docs: update ray sphere intersection brief

tests: test for ray, reflect, refract and faceforward
docs for new ray functions
2026-02-17 03:39:05 +00:00 · 2024-03-22 23:49:05 +03:00 · 2024-03-22 23:44:43 +03:00 · 2024-03-22 22:30:22 +03:00 · 2024-03-22 21:59:10 +03:00 · 2024-03-22 10:42:29 +03:00
160 changed files with 4523 additions and 602 deletions
--- a/.github/workflows/ci.yml
+++ b/.github/workflows/ci.yml
@@ -0,0 +1,236 @@
 name: CI
 on:
  push:
    branches: [ "master" ]
  pull_request:
    branches: [ "master" ]
 jobs:
  build_autotools:
    name: Autotools / ${{ matrix.os }}
    runs-on: ${{ matrix.os }}
    strategy:
      fail-fast: false
      matrix:
        os: [macos-12, macos-14, ubuntu-22.04]
    steps:
    - uses: actions/checkout@v4
    - name: Install Autotools
      if: runner.os == 'macOS'
      run: brew upgrade && brew install autoconf automake libtool
    - name: Generate Autotools
      run: ./autogen.sh
    - name: Configure Autotools
      run: ./configure
    - name: Build
      run: make
    - name: Test
      run: make check
  build_cmake_ios:
    name: CMake / iOS
    runs-on: macos-14
    steps:
    - uses: actions/checkout@v4
    - name: Configure CMake
      run: |
        cmake \
          -B build \
          -GXcode \
          -DCMAKE_SYSTEM_NAME=iOS \
          -DCMAKE_BUILD_TYPE=Release \
          -DCMAKE_XCODE_ATTRIBUTE_CODE_SIGNING_ALLOWED=NO \
          -DCGLM_STATIC=ON \
          -DCGLM_USE_TEST=ON
    - name: Build
      run: cmake --build build
  build_cmake_macos:
    name: CMake / ${{ matrix.os }}
    runs-on: ${{ matrix.os }}
    strategy:
      fail-fast: false
      matrix:
        os: [macos-12, macos-14]
    steps:
    - uses: actions/checkout@v4
    - name: Install Ninja
      if: runner.os == 'macOS'
      run: brew upgrade && brew install ninja
    - name: Configure CMake
      run: |
        cmake \
          -B build \
          -GNinja \
          -DCMAKE_BUILD_TYPE=Release \
          -DCGLM_STATIC=ON \
          -DCGLM_USE_TEST=ON
    - name: Build
      run: cmake --build build
    - name: Test
      working-directory: build
      run: ./tests
  build_cmake_ubuntu:
    name: CMake / ${{ matrix.target.os }} / ${{ matrix.target.cc }}
    runs-on: ${{ matrix.target.os }}
    strategy:
      fail-fast: false
      matrix:
        target:
          - { os: ubuntu-20.04, cc: gcc-11 }
          - { os: ubuntu-22.04, cc: gcc-12 }
          - { os: ubuntu-22.04, cc: gcc-13 }
          - { os: ubuntu-20.04, cc: clang-12 }
          - { os: ubuntu-22.04, cc: clang-15 }
    steps:
    - uses: actions/checkout@v4
    - name: Install Compiler and Ninja
      run: |
        sudo apt-get update -y
        sudo apt-get install -y ${{ matrix.target.cc }} ninja-build
    - name: Configure CMake
      run: |
        cmake \
          -B build \
          -GNinja \
          -DCMAKE_C_COMPILER=${{ matrix.target.cc }} \
          -DCMAKE_BUILD_TYPE=Release \
          -DCGLM_STATIC=ON \
          -DCGLM_USE_TEST=ON
    - name: Build
      run: cmake --build build
    - name: Test
      working-directory: build
      run: ./tests
  build_cmake_windows:
    name: CMake / ${{ matrix.platform.name }}
    runs-on: windows-2022
    strategy:
      fail-fast: false
      matrix:
        platform:
        - { name: Windows (x64),          flags: -A x64 }
        - { name: Windows (x86),          flags: -A Win32 }
        - { name: Windows (clang-cl x64), flags: -T ClangCL -A x64 }
        - { name: Windows (clang-cl x86), flags: -T ClangCL -A Win32 }
        - { name: Windows (ARM),          flags: -A ARM, skip_tests: true, skip_build: true } # This fails to build.
        - { name: Windows (ARM64),        flags: -A ARM64, skip_tests: true }
        - { name: UWP (ARM64),            flags: -A ARM64, -DCMAKE_SYSTEM_NAME=WindowsStore -DCMAKE_SYSTEM_VERSION="10.0", skip_tests: true }
        - { name: UWP (x64),              flags: -A x64 -DCMAKE_SYSTEM_NAME=WindowsStore -DCMAKE_SYSTEM_VERSION="10.0", skip_tests: true }
    steps:
    - uses: actions/checkout@v4
    - name: Configure CMake
      run: cmake -B build `
          -DCGLM_STATIC=ON `
          -DCGLM_USE_TEST=ON `
          ${{ matrix.platform.flags }}
    - name: Build
      if: ${{ !matrix.platform.skip_build }}
      run: cmake --build build --config Release --parallel
    - name: Test
      if: ${{ !matrix.platform.skip_tests }}
      working-directory: build
      run: .\Release\tests.exe
  build_documentation:
    name: Documentation
    runs-on: ubuntu-22.04
    steps:
    - uses: actions/checkout@v4
    - uses: actions/setup-python@v5
      with:
        python-version: '3.12'
    - name: Install Dependencies
      working-directory: docs
      run: python3 -m pip install -r requirements.txt
    - name: Build
      working-directory: docs
      run: sphinx-build -W --keep-going source build
  build_meson:
    name: Meson / ${{ matrix.os }}
    runs-on: ${{ matrix.os }}
    strategy:
      fail-fast: false
      matrix:
        os: [macos-14, ubuntu-22.04]
    steps:
    - uses: actions/checkout@v4
    - uses: actions/setup-python@v5
      with:
        python-version: '3.12'
        cache: 'pip'
    - name: Install meson
      run: python3 -m pip install meson ninja
    - name: Build
      run: meson setup build -Dbuildtype=release --default-library=static -Dbuild_tests=true
    - name: Test
      run: meson test -C build
  build_msbuild:
    name: MSBuild / Windows
    runs-on: windows-2022
    # This has no test yet.
    # It could also try building for ARM, ARM64, ARM64EC, but those fail currently.
    steps:
    - uses: actions/checkout@v4
    - uses: microsoft/setup-msbuild@v2
    - name: Build (x86)
      working-directory: win
      run: msbuild cglm.vcxproj /p:Configuration=Release /p:Platform=x86 /p:BuildInParallel=true
    - name: Build (x64)
      working-directory: win
      run: msbuild cglm.vcxproj /p:Configuration=Release /p:Platform=x64 /p:BuildInParallel=true
  build_swift:
    name: Swift ${{ matrix.swift }} / ${{ matrix.os }}
    runs-on: ${{ matrix.os }}
    strategy:
      fail-fast: false
      matrix:
        os: [macos-12, macos-14, ubuntu-22.04]
    # This has no test yet.
    steps:
      - uses: actions/checkout@v4
      - name: Build
        run: swift build
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@@ -1,6 +1,6 @@
 cmake_minimum_required(VERSION 3.8.2)
 project(cglm
-  VERSION 0.9.2
+  VERSION 0.9.3
  HOMEPAGE_URL https://github.com/recp/cglm
  DESCRIPTION "OpenGL Mathematics (glm) for C"
  LANGUAGES C
@@ -32,18 +32,23 @@ if(CGLM_USE_C99)
 endif()
 if(MSVC)
-  add_definitions(-DNDEBUG -D_WINDOWS -D_USRDLL)
+  add_definitions(-D_WINDOWS -D_USRDLL)
-  add_compile_options(/W3 /Ox /Gy /Oi /TC)
+
-  
+  if(NOT CMAKE_BUILD_TYPE MATCHES Debug)
-  # Ref: https://skia.googlesource.com/third_party/sdl/+/refs/heads/master/CMakeLists.txt#225
+    add_definitions(-DNDEBUG)
-  # Make sure /RTC1 is disabled, otherwise it will use functions from the CRT
+    add_compile_options(/W3 /Ox /Gy /Oi /TC)
-  foreach(flag_var
+    foreach(flag_var
-      CMAKE_C_FLAGS CMAKE_C_FLAGS_DEBUG CMAKE_C_FLAGS_RELEASE
+        CMAKE_C_FLAGS CMAKE_C_FLAGS_DEBUG CMAKE_C_FLAGS_RELEASE
-      CMAKE_C_FLAGS_MINSIZEREL CMAKE_C_FLAGS_RELWITHDEBINFO)
+        CMAKE_C_FLAGS_MINSIZEREL CMAKE_C_FLAGS_RELWITHDEBINFO)
-    string(REGEX REPLACE "/RTC(su|[1su])" "" ${flag_var} "${${flag_var}}")
+      string(REGEX REPLACE "/RTC(su|[1su])" "" ${flag_var} "${${flag_var}}")
-  endforeach(flag_var)
+    endforeach(flag_var)
  endif()
 else()
-  add_compile_options(-Wall -O3)
+  add_compile_options(-Wall)
  if(NOT CMAKE_BUILD_TYPE MATCHES Debug)
    add_compile_options(-O3)
  endif()
 endif()
 get_directory_property(hasParent PARENT_DIRECTORY)
--- a/14
+++ b/14
@@ -82,3 +82,17 @@ http://github.com/microsoft/DirectXMath
 17. Pick Matrix
 glu project -> project.c
 18. Ray sphere intersection
 RAY TRACING GEMS
 HIGH-QUALITY AND REAL-TIME RENDERING WITH DXR AND OTHER APIS
 CHAPTER 7
 Precision Improvements for Ray/Sphere Intersection
 Eric Haines (1), Johannes Günther (2), and Tomas Akenine-Möller (1)
  (1) NVIDIA
  (2) Intel
 Wyman, C., and Haines, E. Getting Started with RTX Ray Tracing.
