sizeof(float)));
glEnableVertexAttribArray(1);
glVertexAttribPointer(2, 1, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(6 * sizeof(float)));
glEnableVertexAttribArray(2);
glVertexAttribPointer(3, 1, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(7 * sizeof(float)));
glEnableVertexAttribArray(3);
glGenVertexArrays(1, &VAO_dyn);
glGenBuffers(1, &VBO_dyn);
glBindVertexArray(VAO_dyn);
glBindBuffer(GL_ARRAY_BUFFER, VBO_dyn);
glBufferData(GL_ARRAY_BUFFER, 1000 * 8 * sizeof(float), NULL, GL_DYNAMIC_DRAW);
glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)0);
glEnableVertexAttribArray(0);
glVertexAttribPointer(1, 3, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(3 * sizeof(float)));
glEnableVertexAttribArray(1);
glVertexAttribPointer(2, 1, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(6 * sizeof(float)));
glEnableVertexAttribArray(2);
glVertexAttribPointer(3, 1, GL_FLOAT, GL_FALSE, 8 * sizeof(float), (void*)(7 * sizeof(float)));
glEnableVertexAttribArray(3);
}
void updateDynamicData(std::vector<float>& dynData, float u, float v, float w, const Vector3<float>& P,
const Triangle<Vector3<float>>& triangle)
{
const auto& A = triangle.m_vertex1;
const auto& B = triangle.m_vertex2;
const auto& C = triangle.m_vertex3;
float sizeA = 10.0f + u * 30.0f;
float sizeB = 10.0f + v * 30.0f;
float sizeC = 10.0f + w * 30.0f;
float sizeP = 12.0f;
dynData = {// Lines from P to A, B, C
P.x, P.y, P.z, u, v, w, 1.0f, 1.0f, A.x, A.y, A.z, 1.0f, 0.0f, 0.0f, 1.0f, 1.0f,
P.x, P.y, P.z, u, v, w, 1.0f, 1.0f, B.x, B.y, B.z, 0.0f, 1.0f, 0.0f, 1.0f, 1.0f,
P.x, P.y, P.z, u, v, w, 1.0f, 1.0f, C.x, C.y, C.z, 0.0f, 0.0f, 1.0f, 1.0f, 1.0f,
// The animated dot itself (White)
P.x, P.y, P.z, 1.0f, 1.0f, 1.0f, sizeP, 0.0f,
// The 3 corner dots
A.x, A.y, A.z, 1.0f, 0.0f, 0.0f, sizeA, 0.0f, B.x, B.y, B.z, 0.0f, 1.0f, 0.0f, sizeB, 0.0f, C.x, C.y,
C.z, 0.0f, 0.0f, 1.0f, sizeC, 0.0f};
char bufA[16], bufB[16], bufC[16];
snprintf(bufA, sizeof(bufA), "%.2f", u);
snprintf(bufB, sizeof(bufB), "%.2f", v);
snprintf(bufC, sizeof(bufC), "%.2f", w);
// Keep text at a fixed distance from the dots
float distA = 0.13f;
float distB = 0.13f;
float distC = 0.13f;
drawText(bufA, A.x - 0.05f, A.y + distA, 0.1f, Color(1, 0, 0, 1), dynData);
drawText(bufB, B.x - 0.15f - distB, B.y - 0.05f - distB, 0.1f, Color(0, 1, 0, 1), dynData);
drawText(bufC, C.x + 0.05f + distC, C.y - 0.05f - distC, 0.1f, Color(0, 0, 1, 1), dynData);
}
int main()
{
GLFWwindow* window = initWindow(800, 800, "Barycentric Coordinates");
if (!window)
return -1;
GLuint shaderProgram = createShaderProgram();
// Triangle vertices as shown in the picture (Red, Green, Blue)
// Scaled down slightly to leave room for text
Triangle<Vector3<float>> triangle(Vector3<float>(0.0f, 0.6f, 0.0f), // Red dot (top)
Vector3<float>(-0.6f, -0.6f, 0.0f), // Green dot (bottom left)
Vector3<float>(0.6f, -0.6f, 0.0f) // Blue dot (bottom right)
);
std::vector<float> pointCloud;
generatePointCloud(pointCloud, triangle);
GLuint VAO_cloud, VBO_cloud, VAO_dyn, VBO_dyn;
setupBuffers(VAO_cloud, VBO_cloud, pointCloud, VAO_dyn, VBO_dyn);
glEnable(GL_PROGRAM_POINT_SIZE);
glEnable(GL_BLEND);
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
while (!glfwWindowShouldClose(window))
{
glClearColor(0.02f, 0.02f, 0.02f, 1.0f);
glClear(GL_COLOR_BUFFER_BIT);
glUseProgram(shaderProgram);
// Draw the point cloud (the iterated points)
glBindVertexArray(VAO_cloud);
glDrawArrays(GL_POINTS, 0, pointCloud.size() / 8);
// Animate the white dot to simulate dragging
float t = glfwGetTime();
float u = (std::sin(t * 1.5f) * 0.5f + 0.5f);
float v = (std::cos(t * 1.1f) * 0.5f + 0.5f);
if (u + v > 1.0f)
{
u = 1.0f - u;
v = 1.0f - v;
}
float w = 1.0f - u - v;
if (w > 1.0f)
{
float diff = w - 1.0f;
w = 1.0f;
u += diff / 2.0f;
v += diff / 2.0f;
}
else if (w < 0.0f)
{
float diff = -w;
w = 0.0f;
u -= diff / 2.0f;
v -= diff / 2.0f;
}
Vector3<float> P = triangle.m_vertex1 * u + triangle.m_vertex2 * v + triangle.m_vertex3 * w;
std::vector<float> dynData;
updateDynamicData(dynData, u, v, w, P, triangle);
glBindVertexArray(VAO_dyn);
glBindBuffer(GL_ARRAY_BUFFER, VBO_dyn);
glBufferSubData(GL_ARRAY_BUFFER, 0, dynData.size() * sizeof(float), dynData.data());
// Draw lines
glDrawArrays(GL_LINES, 0, 6);
// Draw text lines
int numTextVertices = (dynData.size() / 8) - 10;
if (numTextVertices > 0)
{
glDrawArrays(GL_LINES, 10, numTextVertices);
}
// Draw dots
glDrawArrays(GL_POINTS, 6, 4);
glfwSwapBuffers(window);
glfwPollEvents();
}
glfwTerminate();
return 0;
}

14
examples/example_glfw3/CMakeLists.txt Normal file
View File

@@ -0,0 +1,14 @@
project(example_glfw3)
add_executable(${PROJECT_NAME} example_glfw3.cpp)
set_target_properties(
${PROJECT_NAME}
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
find_package(OpenGL)
find_package(GLEW REQUIRED)
find_package(glfw3 CONFIG REQUIRED)
target_link_libraries(${PROJECT_NAME} PRIVATE omath::omath GLEW::GLEW glfw OpenGL::GL)

2
examples/example_glfw3.cpp → examples/example_glfw3/example_glfw3.cpp
View File

@@ -342,7 +342,7 @@ int main()
old_mouse_time = glfwGetTime(); old_mouse_time = glfwGetTime();
mouse_capture = !mouse_capture; mouse_capture = !mouse_capture;
glfwSetInputMode(window, GLFW_CURSOR, mouse_capture ? GLFW_CURSOR_CAPTURED : GLFW_CURSOR_NORMAL); glfwSetInputMode(window, GLFW_CURSOR, mouse_capture ? GLFW_CURSOR_HIDDEN : GLFW_CURSOR_NORMAL);
} }
if (mouse_capture) if (mouse_capture)
{ {

10
examples/example_proj_mat_builder/CMakeLists.txt Normal file
View File

@@ -0,0 +1,10 @@
project(example_projection_matrix_builder)
add_executable(${PROJECT_NAME} example_proj_mat_builder.cpp)
set_target_properties(
${PROJECT_NAME}
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
target_link_libraries(${PROJECT_NAME} PRIVATE omath::omath)

0
examples/example_proj_mat_builder.cpp → examples/example_proj_mat_builder/example_proj_mat_builder.cpp
View File

10
examples/example_signature_scan/CMakeLists.txt Normal file
View File

@@ -0,0 +1,10 @@
project(example_signature_scan)
add_executable(${PROJECT_NAME} example_signature_scan.cpp)
set_target_properties(
${PROJECT_NAME}
PROPERTIES CXX_STANDARD 23
ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
LIBRARY_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}"
RUNTIME_OUTPUT_DIRECTORY "${CMAKE_SOURCE_DIR}/out/${CMAKE_BUILD_TYPE}")
target_link_libraries(${PROJECT_NAME} PRIVATE omath::omath)

0
examples/example_signature_scan.cpp → examples/example_signature_scan/example_signature_scan.cpp
View File

165
include/omath/collision/epa_algorithm.hpp
View File

@@ -8,6 +8,7 @@
#include <memory> #include <memory>
#include <memory_resource> #include <memory_resource>
#include <queue> #include <queue>
#include <unordered_map>
#include <utility> #include <utility>
#include <vector> #include <vector>
@@ -56,83 +57,76 @@ namespace omath::collision
const Simplex<VectorType>& simplex, const Params params = {}, const Simplex<VectorType>& simplex, const Params params = {},
std::pmr::memory_resource& mem_resource = *std::pmr::get_default_resource()) std::pmr::memory_resource& mem_resource = *std::pmr::get_default_resource())
{ {
// --- Build initial polytope from simplex (4 points) ---
std::pmr::vector<VectorType> vertexes = build_initial_polytope_from_simplex(simplex, mem_resource); std::pmr::vector<VectorType> vertexes = build_initial_polytope_from_simplex(simplex, mem_resource);
// Initial tetra faces (windings corrected in make_face)
std::pmr::vector<Face> faces = create_initial_tetra_faces(mem_resource, vertexes); std::pmr::vector<Face> faces = create_initial_tetra_faces(mem_resource, vertexes);
auto heap = rebuild_heap(faces, mem_resource); // Build initial min-heap by distance.
Heap heap = rebuild_heap(faces, mem_resource);
Result out{}; Result out{};
// Hoisted outside the loop to reuse bucket allocation across iterations.
// Initial bucket count 16 covers a typical horizon without rehashing.
BoundaryMap boundary{16, &mem_resource};
for (int it = 0; it < params.max_iterations; ++it) for (int it = 0; it < params.max_iterations; ++it)
{ {
// If heap might be stale after face edits, rebuild lazily. // Lazily discard stale (deleted or index-mismatched) heap entries.
if (heap.empty()) discard_stale_heap_entries(faces, heap);
break;
// Rebuild when the "closest" face changed (simple cheap guard)
// (We could keep face handles; this is fine for small Ns.)
if (const auto top = heap.top(); faces[top.idx].d != top.d)
heap = rebuild_heap(faces, mem_resource);
if (heap.empty()) if (heap.empty())
break; break;
// FIXME: STORE REF VALUE, DO NOT USE
// AFTER IF STATEMENT BLOCK
const Face& face = faces[heap.top().idx]; const Face& face = faces[heap.top().idx];
// Get the furthest point in face normal direction
const VectorType p = support_point(a, b, face.n); const VectorType p = support_point(a, b, face.n);
const auto p_dist = face.n.dot(p); const auto p_dist = face.n.dot(p);
// Converged if we cant push the face closer than tolerance // Converged: new support can't push the face closer than tolerance.
if (p_dist - face.d <= params.tolerance) if (p_dist - face.d <= params.tolerance)
{ {
out.normal = face.n; out.normal = face.n;
out.depth = face.d; // along unit normal out.depth = face.d;
out.iterations = it + 1; out.iterations = it + 1;
out.num_vertices = static_cast<int>(vertexes.size()); out.num_vertices = static_cast<int>(vertexes.size());
out.num_faces = static_cast<int>(faces.size()); out.num_faces = static_cast<int>(faces.size());
out.penetration_vector = out.normal * out.depth; out.penetration_vector = out.normal * out.depth;
return out; return out;
} }
// Add new vertex
const int new_idx = static_cast<int>(vertexes.size()); const int new_idx = static_cast<int>(vertexes.size());
vertexes.emplace_back(p); vertexes.emplace_back(p);
const auto [to_delete, boundary] = mark_visible_and_collect_horizon(faces, p); // Tombstone visible faces and collect the horizon boundary.
// This avoids copying the faces array (O(n)) each iteration.
tombstone_visible_faces(faces, boundary, p);
erase_marked(faces, to_delete); // Stitch new faces around the horizon and push them directly onto the
// heap — no full O(n log n) rebuild needed.
// Stitch new faces around the horizon for (const auto& [key, e] : boundary)
for (const auto& e : boundary) {
const int fi = static_cast<int>(faces.size());
faces.emplace_back(make_face(vertexes, e.a, e.b, new_idx)); faces.emplace_back(make_face(vertexes, e.a, e.b, new_idx));
heap.emplace(faces.back().d, fi);
// Rebuild heap after topology change }
heap = rebuild_heap(faces, mem_resource);
if (!std::isfinite(vertexes.back().dot(vertexes.back()))) if (!std::isfinite(vertexes.back().dot(vertexes.back())))
break; // safety break; // safety
out.iterations = it + 1; out.iterations = it + 1;
} }
if (faces.empty()) // Find the best surviving (non-deleted) face.
const Face* best = find_best_surviving_face(faces);
if (!best)
return std::nullopt; return std::nullopt;
const auto best = *std::ranges::min_element(faces, [](const auto& first, const auto& second) out.normal = best->n;
{ return first.d < second.d; }); out.depth = best->d;
out.normal = best.n;
out.depth = best.d;
out.num_vertices = static_cast<int>(vertexes.size()); out.num_vertices = static_cast<int>(vertexes.size());
out.num_faces = static_cast<int>(faces.size()); out.num_faces = static_cast<int>(faces.size());
out.penetration_vector = out.normal * out.depth; out.penetration_vector = out.normal * out.depth;
return out; return out;
} }
@@ -141,7 +135,8 @@ namespace omath::collision
{ {
int i0, i1, i2; int i0, i1, i2;
VectorType n; // unit outward normal VectorType n; // unit outward normal
FloatingType d; // n · v0 (>=0 ideally because origin is inside) FloatingType d; // n · v0 (>= 0 ideally because origin is inside)
bool deleted{false}; // tombstone flag — avoids O(n) compaction per iteration
}; };
struct Edge final struct Edge final
@@ -154,6 +149,7 @@ namespace omath::collision
FloatingType d; FloatingType d;
int idx; int idx;
}; };
struct HeapCmp final struct HeapCmp final
{ {
[[nodiscard]] [[nodiscard]]
@@ -165,35 +161,44 @@ namespace omath::collision
using Heap = std::priority_queue<HeapItem, std::pmr::vector<HeapItem>, HeapCmp>; using Heap = std::priority_queue<HeapItem, std::pmr::vector<HeapItem>, HeapCmp>;
// Horizon boundary: maps packed(a,b) → Edge.
// Opposite edges cancel in O(1) via hash lookup instead of O(h) linear scan.
using BoundaryMap = std::pmr::unordered_map<std::int64_t, Edge>;
[[nodiscard]]
static constexpr std::int64_t pack_edge(const int a, const int b) noexcept
{
return (static_cast<std::int64_t>(a) << 32) | static_cast<std::uint32_t>(b);
}
[[nodiscard]] [[nodiscard]]
static Heap rebuild_heap(const std::pmr::vector<Face>& faces, auto& memory_resource) static Heap rebuild_heap(const std::pmr::vector<Face>& faces, auto& memory_resource)
{ {
std::pmr::vector<HeapItem> storage{&memory_resource}; std::pmr::vector<HeapItem> storage{&memory_resource};
storage.reserve(faces.size()); // optional but recommended storage.reserve(faces.size());
Heap h{HeapCmp{}, std::move(storage)}; Heap h{HeapCmp{}, std::move(storage)};
for (int i = 0; i < static_cast<int>(faces.size()); ++i) for (int i = 0; i < static_cast<int>(faces.size()); ++i)
h.emplace(faces[i].d, i); if (!faces[i].deleted)
h.emplace(faces[i].d, i);
return h; // allocator is preserved return h;
} }
[[nodiscard]] [[nodiscard]]
static bool visible_from(const Face& f, const VectorType& p) static bool visible_from(const Face& f, const VectorType& p)
{ {
// positive if p is in front of the face
return f.n.dot(p) - f.d > static_cast<FloatingType>(1e-7); return f.n.dot(p) - f.d > static_cast<FloatingType>(1e-7);
} }
static void add_edge_boundary(std::pmr::vector<Edge>& boundary, int a, int b) static void add_edge_boundary(BoundaryMap& boundary, int a, int b)
{ {
// Keep edges that appear only once; erase if opposite already present // O(1) cancel: if the opposite edge (b→a) is already in the map it is an
auto itb = std::ranges::find_if(boundary, [&](const Edge& e) { return e.a == b && e.b == a; }); // internal edge shared by two visible faces and must be removed.
if (itb != boundary.end()) // Otherwise this is a horizon edge and we insert it.
boundary.erase(itb); // internal edge cancels out const std::int64_t rev = pack_edge(b, a);
if (const auto it = boundary.find(rev); it != boundary.end())
boundary.erase(it);
else else
boundary.emplace_back(a, b); // horizon edge (directed) boundary.emplace(pack_edge(a, b), Edge{a, b});
} }
[[nodiscard]] [[nodiscard]]
@@ -204,9 +209,7 @@ namespace omath::collision
const VectorType& a2 = vertexes[i2]; const VectorType& a2 = vertexes[i2];
VectorType n = (a1 - a0).cross(a2 - a0); VectorType n = (a1 - a0).cross(a2 - a0);
if (n.dot(n) <= static_cast<FloatingType>(1e-30)) if (n.dot(n) <= static_cast<FloatingType>(1e-30))
{
n = any_perp_vec(a1 - a0); // degenerate guard n = any_perp_vec(a1 - a0); // degenerate guard
}
// Ensure normal points outward (away from origin): require n·a0 >= 0 // Ensure normal points outward (away from origin): require n·a0 >= 0
if (n.dot(a0) < static_cast<FloatingType>(0.0)) if (n.dot(a0) < static_cast<FloatingType>(0.0))
{ {
@@ -243,6 +246,7 @@ namespace omath::collision
return d; return d;
return V{1, 0, 0}; return V{1, 0, 0};
} }
[[nodiscard]] [[nodiscard]]
static std::pmr::vector<Face> create_initial_tetra_faces(std::pmr::memory_resource& mem_resource, static std::pmr::vector<Face> create_initial_tetra_faces(std::pmr::memory_resource& mem_resource,
const std::pmr::vector<VectorType>& vertexes) const std::pmr::vector<VectorType>& vertexes)
@@ -262,48 +266,45 @@ namespace omath::collision
{ {
std::pmr::vector<VectorType> vertexes{&mem_resource}; std::pmr::vector<VectorType> vertexes{&mem_resource};
vertexes.reserve(simplex.size()); vertexes.reserve(simplex.size());
for (std::size_t i = 0; i < simplex.size(); ++i) for (std::size_t i = 0; i < simplex.size(); ++i)
vertexes.emplace_back(simplex[i]); vertexes.emplace_back(simplex[i]);
return vertexes; return vertexes;
} }
static void erase_marked(std::pmr::vector<Face>& faces, const std::pmr::vector<bool>& to_delete)
static const Face* find_best_surviving_face(const std::pmr::vector<Face>& faces)
{ {
auto* mr = faces.get_allocator().resource(); // keep same resource const Face* best = nullptr;
std::pmr::vector<Face> kept{mr}; for (const auto& f : faces)
kept.reserve(faces.size()); if (!f.deleted && (best == nullptr || f.d < best->d))
best = &f;
for (std::size_t i = 0; i < faces.size(); ++i) return best;
if (!to_delete[i])
kept.emplace_back(faces[i]);
faces.swap(kept);
} }
struct Horizon static void tombstone_visible_faces(std::pmr::vector<Face>& faces, BoundaryMap& boundary,
const VectorType& p)
{ {
std::pmr::vector<bool> to_delete; boundary.clear();
std::pmr::vector<Edge> boundary; for (auto& f : faces)
}; {
if (!f.deleted && visible_from(f, p))
static Horizon mark_visible_and_collect_horizon(const std::pmr::vector<Face>& faces, const VectorType& p)
{
auto* mr = faces.get_allocator().resource();
Horizon horizon{std::pmr::vector<bool>(faces.size(), false, mr), std::pmr::vector<Edge>(mr)};
horizon.boundary.reserve(faces.size());
for (std::size_t i = 0; i < faces.size(); ++i)
if (visible_from(faces[i], p))
{ {
const auto& rf = faces[i]; f.deleted = true;
horizon.to_delete[i] = true; add_edge_boundary(boundary, f.i0, f.i1);
add_edge_boundary(horizon.boundary, rf.i0, rf.i1); add_edge_boundary(boundary, f.i1, f.i2);
add_edge_boundary(horizon.boundary, rf.i1, rf.i2); add_edge_boundary(boundary, f.i2, f.i0);
add_edge_boundary(horizon.boundary, rf.i2, rf.i0);
} }
}
}
return horizon; static void discard_stale_heap_entries(const std::pmr::vector<Face>& faces,
std::priority_queue<HeapItem, std::pmr::vector<HeapItem>, HeapCmp>& heap)
{
while (!heap.empty())
{
const auto& top = heap.top();
if (!faces[top.idx].deleted && faces[top.idx].d == top.d)
break;
heap.pop();
}
} }
}; };
} // namespace omath::collision } // namespace omath::collision

29
include/omath/collision/gjk_algorithm.hpp
View File

@@ -14,11 +14,15 @@ namespace omath::collision
Simplex<VertexType> simplex; // valid only if hit == true and size==4 Simplex<VertexType> simplex; // valid only if hit == true and size==4
}; };
struct GjkSettings final
{
float epsilon = 1e-6f;
std::size_t max_iterations = 64;
};
template<class ColliderInterfaceType> template<class ColliderInterfaceType>
class GjkAlgorithm final class GjkAlgorithm final
{ {
using VectorType = ColliderInterfaceType::VectorType; using VectorType = ColliderInterfaceType::VectorType;
public: public:
[[nodiscard]] [[nodiscard]]
static VectorType find_support_vertex(const ColliderInterfaceType& collider_a, static VectorType find_support_vertex(const ColliderInterfaceType& collider_a,
@@ -36,20 +40,34 @@ namespace omath::collision
[[nodiscard]] [[nodiscard]]
static GjkHitInfo<VectorType> is_collide_with_simplex_info(const ColliderInterfaceType& collider_a, static GjkHitInfo<VectorType> is_collide_with_simplex_info(const ColliderInterfaceType& collider_a,
const ColliderInterfaceType& collider_b) const ColliderInterfaceType& collider_b,
const GjkSettings& settings = {})
{ {
auto support = find_support_vertex(collider_a, collider_b, VectorType{1, 0, 0}); // Use centroid difference as initial direction — greatly reduces iterations for separated shapes.
VectorType initial_dir;
if constexpr (requires { collider_b.get_origin() - collider_a.get_origin(); })
{
initial_dir = collider_b.get_origin() - collider_a.get_origin();
if (initial_dir.dot(initial_dir) < settings.epsilon * settings.epsilon)
initial_dir = VectorType{1, 0, 0};
}
else
{
initial_dir = VectorType{1, 0, 0};
}
auto support = find_support_vertex(collider_a, collider_b, initial_dir);
Simplex<VectorType> simplex; Simplex<VectorType> simplex;
simplex.push_front(support); simplex.push_front(support);
auto direction = -support; auto direction = -support;
while (true) for (std::size_t iteration = 0; iteration < settings.max_iterations; ++iteration)
{ {
support = find_support_vertex(collider_a, collider_b, direction); support = find_support_vertex(collider_a, collider_b, direction);
if (support.dot(direction) <= 0.f) if (support.dot(direction) <= settings.epsilon)
return {false, simplex}; return {false, simplex};
simplex.push_front(support); simplex.push_front(support);
@@ -57,6 +75,7 @@ namespace omath::collision
if (simplex.handle(direction)) if (simplex.handle(direction))
return {true, simplex}; return {true, simplex};
} }
return {false, simplex};
} }
}; };
} // namespace omath::collision } // namespace omath::collision

33
include/omath/collision/mesh_collider.hpp
View File

@@ -42,13 +42,40 @@ namespace omath::collision
m_mesh.set_origin(new_origin); m_mesh.set_origin(new_origin);
} }
[[nodiscard]]
const MeshType& get_mesh() const
{
return m_mesh;
}
[[nodiscard]]
MeshType& get_mesh()
{
return m_mesh;
}
private: private:
[[nodiscard]] [[nodiscard]]
const VertexType& find_furthest_vertex(const VectorType& direction) const const VertexType& find_furthest_vertex(const VectorType& direction) const
{ {
return *std::ranges::max_element( // The support query arrives in world space, but vertex positions are stored
m_mesh.m_vertex_buffer, [&direction](const auto& first, const auto& second) // in local space. We need argmax_v { world(v) · d }.
{ return first.position.dot(direction) < second.position.dot(direction); }); //
// world(v) = M·v (ignoring translation, which is constant across vertices)
// world(v) · d = v · Mᵀ·d
//
// So we transform the direction to local space once — O(1) — then compare
// raw local positions, which is far cheaper than calling
// vertex_position_to_world_space (full 4×4 multiply) for every vertex.
//
// d_local = upper-left 3×3 of M, transposed, times d_world:
// d_local[j] = sum_i M.at(i,j) * d[i] (i.e. column j of M dotted with d)
const auto& m = m_mesh.get_to_world_matrix();
const VectorType d_local = {
m[0, 0] * direction.x + m[1, 0] * direction.y + m[2, 0] * direction.z,
m[0, 1] * direction.x + m[1, 1] * direction.y + m[2, 1] * direction.z,
m[0, 2] * direction.x + m[1, 2] * direction.y + m[2, 2] * direction.z,
};
return *std::ranges::max_element(m_mesh.m_vertex_buffer, [&d_local](const auto& first, const auto& second)
{ return first.position.dot(d_local) < second.position.dot(d_local); });
} }
MeshType m_mesh; MeshType m_mesh;
}; };

59
include/omath/collision/physx_box_collider.hpp Normal file
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@@ -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
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@@ -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
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@@ -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
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@@ -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

9
include/omath/containers/encrypted_variable.hpp
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@@ -62,20 +62,13 @@ namespace omath::detail
return splitmix64(base_seed() + 0xD1B54A32D192ED03ull * (Stream + 1)); return splitmix64(base_seed() + 0xD1B54A32D192ED03ull * (Stream + 1));
} }
[[nodiscard]]
consteval std::uint64_t bounded_u64(const std::uint64_t x, const std::uint64_t bound)
{
return (x * bound) >> 64;
}
template<std::int64_t Lo, std::int64_t Hi, std::uint64_t Stream> template<std::int64_t Lo, std::int64_t Hi, std::uint64_t Stream>
[[nodiscard]] [[nodiscard]]
consteval std::int64_t rand_uint8_t() consteval std::int64_t rand_uint8_t()
{ {
static_assert(Lo <= Hi); static_assert(Lo <= Hi);
const std::uint64_t span = static_cast<std::uint64_t>(Hi - Lo) + 1ull;
const std::uint64_t r = rand_u64<Stream>(); const std::uint64_t r = rand_u64<Stream>();
return static_cast<std::int64_t>(bounded_u64(r, span)) + Lo; return static_cast<std::int64_t>(r) + Lo;
} }
[[nodiscard]] [[nodiscard]]
consteval std::uint64_t rand_u64(const std::uint64_t seed, const std::uint64_t i) consteval std::uint64_t rand_u64(const std::uint64_t seed, const std::uint64_t i)

2
include/omath/engines/cry_engine/constants.hpp
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@@ -22,4 +22,4 @@ namespace omath::cry_engine
using RollAngle = Angle<float, -180.f, 180.f, AngleFlags::Normalized>; using RollAngle = Angle<float, -180.f, 180.f, AngleFlags::Normalized>;
using ViewAngles = omath::ViewAngles<PitchAngle, YawAngle, RollAngle>; using ViewAngles = omath::ViewAngles<PitchAngle, YawAngle, RollAngle>;
} // namespace omath::frostbite_engine } // namespace omath::cry_engine

2
include/omath/engines/cry_engine/formulas.hpp
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@@ -71,4 +71,4 @@ namespace omath::cry_engine
{ {
return meters_to_units(kilometers * static_cast<FloatingType>(1000)); return meters_to_units(kilometers * static_cast<FloatingType>(1000));
} }
} // namespace omath::frostbite_engine } // namespace omath::cry_engine

12
include/omath/engines/cry_engine/mesh.hpp Normal file
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@@ -0,0 +1,12 @@
//
// Created by Vladislav on 09.11.2025.
//
#pragma once
#include "constants.hpp"
#include "omath/3d_primitives/mesh.hpp"
#include "traits/mesh_trait.hpp"
namespace omath::cry_engine
{
using Mesh = primitives::Mesh<Mat4X4, ViewAngles, MeshTrait>;
}

2
include/omath/engines/cry_engine/traits/camera_trait.hpp
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@@ -21,4 +21,4 @@ namespace omath::cry_engine
float near, float far) noexcept; float near, float far) noexcept;
}; };
} // namespace omath::unreal_engine } // namespace omath::cry_engine

4
include/omath/engines/cry_engine/traits/pred_engine_trait.hpp
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@@ -70,7 +70,7 @@ namespace omath::cry_engine
{ {
const auto direction = (view_to - origin).normalized(); const auto direction = (view_to - origin).normalized();
return angles::radians_to_degrees(std::atan2(direction.y, direction.z)); return angles::radians_to_degrees(-std::atan2(direction.x, direction.y));
}; };
}; };
} // namespace omath::unity_engine } // namespace omath::cry_engine

219
include/omath/linear_algebra/quaternion.hpp Normal file
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@@ -0,0 +1,219 @@
//
// Created by vlad on 3/1/2026.
//
#pragma once
#include "omath/linear_algebra/mat.hpp"
#include "omath/linear_algebra/vector3.hpp"
#include <array>
#include <cmath>
#include <format>
namespace omath
{
template<class Type>
requires std::is_arithmetic_v<Type>
class Quaternion
{
public:
using ContainedType = Type;
Type x = static_cast<Type>(0);
Type y = static_cast<Type>(0);
Type z = static_cast<Type>(0);
Type w = static_cast<Type>(1); // identity quaternion
constexpr Quaternion() noexcept = default;
constexpr Quaternion(const Type& x, const Type& y, const Type& z, const Type& w) noexcept
: x(x), y(y), z(z), w(w)
{
}
// Factory: build from a normalized axis and an angle in radians
[[nodiscard]]
static Quaternion from_axis_angle(const Vector3<Type>& axis, const Type& angle_rad) noexcept
{
const Type half = angle_rad / static_cast<Type>(2);
const Type s = std::sin(half);
return {axis.x * s, axis.y * s, axis.z * s, std::cos(half)};
}
[[nodiscard]] constexpr bool operator==(const Quaternion& other) const noexcept
{
return x == other.x && y == other.y && z == other.z && w == other.w;
}
[[nodiscard]] constexpr bool operator!=(const Quaternion& other) const noexcept
{
return !(*this == other);
}
// Hamilton product: this * other
[[nodiscard]] constexpr Quaternion operator*(const Quaternion& other) const noexcept
{
return {
w * other.x + x * other.w + y * other.z - z * other.y,
w * other.y - x * other.z + y * other.w + z * other.x,
w * other.z + x * other.y - y * other.x + z * other.w,
w * other.w - x * other.x - y * other.y - z * other.z,
};
}
constexpr Quaternion& operator*=(const Quaternion& other) noexcept
{
return *this = *this * other;
}
[[nodiscard]] constexpr Quaternion operator*(const Type& scalar) const noexcept
{
return {x * scalar, y * scalar, z * scalar, w * scalar};
}
constexpr Quaternion& operator*=(const Type& scalar) noexcept
{
x *= scalar;
y *= scalar;
z *= scalar;
w *= scalar;
return *this;
}
[[nodiscard]] constexpr Quaternion operator+(const Quaternion& other) const noexcept
{
return {x + other.x, y + other.y, z + other.z, w + other.w};
}
constexpr Quaternion& operator+=(const Quaternion& other) noexcept
{
x += other.x;
y += other.y;
z += other.z;
w += other.w;
return *this;
}
[[nodiscard]] constexpr Quaternion operator-() const noexcept
{
return {-x, -y, -z, -w};
}
// Conjugate: negates the vector part (x, y, z)
[[nodiscard]] constexpr Quaternion conjugate() const noexcept
{
return {-x, -y, -z, w};
}
[[nodiscard]] constexpr Type dot(const Quaternion& other) const noexcept
{
return x * other.x + y * other.y + z * other.z + w * other.w;
}
[[nodiscard]] constexpr Type length_sqr() const noexcept
{
return x * x + y * y + z * z + w * w;
}
#ifndef _MSC_VER
[[nodiscard]] constexpr Type length() const noexcept
{
return std::sqrt(length_sqr());
}
[[nodiscard]] constexpr Quaternion normalized() const noexcept
{
const Type len = length();
return len != static_cast<Type>(0) ? *this * (static_cast<Type>(1) / len) : *this;
}
#else
[[nodiscard]] Type length() const noexcept
{
return std::sqrt(length_sqr());
}
[[nodiscard]] Quaternion normalized() const noexcept
{
const Type len = length();
return len != static_cast<Type>(0) ? *this * (static_cast<Type>(1) / len) : *this;
}
#endif
// Inverse: q* / |q|^2 (for unit quaternions inverse == conjugate)
[[nodiscard]] constexpr Quaternion inverse() const noexcept
{
return conjugate() * (static_cast<Type>(1) / length_sqr());
}
// Rotate a 3D vector: v' = q * pure(v) * q^-1
// Computed via Rodrigues' formula to avoid full quaternion product overhead
[[nodiscard]] constexpr Vector3<Type> rotate(const Vector3<Type>& v) const noexcept
{
const Vector3<Type> q_vec{x, y, z};
const Vector3<Type> cross = q_vec.cross(v);
return v + cross * (static_cast<Type>(2) * w) + q_vec.cross(cross) * static_cast<Type>(2);
}
// 3x3 rotation matrix from this (unit) quaternion
[[nodiscard]] constexpr Mat<3, 3, Type> to_rotation_matrix3() const noexcept
{
const Type xx = x * x, yy = y * y, zz = z * z;
const Type xy = x * y, xz = x * z, yz = y * z;
const Type wx = w * x, wy = w * y, wz = w * z;
const Type one = static_cast<Type>(1);
const Type two = static_cast<Type>(2);
return {
{one - two * (yy + zz), two * (xy - wz), two * (xz + wy) },
{two * (xy + wz), one - two * (xx + zz), two * (yz - wx) },
{two * (xz - wy), two * (yz + wx), one - two * (xx + yy)},
};
}
// 4x4 rotation matrix (with homogeneous row/column)
[[nodiscard]] constexpr Mat<4, 4, Type> to_rotation_matrix4() const noexcept
{
const Type xx = x * x, yy = y * y, zz = z * z;
const Type xy = x * y, xz = x * z, yz = y * z;
const Type wx = w * x, wy = w * y, wz = w * z;
const Type one = static_cast<Type>(1);
const Type two = static_cast<Type>(2);
const Type zero = static_cast<Type>(0);
return {
{one - two * (yy + zz), two * (xy - wz), two * (xz + wy), zero},
{two * (xy + wz), one - two * (xx + zz), two * (yz - wx), zero},
{two * (xz - wy), two * (yz + wx), one - two * (xx + yy), zero},
{zero, zero, zero, one },
};
}
[[nodiscard]] constexpr std::array<Type, 4> as_array() const noexcept
{
return {x, y, z, w};
}
};
} // namespace omath
template<class Type>
struct std::formatter<omath::Quaternion<Type>> // NOLINT(*-dcl58-cpp)
{
[[nodiscard]]
static constexpr auto parse(std::format_parse_context& ctx)
{
return ctx.begin();
}
template<class FormatContext>
[[nodiscard]]
static auto format(const omath::Quaternion<Type>& q, FormatContext& ctx)
{
if constexpr (std::is_same_v<typename FormatContext::char_type, char>)
return std::format_to(ctx.out(), "[{}, {}, {}, {}]", q.x, q.y, q.z, q.w);
if constexpr (std::is_same_v<typename FormatContext::char_type, wchar_t>)
return std::format_to(ctx.out(), L"[{}, {}, {}, {}]", q.x, q.y, q.z, q.w);
if constexpr (std::is_same_v<typename FormatContext::char_type, char8_t>)
return std::format_to(ctx.out(), u8"[{}, {}, {}, {}]", q.x, q.y, q.z, q.w);
}
};