 https://github.com/NVIDIAGameWorks/GettingStartedWithRTXRayTracing
--- a/Makefile.am
+++ b/Makefile.am
@@ -198,10 +198,13 @@ cglm_struct_HEADERS = include/cglm/struct/mat4.h \
                      include/cglm/struct/affine2d.h \
                      include/cglm/struct/vec2.h \
                      include/cglm/struct/vec2-ext.h \
                      include/cglm/struct/ivec2.h \
                      include/cglm/struct/vec3.h \
                      include/cglm/struct/vec3-ext.h \
                      include/cglm/struct/ivec3.h \
                      include/cglm/struct/vec4.h \
                      include/cglm/struct/vec4-ext.h \
                      include/cglm/struct/ivec4.h \
                      include/cglm/struct/io.h \
                      include/cglm/struct/cam.h \
                      include/cglm/struct/quat.h \
@@ -213,7 +216,8 @@ cglm_struct_HEADERS = include/cglm/struct/mat4.h \
                      include/cglm/struct/project.h \
                      include/cglm/struct/sphere.h \
                      include/cglm/struct/color.h \
-                      include/cglm/struct/curve.h
+                      include/cglm/struct/curve.h \
                      include/cglm/struct/ray.h
 cglm_struct_clipspacedir=$(includedir)/cglm/struct/clipspace
 cglm_struct_clipspace_HEADERS = include/cglm/struct/clipspace/persp_lh_no.h \
--- a/README.md
+++ b/README.md
@@ -5,14 +5,10 @@
 </p>
 <br>
 <p align="center">
-    <a href="https://travis-ci.com/recp/cglm">
+    <a href="https://github.com/recp/cglm/actions/workflows/ci.yml">
-        <img src="https://travis-ci.com/recp/cglm.svg?branch=master"
+        <img src="https://github.com/recp/cglm/actions/workflows/ci.yml/badge.svg"
             alt="Build Status">
    </a>
    <a href="https://ci.appveyor.com/project/recp/cglm/branch/master">
        <img src="https://ci.appveyor.com/api/projects/status/av7l3gc0yhfex8y4/branch/master?svg=true"
             alt="Windows Build Status">
    </a>
    <a href="http://cglm.readthedocs.io/en/latest/?badge=latest">
        <img src="https://readthedocs.org/projects/cglm/badge/?version=latest"
             alt="Documentation Status">
@@ -66,7 +62,7 @@ you have the latest version
 - **[major change]** by starting v0.5.0, vec3 functions use **glm_vec3_** namespace, it was **glm_vec_** until v0.5.0
 - **[major change]** by starting v0.5.1, built-in alignment is removed from **vec3** and **mat3** types
 - **[major change]** by starting v0.7.3, inline print functions are disabled in release/production mode to eliminate print costs (see options in documentation). Print output also improved. You can disable colors if you need  (see documentation)
- **[major change]** by starting v0.8.3, **cglm** supports alternative clipspace configuations e.g. Left Handed, Zero-to-One (_zo)... `CGLM_FORCE_DEPTH_ZERO_TO_ONE` and `CGLM_FORCE_LEFT_HANDED` is provided to control clipspace. You should be able to use **cglm** with Vulkan, DirectX and Metal now... see https://cglm.readthedocs.io/en/latest/opt.html#clipspace-option-s
+- **[major change]** by starting v0.8.3, **cglm** supports alternative clipspace configurations e.g. Left Handed, Zero-to-One (_zo)... `CGLM_FORCE_DEPTH_ZERO_TO_ONE` and `CGLM_FORCE_LEFT_HANDED` is provided to control clipspace. You should be able to use **cglm** with Vulkan, DirectX and Metal now... see https://cglm.readthedocs.io/en/latest/opt.html#clipspace-option-s
 #### 📌 Note for C++ developers:
 If you are not aware of the original GLM library yet, you may also want to look at:
@@ -108,7 +104,7 @@ https://github.com/g-truc/glm
 ## 🚀 Features
 - **scalar** and **simd** (sse, avx, neon...) optimizations
- option to use different clipspaces e.g. Left Handed, Zero-to-One... (currrently right handed negative-one is default)
+- option to use different clipspaces e.g. Left Handed, Zero-to-One... (currently right handed negative-one is default)
 - array api and struct api, you can use arrays or structs.
 - general purpose matrix operations (mat4, mat3)
 - chain matrix multiplication (square only)
@@ -148,7 +144,7 @@ To call pre-compiled versions, just use `glmc_` (c stands for 'call') instead of
  glm_mul(trans, rot, rt);  /* inline */
  glmc_mul(trans, rot, rt); /* call from library */
 ```
-Most of math functions are optimized manualy with SSE2 if available, if not? Dont worry there are non-sse versions of all operations
+Most of math functions are optimized manually with SSE2 if available, if not? Dont worry there are non-sse versions of all operations
 You can pass matrices and vectors as array to functions rather than get address.
--- a/appveyor.yml
+++ b/appveyor.yml
@@ -1,7 +0,0 @@
 image: Visual Studio 2017
 build_script:
 - ps: >-
    cd win
    .\build.bat
--- a/autogen.sh
+++ b/autogen.sh
--- a/cglm.podspec
+++ b/cglm.podspec
@@ -2,7 +2,7 @@ Pod::Spec.new do |s|
  # Description
  s.name         = "cglm"
-  s.version      = "0.9.1"
+  s.version      = "0.9.2"
  s.summary      = "📽 Highly Optimized Graphics Math (glm) for C"
  s.description  = <<-DESC
 cglm is math library for graphics programming for C. See the documentation or README for all features.
--- a/configure.ac
+++ b/configure.ac
@@ -7,7 +7,7 @@
 #*****************************************************************************
 AC_PREREQ([2.69])
-AC_INIT([cglm], [0.9.2], [info@recp.me])
+AC_INIT([cglm], [0.9.3], [info@recp.me])
 AM_INIT_AUTOMAKE([-Wall foreign subdir-objects serial-tests])
 # Don't use the default cflags (-O2 -g), we set ours manually in Makefile.am.
--- a/docs/make.bat
+++ b/docs/make.bat
--- a/docs/requirements.txt
+++ b/docs/requirements.txt
@@ -1,4 +1,4 @@
 # Defining the exact version will make sure things don't break
-sphinx==5.3.0
+sphinx==7.2.6
-sphinx_rtd_theme==1.1.1
+sphinx_rtd_theme==2.0.0
-readthedocs-sphinx-search==0.1.1
+readthedocs-sphinx-search==0.3.2
--- a/docs/source/aabb2d.rst
+++ b/docs/source/aabb2d.rst
@@ -17,16 +17,22 @@ convert it before and after calling a cglm aabb2d function.
 Table of contents (click to go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 Macros:
 1. :c:func:`glm_aabb2d_size`
 Functions:
 1. :c:func:`glm_aabb2d_copy`
 #. :c:func:`glm_aabb2d_zero`
 #. :c:func:`glm_aabb2d_transform`
 #. :c:func:`glm_aabb2d_merge`
 #. :c:func:`glm_aabb2d_crop`
 #. :c:func:`glm_aabb2d_crop_until`
 #. :c:func:`glm_aabb2d_invalidate`
 #. :c:func:`glm_aabb2d_isvalid`
-#. :c:func:`glm_aabb2d_size`
+#. :c:func:`glm_aabb2d_diag`
 #. :c:func:`glm_aabb2d_sizev`
 #. :c:func:`glm_aabb2d_radius`
 #. :c:func:`glm_aabb2d_center`
 #. :c:func:`glm_aabb2d_aabb`
@@ -45,6 +51,13 @@ Functions documentation
      | *[in]*  **aabb**  bounding box
      | *[out]* **dest**  destination
 .. c:function:: void  glm_aabb2d_zero(vec2 aabb[2])
    | makes all members of [aabb] 0.0f (zero)
    Parameters:
      | *[in, out]*  **aabb**     bounding box
 .. c:function:: void  glm_aabb2d_transform(vec2 aabb[2], mat3 m, vec2 dest[2])
    | apply transform to Axis-Aligned Bounding Box
@@ -89,7 +102,7 @@ Functions documentation
    Parameters:
      | *[in]*  **aabb**      bounding box
      | *[in]*  **cropAabb**  crop box
-      | *[in]*  **clampAabb** miniumum box
+      | *[in]*  **clampAabb** minimum box
      | *[out]* **dest**     cropped bounding box
 .. c:function:: void  glm_aabb2d_invalidate(vec2 aabb[2])
@@ -111,9 +124,9 @@ Functions documentation
    Returns:
      returns true if aabb is valid otherwise false
-.. c:function:: float  glm_aabb2d_size(vec2 aabb[2])
+.. c:function:: float  glm_aabb2d_diag(vec2 aabb[2])
-    | distance between of min and max
+    | distance between min and max
    Parameters:
      | *[in]*   **aabb**     bounding box
@@ -121,6 +134,18 @@ Functions documentation
    Returns:
      distance between min - max
 .. c:function:: void  glm_aabb2d_sizev(vec2 aabb[2], vec2 dest)
    | size vector of aabb
    Parameters:
      | *[in]*   **aabb**     bounding box
      | *[out]*  **dest**     size vector
    Returns:
      size vector of aabb max - min
 .. c:function:: float  glm_aabb2d_radius(vec2 aabb[2])
    | radius of sphere which surrounds AABB
--- a/docs/source/affine-common.rst
+++ b/docs/source/affine-common.rst
@@ -3,7 +3,7 @@
 3D Affine Transforms (common)
 ================================================================================
-Common transfrom functions.
+Common transform functions.
 Table of contents (click to go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -30,7 +30,7 @@ Functions documentation
    creates NEW translate transform matrix by *v* vector.
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  translate vector [x, y, z]
 .. c:function:: void  glm_scale_to(mat4 m, vec3 v, mat4 dest)
@@ -38,7 +38,7 @@ Functions documentation
    scale existing transform matrix by *v* vector and store result in dest
    Parameters:
-      | *[in]*  **m**    affine transfrom
+      | *[in]*  **m**    affine transform
      | *[in]*  **v**    scale vector [x, y, z]
      | *[out]* **dest** scaled matrix
@@ -47,7 +47,7 @@ Functions documentation
    creates NEW scale matrix by v vector
    Parameters:
-      | *[out]* **m** affine transfrom
+      | *[out]* **m** affine transform
      | *[in]*  **v** scale vector [x, y, z]
 .. c:function:: void  glm_scale(mat4 m, vec3 v)
@@ -56,7 +56,7 @@ Functions documentation
    and stores result in same matrix
    Parameters:
-      | *[in, out]* **m** affine transfrom
+      | *[in, out]* **m** affine transform
      | *[in]*      **v** scale vector [x, y, z]
 .. c:function:: void  glm_scale_uni(mat4 m, float s)
@@ -65,7 +65,7 @@ Functions documentation
    and stores result in same matrix
    Parameters:
-      | *[in, out]* **m** affine transfrom
+      | *[in, out]* **m** affine transform
      | *[in]*      **v** scale factor
 .. c:function:: void  glm_rotate_make(mat4 m, float angle, vec3 axis)
@@ -74,7 +74,7 @@ Functions documentation
    axis will be normalized so you don't need to normalize it
    Parameters:
-      | *[out]* **m**    affine transfrom
+      | *[out]* **m**    affine transform
      | *[in]*  **axis** angle (radians)
      | *[in]*  **axis** axis
@@ -86,7 +86,7 @@ Functions documentation
    | this should work faster than glm_rotate_at because it reduces one glm_translate.
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **pivot** pivot, anchor point, rotation center
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
@@ -123,7 +123,7 @@ Functions documentation
    DON'T pass projected matrix here
    Parameters:
-      | *[in]*  **m** affine transfrom
+      | *[in]*  **m** affine transform
      | *[out]* **t** translation vector
      | *[out]* **r** rotation matrix (mat4)
      | *[out]* **s** scaling vector [X, Y, Z]
--- a/docs/source/affine-mat.rst
+++ b/docs/source/affine-mat.rst
@@ -25,7 +25,7 @@ You cannot use :c:func:`glm_mul` anymore.
 Same is also true for :c:func:`glm_inv_tr` if you only have rotation and
 translation then it will work as expected, otherwise you cannot use that.
-In the future it may accept scale factors too but currectly it does not.
+In the future it may accept scale factors too but currently it does not.
 Table of contents (click func go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--- a/docs/source/affine-post.rst
+++ b/docs/source/affine-post.rst
@@ -3,10 +3,8 @@
 3D Affine Transforms (post)
 ================================================================================
-Post transfrom functions are similar to pre transform functions except order of application is reversed.  
+Post transform functions are similar to pre transform functions except order of application is reversed.
-Post transform functions are applied after the object is transformed with given (model matrix) transfrom. 
+Post transform functions are applied after the object is transformed with given (model matrix) transform.
 Ther are named af
 Table of contents (click to go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -33,7 +31,7 @@ Functions documentation
    translate existing transform matrix by *v* vector and store result in dest
    Parameters:
-      | *[in]*  **m**    affine transfrom
+      | *[in]*  **m**    affine transform
      | *[in]*  **v**    translate vector [x, y, z]
      | *[out]* **dest** translated matrix
@@ -43,7 +41,7 @@ Functions documentation
    and stores result in same matrix
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  translate vector [x, y, z]
 .. c:function:: void  glm_translated_x(mat4 m, float x)
@@ -51,7 +49,7 @@ Functions documentation
    translate existing transform matrix by x factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  x factor
 .. c:function:: void  glm_translated_y(mat4 m, float y)
@@ -59,7 +57,7 @@ Functions documentation
    translate existing transform matrix by *y* factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  y factor
 .. c:function:: void  glm_translated_z(mat4 m, float z)
@@ -67,7 +65,7 @@ Functions documentation
    translate existing transform matrix by *z* factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  z factor
 .. c:function:: void  glm_rotated_x(mat4 m, float angle, mat4 dest)
@@ -76,7 +74,7 @@ Functions documentation
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
@@ -86,7 +84,7 @@ Functions documentation
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
@@ -96,7 +94,7 @@ Functions documentation
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
@@ -105,7 +103,7 @@ Functions documentation
    rotate existing transform matrix around Z axis by angle and axis
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
@@ -114,7 +112,7 @@ Functions documentation
    rotate existing transform around given axis by angle at given pivot point (rotation center)
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **pivot** pivot, anchor point, rotation center
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
@@ -124,6 +122,6 @@ Functions documentation
    | rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
--- a/docs/source/affine-pre.rst
+++ b/docs/source/affine-pre.rst
@@ -3,7 +3,7 @@
 3D Affine Transforms (pre)
 ================================================================================
-Pre transfrom functions which are regular transfrom functions.
+Pre transform functions which are regular transform functions.
 Table of contents (click to go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -41,7 +41,7 @@ Functions documentation
    translate existing transform matrix by *v* vector and store result in dest
    Parameters:
-      | *[in]*  **m**    affine transfrom
+      | *[in]*  **m**    affine transform
      | *[in]*  **v**    translate vector [x, y, z]
      | *[out]* **dest** translated matrix
@@ -51,7 +51,7 @@ Functions documentation
    and stores result in same matrix
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  translate vector [x, y, z]
 .. c:function:: void  glm_translate_x(mat4 m, float x)
@@ -59,7 +59,7 @@ Functions documentation
    translate existing transform matrix by x factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  x factor
 .. c:function:: void  glm_translate_y(mat4 m, float y)
@@ -67,7 +67,7 @@ Functions documentation
    translate existing transform matrix by *y* factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  y factor
 .. c:function:: void  glm_translate_z(mat4 m, float z)
@@ -75,59 +75,16 @@ Functions documentation
    translate existing transform matrix by *z* factor
    Parameters:
-      | *[in, out]* **m**  affine transfrom
+      | *[in, out]* **m**  affine transform
      | *[in]*      **v**  z factor
 .. c:function:: void  glm_translate_make(mat4 m, vec3 v)
    creates NEW translate transform matrix by *v* vector.
    Parameters:
      | *[in, out]* **m**  affine transfrom
      | *[in]*      **v**  translate vector [x, y, z]
 .. c:function:: void  glm_scale_to(mat4 m, vec3 v, mat4 dest)
    scale existing transform matrix by *v* vector and store result in dest
    Parameters:
      | *[in]*  **m**    affine transfrom
      | *[in]*  **v**    scale vector [x, y, z]
      | *[out]* **dest** scaled matrix
 .. c:function:: void  glm_scale_make(mat4 m, vec3 v)
    creates NEW scale matrix by v vector
    Parameters:
      | *[out]* **m** affine transfrom
      | *[in]*  **v** scale vector [x, y, z]
 .. c:function:: void  glm_scale(mat4 m, vec3 v)
    scales existing transform matrix by v vector
    and stores result in same matrix
    Parameters:
      | *[in, out]* **m** affine transfrom
      | *[in]*      **v** scale vector [x, y, z]
 .. c:function:: void  glm_scale_uni(mat4 m, float s)
    applies uniform scale to existing transform matrix v = [s, s, s]
    and stores result in same matrix
    Parameters:
      | *[in, out]* **m** affine transfrom
      | *[in]*      **v** scale factor
 .. c:function:: void  glm_rotate_x(mat4 m, float angle, mat4 dest)
    rotate existing transform matrix around X axis by angle
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
@@ -137,7 +94,7 @@ Functions documentation
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
@@ -147,26 +104,33 @@ Functions documentation
    and store result in dest
    Parameters:
-      | *[in]*  **m**     affine transfrom
+      | *[in]*  **m**     affine transform
      | *[in]*  **angle** angle (radians)
      | *[out]* **dest**  rotated matrix
 .. c:function:: void  glm_rotate_make(mat4 m, float angle, vec3 axis)
    creates NEW rotation matrix by angle and axis,
    axis will be normalized so you don't need to normalize it
    Parameters:
      | *[out]* **m**    affine transfrom
      | *[in]*  **axis** angle (radians)
      | *[in]*  **axis** axis
 .. c:function:: void  glm_rotate(mat4 m, float angle, vec3 axis)
-    rotate existing transform matrix around Z axis by angle and axis
+    rotate existing transform matrix around given axis by angle at ORIGIN (0,0,0)
    **❗️IMPORTANT ❗️**
    If you need to rotate object around itself e.g. center of object or at
    some point [of object] then `glm_rotate_at()` would be better choice to do so.