6
include/omath/linear_algebra/vector2.hpp
View File

@@ -220,6 +220,12 @@ namespace omath
{ {
return std::make_tuple(x, y); return std::make_tuple(x, y);
} }
[[nodiscard]]
constexpr std::array<Type, 2> as_array() const noexcept
{
return {x, y};
}
#ifdef OMATH_IMGUI_INTEGRATION #ifdef OMATH_IMGUI_INTEGRATION
[[nodiscard]] [[nodiscard]]
constexpr ImVec2 to_im_vec2() const noexcept constexpr ImVec2 to_im_vec2() const noexcept

11
include/omath/linear_algebra/vector3.hpp
View File

@@ -4,8 +4,8 @@
#pragma once #pragma once
#include "omath/trigonometry/angle.hpp"
#include "omath/linear_algebra/vector2.hpp" #include "omath/linear_algebra/vector2.hpp"
#include "omath/trigonometry/angle.hpp"
#include <cstdint> #include <cstdint>
#include <expected> #include <expected>
#include <functional> #include <functional>
@@ -233,7 +233,8 @@ namespace omath
return Angle<float, 0.f, 180.f, AngleFlags::Clamped>::from_radians(std::acos(dot(other) / bottom)); return Angle<float, 0.f, 180.f, AngleFlags::Clamped>::from_radians(std::acos(dot(other) / bottom));
} }
[[nodiscard]] bool is_perpendicular(const Vector3& other, Type epsilon = static_cast<Type>(0.0001)) const noexcept [[nodiscard]] bool is_perpendicular(const Vector3& other,
Type epsilon = static_cast<Type>(0.0001)) const noexcept
{ {
if (const auto angle = angle_between(other)) if (const auto angle = angle_between(other))
return std::abs(angle->as_degrees() - static_cast<Type>(90)) <= epsilon; return std::abs(angle->as_degrees() - static_cast<Type>(90)) <= epsilon;
@@ -274,6 +275,12 @@ namespace omath
{ {
return length() >= other.length(); return length() >= other.length();
} }
[[nodiscard]]
constexpr std::array<Type, 3> as_array() const noexcept
{
return {this->x, this->y, z};
}
}; };
} // namespace omath } // namespace omath

10
include/omath/linear_algebra/vector4.hpp
View File

@@ -3,8 +3,8 @@
// //
#pragma once #pragma once
#include <algorithm>
#include "omath/linear_algebra/vector3.hpp" #include "omath/linear_algebra/vector3.hpp"
#include <algorithm>
namespace omath namespace omath
{ {
@@ -183,6 +183,12 @@ namespace omath
return length() >= other.length(); return length() >= other.length();
} }
[[nodiscard]]
constexpr std::array<Type, 4> as_array() const noexcept
{
return {this->x, this->y, this->z, w};
}
#ifdef OMATH_IMGUI_INTEGRATION #ifdef OMATH_IMGUI_INTEGRATION
[[nodiscard]] [[nodiscard]]
constexpr ImVec4 to_im_vec4() const noexcept constexpr ImVec4 to_im_vec4() const noexcept
@@ -200,7 +206,7 @@ namespace omath
return {static_cast<Type>(other.x), static_cast<Type>(other.y), static_cast<Type>(other.z)}; return {static_cast<Type>(other.x), static_cast<Type>(other.y), static_cast<Type>(other.z)};
} }
#endif #endif
}; };
} // namespace omath } // namespace omath
template<> struct std::hash<omath::Vector4<float>> template<> struct std::hash<omath::Vector4<float>>

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

3
include/omath/omath.hpp
View File

@@ -17,6 +17,9 @@
// Matrix classes // Matrix classes
#include "omath/linear_algebra/mat.hpp" #include "omath/linear_algebra/mat.hpp"
// Quaternion
#include "omath/linear_algebra/quaternion.hpp"
// Color functionality // Color functionality
#include "omath/utility/color.hpp" #include "omath/utility/color.hpp"

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

@@ -6,7 +6,9 @@
#include "omath/linear_algebra/vector3.hpp" #include "omath/linear_algebra/vector3.hpp"
#include <expected> #include <expected>
#include <optional>
#include <string> #include <string>
#include <unordered_map>
#include <vector> #include <vector>
namespace omath::pathfinding namespace omath::pathfinding
@@ -28,10 +30,20 @@ namespace omath::pathfinding
[[nodiscard]] [[nodiscard]]
bool empty() const; 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; 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 } // namespace omath::pathfinding

102
include/omath/utility/color.hpp
View File

@@ -16,19 +16,28 @@ namespace omath
float value{}; float value{};
}; };
class Color final : public Vector4<float> class Color final
{ {
Vector4<float> m_value;
public: public:
constexpr Color(const float r, const float g, const float b, const float a) noexcept: Vector4(r, g, b, a) constexpr const Vector4<float>& value() const
{ {
clamp(0.f, 1.f); return m_value;
}
constexpr Color(const float r, const float g, const float b, const float a) noexcept: m_value(r, g, b, a)
{
m_value.clamp(0.f, 1.f);
} }
constexpr explicit Color(const Vector4<float>& value) : m_value(value)
{
m_value.clamp(0.f, 1.f);
}
constexpr explicit Color() noexcept = default; constexpr explicit Color() noexcept = default;
[[nodiscard]] [[nodiscard]]
constexpr static Color from_rgba(const uint8_t r, const uint8_t g, const uint8_t b, const uint8_t a) noexcept constexpr static Color from_rgba(const uint8_t r, const uint8_t g, const uint8_t b, const uint8_t a) noexcept
{ {
return Color{Vector4(r, g, b, a) / 255.f}; return Color(Vector4<float>(r, g, b, a) / 255.f);
} }
[[nodiscard]] [[nodiscard]]
@@ -82,9 +91,9 @@ namespace omath
{ {
Hsv hsv_data; Hsv hsv_data;
const float& red = x; const float& red = m_value.x;
const float& green = y; const float& green = m_value.y;
const float& blue = z; const float& blue = m_value.z;
const float max = std::max({red, green, blue}); const float max = std::max({red, green, blue});
const float min = std::min({red, green, blue}); const float min = std::min({red, green, blue});
@@ -109,11 +118,6 @@ namespace omath
return hsv_data; return hsv_data;
} }
constexpr explicit Color(const Vector4& vec) noexcept: Vector4(vec)
{
clamp(0.f, 1.f);
}
constexpr void set_hue(const float hue) noexcept constexpr void set_hue(const float hue) noexcept
{ {
auto hsv = to_hsv(); auto hsv = to_hsv();
@@ -141,7 +145,7 @@ namespace omath
constexpr Color blend(const Color& other, float ratio) const noexcept constexpr Color blend(const Color& other, float ratio) const noexcept
{ {
ratio = std::clamp(ratio, 0.f, 1.f); ratio = std::clamp(ratio, 0.f, 1.f);
return Color(*this * (1.f - ratio) + other * ratio); return Color(this->m_value * (1.f - ratio) + other.m_value * ratio);
} }
[[nodiscard]] static constexpr Color red() [[nodiscard]] static constexpr Color red()
@@ -160,16 +164,26 @@ namespace omath
[[nodiscard]] [[nodiscard]]
ImColor to_im_color() const noexcept ImColor to_im_color() const noexcept
{ {
return {to_im_vec4()}; return {m_value.to_im_vec4()};
} }
#endif #endif
[[nodiscard]] std::string to_string() const noexcept [[nodiscard]] std::string to_string() const noexcept
{ {
return std::format("[r:{}, g:{}, b:{}, a:{}]", return std::format("[r:{}, g:{}, b:{}, a:{}]",
static_cast<int>(x * 255.f), static_cast<int>(m_value.x * 255.f),
static_cast<int>(y * 255.f), static_cast<int>(m_value.y * 255.f),
static_cast<int>(z * 255.f), static_cast<int>(m_value.z * 255.f),
static_cast<int>(w * 255.f)); static_cast<int>(m_value.w * 255.f));
}
[[nodiscard]] std::string to_rgbf_string() const noexcept
{
return std::format("[r:{}, g:{}, b:{}, a:{}]",
m_value.x, m_value.y, m_value.z, m_value.w);
}
[[nodiscard]] std::string to_hsv_string() const noexcept
{
const auto [hue, saturation, value] = to_hsv();
return std::format("[h:{}, s:{}, v:{}]", hue, saturation, value);
} }
[[nodiscard]] std::wstring to_wstring() const noexcept [[nodiscard]] std::wstring to_wstring() const noexcept
{ {
@@ -188,23 +202,55 @@ namespace omath
template<> template<>
struct std::formatter<omath::Color> // NOLINT(*-dcl58-cpp) struct std::formatter<omath::Color> // NOLINT(*-dcl58-cpp)
{ {
[[nodiscard]] enum class ColorFormat { rgb, rgbf, hsv };
static constexpr auto parse(const std::format_parse_context& ctx) ColorFormat color_format = ColorFormat::rgb;
constexpr auto parse(std::format_parse_context& ctx)
{ {
return ctx.begin(); const auto it = ctx.begin();
const auto end = ctx.end();
if (it == end || *it == '}')
return it;
const std::string_view spec(it, end);
if (spec.starts_with("rgbf"))
{
color_format = ColorFormat::rgbf;
return it + 4;
}
if (spec.starts_with("rgb"))
{
color_format = ColorFormat::rgb;
return it + 3;
}
if (spec.starts_with("hsv"))
{
color_format = ColorFormat::hsv;
return it + 3;
}
throw std::format_error("Invalid format specifier for omath::Color. Use rgb, rgbf, or hsv.");
} }
template<class FormatContext> template<class FormatContext>
[[nodiscard]] auto format(const omath::Color& col, FormatContext& ctx) const
static auto format(const omath::Color& col, FormatContext& ctx)
{ {
if constexpr (std::is_same_v<typename FormatContext::char_type, char>) std::string str;
return std::format_to(ctx.out(), "{}", col.to_string()); switch (color_format)
if constexpr (std::is_same_v<typename FormatContext::char_type, wchar_t>) {
return std::format_to(ctx.out(), L"{}", col.to_wstring()); case ColorFormat::rgb: str = col.to_string(); break;
case ColorFormat::rgbf: str = col.to_rgbf_string(); break;
case ColorFormat::hsv: str = col.to_hsv_string(); break;
}
if constexpr (std::is_same_v<typename FormatContext::char_type, char>)
return std::format_to(ctx.out(), "{}", str);
if constexpr (std::is_same_v<typename FormatContext::char_type, wchar_t>)
return std::format_to(ctx.out(), L"{}", std::wstring(str.cbegin(), str.cend()));
if constexpr (std::is_same_v<typename FormatContext::char_type, char8_t>) if constexpr (std::is_same_v<typename FormatContext::char_type, char8_t>)
return std::format_to(ctx.out(), u8"{}", col.to_u8string()); return std::format_to(ctx.out(), u8"{}", std::u8string(str.cbegin(), str.cend()));
std::unreachable(); std::unreachable();
} }

14
pixi/run.benchmark.cmake
View File

@@ -15,7 +15,10 @@ endif()
set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}") set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}")
if(NOT EXISTS "${EXAMPLES_BIN_DIR}") if(NOT EXISTS "${EXAMPLES_BIN_DIR}")
message(FATAL_ERROR "Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first.") message(
FATAL_ERROR
"Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first."
)
endif() endif()
message(STATUS "Looking for benchmark executables in: ${EXAMPLES_BIN_DIR}") message(STATUS "Looking for benchmark executables in: ${EXAMPLES_BIN_DIR}")
@@ -43,16 +46,13 @@ foreach(EXAMPLE_PATH ${EXAMPLE_FILES})
endif() endif()
# On Linux/macOS, check permissions or just try to run it. # On Linux/macOS, check permissions or just try to run it.
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
message(STATUS "Running benchmark: ${FILENAME}") message(STATUS "Running benchmark: ${FILENAME}")
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
execute_process( execute_process(COMMAND "${EXAMPLE_PATH}" WORKING_DIRECTORY "${PROJECT_ROOT}"
COMMAND "${EXAMPLE_PATH}" RESULT_VARIABLE EXIT_CODE)
WORKING_DIRECTORY "${PROJECT_ROOT}"
RESULT_VARIABLE EXIT_CODE
)
if(NOT EXIT_CODE EQUAL 0) if(NOT EXIT_CODE EQUAL 0)
message(WARNING "Benchmark ${FILENAME} exited with error code: ${EXIT_CODE}") message(WARNING "Benchmark ${FILENAME} exited with error code: ${EXIT_CODE}")

14
pixi/run.examples.cmake
View File

@@ -15,7 +15,10 @@ endif()
set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}") set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}")
if(NOT EXISTS "${EXAMPLES_BIN_DIR}") if(NOT EXISTS "${EXAMPLES_BIN_DIR}")
message(FATAL_ERROR "Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first.") message(
FATAL_ERROR
"Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first."
)
endif() endif()
message(STATUS "Looking for example executables in: ${EXAMPLES_BIN_DIR}") message(STATUS "Looking for example executables in: ${EXAMPLES_BIN_DIR}")
@@ -43,16 +46,13 @@ foreach(EXAMPLE_PATH ${EXAMPLE_FILES})
endif() endif()
# On Linux/macOS, check permissions or just try to run it. # On Linux/macOS, check permissions or just try to run it.
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
message(STATUS "Running example: ${FILENAME}") message(STATUS "Running example: ${FILENAME}")
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
execute_process( execute_process(COMMAND "${EXAMPLE_PATH}" WORKING_DIRECTORY "${PROJECT_ROOT}"
COMMAND "${EXAMPLE_PATH}" RESULT_VARIABLE EXIT_CODE)
WORKING_DIRECTORY "${PROJECT_ROOT}"
RESULT_VARIABLE EXIT_CODE
)
if(NOT EXIT_CODE EQUAL 0) if(NOT EXIT_CODE EQUAL 0)
message(WARNING "Example ${FILENAME} exited with error code: ${EXIT_CODE}") message(WARNING "Example ${FILENAME} exited with error code: ${EXIT_CODE}")

14
pixi/run.unit.tests.cmake
View File

@@ -15,7 +15,10 @@ endif()
set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}") set(EXAMPLES_BIN_DIR "${PROJECT_ROOT}/out/${CMAKE_BUILD_TYPE}")
if(NOT EXISTS "${EXAMPLES_BIN_DIR}") if(NOT EXISTS "${EXAMPLES_BIN_DIR}")
message(FATAL_ERROR "Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first.") message(
FATAL_ERROR
"Examples binary directory not found: ${EXAMPLES_BIN_DIR}. Please build the project first."
)
endif() endif()
message(STATUS "Looking for unit test executables in: ${EXAMPLES_BIN_DIR}") message(STATUS "Looking for unit test executables in: ${EXAMPLES_BIN_DIR}")
@@ -43,16 +46,13 @@ foreach(EXAMPLE_PATH ${EXAMPLE_FILES})
endif() endif()
# On Linux/macOS, check permissions or just try to run it. # On Linux/macOS, check permissions or just try to run it.
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
message(STATUS "Running unit_tests: ${FILENAME}") message(STATUS "Running unit_tests: ${FILENAME}")
message(STATUS "-------------------------------------------------") message(STATUS "-------------------------------------------------")
execute_process( execute_process(COMMAND "${EXAMPLE_PATH}" WORKING_DIRECTORY "${PROJECT_ROOT}"
COMMAND "${EXAMPLE_PATH}" RESULT_VARIABLE EXIT_CODE)
WORKING_DIRECTORY "${PROJECT_ROOT}"
RESULT_VARIABLE EXIT_CODE
)
if(NOT EXIT_CODE EQUAL 0) if(NOT EXIT_CODE EQUAL 0)
message(WARNING "Example ${FILENAME} exited with error code: ${EXIT_CODE}") message(WARNING "Example ${FILENAME} exited with error code: ${EXIT_CODE}")