    Even if object's model transform is identiy, rotation may not be around
    center of object if object does not lay out at ORIGIN perfectly.
    Using `glm_rotate_at()` with center of bounding shape ( AABB, Sphere ... )
    would be an easy option to rotate around object if object is not at origin.
    One another option to rotate around itself at any point is `glm_spin()`
    which is perfect if only rotating around model position is desired e.g. not
    specific point on model for instance center of geometry or center of mass,
    again if geometry is not perfectly centered at origin at identity transform,
    rotation may not be around geometry.
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
@@ -175,66 +139,16 @@ Functions documentation
    rotate existing transform around given axis by angle at given pivot point (rotation center)
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **pivot** pivot, anchor point, rotation center
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
 .. c:function:: void  glm_rotate_atm(mat4 m, vec3 pivot, float angle, vec3 axis)
    | creates NEW rotation matrix by angle and axis at given point
    | this creates rotation matrix, it assumes you don't have a matrix
    | this should work faster than glm_rotate_at because it reduces one glm_translate.
    Parameters:
      | *[in, out]* **m**     affine transfrom
      | *[in]*      **pivot** pivot, anchor point, rotation center
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
 .. c:function:: void  glm_decompose_scalev(mat4 m, vec3 s)
    decompose scale vector
    Parameters:
      | *[in]*  **m**  affine transform
      | *[out]* **s**  scale vector (Sx, Sy, Sz)
 .. c:function:: bool  glm_uniscaled(mat4 m)
    returns true if matrix is uniform scaled.
    This is helpful for creating normal matrix.
    Parameters:
      | *[in]*  **m**   matrix
 .. c:function:: void  glm_decompose_rs(mat4 m, mat4 r, vec3 s)
    decompose rotation matrix (mat4) and scale vector [Sx, Sy, Sz]
    DON'T pass projected matrix here
    Parameters:
      | *[in]*  **m** affine transform
      | *[out]* **r** rotation matrix
      | *[out]* **s** scale matrix
 .. c:function:: void  glm_decompose(mat4 m, vec4 t, mat4 r, vec3 s)
    decompose affine transform, TODO: extract shear factors.
    DON'T pass projected matrix here
    Parameters:
      | *[in]*  **m** affine transfrom
      | *[out]* **t** translation vector
      | *[out]* **r** rotation matrix (mat4)
      | *[out]* **s** scaling vector [X, Y, Z]
 .. c:function:: void  glm_spin(mat4 m, float angle, vec3 axis)
    | rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
    Parameters:
-      | *[in, out]* **m**     affine transfrom
+      | *[in, out]* **m**     affine transform
      | *[in]*      **angle** angle (radians)
      | *[in]*      **axis**  axis
--- a/docs/source/affine.rst
+++ b/docs/source/affine.rst
@@ -13,7 +13,7 @@ Post functions (`T' = T * Tnew`) are like `glm_translated`, `glm_rotated` which
 `glm_translate`, `glm_rotate` are pre functions and are similar to C++ **glm** which you are familiar with. 
 In new versions of **cglm** we added `glm_translated`, `glm_rotated`... which are post functions, 
-they are useful in some cases, e.g. append transform to existing transform (apply/append transform as last transfrom T' = T * Tnew).
+they are useful in some cases, e.g. append transform to existing transform (apply/append transform as last transform T' = T * Tnew).
 Post functions are named after pre functions with `ed` suffix, e.g. `glm_translate` -> `glm_translated`. So don't mix them up.
@@ -24,7 +24,7 @@ a matrix for you. You don't need to pass identity matrix.
 But other functions expect you have a matrix and you want to transform them. If
 you didn't have any existing matrix you have to initialize matrix to identity
-before sending to transfrom functions.
+before sending to transform functions.
 There are also functions to decompose transform matrix. These functions can't
 decompose matrix after projected.
@@ -35,7 +35,7 @@ Rotation Center
 Rotating functions uses origin as rotation center (pivot/anchor point),
 since scale factors are stored in rotation matrix, same may also true for scalling.
 cglm provides some functions for rotating around at given point e.g.
-**glm_rotate_at**, **glm_quat_rotate_at**. Use them or follow next section for algorihm ("Rotate or Scale around specific Point (Pivot Point / Anchor Point)").
+**glm_rotate_at**, **glm_quat_rotate_at**. Use them or follow next section for algorithm ("Rotate or Scale around specific Point (Pivot Point / Anchor Point)").
 Also **cglm** provides :c:func:`glm_spin` and :c:func:`glm_spinned` functions to rotate around itself. No need to give pivot.
 These functions are useful for rotating around center of object. 
@@ -43,7 +43,7 @@ These functions are useful for rotating around center of object.
 Rotate or Scale around specific Point (Anchor Point)
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-If you want to rotate model around arbibtrary point follow these steps:
+If you want to rotate model around arbitrary point follow these steps:
 1. Move model from pivot point to origin: **translate(-pivot.x, -pivot.y, -pivot.z)**
 2. Apply rotation (or scaling maybe)
@@ -82,11 +82,11 @@ helpers functions works like this (cglm provides reverse order as `ed` suffix e.
 .. code-block:: c
  :linenos:
-  TransformMatrix = TransformMatrix * TraslateMatrix; // glm_translate()
+  TransformMatrix = TransformMatrix * TranslateMatrix; // glm_translate()
  TransformMatrix = TransformMatrix * RotateMatrix;   // glm_rotate(), glm_quat_rotate()
  TransformMatrix = TransformMatrix * ScaleMatrix;    // glm_scale()
-As you can see it is multipled as right matrix. For instance what will happen if you call `glm_translate` twice?
+As you can see it is multiplied as right matrix. For instance what will happen if you call `glm_translate` twice?
 .. code-block:: c
  :linenos:
--- a/docs/source/affine2d.rst
+++ b/docs/source/affine2d.rst
@@ -14,7 +14,7 @@ a matrix for you. You don't need to pass identity matrix.
 But other functions expect you have a matrix and you want to transform them. If
 you didn't have any existing matrix you have to initialize matrix to identity
-before sending to transfrom functions.
+before sending to transform functions.
 Transforms Order
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -45,7 +45,7 @@ Functions:
    translate existing 2d transform matrix by *v* vector and stores result in same matrix
    Parameters:
-      | *[in, out]*  **m**    2d affine transfrom
+      | *[in, out]*  **m**    2d affine transform
      | *[in]*       **v**    translate vector [x, y]
 .. c:function:: void glm_translate2d_to(mat3 m, vec2 v, mat3 dest)
@@ -53,7 +53,7 @@ Functions:
    translate existing 2d transform matrix by *v* vector and store result in dest
    Parameters:
-      | *[in]*  **m**    2d affine transfrom
+      | *[in]*  **m**    2d affine transform
      | *[in]*  **v**    translate vector [x, y]
      | *[out]* **dest** translated matrix
@@ -62,7 +62,7 @@ Functions:
    translate existing 2d transform matrix by x factor
    Parameters:
-      | *[in, out]*  **m**    2d affine transfrom
+      | *[in, out]*  **m**    2d affine transform
      | *[in]*       **x**    x factor
 .. c:function:: void glm_translate2d_y(mat3 m, float y)
@@ -70,7 +70,7 @@ Functions:
    translate existing 2d transform matrix by y factor
    Parameters:
-      | *[in, out]*  **m**    2d affine transfrom
+      | *[in, out]*  **m**    2d affine transform
      | *[in]*       **y**    y factor
 .. c:function:: void glm_translate2d_make(mat3 m, vec2 v)
@@ -78,7 +78,7 @@ Functions:
    creates NEW translate 2d transform matrix by *v* vector
    Parameters:
-      | *[in, out]*  **m**    affine transfrom
+      | *[in, out]*  **m**    affine transform
      | *[in]*       **v**    translate vector [x, y]
 .. c:function:: void glm_scale2d_to(mat3 m, vec2 v, mat3 dest)
@@ -86,7 +86,7 @@ Functions:
    scale existing 2d transform matrix by *v* vector and store result in dest
    Parameters:
-      | *[in]*  **m**    affine transfrom
+      | *[in]*  **m**    affine transform
      | *[in]*  **v**    scale vector [x, y]
      | *[out]* **dest** scaled matrix
@@ -95,7 +95,7 @@ Functions:
    creates NEW 2d scale matrix by *v* vector
    Parameters:
-      | *[in, out]*  **m**    affine transfrom
+      | *[in, out]*  **m**    affine transform
      | *[in]*       **v**    scale vector [x, y]
 .. c:function:: void glm_scale2d(mat3 m, vec2 v)
@@ -103,7 +103,7 @@ Functions:
    scales existing 2d transform matrix by *v* vector and stores result in same matrix
    Parameters:
-      | *[in, out]*  **m**    affine transfrom
+      | *[in, out]*  **m**    affine transform
      | *[in]*       **v**    translate vector [x, y]
 .. c:function:: void glm_scale2d_uni(mat3 m, float s)
@@ -111,7 +111,7 @@ Functions:
    applies uniform scale to existing 2d transform matrix v = [s, s] and stores result in same matrix
    Parameters:
-      | *[in, out]*  **m**  affine transfrom
+      | *[in, out]*  **m**  affine transform
      | *[in]*       **s**  scale factor
 .. c:function:: void glm_rotate2d_make(mat3 m, float angle)
@@ -119,7 +119,7 @@ Functions:
    creates NEW rotation matrix by angle around *Z* axis
    Parameters:
-      | *[in, out]*  **m**      affine transfrom
+      | *[in, out]*  **m**      affine transform
      | *[in]*       **angle**  angle (radians)
 .. c:function:: void glm_rotate2d(mat3 m, float angle)
@@ -127,7 +127,7 @@ Functions:
    rotate existing 2d transform matrix around *Z* axis by angle and store result in same matrix
    Parameters:
-      | *[in, out]*  **m**      affine transfrom
+      | *[in, out]*  **m**      affine transform
      | *[in]*       **angle**  angle (radians)
 .. c:function:: void glm_rotate2d_to(mat3 m, float angle, mat3 dest)
@@ -135,6 +135,6 @@ Functions:
    rotate existing 2d transform matrix around *Z* axis by angle and store result in dest
    Parameters:
-      | *[in]*  **m**      affine transfrom
+      | *[in]*  **m**      affine transform
      | *[in]*  **angle**  angle (radians)
      | *[out]* **dest**   rotated matrix
--- a/docs/source/api_inline_array.rst
+++ b/docs/source/api_inline_array.rst
@@ -9,7 +9,7 @@ In the future there may be option to forward struct api to call api instead of i
 📌 **USE this API docs for similar functions in struct and call api** 
-📌 In struct api you can omit namespace e.g :code:`glms_vec3_dot` can be called as :code:`vec3_dot` in struct api, see :doc:`struct-api` to configure struct api for more details. 
+📌 In struct api you can omit namespace e.g :code:`glms_vec3_dot` can be called as :code:`vec3_dot` in struct api, see :doc:`api_struct` to configure struct api for more details.
 📌 In struct api functions can return struct/union
 📌 In struct api you can access items like **.x**, **.y**, **.z**, **.w**, **.r**, **.g**, **.b**, **.a**, **.m00**, **m01**... 
@@ -43,6 +43,7 @@ Follow the :doc:`build` documentation for this
   cam
   frustum
   box
   aabb2d
   quat
   euler
   mat2
--- a/docs/source/api_struct.rst
+++ b/docs/source/api_struct.rst
@@ -10,7 +10,7 @@ Also struct api `s` suffix to namespace e.g. `glms_vec3_add`, `glms_mat4_mul` et
 By starting v0.9.0, struct api namespace is configurable. We can omit **glms_** namespace or 
 even change it with custom name to move existing api integrations to **cglm** more easliy...
-We can also add **s** to functin names if we want e.g. `glms_vec3_add()` -> `vec3_add()` or `vec3s_add()`.
+We can also add **s** to function names if we want e.g. `glms_vec3_add()` -> `vec3_add()` or `vec3s_add()`.
 By including **cglm/struct.h** header you will include all struct api. It will also include **cglm/cglm.h** too. 
 Since struct apis are inline you don't need to build or link *cglm* against 
--- a/docs/source/box.rst
+++ b/docs/source/box.rst
@@ -82,7 +82,7 @@ Functions documentation
    Parameters:
      | *[in]*  **box**      bounding box
      | *[in]*  **cropBox**  crop box
-      | *[in]*  **clampBox** miniumum box
+      | *[in]*  **clampBox** minimum box
      | *[out]* **dest**     cropped bounding box
 .. c:function:: bool  glm_aabb_frustum(vec3 box[2], vec4 planes[6])
--- a/docs/source/build.rst
+++ b/docs/source/build.rst
@@ -3,9 +3,9 @@ Build cglm
 | **cglm** does not have any external dependencies.
-**NOTE:**
+.. note::
-If you only need to inline versions, you don't need to build **cglm**, you don't need to link it to your program.
+   If you only need to inline versions, you don't need to build **cglm**, you don't need to link it to your program.
-Just import cglm to your project as dependency / external lib by copy-paste then use it as usual
+   Just import cglm to your project as dependency / external lib by copy-paste then use it as usual
 CMake (All platforms):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--- a/docs/source/call.rst
+++ b/docs/source/call.rst
@@ -3,17 +3,17 @@
 precompiled functions (call)
 ================================================================================
-All funcitons in **glm_** namespace are forced to **inline**.
+All functions in **glm_** namespace are forced to **inline**.
 Most functions also have pre-compiled version.
 Precompiled versions are in **glmc_** namespace. *c* in the namespace stands for
 "call".
-Since precompiled functions are just wrapper for inline verisons,
+Since precompiled functions are just wrapper for inline versions,
 these functions are not documented individually.
 It would be duplicate documentation also it
-would be hard to sync documentation between inline and call verison for me.
+would be hard to sync documentation between inline and call version for me.
-By including **clgm/cglm.h** you include all inline verisons. To get precompiled
+By including **clgm/cglm.h** you include all inline versions. To get precompiled
 versions you need to include **cglm/call.h** header it also includes all
-call versions plus *clgm/cglm.h* (inline verisons)
+call versions plus *clgm/cglm.h* (inline versions)
--- a/docs/source/cam.rst
+++ b/docs/source/cam.rst
@@ -18,10 +18,10 @@ fast if you don't care specific projection values.
 *_decomp* means decompose; these function can help to decompose projection
 matrices.
- **NOTE**: Be careful when working with high range (very small near, very large
+.. note:: Be careful when working with high range (very small near, very large
- far) projection matrices. You may not get exact value you gave.
+   far) projection matrices. You may not get exact value you gave.
- **float** type cannot store very high precision so you will lose precision.
+   **float** type cannot store very high precision so you will lose precision.
- Also your projection matrix will be inaccurate due to losing precision
+   Also your projection matrix will be inaccurate due to losing precision
 Table of contents (click to go):
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -178,7 +178,7 @@ Functions documentation
    | set up view matrix
-    **NOTE:** The UP vector must not be parallel to the line of sight from the eye point to the reference point.
+    .. note:: The UP vector must not be parallel to the line of sight from the eye point to the reference point.
    Parameters:
      | *[in]*  **eye**     eye vector
@@ -194,7 +194,7 @@ Functions documentation
    target self then this might be useful. Because you need to get target
    from direction.
-    **NOTE:** The UP vector must not be parallel to the line of sight from the eye point to the reference point.
+    .. note:: The UP vector must not be parallel to the line of sight from the eye point to the reference point.
    Parameters:
      | *[in]*  **eye**     eye vector
@@ -250,7 +250,7 @@ Functions documentation
 .. c:function:: void  glm_persp_decomp_y(mat4 proj, float *top, float *bottom)
    | decomposes top and bottom values of perspective projection.
-    | y stands for y axis (top / botom axis)
+    | y stands for y axis (top / bottom axis)
    Parameters:
      | *[in]*   **proj**    perspective projection matrix
--- a/docs/source/features.rst
+++ b/docs/source/features.rst
@@ -2,7 +2,7 @@ Features
 ================================================================================
 * **scalar** and **simd** (sse, avx, neon, wasm...) optimizations
-* option to use different clipspaces e.g. Left Handed, Zero-to-One... (currrently right handed negative-one is default)
+* option to use different clipspaces e.g. Left Handed, Zero-to-One... (currently right handed negative-one is default)
 * array api and struct api, you can use arrays or structs.
 * general purpose matrix operations (mat4, mat3)
 * chain matrix multiplication (square only)
--- a/docs/source/frustum.rst
+++ b/docs/source/frustum.rst
@@ -11,9 +11,9 @@ not **vec3**. If you want to store them to save space you msut convert them
 yourself.
 **vec4** is used to speed up functions need to corners. This is why frustum
-fucntions use *vec4* instead of *vec3*
+functions use *vec4* instead of *vec3*
-Currenty related-functions use [-1, 1] clip space configuration to extract
+Currently related-functions use [-1, 1] clip space configuration to extract
 corners but you can override it by prodiving **GLM_CUSTOM_CLIPSPACE** macro.
 If you provide it then you have to all bottom macros as *vec4*
--- a/docs/source/getting_started.rst
+++ b/docs/source/getting_started.rst
@@ -22,7 +22,7 @@ Types:
  typedef CGLM_ALIGN_IF(16) vec4  mat4[4];
  #endif
-As you can see types don't store extra informations in favor of space.
+As you can see types don't store extra information in favor of space.
 You can send these values e.g. matrix to OpenGL directly without casting or calling a function like *value_ptr*
 Alignment Is Required:
@@ -35,16 +35,16 @@ Alignment Is Required:
  | Check :doc:`opt` page for more details
-  Also alignment is disabled for older msvc verisons as default. Now alignment is only required in Visual Studio 2017 version 15.6+ if CGLM_ALL_UNALIGNED macro is not defined.
+  Also alignment is disabled for older msvc versions as default. Now alignment is only required in Visual Studio 2017 version 15.6+ if CGLM_ALL_UNALIGNED macro is not defined.
 Allocations:
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 *cglm* doesn't alloc any memory on heap. So it doesn't provide any allocator.
 You must allocate memory yourself. You should alloc memory for out parameters too if you pass pointer of memory location. When allocating memory, don't forget that **vec4** and **mat4** require alignment.
-**NOTE:** Unaligned **vec4** and unaligned **mat4** operations will be supported in the future. Check todo list.
+.. note:: Unaligned **vec4** and unaligned **mat4** operations will be supported in the future. Check todo list.
-Because you may want to multiply a CGLM matrix with external matrix.
+   Because you may want to multiply a CGLM matrix with external matrix.