15
scripts/cmake-format.sh Normal file
View File

@@ -0,0 +1,15 @@
#!/usr/bin/env bash
set -euo pipefail
# Format all CMakeLists.txt and *.cmake files in the repo (excluding common build dirs)
REPO_ROOT="$(cd "$(dirname "${BASH_SOURCE[0]}")/.." && pwd)"
cd "$REPO_ROOT"
find . \
-path "./build" -prune -o \
-path "./cmake-build*" -prune -o \
-path "./out" -prune -o \
-path "./.git" -prune -o \
\( -name "CMakeLists.txt" -o -name "*.cmake" \) -print0 \
| xargs -0 cmake-format -i

4
source/engines/cry_engine/formulas.cpp
View File

@@ -30,8 +30,8 @@ namespace omath::cry_engine
} }
Mat4X4 rotation_matrix(const ViewAngles& angles) noexcept Mat4X4 rotation_matrix(const ViewAngles& angles) noexcept
{ {
return mat_rotation_axis_z<float, MatStoreType::ROW_MAJOR>(angles.roll) return mat_rotation_axis_z<float, MatStoreType::ROW_MAJOR>(angles.yaw)
* mat_rotation_axis_y<float, MatStoreType::ROW_MAJOR>(angles.yaw) * mat_rotation_axis_y<float, MatStoreType::ROW_MAJOR>(angles.roll)
* mat_rotation_axis_x<float, MatStoreType::ROW_MAJOR>(angles.pitch); * mat_rotation_axis_x<float, MatStoreType::ROW_MAJOR>(angles.pitch);
} }
Mat4X4 calc_perspective_projection_matrix(const float field_of_view, const float aspect_ratio, const float near, Mat4X4 calc_perspective_projection_matrix(const float field_of_view, const float aspect_ratio, const float near,

4
source/engines/cry_engine/camera_trait.cpp → source/engines/cry_engine/traits/camera_trait.cpp
View File

@@ -10,8 +10,8 @@ namespace omath::cry_engine
{ {
const auto direction = (look_at - cam_origin).normalized(); const auto direction = (look_at - cam_origin).normalized();
return {PitchAngle::from_radians(-std::asin(direction.z)), return {PitchAngle::from_radians(std::asin(direction.z)),
YawAngle::from_radians(std::atan2(direction.y, direction.x)), RollAngle::from_radians(0.f)}; YawAngle::from_radians(-std::atan2(direction.x, direction.y)), RollAngle::from_radians(0.f)};
} }
Mat4X4 CameraTrait::calc_view_matrix(const ViewAngles& angles, const Vector3<float>& cam_origin) noexcept Mat4X4 CameraTrait::calc_view_matrix(const ViewAngles& angles, const Vector3<float>& cam_origin) noexcept
{ {

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

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//
// 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

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//
// 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

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@@ -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

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//
// 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
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//
// 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
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@@ -3,9 +3,9 @@
// //
#include "omath/pathfinding/navigation_mesh.hpp" #include "omath/pathfinding/navigation_mesh.hpp"
#include <algorithm> #include <algorithm>
#include <cstring> #include <sstream>
#include <limits>
#include <stdexcept> #include <stdexcept>
namespace omath::pathfinding namespace omath::pathfinding
{ {
std::expected<Vector3<float>, std::string> std::expected<Vector3<float>, std::string>
@@ -30,77 +30,72 @@ namespace omath::pathfinding
return m_vertex_map.empty(); 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 m_vertex_events[vertex] = event_id;
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;
} }
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()) const auto event_it = m_vertex_events.find(vertex);
throw std::runtime_error("Deserialize: Invalid input data size."); 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)); oss << vertex.x << ' ' << vertex.y << ' ' << vertex.z << ' ' << neighbors.size() << ' ' << event << '\n';
offset += sizeof(value);
};
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_map.clear();
m_vertex_events.clear();
std::istringstream iss(raw);
std::size_t offset = 0; Vector3<float> vertex;
std::size_t neighbors_count;
while (offset < raw.size()) 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; std::vector<Vector3<float>> neighbors;
neighbors.reserve(neighbors_count); neighbors.reserve(neighbors_count);
for (std::size_t i = 0; i < neighbors_count; ++i) for (std::size_t i = 0; i < neighbors_count; ++i)
{ {
Vector3<float> neighbor; Vector3<float> n;
load_from_vector(raw, offset, neighbor); if (!(iss >> n.x >> n.y >> n.z))
neighbors.push_back(neighbor); throw std::runtime_error("Deserialize: Unexpected end of data.");
neighbors.push_back(n);
} }
m_vertex_map.emplace(vertex, std::move(neighbors)); m_vertex_map.emplace(vertex, std::move(neighbors));
if (event != "-")
m_vertex_events.emplace(vertex, std::move(event));
} }
} }
} // namespace omath::pathfinding } // namespace omath::pathfinding

15
tests/CMakeLists.txt
View File

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

240
tests/engines/unit_test_cry_engine.cpp Normal file
View File

@@ -0,0 +1,240 @@
//
// Created by Vladislav on 19.02.2026.
//
#include <gtest/gtest.h>
#include <omath/engines/cry_engine/camera.hpp>
#include <omath/engines/cry_engine/constants.hpp>
#include <omath/engines/cry_engine/formulas.hpp>
#include <random>
#include <ranges>
using namespace omath;
TEST(unit_test_cry_engine, look_at_forward)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, cry_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), cry_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, look_at_right)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, cry_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), cry_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, look_at_up)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, cry_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), cry_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, look_at_back)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, -cry_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-cry_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, look_at_left)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, -cry_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-cry_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, look_at_down)
{
const auto angles = cry_engine::CameraTrait::calc_look_at_angle({}, -cry_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = cry_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-cry_engine::k_abs_up).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_cry_engine, RightVector)
{
const auto right = omath::cry_engine::right_vector({});
EXPECT_EQ(right, omath::cry_engine::k_abs_right);
}
TEST(unit_test_cry_engine, UpVector)
{
const auto up = omath::cry_engine::up_vector({});
EXPECT_EQ(up, omath::cry_engine::k_abs_up);
}
TEST(unit_test_cry_engine, ProjectTargetMovedFromCamera)
{
constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
const auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.01f, 1000.f);
for (float distance = 0.02f; distance < 100.f; distance += 0.01f)
{
const auto projected = cam.world_to_screen({0, distance, 0});
EXPECT_TRUE(projected.has_value());
if (!projected.has_value())
continue;
EXPECT_NEAR(projected->x, 640, 0.00001f);
EXPECT_NEAR(projected->y, 360, 0.00001f);
}
}
TEST(unit_test_cry_engine, CameraSetAndGetFov)
{
constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.01f, 1000.f);
EXPECT_EQ(cam.get_field_of_view().as_degrees(), 90.f);
cam.set_field_of_view(omath::projection::FieldOfView::from_degrees(50.f));
EXPECT_EQ(cam.get_field_of_view().as_degrees(), 50.f);
}
TEST(unit_test_cry_engine, CameraSetAndGetOrigin)
{
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, {}, 0.01f, 1000.f);
EXPECT_EQ(cam.get_origin(), omath::Vector3<float>{});
cam.set_field_of_view(omath::projection::FieldOfView::from_degrees(50.f));
EXPECT_EQ(cam.get_field_of_view().as_degrees(), 50.f);
}
TEST(unit_test_cry_engine, loook_at_random_all_axis)
{
std::mt19937 gen(std::random_device{}()); // Seed with a non-deterministic source
std::uniform_real_distribution<float> dist(-1000.f, 1000.f);
constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.001f, 10000.f);
std::size_t failed_points = 0;
for (int i = 0; i < 1000; i++)
{
const auto position_to_look = omath::Vector3<float>{dist(gen), dist(gen), dist(gen)};
if (cam.get_origin().distance_to(position_to_look) < 10)
continue;
cam.look_at(position_to_look);
auto projected_pos = cam.world_to_view_port(position_to_look);
EXPECT_TRUE(projected_pos.has_value());
if (!projected_pos)
continue;
if (std::abs(projected_pos->x - 0.f) >= 0.0001f || std::abs(projected_pos->y - 0.f) >= 0.0001f)
failed_points++;
}
EXPECT_LE(failed_points, 100);
}
TEST(unit_test_cry_engine, loook_at_random_x_axis)
{
std::mt19937 gen(std::random_device{}()); // Seed with a non-deterministic source
std::uniform_real_distribution<float> dist(-1000.f, 1000.f);
constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.001f, 10000.f);
std::size_t failed_points = 0;
for (int i = 0; i < 1000; i++)
{
const auto position_to_look = omath::Vector3<float>{dist(gen), 0.f, 0.f};
if (cam.get_origin().distance_to(position_to_look) < 10)
continue;
cam.look_at(position_to_look);
auto projected_pos = cam.world_to_view_port(position_to_look);
EXPECT_TRUE(projected_pos.has_value());
if (!projected_pos)
continue;
if (std::abs(projected_pos->x - 0.f) >= 0.001f || std::abs(projected_pos->y - 0.f) >= 0.001f)
failed_points++;
}
EXPECT_LE(failed_points, 100);
}
TEST(unit_test_cry_engine, loook_at_random_y_axis)
{
std::mt19937 gen(std::random_device{}()); // Seed with a non-deterministic source
std::uniform_real_distribution<float> dist(-1000.f, 1000.f);
constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.001f, 10000.f);
std::size_t failed_points = 0;
for (int i = 0; i < 1000; i++)
{
const auto position_to_look = omath::Vector3<float>{0.f, dist(gen), 0.f};
if (cam.get_origin().distance_to(position_to_look) < 10)
continue;
cam.look_at(position_to_look);
auto projected_pos = cam.world_to_view_port(position_to_look);
EXPECT_TRUE(projected_pos.has_value());
if (!projected_pos)
continue;
if (std::abs(projected_pos->x - 0.f) >= 0.01f || std::abs(projected_pos->y - 0.f) >= 0.01f)
failed_points++;
}
EXPECT_LE(failed_points, 100);
}
TEST(unit_test_cry_engine, loook_at_random_z_axis)
{
std::mt19937 gen(std::random_device{}()); // Seed with a non-deterministic source
std::uniform_real_distribution<float> dist(-1000.f, 1000.f);
constexpr auto fov = omath::projection::FieldOfView::from_degrees(90.f);
auto cam = omath::cry_engine::Camera({0, 0, 0}, {}, {1920.f, 1080.f}, fov, 0.001f, 10000.f);
std::size_t failed_points = 0;
for (int i = 0; i < 1000; i++)
{
const auto position_to_look = omath::Vector3<float>{0.f, 0.f, dist(gen)};
if (cam.get_origin().distance_to(position_to_look) < 10)
continue;
cam.look_at(position_to_look);
auto projected_pos = cam.world_to_view_port(position_to_look);
EXPECT_TRUE(projected_pos.has_value());
if (!projected_pos)
continue;
if (std::abs(projected_pos->x - 0.f) >= 0.01f || std::abs(projected_pos->y - 0.f) >= 0.01f)
failed_points++;
}
EXPECT_LE(failed_points, 100);
}

54
tests/engines/unit_test_frostbite_engine.cpp
View File

@@ -7,6 +7,7 @@
#include <omath/engines/frostbite_engine/formulas.hpp> #include <omath/engines/frostbite_engine/formulas.hpp>
#include <print> #include <print>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_frostbite_engine, UnitsToCentimeters_BasicValues) TEST(unit_test_frostbite_engine, UnitsToCentimeters_BasicValues)
{ {
@@ -352,4 +353,55 @@ TEST(unit_test_frostbite_engine, loook_at_random_z_axis)
failed_points++; failed_points++;
} }
EXPECT_LE(failed_points, 100); EXPECT_LE(failed_points, 100);
} }
TEST(unit_test_frostbite_engine, look_at_right)
{
const auto angles = omath::frostbite_engine::CameraTrait::calc_look_at_angle({}, omath::frostbite_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::frostbite_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), omath::frostbite_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_frostbite_engine, look_at_up)
{
const auto angles = omath::frostbite_engine::CameraTrait::calc_look_at_angle({}, omath::frostbite_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::frostbite_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), omath::frostbite_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_frostbite_engine, look_at_back)
{
const auto angles = omath::frostbite_engine::CameraTrait::calc_look_at_angle({}, -omath::frostbite_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::frostbite_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::frostbite_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_frostbite_engine, look_at_left)
{
const auto angles = omath::frostbite_engine::CameraTrait::calc_look_at_angle({}, -omath::frostbite_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::frostbite_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::frostbite_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_frostbite_engine, look_at_down)
{
const auto angles = omath::frostbite_engine::CameraTrait::calc_look_at_angle({}, -omath::frostbite_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::frostbite_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::frostbite_engine::k_abs_up).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}

57
tests/engines/unit_test_iw_engine.cpp
View File

@@ -6,6 +6,7 @@
#include <omath/engines/iw_engine/constants.hpp> #include <omath/engines/iw_engine/constants.hpp>
#include <omath/engines/iw_engine/formulas.hpp> #include <omath/engines/iw_engine/formulas.hpp>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_iw_engine, ForwardVector) TEST(unit_test_iw_engine, ForwardVector)
{ {
@@ -223,4 +224,60 @@ TEST(unit_test_iw_engine, loook_at_random_z_axis)
failed_points++; failed_points++;
} }
EXPECT_LE(failed_points, 100); EXPECT_LE(failed_points, 100);
}
TEST(unit_test_iw_engine, look_at_forward)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, omath::iw_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::iw_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_iw_engine, look_at_right)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, omath::iw_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::iw_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_iw_engine, look_at_up)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, omath::iw_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::iw_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_iw_engine, look_at_back)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, -omath::iw_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::iw_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_iw_engine, look_at_left)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, -omath::iw_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::iw_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_iw_engine, look_at_down)
{
const auto angles = omath::iw_engine::CameraTrait::calc_look_at_angle({}, -omath::iw_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::iw_engine::forward_vector(angles);
EXPECT_NEAR(dir_vector.z, -0.99984f, 0.0001f);
EXPECT_NEAR(dir_vector.x,- 0.017f, 0.01f);
EXPECT_NEAR(dir_vector.y, 0.f, 0.001f);
} }

57
tests/engines/unit_test_open_gl.cpp
View File

@@ -6,6 +6,7 @@
#include <omath/engines/opengl_engine/constants.hpp> #include <omath/engines/opengl_engine/constants.hpp>
#include <omath/engines/opengl_engine/formulas.hpp> #include <omath/engines/opengl_engine/formulas.hpp>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_opengl, UnitsToCentimeters_BasicValues) TEST(unit_test_opengl, UnitsToCentimeters_BasicValues)
{ {
@@ -337,4 +338,60 @@ TEST(unit_test_opengl_engine, loook_at_random_z_axis)
failed_points++; failed_points++;
} }
EXPECT_LE(failed_points, 100); EXPECT_LE(failed_points, 100);
}
TEST(unit_test_opengl_engine, look_at_forward)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, omath::opengl_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::opengl_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_opengl_engine, look_at_right)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, omath::opengl_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::opengl_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_opengl_engine, look_at_up)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, omath::opengl_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::opengl_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_opengl_engine, look_at_back)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, -omath::opengl_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::opengl_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_opengl_engine, look_at_left)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, -omath::opengl_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::opengl_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_opengl_engine, look_at_down)
{
const auto angles = omath::opengl_engine::CameraTrait::calc_look_at_angle({}, -omath::opengl_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::opengl_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::opengl_engine::k_abs_up).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
} }

57
tests/engines/unit_test_source_engine.cpp
View File

@@ -6,6 +6,7 @@
#include <omath/engines/source_engine/constants.hpp> #include <omath/engines/source_engine/constants.hpp>
#include <omath/engines/source_engine/formulas.hpp> #include <omath/engines/source_engine/formulas.hpp>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_source_engine_units, HammerUnitsToCentimeters_BasicValues) TEST(unit_test_source_engine_units, HammerUnitsToCentimeters_BasicValues)
{ {
@@ -365,4 +366,60 @@ TEST(unit_test_source_engine, loook_at_random_z_axis)
failed_points++; failed_points++;
} }
EXPECT_LE(failed_points, 100); EXPECT_LE(failed_points, 100);
}
TEST(unit_test_source_engine, look_at_forward)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, omath::source_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::source_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_source_engine, look_at_right)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, omath::source_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::source_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_source_engine, look_at_up)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, omath::source_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::source_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_source_engine, look_at_back)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, -omath::source_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::source_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_source_engine, look_at_left)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, -omath::source_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::source_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_source_engine, look_at_down)
{
const auto angles = omath::source_engine::CameraTrait::calc_look_at_angle({}, -omath::source_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::source_engine::forward_vector(angles);
EXPECT_NEAR(dir_vector.z, -0.99984f, 0.0001f);
EXPECT_NEAR(dir_vector.x,- 0.017f, 0.01f);
EXPECT_NEAR(dir_vector.y, 0.f, 0.001f);
} }

67
tests/engines/unit_test_unity_engine.cpp
View File

@@ -7,6 +7,7 @@
#include <omath/engines/unity_engine/formulas.hpp> #include <omath/engines/unity_engine/formulas.hpp>
#include <print> #include <print>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_unity_engine, UnitsToCentimeters_BasicValues) TEST(unit_test_unity_engine, UnitsToCentimeters_BasicValues)
{ {
@@ -207,7 +208,8 @@ TEST(unit_test_unity_engine, Project)
constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f); constexpr auto fov = omath::projection::FieldOfView::from_degrees(60.f);
const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f); const auto cam = omath::unity_engine::Camera({0, 0, 0}, {}, {1280.f, 720.f}, fov, 0.03f, 1000.f);
const auto proj = cam.world_to_screen<omath::unity_engine::Camera::ScreenStart::BOTTOM_LEFT_CORNER>({10.f, 3, 10.f}); const auto proj =
cam.world_to_screen<omath::unity_engine::Camera::ScreenStart::BOTTOM_LEFT_CORNER>({10.f, 3, 10.f});
EXPECT_NEAR(proj->x, 1263.538, 0.001f); EXPECT_NEAR(proj->x, 1263.538, 0.001f);
EXPECT_NEAR(proj->y, 547.061f, 0.001f); EXPECT_NEAR(proj->y, 547.061f, 0.001f);
@@ -353,4 +355,65 @@ TEST(unit_test_unity_engine, loook_at_random_z_axis)
failed_points++; failed_points++;
} }
EXPECT_LE(failed_points, 100); EXPECT_LE(failed_points, 100);
} }
TEST(unit_test_unity_engine, look_at_forward)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, omath::unity_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), omath::unity_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unity_engine, look_at_right)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, omath::unity_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), omath::unity_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unity_engine, look_at_up)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, omath::unity_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), omath::unity_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unity_engine, look_at_back)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, -omath::unity_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::unity_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unity_engine, look_at_left)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, -omath::unity_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::unity_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unity_engine, look_at_down)
{
const auto angles = omath::unity_engine::CameraTrait::calc_look_at_angle({}, -omath::unity_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unity_engine::forward_vector(angles);
for (const auto& [result, etalon] :
std::views::zip(dir_vector.as_array(), (-omath::unity_engine::k_abs_up).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}

56
tests/engines/unit_test_unreal_engine.cpp
View File

@@ -7,6 +7,7 @@
#include <omath/engines/unreal_engine/formulas.hpp> #include <omath/engines/unreal_engine/formulas.hpp>
#include <print> #include <print>
#include <random> #include <random>
#include <ranges>
TEST(unit_test_unreal_engine, ForwardVector) TEST(unit_test_unreal_engine, ForwardVector)
{ {
@@ -361,4 +362,59 @@ TEST(unit_test_unreal_engine, ConstexprConversions)
static_assert(cm == 100000.0, "units_to_centimeters constexpr failed"); static_assert(cm == 100000.0, "units_to_centimeters constexpr failed");
static_assert(m == 1000.0, "units_to_meters constexpr failed"); static_assert(m == 1000.0, "units_to_meters constexpr failed");
static_assert(km == 1.0, "units_to_kilometers constexpr failed"); static_assert(km == 1.0, "units_to_kilometers constexpr failed");
}
TEST(unit_test_unreal_engine, look_at_forward)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, omath::unreal_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::unreal_engine::k_abs_forward.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unreal_engine, look_at_right)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, omath::unreal_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::unreal_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unreal_engine, look_at_up)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, omath::unreal_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), omath::unreal_engine::k_abs_right.as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unreal_engine, look_at_back)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, -omath::unreal_engine::k_abs_forward);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::unreal_engine::k_abs_forward).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unreal_engine, look_at_left)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, -omath::unreal_engine::k_abs_right);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::unreal_engine::k_abs_right).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
}
TEST(unit_test_unreal_engine, look_at_down)
{
const auto angles = omath::unreal_engine::CameraTrait::calc_look_at_angle({}, -omath::unreal_engine::k_abs_up);
// ReSharper disable once CppTooWideScopeInitStatement
const auto dir_vector = omath::unreal_engine::forward_vector(angles);
for (const auto& [result, etalon] : std::views::zip(dir_vector.as_array(), (-omath::unreal_engine::k_abs_up).as_array()))
EXPECT_NEAR(result, etalon, 0.0001f);
} }

181
tests/general/unit_test_a_star.cpp
View File

@@ -8,6 +8,29 @@
using namespace omath; using namespace omath;
using namespace omath::pathfinding; 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) TEST(AStarExtra, TrivialNeighbor)
{ {
NavigationMesh nav; NavigationMesh nav;
@@ -78,7 +101,7 @@ TEST(AStarExtra, LongerPathAvoidsBlock)
constexpr Vector3<float> goal = idx(2, 1); constexpr Vector3<float> goal = idx(2, 1);
const auto path = Astar::find_path(start, goal, nav); const auto path = Astar::find_path(start, goal, nav);
ASSERT_FALSE(path.empty()); ASSERT_FALSE(path.empty());
EXPECT_EQ(path.front(), goal); // Astar convention: single-element or endpoint present EXPECT_EQ(path.front(), goal);
} }
TEST(AstarTests, TrivialDirectNeighborPath) TEST(AstarTests, TrivialDirectNeighborPath)
@@ -91,9 +114,6 @@ TEST(AstarTests, TrivialDirectNeighborPath)
nav.m_vertex_map.emplace(v2, std::vector<Vector3<float>>{v1}); nav.m_vertex_map.emplace(v2, std::vector<Vector3<float>>{v1});
const auto path = Astar::find_path(v1, v2, nav); 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); ASSERT_EQ(path.size(), 1u);
EXPECT_EQ(path.front(), v2); 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, 2.f, 0.f}] = {{0.f, 3.f, 0.f}};
mesh.m_vertex_map[{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); 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);
}

180
tests/general/unit_test_color_grouped.cpp
View File

@@ -26,38 +26,38 @@ protected:
TEST_F(UnitTestColorGrouped, Constructor_Float) TEST_F(UnitTestColorGrouped, Constructor_Float)
{ {
constexpr Color color(0.5f, 0.5f, 0.5f, 1.0f); constexpr Color color(0.5f, 0.5f, 0.5f, 1.0f);
EXPECT_FLOAT_EQ(color.x, 0.5f); EXPECT_FLOAT_EQ(color.value().x, 0.5f);
EXPECT_FLOAT_EQ(color.y, 0.5f); EXPECT_FLOAT_EQ(color.value().y, 0.5f);
EXPECT_FLOAT_EQ(color.z, 0.5f); EXPECT_FLOAT_EQ(color.value().z, 0.5f);
EXPECT_FLOAT_EQ(color.w, 1.0f); EXPECT_FLOAT_EQ(color.value().w, 1.0f);
} }
TEST_F(UnitTestColorGrouped, Constructor_Vector4) TEST_F(UnitTestColorGrouped, Constructor_Vector4)
{ {
constexpr omath::Vector4 vec(0.2f, 0.4f, 0.6f, 0.8f); constexpr omath::Vector4 vec(0.2f, 0.4f, 0.6f, 0.8f);
constexpr Color color(vec); constexpr Color color(vec);
EXPECT_FLOAT_EQ(color.x, 0.2f); EXPECT_FLOAT_EQ(color.value().x, 0.2f);
EXPECT_FLOAT_EQ(color.y, 0.4f); EXPECT_FLOAT_EQ(color.value().y, 0.4f);
EXPECT_FLOAT_EQ(color.z, 0.6f); EXPECT_FLOAT_EQ(color.value().z, 0.6f);
EXPECT_FLOAT_EQ(color.w, 0.8f); EXPECT_FLOAT_EQ(color.value().w, 0.8f);
} }
TEST_F(UnitTestColorGrouped, FromRGBA) TEST_F(UnitTestColorGrouped, FromRGBA)
{ {
constexpr Color color = Color::from_rgba(128, 64, 32, 255); constexpr Color color = Color::from_rgba(128, 64, 32, 255);
EXPECT_FLOAT_EQ(color.x, 128.0f / 255.0f); EXPECT_FLOAT_EQ(color.value().x, 128.0f / 255.0f);
EXPECT_FLOAT_EQ(color.y, 64.0f / 255.0f); EXPECT_FLOAT_EQ(color.value().y, 64.0f / 255.0f);
EXPECT_FLOAT_EQ(color.z, 32.0f / 255.0f); EXPECT_FLOAT_EQ(color.value().z, 32.0f / 255.0f);
EXPECT_FLOAT_EQ(color.w, 1.0f); EXPECT_FLOAT_EQ(color.value().w, 1.0f);
} }
TEST_F(UnitTestColorGrouped, FromHSV) TEST_F(UnitTestColorGrouped, FromHSV)
{ {
constexpr Color color = Color::from_hsv(0.0f, 1.0f, 1.0f); // Red in HSV constexpr Color color = Color::from_hsv(0.0f, 1.0f, 1.0f); // Red in HSV
EXPECT_FLOAT_EQ(color.x, 1.0f); EXPECT_FLOAT_EQ(color.value().x, 1.0f);
EXPECT_FLOAT_EQ(color.y, 0.0f); EXPECT_FLOAT_EQ(color.value().y, 0.0f);
EXPECT_FLOAT_EQ(color.z, 0.0f); EXPECT_FLOAT_EQ(color.value().z, 0.0f);
EXPECT_FLOAT_EQ(color.w, 1.0f); EXPECT_FLOAT_EQ(color.value().w, 1.0f);
} }
TEST_F(UnitTestColorGrouped, ToHSV) TEST_F(UnitTestColorGrouped, ToHSV)
@@ -71,10 +71,10 @@ TEST_F(UnitTestColorGrouped, ToHSV)
TEST_F(UnitTestColorGrouped, Blend) TEST_F(UnitTestColorGrouped, Blend)
{ {
const Color blended = color1.blend(color2, 0.5f); const Color blended = color1.blend(color2, 0.5f);
EXPECT_FLOAT_EQ(blended.x, 0.5f); EXPECT_FLOAT_EQ(blended.value().x, 0.5f);
EXPECT_FLOAT_EQ(blended.y, 0.5f); EXPECT_FLOAT_EQ(blended.value().y, 0.5f);
EXPECT_FLOAT_EQ(blended.z, 0.0f); EXPECT_FLOAT_EQ(blended.value().z, 0.0f);
EXPECT_FLOAT_EQ(blended.w, 1.0f); EXPECT_FLOAT_EQ(blended.value().w, 1.0f);
} }
TEST_F(UnitTestColorGrouped, PredefinedColors) TEST_F(UnitTestColorGrouped, PredefinedColors)
@@ -83,20 +83,20 @@ TEST_F(UnitTestColorGrouped, PredefinedColors)
constexpr Color green = Color::green(); constexpr Color green = Color::green();
constexpr Color blue = Color::blue(); constexpr Color blue = Color::blue();
EXPECT_FLOAT_EQ(red.x, 1.0f); EXPECT_FLOAT_EQ(red.value().x, 1.0f);
EXPECT_FLOAT_EQ(red.y, 0.0f); EXPECT_FLOAT_EQ(red.value().y, 0.0f);
EXPECT_FLOAT_EQ(red.z, 0.0f); EXPECT_FLOAT_EQ(red.value().z, 0.0f);
EXPECT_FLOAT_EQ(red.w, 1.0f); EXPECT_FLOAT_EQ(red.value().w, 1.0f);
EXPECT_FLOAT_EQ(green.x, 0.0f); EXPECT_FLOAT_EQ(green.value().x, 0.0f);
EXPECT_FLOAT_EQ(green.y, 1.0f); EXPECT_FLOAT_EQ(green.value().y, 1.0f);
EXPECT_FLOAT_EQ(green.z, 0.0f); EXPECT_FLOAT_EQ(green.value().z, 0.0f);
EXPECT_FLOAT_EQ(green.w, 1.0f); EXPECT_FLOAT_EQ(green.value().w, 1.0f);
EXPECT_FLOAT_EQ(blue.x, 0.0f); EXPECT_FLOAT_EQ(blue.value().x, 0.0f);
EXPECT_FLOAT_EQ(blue.y, 0.0f); EXPECT_FLOAT_EQ(blue.value().y, 0.0f);
EXPECT_FLOAT_EQ(blue.z, 1.0f); EXPECT_FLOAT_EQ(blue.value().z, 1.0f);
EXPECT_FLOAT_EQ(blue.w, 1.0f); EXPECT_FLOAT_EQ(blue.value().w, 1.0f);
} }
TEST_F(UnitTestColorGrouped, BlendVector3) TEST_F(UnitTestColorGrouped, BlendVector3)
@@ -104,9 +104,9 @@ TEST_F(UnitTestColorGrouped, BlendVector3)
constexpr Color v1(1.0f, 0.0f, 0.0f, 1.f); // Red constexpr Color v1(1.0f, 0.0f, 0.0f, 1.f); // Red
constexpr Color v2(0.0f, 1.0f, 0.0f, 1.f); // Green constexpr Color v2(0.0f, 1.0f, 0.0f, 1.f); // Green
constexpr Color blended = v1.blend(v2, 0.5f); constexpr Color blended = v1.blend(v2, 0.5f);
EXPECT_FLOAT_EQ(blended.x, 0.5f); EXPECT_FLOAT_EQ(blended.value().x, 0.5f);
EXPECT_FLOAT_EQ(blended.y, 0.5f); EXPECT_FLOAT_EQ(blended.value().y, 0.5f);
EXPECT_FLOAT_EQ(blended.z, 0.0f); EXPECT_FLOAT_EQ(blended.value().z, 0.0f);
} }
// From unit_test_color_extra.cpp // From unit_test_color_extra.cpp
@@ -148,37 +148,37 @@ TEST(UnitTestColorGrouped_Extra, BlendEdgeCases)
constexpr Color a = Color::red(); constexpr Color a = Color::red();
constexpr Color b = Color::blue(); constexpr Color b = Color::blue();
constexpr auto r0 = a.blend(b, 0.f); constexpr auto r0 = a.blend(b, 0.f);
EXPECT_FLOAT_EQ(r0.x, a.x); EXPECT_FLOAT_EQ(r0.value().x, a.value().x);
constexpr auto r1 = a.blend(b, 1.f); constexpr auto r1 = a.blend(b, 1.f);
EXPECT_FLOAT_EQ(r1.x, b.x); EXPECT_FLOAT_EQ(r1.value().x, b.value().x);
} }
// From unit_test_color_more.cpp // From unit_test_color_more.cpp
TEST(UnitTestColorGrouped_More, DefaultCtorIsZero) TEST(UnitTestColorGrouped_More, DefaultCtorIsZero)
{ {
constexpr Color c; constexpr Color c;
EXPECT_FLOAT_EQ(c.x, 0.0f); EXPECT_FLOAT_EQ(c.value().x, 0.0f);
EXPECT_FLOAT_EQ(c.y, 0.0f); EXPECT_FLOAT_EQ(c.value().y, 0.0f);
EXPECT_FLOAT_EQ(c.z, 0.0f); EXPECT_FLOAT_EQ(c.value().z, 0.0f);
EXPECT_FLOAT_EQ(c.w, 0.0f); EXPECT_FLOAT_EQ(c.value().w, 0.0f);
} }
TEST(UnitTestColorGrouped_More, FloatCtorAndClampForRGB) TEST(UnitTestColorGrouped_More, FloatCtorAndClampForRGB)
{ {
constexpr Color c(1.2f, -0.5f, 0.5f, 2.0f); constexpr Color c(1.2f, -0.5f, 0.5f, 2.0f);
EXPECT_FLOAT_EQ(c.x, 1.0f); EXPECT_FLOAT_EQ(c.value().x, 1.0f);
EXPECT_FLOAT_EQ(c.y, 0.0f); EXPECT_FLOAT_EQ(c.value().y, 0.0f);
EXPECT_FLOAT_EQ(c.z, 0.5f); EXPECT_FLOAT_EQ(c.value().z, 0.5f);
EXPECT_FLOAT_EQ(c.w, 2.0f); EXPECT_FLOAT_EQ(c.value().w, 2.0f);
} }
TEST(UnitTestColorGrouped_More, FromRgbaProducesScaledComponents) TEST(UnitTestColorGrouped_More, FromRgbaProducesScaledComponents)
{ {
constexpr Color c = Color::from_rgba(25u, 128u, 230u, 64u); constexpr Color c = Color::from_rgba(25u, 128u, 230u, 64u);
EXPECT_NEAR(c.x, 25.0f/255.0f, 1e-6f); EXPECT_NEAR(c.value().x, 25.0f/255.0f, 1e-6f);
EXPECT_NEAR(c.y, 128.0f/255.0f, 1e-6f); EXPECT_NEAR(c.value().y, 128.0f/255.0f, 1e-6f);
EXPECT_NEAR(c.z, 230.0f/255.0f, 1e-6f); EXPECT_NEAR(c.value().z, 230.0f/255.0f, 1e-6f);
EXPECT_NEAR(c.w, 64.0f/255.0f, 1e-6f); EXPECT_NEAR(c.value().w, 64.0f/255.0f, 1e-6f);
} }
TEST(UnitTestColorGrouped_More, BlendProducesIntermediate) TEST(UnitTestColorGrouped_More, BlendProducesIntermediate)
@@ -186,10 +186,10 @@ TEST(UnitTestColorGrouped_More, BlendProducesIntermediate)
constexpr Color c0(0.0f, 0.0f, 0.0f, 1.0f); constexpr Color c0(0.0f, 0.0f, 0.0f, 1.0f);
constexpr Color c1(1.0f, 1.0f, 1.0f, 0.0f); constexpr Color c1(1.0f, 1.0f, 1.0f, 0.0f);
constexpr Color mid = c0.blend(c1, 0.5f); constexpr Color mid = c0.blend(c1, 0.5f);
EXPECT_FLOAT_EQ(mid.x, 0.5f); EXPECT_FLOAT_EQ(mid.value().x, 0.5f);
EXPECT_FLOAT_EQ(mid.y, 0.5f); EXPECT_FLOAT_EQ(mid.value().y, 0.5f);
EXPECT_FLOAT_EQ(mid.z, 0.5f); EXPECT_FLOAT_EQ(mid.value().z, 0.5f);
EXPECT_FLOAT_EQ(mid.w, 0.5f); EXPECT_FLOAT_EQ(mid.value().w, 0.5f);
} }
TEST(UnitTestColorGrouped_More, HsvRoundTrip) TEST(UnitTestColorGrouped_More, HsvRoundTrip)
@@ -197,9 +197,9 @@ TEST(UnitTestColorGrouped_More, HsvRoundTrip)
constexpr Color red = Color::red(); constexpr Color red = Color::red();
const auto hsv = red.to_hsv(); const auto hsv = red.to_hsv();
const Color back = Color::from_hsv(hsv); const Color back = Color::from_hsv(hsv);
EXPECT_NEAR(back.x, 1.0f, 1e-6f); EXPECT_NEAR(back.value().x, 1.0f, 1e-6f);
EXPECT_NEAR(back.y, 0.0f, 1e-6f); EXPECT_NEAR(back.value().y, 0.0f, 1e-6f);
EXPECT_NEAR(back.z, 0.0f, 1e-6f); EXPECT_NEAR(back.value().z, 0.0f, 1e-6f);
} }
TEST(UnitTestColorGrouped_More, ToStringContainsComponents) TEST(UnitTestColorGrouped_More, ToStringContainsComponents)
@@ -230,18 +230,18 @@ TEST(UnitTestColorGrouped_More2, FromHsvCases)
auto check_hue = [&](float h) { auto check_hue = [&](float h) {
SCOPED_TRACE(::testing::Message() << "h=" << h); SCOPED_TRACE(::testing::Message() << "h=" << h);
Color c = Color::from_hsv(h, 1.f, 1.f); Color c = Color::from_hsv(h, 1.f, 1.f);
EXPECT_TRUE(std::isfinite(c.x)); EXPECT_TRUE(std::isfinite(c.value().x));
EXPECT_TRUE(std::isfinite(c.y)); EXPECT_TRUE(std::isfinite(c.value().y));
EXPECT_TRUE(std::isfinite(c.z)); EXPECT_TRUE(std::isfinite(c.value().z));
EXPECT_GE(c.x, -eps); EXPECT_GE(c.value().x, -eps);
EXPECT_LE(c.x, 1.f + eps); EXPECT_LE(c.value().x, 1.f + eps);
EXPECT_GE(c.y, -eps); EXPECT_GE(c.value().y, -eps);
EXPECT_LE(c.y, 1.f + eps); EXPECT_LE(c.value().y, 1.f + eps);
EXPECT_GE(c.z, -eps); EXPECT_GE(c.value().z, -eps);
EXPECT_LE(c.z, 1.f + eps); EXPECT_LE(c.value().z, 1.f + eps);
float mx = std::max({c.x, c.y, c.z}); float mx = std::max({c.value().x, c.value().y, c.value().z});
float mn = std::min({c.x, c.y, c.z}); float mn = std::min({c.value().x, c.value().y, c.value().z});
EXPECT_GE(mx, 0.999f); EXPECT_GE(mx, 0.999f);
EXPECT_LE(mn, 1e-3f + 1e-4f); EXPECT_LE(mn, 1e-3f + 1e-4f);
}; };
@@ -261,13 +261,13 @@ TEST(UnitTestColorGrouped_More2, ToHsvAndSetters)
EXPECT_NEAR(hsv.value, 0.6f, 1e-6f); EXPECT_NEAR(hsv.value, 0.6f, 1e-6f);
c.set_hue(0.0f); c.set_hue(0.0f);
EXPECT_TRUE(std::isfinite(c.x)); EXPECT_TRUE(std::isfinite(c.value().x));
c.set_saturation(0.0f); c.set_saturation(0.0f);
EXPECT_TRUE(std::isfinite(c.y)); EXPECT_TRUE(std::isfinite(c.value().y));
c.set_value(0.5f); c.set_value(0.5f);
EXPECT_TRUE(std::isfinite(c.z)); EXPECT_TRUE(std::isfinite(c.value().z));
} }
TEST(UnitTestColorGrouped_More2, BlendAndStaticColors) TEST(UnitTestColorGrouped_More2, BlendAndStaticColors)
@@ -275,14 +275,14 @@ TEST(UnitTestColorGrouped_More2, BlendAndStaticColors)
constexpr Color a = Color::red(); constexpr Color a = Color::red();
constexpr Color b = Color::blue(); constexpr Color b = Color::blue();
constexpr auto mid = a.blend(b, 0.5f); constexpr auto mid = a.blend(b, 0.5f);
EXPECT_GT(mid.x, 0.f); EXPECT_GT(mid.value().x, 0.f);
EXPECT_GT(mid.z, 0.f); EXPECT_GT(mid.value().z, 0.f);
constexpr auto all_a = a.blend(b, -1.f); constexpr auto all_a = a.blend(b, -1.f);
EXPECT_NEAR(all_a.x, a.x, 1e-6f); EXPECT_NEAR(all_a.value().x, a.value().x, 1e-6f);
constexpr auto all_b = a.blend(b, 2.f); constexpr auto all_b = a.blend(b, 2.f);
EXPECT_NEAR(all_b.z, b.z, 1e-6f); EXPECT_NEAR(all_b.value().z, b.value().z, 1e-6f);
} }
TEST(UnitTestColorGrouped_More2, FormatterUsesToString) TEST(UnitTestColorGrouped_More2, FormatterUsesToString)
@@ -291,3 +291,35 @@ TEST(UnitTestColorGrouped_More2, FormatterUsesToString)
const auto formatted = std::format("{}", c); const auto formatted = std::format("{}", c);
EXPECT_NE(formatted.find("r:10"), std::string::npos); EXPECT_NE(formatted.find("r:10"), std::string::npos);
} }
TEST(UnitTestColorGrouped_More2, FormatterRgb)
{
constexpr Color c = Color::from_rgba(255, 128, 0, 64);
const auto s = std::format("{:rgb}", c);
EXPECT_NE(s.find("r:255"), std::string::npos);
EXPECT_NE(s.find("g:128"), std::string::npos);
EXPECT_NE(s.find("b:0"), std::string::npos);
EXPECT_NE(s.find("a:64"), std::string::npos);
}
TEST(UnitTestColorGrouped_More2, FormatterRgbf)
{
constexpr Color c(0.5f, 0.25f, 1.0f, 0.75f);
const auto s = std::format("{:rgbf}", c);
EXPECT_NE(s.find("r:"), std::string::npos);
EXPECT_NE(s.find("g:"), std::string::npos);
EXPECT_NE(s.find("b:"), std::string::npos);
EXPECT_NE(s.find("a:"), std::string::npos);
// Values should be in [0,1] float range, not 0-255
EXPECT_EQ(s.find("r:127"), std::string::npos);
EXPECT_EQ(s.find("r:255"), std::string::npos);
}
TEST(UnitTestColorGrouped_More2, FormatterHsv)
{
const Color c = Color::red();
const auto s = std::format("{:hsv}", c);
EXPECT_NE(s.find("h:"), std::string::npos);
EXPECT_NE(s.find("s:"), std::string::npos);
EXPECT_NE(s.find("v:"), std::string::npos);
}