-There is no guarantee that non-CGLM matrix is aligned. Unaligned types will have *u* prefix e.g. **umat4**
+   There is no guarantee that non-CGLM matrix is aligned. Unaligned types will have *u* prefix e.g. **umat4**
 Array vs Struct:
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--- a/docs/source/io.rst
+++ b/docs/source/io.rst
@@ -24,12 +24,12 @@ Example to print mat4 matrix:
   /* ... */
   glm_mat4_print(transform, stderr);
-**NOTE:** print functions use **%0.4f** precision if you need more
+.. note:: print functions use **%0.4f** precision if you need more
-(you probably will in some cases), you can change it temporary.
+   (you probably will in some cases), you can change it temporary.
-cglm may provide precision parameter in the future
+   cglm may provide precision parameter in the future.
 Changes since **v0.7.3**:
-* Now mis-alignment of columns are fixed: larger numbers are printed via %g and others are printed via %f. Column withs are calculated before print.
+* Now mis-alignment of columns are fixed: larger numbers are printed via %g and others are printed via %f. Column widths are calculated before print.
 * Now values are colorful ;)
 * Some print improvements
 * New options with default values:
@@ -143,5 +143,5 @@ Functions documentation
    Parameters:
      | *[in]*  **vec**      aabb (axis-aligned bounding box)
-      | *[in]*  **tag**      tag to find it more easly in logs
+      | *[in]*  **tag**      tag to find it more easily in logs
      | *[in]*  **ostream**  FILE to write
--- a/docs/source/ivec2.rst
+++ b/docs/source/ivec2.rst
@@ -21,12 +21,17 @@ Functions:
 #. :c:func:`glm_ivec2_copy`
 #. :c:func:`glm_ivec2_zero`
 #. :c:func:`glm_ivec2_one`
 #. :c:func:`glm_ivec2_dot`
 #. :c:func:`glm_ivec2_cross`
 #. :c:func:`glm_ivec2_add`
 #. :c:func:`glm_ivec2_adds`
 #. :c:func:`glm_ivec2_sub`
 #. :c:func:`glm_ivec2_subs`
 #. :c:func:`glm_ivec2_mul`
 #. :c:func:`glm_ivec2_scale`
 #. :c:func:`glm_ivec2_div`
 #. :c:func:`glm_ivec2_divs`
 #. :c:func:`glm_ivec2_mod`
 #. :c:func:`glm_ivec2_distance2`
 #. :c:func:`glm_ivec2_distance`
 #. :c:func:`glm_ivec2_maxv`
@@ -67,6 +72,30 @@ Functions documentation
    Parameters:
      | *[out]* **v** vector
 .. c:function:: int glm_ivec2_dot(ivec2 a, ivec2 b)
    dot product of ivec2
    Parameters:
      | *[in]*  **a**  vector1
      | *[in]*  **b**  vector2
    Returns:
      dot product
 .. c:function:: int glm_ivec2_cross(ivec2 a, ivec2 b)
    cross product of two vector (RH)
    | ref: http://allenchou.net/2013/07/cross-product-of-2d-vectors/
    Parameters:
      | *[in]*  **a**     vector 1
      | *[in]*  **b**     vector 2
    Returns:
      Z component of cross product
 .. c:function:: void glm_ivec2_add(ivec2 a, ivec2 b, ivec2 dest)
    add vector [a] to vector [b] and store result in [dest]
@@ -121,6 +150,33 @@ Functions documentation
      | *[in]*  **s**    scalar
      | *[out]* **dest** destination
 .. c:function:: void glm_ivec2_div(ivec2 a, ivec2 b, ivec2 dest)
    div vector with another component-wise division: d = a / b
    Parameters:
      | *[in]*  **a**     vector 1
      | *[in]*  **b**     vector 2
      | *[out]* **dest**  result = (a[0] / b[0], a[1] / b[1], a[2] / b[2])
 .. c:function:: void glm_ivec2_divs(ivec2 v, int s, ivec2 dest)
    div vector with scalar: d = v / s
    Parameters:
      | *[in]*  **v**     vector
      | *[in]*  **s**     scalar
      | *[out]* **dest**  result = (a[0] / s, a[1] / s, a[2] / s)
 .. c:function:: void glm_ivec2_mod(ivec2 a, ivec2 b, ivec2 dest)
    mod vector with another component-wise modulo: d = a % b
    Parameters:
      | *[in]*  **a**     vector
      | *[in]*  **b**     scalar
      | *[out]* **dest**  result = (a[0] % b[0], a[1] % b[1])
 .. c:function:: int glm_ivec2_distance2(ivec2 a, ivec2 b)
    squared distance between two vectors
--- a/docs/source/ivec3.rst
+++ b/docs/source/ivec3.rst
@@ -21,12 +21,18 @@ Functions:
 #. :c:func:`glm_ivec3_copy`
 #. :c:func:`glm_ivec3_zero`
 #. :c:func:`glm_ivec3_one`
 #. :c:func:`glm_ivec3_dot`
 #. :c:func:`glm_ivec3_norm2`
 #. :c:func:`glm_ivec3_norm`
 #. :c:func:`glm_ivec3_add`
 #. :c:func:`glm_ivec3_adds`
 #. :c:func:`glm_ivec3_sub`
 #. :c:func:`glm_ivec3_subs`
 #. :c:func:`glm_ivec3_mul`
 #. :c:func:`glm_ivec3_scale`
 #. :c:func:`glm_ivec3_div`
 #. :c:func:`glm_ivec3_divs`
 #. :c:func:`glm_ivec3_mod`
 #. :c:func:`glm_ivec3_distance2`
 #. :c:func:`glm_ivec3_distance`
 #. :c:func:`glm_ivec3_fill`
@@ -70,6 +76,39 @@ Functions documentation
    Parameters:
      | *[out]* **v** vector
 .. c:function:: int glm_ivec3_dot(ivec3 a, ivec3 b)
    dot product of ivec3
    Parameters:
      | *[in]*  **a**  vector1
      | *[in]*  **b**  vector2
    Returns:
      dot product
 .. c:function:: int glm_ivec3_norm2(ivec3 v)
    norm * norm (magnitude) of vector
    we can use this func instead of calling norm * norm, because it would call
    sqrtf function twice but with this func we can avoid func call, maybe this is
    not good name for this func
    Parameters:
      | *[in]*  **v**   vector
    Returns:
      square of norm / magnitude, cast to an integer
 .. c:function:: int glm_ivec3_norm(ivec3 vec)
    | euclidean norm (magnitude), also called L2 norm
    | this will give magnitude of vector in euclidean space
    Parameters:
      | *[in]*  **vec**   vector
 .. c:function:: void glm_ivec3_add(ivec3 a, ivec3 b, ivec3 dest)
    add vector [a] to vector [b] and store result in [dest]
@@ -124,6 +163,33 @@ Functions documentation
      | *[in]*  **s**    scalar
      | *[out]* **dest** destination
 .. c:function:: void glm_ivec3_div(ivec3 a, ivec3 b, ivec3 dest)
    div vector with another component-wise division: d = a / b
    Parameters:
      | *[in]*  **a**     vector 1
      | *[in]*  **b**     vector 2
      | *[out]* **dest**  result = (a[0] / b[0], a[1] / b[1], a[2] / b[2])
 .. c:function:: void glm_ivec3_divs(ivec3 v, int s, ivec3 dest)
    div vector with scalar: d = v / s
    Parameters:
      | *[in]*  **v**     vector
      | *[in]*  **s**     scalar
      | *[out]* **dest**  result = (a[0] / s, a[1] / s, a[2] / s)
 .. c:function:: void glm_ivec3_mod(ivec3 a, ivec3 b, ivec3 dest)
    mod vector with another component-wise modulo: d = a % b
    Parameters:
      | *[in]*  **a**     vector
      | *[in]*  **b**     scalar
      | *[out]* **dest**  result = (a[0] % b[0], a[1] % b[1], a[2] % b[2])
 .. c:function:: int glm_ivec3_distance2(ivec3 a, ivec3 b)
    squared distance between two vectors
--- a/docs/source/mat2.rst
+++ b/docs/source/mat2.rst
@@ -47,7 +47,7 @@ Functions documentation
 .. c:function:: void glm_mat2_identity(mat2 mat)
-    copy identity mat2 to mat, or makes mat to identiy
+    copy identity mat2 to mat, or makes mat to identity
    Parameters:
      | *[out]* **mat**  matrix
@@ -94,7 +94,7 @@ Functions documentation
 .. c:function:: void glm_mat2_transpose(mat2 m)
-    tranpose mat2 and store result in same matrix
+    transpose mat2 and store result in same matrix
    Parameters:
      | *[in]*  **mat**   source
@@ -180,11 +180,11 @@ Functions documentation
    Returns:
        scalar value e.g. Matrix1x1
-.. c:function:: void glm_mat2_make(float * __restrict src, mat2 dest)
+.. c:function:: void glm_mat2_make(const float * __restrict src, mat2 dest)
    Create mat2 matrix from pointer
-    | NOTE: **@src** must contain at least 4 elements.
+    .. note:: **@src** must contain at least 4 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/mat2x3.rst
+++ b/docs/source/mat2x3.rst
@@ -41,11 +41,11 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat2x3_make(float * __restrict src, mat2x3 dest)
+.. c:function:: void glm_mat2x3_make(const float * __restrict src, mat2x3 dest)
    Create mat2x3 matrix from pointer
-    | NOTE: **@src** must contain at least 6 elements.