471
tests/general/unit_test_epa_comprehensive.cpp Normal file
View File

@@ -0,0 +1,471 @@
//
// Comprehensive EPA tests.
// Covers: all 3 axis directions, multiple depth levels, penetration-vector
// round-trips, depth monotonicity, symmetry, asymmetric sizes, memory
// resource variants, tolerance sensitivity, and iteration bookkeeping.
//
#include <cmath>
#include <gtest/gtest.h>
#include <memory_resource>
#include <omath/collision/epa_algorithm.hpp>
#include <omath/collision/gjk_algorithm.hpp>
#include <omath/engines/source_engine/collider.hpp>
#include <omath/engines/source_engine/mesh.hpp>
using Mesh = omath::source_engine::Mesh;
using Collider = omath::source_engine::MeshCollider;
using Gjk = omath::collision::GjkAlgorithm<Collider>;
using Epa = omath::collision::Epa<Collider>;
using Vec3 = omath::Vector3<float>;
namespace
{
const std::vector<omath::primitives::Vertex<>> k_cube_vbo = {
{ { -1.f, -1.f, -1.f }, {}, {} },
{ { -1.f, -1.f, 1.f }, {}, {} },
{ { -1.f, 1.f, -1.f }, {}, {} },
{ { -1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, -1.f }, {}, {} },
{ { 1.f, -1.f, 1.f }, {}, {} },
{ { 1.f, -1.f, -1.f }, {}, {} },
};
const std::vector<omath::Vector3<std::uint32_t>> k_empty_ebo{};
constexpr Epa::Params k_default_params{ .max_iterations = 64, .tolerance = 1e-4f };
Collider make_cube(const Vec3& origin = {}, const Vec3& scale = { 1, 1, 1 })
{
Mesh m{ k_cube_vbo, k_empty_ebo, scale };
m.set_origin(origin);
return Collider{ m };
}
// Run GJK then EPA; asserts GJK hit and EPA converged.
Epa::Result solve(const Collider& a, const Collider& b,
const Epa::Params& params = k_default_params)
{
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
EXPECT_TRUE(hit) << "GJK must detect collision before EPA can run";
auto result = Epa::solve(a, b, simplex, params);
EXPECT_TRUE(result.has_value()) << "EPA must converge";
return *result;
}
} // namespace
// ---------------------------------------------------------------------------
// Normal direction per axis
// ---------------------------------------------------------------------------
// For two unit cubes (half-extent 1) with B offset by d along an axis:
// depth = 2 - d (distance from origin to nearest face of Minkowski diff)
// normal component along that axis ≈ ±1
TEST(EpaComprehensive, NormalAlongX_Positive)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 }));
EXPECT_NEAR(std::abs(r.normal.x), 1.f, 1e-3f);
EXPECT_NEAR(r.normal.y, 0.f, 1e-3f);
EXPECT_NEAR(r.normal.z, 0.f, 1e-3f);
}
TEST(EpaComprehensive, NormalAlongX_Negative)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ -0.5f, 0, 0 }));
EXPECT_NEAR(std::abs(r.normal.x), 1.f, 1e-3f);
EXPECT_NEAR(r.normal.y, 0.f, 1e-3f);
EXPECT_NEAR(r.normal.z, 0.f, 1e-3f);
}
TEST(EpaComprehensive, NormalAlongY_Positive)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 0.5f, 0 }));
EXPECT_NEAR(r.normal.x, 0.f, 1e-3f);
EXPECT_NEAR(std::abs(r.normal.y), 1.f, 1e-3f);
EXPECT_NEAR(r.normal.z, 0.f, 1e-3f);
}
TEST(EpaComprehensive, NormalAlongY_Negative)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, -0.5f, 0 }));
EXPECT_NEAR(r.normal.x, 0.f, 1e-3f);
EXPECT_NEAR(std::abs(r.normal.y), 1.f, 1e-3f);
EXPECT_NEAR(r.normal.z, 0.f, 1e-3f);
}
TEST(EpaComprehensive, NormalAlongZ_Positive)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 0.5f }));
EXPECT_NEAR(r.normal.x, 0.f, 1e-3f);
EXPECT_NEAR(r.normal.y, 0.f, 1e-3f);
EXPECT_NEAR(std::abs(r.normal.z), 1.f, 1e-3f);
}
TEST(EpaComprehensive, NormalAlongZ_Negative)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, -0.5f }));
EXPECT_NEAR(r.normal.x, 0.f, 1e-3f);
EXPECT_NEAR(r.normal.y, 0.f, 1e-3f);
EXPECT_NEAR(std::abs(r.normal.z), 1.f, 1e-3f);
}
// ---------------------------------------------------------------------------
// Depth correctness (depth = 2 - offset for unit cubes)
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, Depth_ShallowOverlap)
{
// offset 1.9 → depth 0.1
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.9f, 0, 0 }));
EXPECT_NEAR(r.depth, 0.1f, 1e-2f);
}
TEST(EpaComprehensive, Depth_QuarterOverlap)
{
// offset 1.5 → depth 0.5
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.5f, 0, 0 }));
EXPECT_NEAR(r.depth, 0.5f, 1e-2f);
}
TEST(EpaComprehensive, Depth_HalfOverlap)
{
// offset 1.0 → depth 1.0
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.0f, 0, 0 }));
EXPECT_NEAR(r.depth, 1.0f, 1e-2f);
}
TEST(EpaComprehensive, Depth_ThreeQuarterOverlap)
{
// offset 0.5 → depth 1.5
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 }));
EXPECT_NEAR(r.depth, 1.5f, 1e-2f);
}
TEST(EpaComprehensive, Depth_AlongY_HalfOverlap)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 1.0f, 0 }));
EXPECT_NEAR(r.depth, 1.0f, 1e-2f);
}
TEST(EpaComprehensive, Depth_AlongZ_HalfOverlap)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 1.0f }));
EXPECT_NEAR(r.depth, 1.0f, 1e-2f);
}
// ---------------------------------------------------------------------------
// Depth monotonicity — deeper overlap → larger depth
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, DepthMonotonic_AlongX)
{
const float d1 = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.9f, 0, 0 })).depth; // ~0.1
const float d2 = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.5f, 0, 0 })).depth; // ~0.5
const float d3 = solve(make_cube({ 0, 0, 0 }), make_cube({ 1.0f, 0, 0 })).depth; // ~1.0
const float d4 = solve(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 })).depth; // ~1.5
EXPECT_LT(d1, d2);
EXPECT_LT(d2, d3);
EXPECT_LT(d3, d4);
}
// ---------------------------------------------------------------------------
// Normal is a unit vector
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, NormalIsUnit_AlongX)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 }));
EXPECT_NEAR(r.normal.dot(r.normal), 1.f, 1e-5f);
}
TEST(EpaComprehensive, NormalIsUnit_AlongY)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 1.2f, 0 }));
EXPECT_NEAR(r.normal.dot(r.normal), 1.f, 1e-5f);
}
TEST(EpaComprehensive, NormalIsUnit_AlongZ)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 0.8f }));
EXPECT_NEAR(r.normal.dot(r.normal), 1.f, 1e-5f);
}
// ---------------------------------------------------------------------------
// Penetration vector = normal * depth
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, PenetrationVectorLength_EqualsDepth)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 }));
const float pen_len = std::sqrt(r.penetration_vector.dot(r.penetration_vector));
EXPECT_NEAR(pen_len, r.depth, 1e-5f);
}
TEST(EpaComprehensive, PenetrationVectorDirection_ParallelToNormal)
{
const auto r = solve(make_cube({ 0, 0, 0 }), make_cube({ 0, 1.0f, 0 }));
// penetration_vector = normal * depth → cross product must be ~zero
const auto cross = r.penetration_vector.cross(r.normal);
EXPECT_NEAR(cross.dot(cross), 0.f, 1e-8f);
}
// ---------------------------------------------------------------------------
// Round-trip: applying penetration_vector separates the shapes
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, RoundTrip_AlongX)
{
const auto a = make_cube({ 0, 0, 0 });
Mesh mesh_b{ k_cube_vbo, k_empty_ebo };
mesh_b.set_origin({ 0.5f, 0, 0 });
const auto b = Collider{ mesh_b };
const auto r = solve(a, b);
constexpr float margin = 1.f + 1e-3f;
// Move B along the penetration vector; it should separate from A
Mesh mesh_sep{ k_cube_vbo, k_empty_ebo };
mesh_sep.set_origin(mesh_b.get_origin() + r.penetration_vector * margin);
EXPECT_FALSE(Gjk::is_collide(a, Collider{ mesh_sep })) << "Applying pen vector must separate";
// Moving the wrong way must still collide
Mesh mesh_wrong{ k_cube_vbo, k_empty_ebo };
mesh_wrong.set_origin(mesh_b.get_origin() - r.penetration_vector * margin);
EXPECT_TRUE(Gjk::is_collide(a, Collider{ mesh_wrong })) << "Opposite direction must still collide";
}
TEST(EpaComprehensive, RoundTrip_AlongY)
{
const auto a = make_cube({ 0, 0, 0 });
Mesh mesh_b{ k_cube_vbo, k_empty_ebo };
mesh_b.set_origin({ 0, 0.8f, 0 });
const auto b = Collider{ mesh_b };
const auto r = solve(a, b);
constexpr float margin = 1.f + 1e-3f;
Mesh mesh_sep{ k_cube_vbo, k_empty_ebo };
mesh_sep.set_origin(mesh_b.get_origin() + r.penetration_vector * margin);
EXPECT_FALSE(Gjk::is_collide(a, Collider{ mesh_sep }));
Mesh mesh_wrong{ k_cube_vbo, k_empty_ebo };
mesh_wrong.set_origin(mesh_b.get_origin() - r.penetration_vector * margin);
EXPECT_TRUE(Gjk::is_collide(a, Collider{ mesh_wrong }));
}
TEST(EpaComprehensive, RoundTrip_AlongZ)
{
const auto a = make_cube({ 0, 0, 0 });
Mesh mesh_b{ k_cube_vbo, k_empty_ebo };
mesh_b.set_origin({ 0, 0, 1.2f });
const auto b = Collider{ mesh_b };
const auto r = solve(a, b);
constexpr float margin = 1.f + 1e-3f;
Mesh mesh_sep{ k_cube_vbo, k_empty_ebo };
mesh_sep.set_origin(mesh_b.get_origin() + r.penetration_vector * margin);
EXPECT_FALSE(Gjk::is_collide(a, Collider{ mesh_sep }));
}
// ---------------------------------------------------------------------------
// Symmetry — swapping A and B preserves depth
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, Symmetry_DepthIsIndependentOfOrder)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const float depth_ab = solve(a, b).depth;
const float depth_ba = solve(b, a).depth;
EXPECT_NEAR(depth_ab, depth_ba, 1e-2f);
}
TEST(EpaComprehensive, Symmetry_NormalsAreOpposite)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const Vec3 n_ab = solve(a, b).normal;
const Vec3 n_ba = solve(b, a).normal;
// The normals should be anti-parallel: n_ab · n_ba ≈ -1
EXPECT_NEAR(n_ab.dot(n_ba), -1.f, 1e-3f);
}
// ---------------------------------------------------------------------------
// Asymmetric sizes
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, LargeVsSmall_DepthCorrect)
{
// Big (half-ext 2) at origin, small (half-ext 0.5) at (2.0, 0, 0)
// Minkowski diff closest face in X at distance 0.5
const auto r = solve(make_cube({ 0, 0, 0 }, { 2, 2, 2 }), make_cube({ 2.0f, 0, 0 }, { 0.5f, 0.5f, 0.5f }));
EXPECT_NEAR(r.depth, 0.5f, 1e-2f);
EXPECT_NEAR(std::abs(r.normal.x), 1.f, 1e-3f);
}
TEST(EpaComprehensive, LargeVsSmall_RoundTrip)
{
const auto a = make_cube({ 0, 0, 0 }, { 2, 2, 2 });
Mesh mesh_b{ k_cube_vbo, k_empty_ebo, { 0.5f, 0.5f, 0.5f } };
mesh_b.set_origin({ 2.0f, 0, 0 });
const auto b = Collider{ mesh_b };
const auto r = solve(a, b);
constexpr float margin = 1.f + 1e-3f;
Mesh mesh_sep{ k_cube_vbo, k_empty_ebo, { 0.5f, 0.5f, 0.5f } };
mesh_sep.set_origin(mesh_b.get_origin() + r.penetration_vector * margin);
EXPECT_FALSE(Gjk::is_collide(a, Collider{ mesh_sep }));
}
// ---------------------------------------------------------------------------
// Memory resource variants
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, MonotonicBuffer_ConvergesCorrectly)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
constexpr std::size_t k_buf = 32768;
alignas(std::max_align_t) char buf[k_buf];
std::pmr::monotonic_buffer_resource mr{ buf, k_buf, std::pmr::null_memory_resource() };
const auto r = Epa::solve(a, b, simplex, k_default_params, mr);
ASSERT_TRUE(r.has_value());
EXPECT_NEAR(r->depth, 1.5f, 1e-2f);
}
TEST(EpaComprehensive, MonotonicBuffer_MultipleReleaseCycles)
{
// Verify mr.release() correctly resets the buffer across multiple calls
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
constexpr std::size_t k_buf = 32768;
alignas(std::max_align_t) char buf[k_buf];
std::pmr::monotonic_buffer_resource mr{ buf, k_buf, std::pmr::null_memory_resource() };
float first_depth = 0.f;
for (int i = 0; i < 5; ++i)
{
mr.release();
const auto r = Epa::solve(a, b, simplex, k_default_params, mr);
ASSERT_TRUE(r.has_value()) << "solve must converge on iteration " << i;
if (i == 0)
first_depth = r->depth;
else
EXPECT_NEAR(r->depth, first_depth, 1e-6f) << "depth must be deterministic";
}
}
TEST(EpaComprehensive, DefaultResource_ConvergesCorrectly)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 1.0f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
const auto r = Epa::solve(a, b, simplex);
ASSERT_TRUE(r.has_value());
EXPECT_NEAR(r->depth, 1.0f, 1e-2f);
}
// ---------------------------------------------------------------------------
// Tolerance sensitivity
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, TighterTolerance_MoreAccurateDepth)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 1.0f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
const Epa::Params loose{ .max_iterations = 64, .tolerance = 1e-2f };
const Epa::Params tight{ .max_iterations = 64, .tolerance = 1e-5f };
const auto r_loose = Epa::solve(a, b, simplex, loose);
const auto r_tight = Epa::solve(a, b, simplex, tight);
ASSERT_TRUE(r_loose.has_value());
ASSERT_TRUE(r_tight.has_value());
// Tighter tolerance must yield a result at least as accurate
EXPECT_LE(std::abs(r_tight->depth - 1.0f), std::abs(r_loose->depth - 1.0f) + 1e-4f);
}
// ---------------------------------------------------------------------------
// Bookkeeping fields
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, Bookkeeping_IterationsInBounds)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const auto r = solve(a, b);
EXPECT_GT(r.iterations, 0);
EXPECT_LE(r.iterations, k_default_params.max_iterations);
}
TEST(EpaComprehensive, Bookkeeping_FacesAndVerticesGrow)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const auto r = solve(a, b);
// Started with a tetrahedron (4 faces, 4 vertices); EPA must have expanded it
EXPECT_GE(r.num_faces, 4);
EXPECT_GE(r.num_vertices, 4);
}
TEST(EpaComprehensive, Bookkeeping_MaxIterationsRespected)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.5f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
constexpr Epa::Params tight{ .max_iterations = 3, .tolerance = 1e-10f };
const auto r = Epa::solve(a, b, simplex, tight);
// Must return something (fallback best-face path) and respect the cap
if (r.has_value())
EXPECT_LE(r->iterations, tight.max_iterations);
}
// ---------------------------------------------------------------------------
// Determinism
// ---------------------------------------------------------------------------
TEST(EpaComprehensive, Deterministic_SameResultOnRepeatedCalls)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 0.7f, 0, 0 });
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(a, b);
ASSERT_TRUE(hit);
const auto first = Epa::solve(a, b, simplex);
ASSERT_TRUE(first.has_value());
for (int i = 0; i < 5; ++i)
{
const auto r = Epa::solve(a, b, simplex);
ASSERT_TRUE(r.has_value());
EXPECT_NEAR(r->depth, first->depth, 1e-6f);
EXPECT_NEAR(r->normal.x, first->normal.x, 1e-6f);
EXPECT_NEAR(r->normal.y, first->normal.y, 1e-6f);
EXPECT_NEAR(r->normal.z, first->normal.z, 1e-6f);
}
}

277
tests/general/unit_test_gjk_comprehensive.cpp Normal file
View File

@@ -0,0 +1,277 @@
//
// Comprehensive GJK tests.
// Covers: all 6 axis directions, diagonal cases, boundary touching,
// asymmetric sizes, nesting, symmetry, simplex info, far separation.
//
#include <gtest/gtest.h>
#include <omath/collision/gjk_algorithm.hpp>
#include <omath/engines/source_engine/collider.hpp>
#include <omath/engines/source_engine/mesh.hpp>
using Mesh = omath::source_engine::Mesh;
using Collider = omath::source_engine::MeshCollider;
using Gjk = omath::collision::GjkAlgorithm<Collider>;
using Vec3 = omath::Vector3<float>;
namespace
{
// Unit cube [-1, 1]^3 in local space.
const std::vector<omath::primitives::Vertex<>> k_cube_vbo = {
{ { -1.f, -1.f, -1.f }, {}, {} },
{ { -1.f, -1.f, 1.f }, {}, {} },
{ { -1.f, 1.f, -1.f }, {}, {} },
{ { -1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, 1.f }, {}, {} },
{ { 1.f, 1.f, -1.f }, {}, {} },
{ { 1.f, -1.f, 1.f }, {}, {} },
{ { 1.f, -1.f, -1.f }, {}, {} },
};
const std::vector<omath::Vector3<std::uint32_t>> k_empty_ebo{};
Collider make_cube(const Vec3& origin = {}, const Vec3& scale = { 1, 1, 1 })
{
Mesh m{ k_cube_vbo, k_empty_ebo, scale };
m.set_origin(origin);
return Collider{ m };
}
} // namespace
// ---------------------------------------------------------------------------
// Separation — expect false
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, Separated_AlongPosX)
{
// A extends to x=1, B starts at x=1.1 → clear gap
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 2.1f, 0, 0 })));
}
TEST(GjkComprehensive, Separated_AlongNegX)
{
// B to the left of A
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ -2.1f, 0, 0 })));
}
TEST(GjkComprehensive, Separated_AlongPosY)
{
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, 2.1f, 0 })));
}
TEST(GjkComprehensive, Separated_AlongNegY)
{
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, -2.1f, 0 })));
}
TEST(GjkComprehensive, Separated_AlongPosZ)
{
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 2.1f })));
}
TEST(GjkComprehensive, Separated_AlongNegZ)
{
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, -2.1f })));
}
TEST(GjkComprehensive, Separated_AlongDiagonal)
{
// All components exceed 2.0 — no overlap on any axis
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 2.1f, 2.1f, 2.1f })));
}
TEST(GjkComprehensive, Separated_LargeDistance)
{
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 100.f, 0, 0 })));
}
TEST(GjkComprehensive, Separated_AsymmetricSizes)
{
// Big (scale 2, half-ext 2), small (scale 0.5, half-ext 0.5) at 2.6 → gap of 0.1
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }, { 2, 2, 2 }), make_cube({ 2.6f, 0, 0 }, { 0.5f, 0.5f, 0.5f })));
}
// ---------------------------------------------------------------------------
// Overlap — expect true
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, Overlapping_AlongPosX)
{
// B offset 1.5 → overlap depth 0.5 in X
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 1.5f, 0, 0 })));
}
TEST(GjkComprehensive, Overlapping_AlongNegX)
{
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ -1.5f, 0, 0 })));
}
TEST(GjkComprehensive, Overlapping_AlongPosZ)
{
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 1.5f })));
}
TEST(GjkComprehensive, Overlapping_AlongNegZ)
{
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, -1.5f })));
}
TEST(GjkComprehensive, Overlapping_AlongDiagonalXY)
{
// Minkowski sum extends ±2 on each axis; offset (1,1,0) is inside
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 1.f, 1.f, 0.f })));
}
TEST(GjkComprehensive, Overlapping_AlongDiagonalXYZ)
{
// All three axes overlap: (1,1,1) is inside the Minkowski sum
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 1.f, 1.f, 1.f })));
}
TEST(GjkComprehensive, FullyNested_SmallInsideBig)
{
// Small cube (half-ext 0.5) fully inside big cube (half-ext 2)
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }, { 2, 2, 2 }), make_cube({ 0, 0, 0 }, { 0.5f, 0.5f, 0.5f })));
}
TEST(GjkComprehensive, FullyNested_OffCenter)
{
// Small at (0.5, 0, 0) still fully inside big (half-ext 2)
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }, { 2, 2, 2 }), make_cube({ 0.5f, 0, 0 }, { 0.5f, 0.5f, 0.5f })));
}
TEST(GjkComprehensive, Overlapping_AsymmetricSizes)
{
// Big (scale 2, half-ext 2) and small (scale 0.5, half-ext 0.5) at 2.0 → overlap 0.5 in X
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }, { 2, 2, 2 }), make_cube({ 2.0f, 0, 0 }, { 0.5f, 0.5f, 0.5f })));
}
// ---------------------------------------------------------------------------
// Boundary cases
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, BoundaryCase_JustColliding)
{
// B at 1.999 — 0.001 overlap in X
EXPECT_TRUE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 1.999f, 0, 0 })));
}
TEST(GjkComprehensive, BoundaryCase_JustSeparated)
{
// B at 2.001 — 0.001 gap in X
EXPECT_FALSE(Gjk::is_collide(make_cube({ 0, 0, 0 }), make_cube({ 2.001f, 0, 0 })));
}
// ---------------------------------------------------------------------------
// Symmetry
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, Symmetry_WhenColliding)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 1.5f, 0, 0 });
EXPECT_EQ(Gjk::is_collide(a, b), Gjk::is_collide(b, a));
}
TEST(GjkComprehensive, Symmetry_WhenSeparated)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 2.1f, 0.5f, 0 });
EXPECT_EQ(Gjk::is_collide(a, b), Gjk::is_collide(b, a));
}
TEST(GjkComprehensive, Symmetry_DiagonalSeparation)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 1.5f, 1.5f, 1.5f });
EXPECT_EQ(Gjk::is_collide(a, b), Gjk::is_collide(b, a));
}
// ---------------------------------------------------------------------------
// Simplex info
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, SimplexInfo_HitProducesSimplex4)
{
// On collision the simplex must be a full tetrahedron (4 points)
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(make_cube({ 0, 0, 0 }), make_cube({ 0.5f, 0, 0 }));
EXPECT_TRUE(hit);
EXPECT_EQ(simplex.size(), 4u);
}
TEST(GjkComprehensive, SimplexInfo_MissProducesLessThan4)
{
// On non-collision the simplex can never be a full tetrahedron
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(make_cube({ 0, 0, 0 }), make_cube({ 2.1f, 0, 0 }));
EXPECT_FALSE(hit);
EXPECT_LT(simplex.size(), 4u);
}
TEST(GjkComprehensive, SimplexInfo_HitAlongY)
{
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(make_cube({ 0, 0, 0 }), make_cube({ 0, 1.5f, 0 }));
EXPECT_TRUE(hit);
EXPECT_EQ(simplex.size(), 4u);
}
TEST(GjkComprehensive, SimplexInfo_HitAlongZ)
{
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(make_cube({ 0, 0, 0 }), make_cube({ 0, 0, 1.5f }));
EXPECT_TRUE(hit);
EXPECT_EQ(simplex.size(), 4u);
}
TEST(GjkComprehensive, SimplexInfo_MissAlongDiagonal)
{
const auto [hit, simplex] = Gjk::is_collide_with_simplex_info(make_cube({ 0, 0, 0 }), make_cube({ 2.1f, 2.1f, 2.1f }));
EXPECT_FALSE(hit);
EXPECT_LT(simplex.size(), 4u);
}
// ---------------------------------------------------------------------------
// Non-trivial geometry — tetrahedron shaped colliders
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, TetrahedronShapes_Overlapping)
{
// A rough tetrahedron mesh; two of them close enough to overlap
const std::vector<omath::primitives::Vertex<>> tet_vbo = {
{ { 0.f, 1.f, 0.f }, {}, {} },
{ { -1.f, -1.f, 1.f }, {}, {} },
{ { 1.f, -1.f, 1.f }, {}, {} },
{ { 0.f, -1.f, -1.f }, {}, {} },
};
Mesh m_a{ tet_vbo, k_empty_ebo };
Mesh m_b{ tet_vbo, k_empty_ebo };
m_b.set_origin({ 0.5f, 0.f, 0.f });
EXPECT_TRUE(Gjk::is_collide(Collider{ m_a }, Collider{ m_b }));
}
TEST(GjkComprehensive, TetrahedronShapes_Separated)
{
const std::vector<omath::primitives::Vertex<>> tet_vbo = {
{ { 0.f, 1.f, 0.f }, {}, {} },
{ { -1.f, -1.f, 1.f }, {}, {} },
{ { 1.f, -1.f, 1.f }, {}, {} },
{ { 0.f, -1.f, -1.f }, {}, {} },
};
Mesh m_a{ tet_vbo, k_empty_ebo };
Mesh m_b{ tet_vbo, k_empty_ebo };
m_b.set_origin({ 3.f, 0.f, 0.f });
EXPECT_FALSE(Gjk::is_collide(Collider{ m_a }, Collider{ m_b }));
}
// ---------------------------------------------------------------------------
// Determinism
// ---------------------------------------------------------------------------
TEST(GjkComprehensive, Deterministic_SameResultOnRepeatedCalls)
{
const auto a = make_cube({ 0, 0, 0 });
const auto b = make_cube({ 1.2f, 0.3f, 0.1f });
const bool first = Gjk::is_collide(a, b);
for (int i = 0; i < 10; ++i)
EXPECT_EQ(Gjk::is_collide(a, b), first);
}

229
tests/general/unit_test_navigation_mesh.cpp
View File

@@ -7,19 +7,18 @@ using namespace omath::pathfinding;
TEST(NavigationMeshTests, SerializeDeserializeRoundTrip) TEST(NavigationMeshTests, SerializeDeserializeRoundTrip)
{ {
NavigationMesh nav; NavigationMesh nav;
Vector3<float> a{0.f,0.f,0.f}; Vector3<float> a{0.f, 0.f, 0.f};
Vector3<float> b{1.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> 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(b, std::vector<Vector3<float>>{a});
nav.m_vertex_map.emplace(c, 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; NavigationMesh nav2;
EXPECT_NO_THROW(nav2.deserialize(data)); EXPECT_NO_THROW(nav2.deserialize(data));
// verify neighbors preserved
EXPECT_EQ(nav2.m_vertex_map.size(), nav.m_vertex_map.size()); EXPECT_EQ(nav2.m_vertex_map.size(), nav.m_vertex_map.size());
EXPECT_EQ(nav2.get_neighbors(a).size(), 2u); EXPECT_EQ(nav2.get_neighbors(a).size(), 2u);
} }
@@ -27,7 +26,223 @@ TEST(NavigationMeshTests, SerializeDeserializeRoundTrip)
TEST(NavigationMeshTests, GetClosestVertexWhenEmpty) TEST(NavigationMeshTests, GetClosestVertexWhenEmpty)
{ {
const NavigationMesh nav; 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); const auto res = nav.get_closest_vertex(p);
EXPECT_FALSE(res.has_value()); 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());
}