+    .. note:: **@src** must contain at least 6 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/mat2x4.rst
+++ b/docs/source/mat2x4.rst
@@ -41,11 +41,11 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat2x4_make(float * __restrict src, mat2x4 dest)
+.. c:function:: void glm_mat2x4_make(const float * __restrict src, mat2x4 dest)
    Create mat2x4 matrix from pointer
-    | NOTE: **@src** must contain at least 8 elements.
+    .. note:: **@src** must contain at least 8 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/mat3.rst
+++ b/docs/source/mat3.rst
@@ -49,7 +49,7 @@ Functions documentation
 .. c:function:: void  glm_mat3_identity(mat3 mat)
-    copy identity mat3 to mat, or makes mat to identiy
+    copy identity mat3 to mat, or makes mat to identity
    Parameters:
      | *[out]* **mat**  matrix
@@ -96,7 +96,7 @@ Functions documentation
 .. c:function:: void  glm_mat3_transpose(mat3 m)
-    tranpose mat3 and store result in same matrix
+    transpose mat3 and store result in same matrix
    Parameters:
      | *[in]*  **mat**   source
@@ -190,11 +190,11 @@ Functions documentation
    Returns:
        scalar value e.g. Matrix1x1
-.. c:function:: void glm_mat3_make(float * __restrict src, mat3 dest)
+.. c:function:: void glm_mat3_make(const float * __restrict src, mat3 dest)
    Create mat3 matrix from pointer
-    | NOTE: **@src** must contain at least 9 elements.
+    .. note:: **@src** must contain at least 9 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/mat3x2.rst
+++ b/docs/source/mat3x2.rst
@@ -41,11 +41,12 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat3x2_make(float * __restrict src, mat3x2 dest)
+.. c:function:: void glm_mat3x2_make(const float * __restrict src, mat3x2 dest)
    Create mat3x2 matrix from pointer
-    | NOTE: **@src** must contain at least 6 elements.
+    .. note:: **@src** must contain at least 6 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination matrix3x2
--- a/docs/source/mat3x4.rst
+++ b/docs/source/mat3x4.rst
@@ -41,11 +41,12 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat3x4_make(float * __restrict src, mat3x4 dest)
+.. c:function:: void glm_mat3x4_make(const float * __restrict src, mat3x4 dest)
    Create mat3x4 matrix from pointer
-    | NOTE: **@src** must contain at least 12 elements.
+    .. note::: **@src** must contain at least 12 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination matrix3x4
--- a/docs/source/mat4.rst
+++ b/docs/source/mat4.rst
@@ -34,8 +34,8 @@ Functions:
 #. :c:func:`glm_mat4_mulN`
 #. :c:func:`glm_mat4_mulv`
 #. :c:func:`glm_mat4_mulv3`
-#. :c:func:`glm_mat3_trace`
+#. :c:func:`glm_mat4_trace`
-#. :c:func:`glm_mat3_trace3`
+#. :c:func:`glm_mat4_trace3`
 #. :c:func:`glm_mat4_quat`
 #. :c:func:`glm_mat4_transpose_to`
 #. :c:func:`glm_mat4_transpose`
@@ -70,7 +70,7 @@ Functions documentation
 .. c:function:: void  glm_mat4_identity(mat4 mat)
-    copy identity mat4 to mat, or makes mat to identiy
+    copy identity mat4 to mat, or makes mat to identity
    Parameters:
      | *[out]* **mat**  matrix
@@ -214,7 +214,7 @@ Functions documentation
 .. c:function:: void  glm_mat4_transpose(mat4 m)
-    tranpose mat4 and store result in same matrix
+    transpose mat4 and store result in same matrix
    Parameters:
      | *[in]*  **m**     source
@@ -263,7 +263,7 @@ Functions documentation
    | e.g Newton-Raphson. this should work faster than normal,
    | to get more precise use glm_mat4_inv version.
-    | NOTE: You will lose precision, glm_mat4_inv is more accurate
+    .. note:: You will lose precision, glm_mat4_inv is more accurate
    Parameters:
      | *[in]*  **mat**   source
@@ -304,11 +304,11 @@ Functions documentation
    Returns:
        scalar value e.g. Matrix1x1
-.. c:function:: void glm_mat4_make(float * __restrict src, mat4 dest)
+.. c:function:: void glm_mat4_make(const float * __restrict src, mat4 dest)
    Create mat4 matrix from pointer
-    | NOTE: **@src** must contain at least 16 elements.
+    .. note:: **@src** must contain at least 16 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/mat4x2.rst
+++ b/docs/source/mat4x2.rst
@@ -41,11 +41,12 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat4x2_make(float * __restrict src, mat4x2 dest)
+.. c:function:: void glm_mat4x2_make(const float * __restrict src, mat4x2 dest)
    Create mat4x2 matrix from pointer
-    | NOTE: **@src** must contain at least 8 elements.
+    .. note:: **@src** must contain at least 8 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination matrix4x2
--- a/docs/source/mat4x3.rst
+++ b/docs/source/mat4x3.rst
@@ -41,11 +41,12 @@ Functions documentation
    Parameters:
      | *[in,out]* **mat**  matrix
-.. c:function:: void glm_mat4x3_make(float * __restrict src, mat4x3 dest)
+.. c:function:: void glm_mat4x3_make(const float * __restrict src, mat4x3 dest)
    Create mat4x3 matrix from pointer
-    | NOTE: **@src** must contain at least 12 elements.
+    .. note:: **@src** must contain at least 12 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination matrix4x3
--- a/docs/source/opengl.rst
+++ b/docs/source/opengl.rst
@@ -43,14 +43,14 @@ array of matrices:
   /* ... */
   glUniformMatrix4fv(location, count, GL_FALSE, (float *)matrix);
-in this way, passing aray of matrices is same
+in this way, passing array of matrices is same
 Passing / Uniforming Vectors to OpenGL:
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 You don't need to do extra thing when passing cglm vectors to OpengL or other APIs.
 Because a function like **glUniform4fv** accepts vector as pointer. cglm's vectors
-are array of floats. So you can pass it directly ot those functions:
+are array of floats. So you can pass it directly to those functions:
 .. code-block:: c
--- a/docs/source/opt.rst
+++ b/docs/source/opt.rst
@@ -29,7 +29,7 @@ have to compile cglm with **CGLM_ALL_UNALIGNED** macro.
 if you do not know what you are doing. Because a cglm header included
 via 'project A' may force types to be aligned and another cglm header
 included via 'project B' may not require alignment. In this case
- cglm functions will read from and write to **INVALID MEMORY LOCATIONs**.
+ cglm functions will read from and write to **INVALID MEMORY LOCATIONSNs**.
 ALWAYS USE SAME CONFIGURATION / OPTION for **cglm** if you have multiple projects.
@@ -43,7 +43,7 @@ By starting **v0.8.3** cglm provides options to switch between clipspace configu
 Clipspace related files are located at `include/cglm/[struct]/clipspace.h` but 
 these are included in related files like `cam.h`. If you don't want to change your existing 
 clipspace configuration and want to use different clipspace function like `glm_lookat_zo` or `glm_lookat_lh_zo`...
-then you can include individual headers or just define `CGLM_CLIPSPACE_INCLUDE_ALL` which will iclude all headers for you.
+then you can include individual headers or just define `CGLM_CLIPSPACE_INCLUDE_ALL` which will include all headers for you.
 1. **CGLM_CLIPSPACE_INCLUDE_ALL**
 2. **CGLM_FORCE_DEPTH_ZERO_TO_ONE**
--- a/docs/source/quat.rst
+++ b/docs/source/quat.rst
@@ -422,11 +422,11 @@ Functions documentation
      | *[in]*       **q**      quaternion
      | *[in]*       **pivot**  pivot
-.. c:function:: void glm_quat_make(float * __restrict src, versor dest)
+.. c:function:: void glm_quat_make(const float * __restrict src, versor dest)
    Create quaternion from pointer
-    | NOTE: **@src** must contain at least 4 elements. cglm store quaternions as [x, y, z, w].
+    .. note:: **@src** must contain at least 4 elements. cglm store quaternions as [x, y, z, w].
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
--- a/docs/source/ray.rst
+++ b/docs/source/ray.rst
@@ -13,6 +13,8 @@ Table of contents (click to go):
 Functions:
 1. :c:func:`glm_ray_triangle`
 #. :c:func:`glm_ray_sphere`
 #. :c:func:`glm_ray_at`
 Functions documentation
 ~~~~~~~~~~~~~~~~~~~~~~~
@@ -29,3 +31,37 @@ Functions documentation
      | *[in]*       **v2**            third vertex of triangle
      | *[in, out]*  **d**             float pointer to save distance to intersection
      | *[out]*      **intersection**  whether there is intersection
 .. c:function:: bool glm_ray_sphere(vec3 origin, vec3 dir, vec4 s, float * __restrict t1, float * __restrict t2)
    ray sphere intersection
    - t1 > 0, t2 > 0: ray intersects the sphere at t1 and t2 both ahead of the origin
    - t1 < 0, t2 > 0: ray starts inside the sphere, exits at t2
    - t1 < 0, t2 < 0: no intersection ahead of the ray
    - the caller can check if the intersection points (t1 and t2) fall within a
      specific range (for example, tmin < t1, t2 < tmax) to determine if the
      intersections are within a desired segment of the ray
    Parameters:
      | *[in]*   **origin**  ray origin
      | *[in]*   **dir**     normalized ray direction
      | *[in]*   **s**       sphere  [center.x, center.y, center.z, radii]
      | *[out]*  **t1**      near point1 (closer to origin)
      | *[out]*  **t2**      far point2 (farther from origin)
    Return:
      | whether there is intersection
 .. c:function:: bool  glm_ray_at(vec3 orig, vec3 dir, float t, vec3 point)
    point using t by 𝐏(𝑡)=𝐀+𝑡𝐛
    Parameters:
      | *[in]*   **origin**  ray origin
      | *[in]*   **dir**     ray direction
      | *[out]*  **t**       parameter
      | *[out]*  **point**   point at t
    Return:
      | point at t
--- a/docs/source/sphere.rst
+++ b/docs/source/sphere.rst
@@ -9,7 +9,7 @@ Header: cglm/sphere.h
 Sphere Representation in cglm is *vec4*: **[center.x, center.y, center.z, radii]**
-You can call any vec3 function by pasing sphere. Because first three elements
+You can call any vec3 function by passing sphere. Because first three elements
 defines center of sphere.