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//
// 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

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//
// Created by vlad on 3/1/2026.
//
#include <omath/linear_algebra/quaternion.hpp>
#include <cmath>
#include <gtest/gtest.h>
#include <numbers>
using namespace omath;
static constexpr float kEps = 1e-5f;
// ── Helpers ──────────────────────────────────────────────────────────────────
static void expect_quat_near(const Quaternion<float>& a, const Quaternion<float>& b, float eps = kEps)
{
EXPECT_NEAR(a.x, b.x, eps);
EXPECT_NEAR(a.y, b.y, eps);
EXPECT_NEAR(a.z, b.z, eps);
EXPECT_NEAR(a.w, b.w, eps);
}
static void expect_vec3_near(const Vector3<float>& a, const Vector3<float>& b, float eps = kEps)
{
EXPECT_NEAR(a.x, b.x, eps);
EXPECT_NEAR(a.y, b.y, eps);
EXPECT_NEAR(a.z, b.z, eps);
}
// ── Constructors ─────────────────────────────────────────────────────────────
TEST(Quaternion, DefaultConstructorIsIdentity)
{
constexpr Quaternion<float> q;
EXPECT_FLOAT_EQ(q.x, 0.f);
EXPECT_FLOAT_EQ(q.y, 0.f);
EXPECT_FLOAT_EQ(q.z, 0.f);
EXPECT_FLOAT_EQ(q.w, 1.f);
}
TEST(Quaternion, ValueConstructor)
{
constexpr Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
EXPECT_FLOAT_EQ(q.x, 1.f);
EXPECT_FLOAT_EQ(q.y, 2.f);
EXPECT_FLOAT_EQ(q.z, 3.f);
EXPECT_FLOAT_EQ(q.w, 4.f);
}
TEST(Quaternion, DoubleInstantiation)
{
constexpr Quaternion<double> q{0.0, 0.0, 0.0, 1.0};
EXPECT_DOUBLE_EQ(q.w, 1.0);
}
// ── Equality ─────────────────────────────────────────────────────────────────
TEST(Quaternion, EqualityOperators)
{
constexpr Quaternion<float> a{1.f, 2.f, 3.f, 4.f};
constexpr Quaternion<float> b{1.f, 2.f, 3.f, 4.f};
constexpr Quaternion<float> c{1.f, 2.f, 3.f, 5.f};
EXPECT_TRUE(a == b);
EXPECT_FALSE(a == c);
EXPECT_FALSE(a != b);
EXPECT_TRUE(a != c);
}
// ── Arithmetic ───────────────────────────────────────────────────────────────
TEST(Quaternion, ScalarMultiply)
{
constexpr Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
constexpr auto r = q * 2.f;
EXPECT_FLOAT_EQ(r.x, 2.f);
EXPECT_FLOAT_EQ(r.y, 4.f);
EXPECT_FLOAT_EQ(r.z, 6.f);
EXPECT_FLOAT_EQ(r.w, 8.f);
}
TEST(Quaternion, ScalarMultiplyAssign)
{
Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
q *= 3.f;
EXPECT_FLOAT_EQ(q.x, 3.f);
EXPECT_FLOAT_EQ(q.y, 6.f);
EXPECT_FLOAT_EQ(q.z, 9.f);
EXPECT_FLOAT_EQ(q.w, 12.f);
}
TEST(Quaternion, Addition)
{
constexpr Quaternion<float> a{1.f, 2.f, 3.f, 4.f};
constexpr Quaternion<float> b{4.f, 3.f, 2.f, 1.f};
constexpr auto r = a + b;
EXPECT_FLOAT_EQ(r.x, 5.f);
EXPECT_FLOAT_EQ(r.y, 5.f);
EXPECT_FLOAT_EQ(r.z, 5.f);
EXPECT_FLOAT_EQ(r.w, 5.f);
}
TEST(Quaternion, AdditionAssign)
{
Quaternion<float> a{1.f, 0.f, 0.f, 0.f};
const Quaternion<float> b{0.f, 1.f, 0.f, 0.f};
a += b;
EXPECT_FLOAT_EQ(a.x, 1.f);
EXPECT_FLOAT_EQ(a.y, 1.f);
}
TEST(Quaternion, UnaryNegation)
{
constexpr Quaternion<float> q{1.f, -2.f, 3.f, -4.f};
constexpr auto r = -q;
EXPECT_FLOAT_EQ(r.x, -1.f);
EXPECT_FLOAT_EQ(r.y, 2.f);
EXPECT_FLOAT_EQ(r.z, -3.f);
EXPECT_FLOAT_EQ(r.w, 4.f);
}
// ── Hamilton product ──────────────────────────────────────────────────────────
TEST(Quaternion, MultiplyByIdentityIsNoop)
{
constexpr Quaternion<float> identity;
constexpr Quaternion<float> q{0.5f, 0.5f, 0.5f, 0.5f};
expect_quat_near(q * identity, q);
expect_quat_near(identity * q, q);
}
TEST(Quaternion, MultiplyAssign)
{
constexpr Quaternion<float> identity;
Quaternion<float> q{0.5f, 0.5f, 0.5f, 0.5f};
q *= identity;
expect_quat_near(q, {0.5f, 0.5f, 0.5f, 0.5f});
}
TEST(Quaternion, MultiplyKnownResult)
{
// i * j = k → (1,0,0,0) * (0,1,0,0) = (0,0,1,0)
constexpr Quaternion<float> i{1.f, 0.f, 0.f, 0.f};
constexpr Quaternion<float> j{0.f, 1.f, 0.f, 0.f};
constexpr auto k = i * j;
EXPECT_FLOAT_EQ(k.x, 0.f);
EXPECT_FLOAT_EQ(k.y, 0.f);
EXPECT_FLOAT_EQ(k.z, 1.f);
EXPECT_FLOAT_EQ(k.w, 0.f);
}
TEST(Quaternion, MultiplyByInverseGivesIdentity)
{
const Quaternion<float> q = Quaternion<float>::from_axis_angle({0.f, 0.f, 1.f},
std::numbers::pi_v<float> / 3.f);
const auto result = q * q.inverse();
expect_quat_near(result, Quaternion<float>{});
}
// ── Conjugate ────────────────────────────────────────────────────────────────
TEST(Quaternion, Conjugate)
{
constexpr Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
constexpr auto c = q.conjugate();
EXPECT_FLOAT_EQ(c.x, -1.f);
EXPECT_FLOAT_EQ(c.y, -2.f);
EXPECT_FLOAT_EQ(c.z, -3.f);
EXPECT_FLOAT_EQ(c.w, 4.f);
}
TEST(Quaternion, ConjugateOfIdentityIsIdentity)
{
constexpr Quaternion<float> id;
constexpr auto c = id.conjugate();
EXPECT_FLOAT_EQ(c.x, 0.f);
EXPECT_FLOAT_EQ(c.y, 0.f);
EXPECT_FLOAT_EQ(c.z, 0.f);
EXPECT_FLOAT_EQ(c.w, 1.f);
}
// ── Dot / length ─────────────────────────────────────────────────────────────
TEST(Quaternion, Dot)
{
constexpr Quaternion<float> a{1.f, 0.f, 0.f, 0.f};
constexpr Quaternion<float> b{0.f, 1.f, 0.f, 0.f};
EXPECT_FLOAT_EQ(a.dot(b), 0.f);
EXPECT_FLOAT_EQ(a.dot(a), 1.f);
}
TEST(Quaternion, LengthSqrIdentity)
{
constexpr Quaternion<float> id;
EXPECT_FLOAT_EQ(id.length_sqr(), 1.f);
}
TEST(Quaternion, LengthSqrGeneral)
{
constexpr Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
EXPECT_FLOAT_EQ(q.length_sqr(), 30.f);
}
TEST(Quaternion, LengthIdentity)
{
const Quaternion<float> id;
EXPECT_NEAR(id.length(), 1.f, kEps);
}
TEST(Quaternion, Normalized)
{
const Quaternion<float> q{1.f, 1.f, 1.f, 1.f};
const auto n = q.normalized();
EXPECT_NEAR(n.length(), 1.f, kEps);
EXPECT_NEAR(n.x, 0.5f, kEps);
EXPECT_NEAR(n.y, 0.5f, kEps);
EXPECT_NEAR(n.z, 0.5f, kEps);
EXPECT_NEAR(n.w, 0.5f, kEps);
}
TEST(Quaternion, NormalizedOfZeroLengthReturnsSelf)
{
// length_sqr = 0 would be UB, but zero-vector part + zero w is degenerate;
// we just verify the guard branch (divides by zero) doesn't crash by
// keeping length > 0 via the default constructor path.
const Quaternion<float> unit;
const auto n = unit.normalized();
expect_quat_near(n, unit);
}
// ── Inverse ───────────────────────────────────────────────────────────────────
TEST(Quaternion, InverseOfUnitIsConjugate)
{
const Quaternion<float> q = Quaternion<float>::from_axis_angle({1.f, 0.f, 0.f},
std::numbers::pi_v<float> / 4.f);
const auto inv = q.inverse();
const auto conj = q.conjugate();
expect_quat_near(inv, conj);
}
// ── from_axis_angle ──────────────────────────────────────────────────────────
TEST(Quaternion, FromAxisAngleZeroAngleIsIdentity)
{
const auto q = Quaternion<float>::from_axis_angle({1.f, 0.f, 0.f}, 0.f);
EXPECT_NEAR(q.x, 0.f, kEps);
EXPECT_NEAR(q.y, 0.f, kEps);
EXPECT_NEAR(q.z, 0.f, kEps);
EXPECT_NEAR(q.w, 1.f, kEps);
}
TEST(Quaternion, FromAxisAngle90DegZ)
{
const float half_pi = std::numbers::pi_v<float> / 2.f;
const auto q = Quaternion<float>::from_axis_angle({0.f, 0.f, 1.f}, half_pi);
const float s = std::sin(half_pi / 2.f);
const float c = std::cos(half_pi / 2.f);
EXPECT_NEAR(q.x, 0.f, kEps);
EXPECT_NEAR(q.y, 0.f, kEps);
EXPECT_NEAR(q.z, s, kEps);
EXPECT_NEAR(q.w, c, kEps);
}
// ── rotate ───────────────────────────────────────────────────────────────────
TEST(Quaternion, RotateByIdentityIsNoop)
{
constexpr Quaternion<float> id;
constexpr Vector3<float> v{1.f, 2.f, 3.f};
const auto r = id.rotate(v);
expect_vec3_near(r, v);
}
TEST(Quaternion, Rotate90DegAroundZ)
{
// Rotating (1,0,0) by 90° around Z should give (0,1,0)
const auto q = Quaternion<float>::from_axis_angle({0.f, 0.f, 1.f}, std::numbers::pi_v<float> / 2.f);
const auto r = q.rotate({1.f, 0.f, 0.f});
expect_vec3_near(r, {0.f, 1.f, 0.f});
}
TEST(Quaternion, Rotate180DegAroundY)
{
// Rotating (1,0,0) by 180° around Y should give (-1,0,0)
const auto q = Quaternion<float>::from_axis_angle({0.f, 1.f, 0.f}, std::numbers::pi_v<float>);
const auto r = q.rotate({1.f, 0.f, 0.f});
expect_vec3_near(r, {-1.f, 0.f, 0.f});
}
TEST(Quaternion, Rotate90DegAroundX)
{
// Rotating (0,1,0) by 90° around X should give (0,0,1)
const auto q = Quaternion<float>::from_axis_angle({1.f, 0.f, 0.f}, std::numbers::pi_v<float> / 2.f);
const auto r = q.rotate({0.f, 1.f, 0.f});
expect_vec3_near(r, {0.f, 0.f, 1.f});
}
// ── to_rotation_matrix3 ───────────────────────────────────────────────────────
TEST(Quaternion, RotationMatrix3FromIdentityIsIdentityMatrix)
{
constexpr Quaternion<float> id;
constexpr auto m = id.to_rotation_matrix3();
for (size_t i = 0; i < 3; ++i)
for (size_t j = 0; j < 3; ++j)
EXPECT_NEAR(m.at(i, j), i == j ? 1.f : 0.f, kEps);
}
TEST(Quaternion, RotationMatrix3From90DegZ)
{
// Expected: | 0 -1 0 |
// | 1 0 0 |
// | 0 0 1 |
const auto q = Quaternion<float>::from_axis_angle({0.f, 0.f, 1.f}, std::numbers::pi_v<float> / 2.f);
const auto m = q.to_rotation_matrix3();
EXPECT_NEAR(m.at(0, 0), 0.f, kEps);
EXPECT_NEAR(m.at(0, 1), -1.f, kEps);
EXPECT_NEAR(m.at(0, 2), 0.f, kEps);
EXPECT_NEAR(m.at(1, 0), 1.f, kEps);
EXPECT_NEAR(m.at(1, 1), 0.f, kEps);
EXPECT_NEAR(m.at(1, 2), 0.f, kEps);
EXPECT_NEAR(m.at(2, 0), 0.f, kEps);
EXPECT_NEAR(m.at(2, 1), 0.f, kEps);
EXPECT_NEAR(m.at(2, 2), 1.f, kEps);
}
TEST(Quaternion, RotationMatrix3ConsistentWithRotate)
{
// Matrix-vector multiply must agree with the rotate() method
const auto q = Quaternion<float>::from_axis_angle({1.f, 1.f, 0.f}, std::numbers::pi_v<float> / 3.f);
const Vector3<float> v{2.f, -1.f, 0.5f};
const auto rotated = q.rotate(v);
const auto m = q.to_rotation_matrix3();
// manual mat-vec multiply (row-major)
const float rx = m.at(0, 0) * v.x + m.at(0, 1) * v.y + m.at(0, 2) * v.z;
const float ry = m.at(1, 0) * v.x + m.at(1, 1) * v.y + m.at(1, 2) * v.z;
const float rz = m.at(2, 0) * v.x + m.at(2, 1) * v.y + m.at(2, 2) * v.z;
EXPECT_NEAR(rotated.x, rx, kEps);
EXPECT_NEAR(rotated.y, ry, kEps);
EXPECT_NEAR(rotated.z, rz, kEps);
}
// ── to_rotation_matrix4 ───────────────────────────────────────────────────────
TEST(Quaternion, RotationMatrix4FromIdentityIsIdentityMatrix)
{
constexpr Quaternion<float> id;
constexpr auto m = id.to_rotation_matrix4();
for (size_t i = 0; i < 4; ++i)
for (size_t j = 0; j < 4; ++j)
EXPECT_NEAR(m.at(i, j), i == j ? 1.f : 0.f, kEps);
}
TEST(Quaternion, RotationMatrix4HomogeneousRowAndColumn)
{
const auto q = Quaternion<float>::from_axis_angle({1.f, 0.f, 0.f}, std::numbers::pi_v<float> / 5.f);
const auto m = q.to_rotation_matrix4();
// Last row and last column must be (0,0,0,1)
for (size_t i = 0; i < 3; ++i)
{
EXPECT_NEAR(m.at(3, i), 0.f, kEps);
EXPECT_NEAR(m.at(i, 3), 0.f, kEps);
}
EXPECT_NEAR(m.at(3, 3), 1.f, kEps);
}
TEST(Quaternion, RotationMatrix4Upper3x3MatchesMatrix3)
{
const auto q = Quaternion<float>::from_axis_angle({0.f, 1.f, 0.f}, std::numbers::pi_v<float> / 7.f);
const auto m3 = q.to_rotation_matrix3();
const auto m4 = q.to_rotation_matrix4();
for (size_t i = 0; i < 3; ++i)
for (size_t j = 0; j < 3; ++j)
EXPECT_NEAR(m4.at(i, j), m3.at(i, j), kEps);
}
// ── as_array ──────────────────────────────────────────────────────────────────
TEST(Quaternion, AsArray)
{
constexpr Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
constexpr auto arr = q.as_array();
EXPECT_FLOAT_EQ(arr[0], 1.f);
EXPECT_FLOAT_EQ(arr[1], 2.f);
EXPECT_FLOAT_EQ(arr[2], 3.f);
EXPECT_FLOAT_EQ(arr[3], 4.f);
}
// ── std::formatter ────────────────────────────────────────────────────────────
TEST(Quaternion, Formatter)
{
const Quaternion<float> q{1.f, 2.f, 3.f, 4.f};
const auto s = std::format("{}", q);
EXPECT_EQ(s, "[1, 2, 3, 4]");
}

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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

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-- 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

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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

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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

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//
// 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"); }

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//
// 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"); }

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//
// 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"); }

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//
// 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"); }

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//
// 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"); }

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

18
vcpkg.json
View File

@@ -17,7 +17,7 @@
], ],
"features": { "features": {
"avx2": { "avx2": {
"description": "Omath will use AVX2 to boost performance", "description": "omath will use AVX2 to boost performance",
"supports": "!arm" "supports": "!arm"
}, },
"benchmark": { "benchmark": {
@@ -35,7 +35,7 @@
] ]
}, },
"imgui": { "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": [ "dependencies": [
"imgui" "imgui"
] ]
@@ -45,6 +45,20 @@
"dependencies": [ "dependencies": [
"gtest" "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)"
} }
} }
} }