 Table of contents (click to go):
--- a/docs/source/util.rst
+++ b/docs/source/util.rst
@@ -68,14 +68,14 @@ Functions documentation
 .. c:function:: void  glm_make_rad(float *degm)
-    | convert exsisting degree to radians. this will override degrees value
+    | convert existing degree to radians. this will override degrees value
    Parameters:
      | *[in, out]*  **deg**      pointer to angle in degrees
 .. c:function:: void  glm_make_deg(float *rad)
-    | convert exsisting radians to degree. this will override radians value
+    | convert existing radians to degree. this will override radians value
    Parameters:
      | *[in, out]*  **rad**      pointer to angle in radians
--- a/docs/source/vec2.rst
+++ b/docs/source/vec2.rst
@@ -53,6 +53,8 @@ Functions:
 #. :c:func:`glm_vec2_clamp`
 #. :c:func:`glm_vec2_lerp`
 #. :c:func:`glm_vec2_make`
 #. :c:func:`glm_vec2_reflect`
 #. :c:func:`glm_vec2_refract`
 Functions documentation
 ~~~~~~~~~~~~~~~~~~~~~~~
@@ -117,7 +119,7 @@ Functions documentation
    norm * norm (magnitude) of vector
    we can use this func instead of calling norm * norm, because it would call
-    sqrtf fuction twice but with this func we can avoid func call, maybe this is
+    sqrtf function twice but with this func we can avoid func call, maybe this is
    not good name for this func
    Parameters:
@@ -385,11 +387,34 @@ Functions documentation
      | *[in]*  **t**      interpolant (amount) clamped between 0 and 1
      | *[out]* **dest**   destination
-.. c:function:: void glm_vec2_make(float * __restrict src, vec2 dest)
+.. c:function:: void glm_vec2_make(const float * __restrict src, vec2 dest)
    Create two dimensional vector from pointer
-    | NOTE: **@src** must contain at least 2 elements.
+    .. note:: **@src** must contain at least 2 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination vector
 .. c:function:: void glm_vec2_reflect(vec2 I, vec2 N, vec2 dest) 
    Reflection vector using an incident ray and a surface normal
    Parameters:
      | *[in]*  **I**     incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[out]* **dest**  destination: reflection result
 .. c:function:: void glm_vec2_refract(vec2 I, vec2 N, float eta, vec2 dest)
    Refraction vector using entering ray, surface normal and refraction index
    If the angle between the entering ray I and the surface normal N is too 
    great for a given refraction index, the return value is zero
    Parameters:
      | *[in]*  **I**     *❗️ normalized ❗️* incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[in]*  **eta**   ratio of indices of refraction ( η )
      | *[out]* **dest**  destination: refraction result
--- a/docs/source/vec3.rst
+++ b/docs/source/vec3.rst
@@ -13,7 +13,7 @@ Header: cglm/vec3.h
 We mostly use vectors in graphics math, to make writing code faster
 and easy to read, some *vec3* functions are aliased in global namespace.
 For instance :c:func:`glm_dot` is alias of :c:func:`glm_vec3_dot`,
-alias means inline wrapper here. There is no call verison of alias functions
+alias means inline wrapper here. There is no call version of alias functions
 There are also functions for rotating *vec3* vector. **_m4**, **_m3** prefixes
 rotate *vec3* with matrix.
@@ -80,6 +80,9 @@ Functions:
 #. :c:func:`glm_vec3_clamp`
 #. :c:func:`glm_vec3_lerp`
 #. :c:func:`glm_vec3_make`
 #. :c:func:`glm_vec3_faceforward`
 #. :c:func:`glm_vec3_reflect`
 #. :c:func:`glm_vec3_refract`
 Functions documentation
 ~~~~~~~~~~~~~~~~~~~~~~~
@@ -148,7 +151,7 @@ Functions documentation
    norm * norm (magnitude) of vector
    we can use this func instead of calling norm * norm, because it would call
-    sqrtf fuction twice but with this func we can avoid func call, maybe this is
+    sqrtf function twice but with this func we can avoid func call, maybe this is
    not good name for this func
    Parameters:
@@ -309,7 +312,7 @@ Functions documentation
 .. c:function:: void  glm_vec3_flipsign(vec3 v)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec3_negate`
@@ -318,7 +321,7 @@ Functions documentation
 .. c:function:: void  glm_vec3_flipsign_to(vec3 v, vec3 dest)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec3_negate_to`
@@ -328,7 +331,7 @@ Functions documentation
 .. c:function:: void  glm_vec3_inv(vec3 v)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec3_negate`
@@ -337,7 +340,7 @@ Functions documentation
 .. c:function:: void  glm_vec3_inv_to(vec3 v, vec3 dest)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec3_negate_to`
@@ -377,7 +380,7 @@ Functions documentation
 .. c:function:: float  glm_vec3_angle(vec3 v1, vec3 v2)
-    angle betwen two vector
+    angle between two vector
    Parameters:
      | *[in]*  **v1**   vector1
@@ -503,12 +506,44 @@ Functions documentation
      | *[in]*  **t**      interpolant (amount) clamped between 0 and 1
      | *[out]* **dest**   destination
-.. c:function:: void glm_vec3_make(float * __restrict src, vec3 dest)
+.. c:function:: void glm_vec3_make(const float * __restrict src, vec3 dest)
    Create three dimensional vector from pointer
-    | NOTE: **@src** must contain at least 3 elements.
+    .. note::: **@src** must contain at least 3 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination vector
 .. c:function:: void glm_vec3_faceforward(vec3 N, vec3 I, vec3 Nref, vec3 dest)
    A vector pointing in the same direction as another
    Parameters:
      | *[in]*  **N**     vector to orient
      | *[in]*  **I**     incident vector
      | *[in]*  **Nref**  reference vector
      | *[out]* **dest**  destination: oriented vector, pointing away from the surface.
 .. c:function:: void glm_vec3_reflect(vec3 I, vec3 N, vec3 dest) 
    Reflection vector using an incident ray and a surface normal
    Parameters:
      | *[in]*  **I**     incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[out]* **dest**  destination: reflection result
 .. c:function:: void glm_vec3_refract(vec3 I, vec3 N, float eta, vec3 dest)
    Refraction vector using entering ray, surface normal and refraction index
    If the angle between the entering ray I and the surface normal N is too 
    great for a given refraction index, the return value is zero
    Parameters:
      | *[in]*  **I**     *❗️ normalized ❗️* incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[in]*  **eta**   ratio of indices of refraction ( η )
      | *[out]* **dest**  destination: refraction result
--- a/docs/source/vec4.rst
+++ b/docs/source/vec4.rst
@@ -60,6 +60,8 @@ Functions:
 #. :c:func:`glm_vec4_lerp`
 #. :c:func:`glm_vec4_cubic`
 #. :c:func:`glm_vec4_make`
 #. :c:func:`glm_vec4_reflect`
 #. :c:func:`glm_vec4_refract`
 Functions documentation
 ~~~~~~~~~~~~~~~~~~~~~~~
@@ -108,6 +110,13 @@ Functions documentation
    Parameters:
      | *[in, out]*  **v**     vector
 .. c:function:: void  glm_vec4_one(vec4 v)
    makes all members one
    Parameters:
      | *[in, out]*  **v**     vector
 .. c:function:: float  glm_vec4_dot(vec4 a, vec4 b)
    dot product of vec4
@@ -124,7 +133,7 @@ Functions documentation
    norm * norm (magnitude) of vector
    we can use this func instead of calling norm * norm, because it would call
-    sqrtf fuction twice but with this func we can avoid func call, maybe this is
+    sqrtf function twice but with this func we can avoid func call, maybe this is
    not good name for this func
    Parameters:
@@ -284,7 +293,7 @@ Functions documentation
 .. c:function:: void  glm_vec4_flipsign(vec4 v)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec4_negate`
@@ -293,7 +302,7 @@ Functions documentation
 .. c:function:: void  glm_vec4_flipsign_to(vec4 v, vec4 dest)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec4_negate_to`
@@ -303,7 +312,7 @@ Functions documentation
 .. c:function:: void  glm_vec4_inv(vec4 v)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec4_negate`
@@ -312,7 +321,7 @@ Functions documentation
 .. c:function:: void  glm_vec4_inv_to(vec4 v, vec4 dest)
-    **DEPRACATED!**
+    **DEPRECATED!**
    use :c:func:`glm_vec4_negate_to`
@@ -408,11 +417,38 @@ Functions documentation
      | *[in]*  **s**      parameter
      | *[out]* **dest**   destination
-.. c:function:: void glm_vec4_make(float * __restrict src, vec4 dest)
+.. c:function:: void glm_vec4_make(const float * __restrict src, vec4 dest)
    Create four dimensional vector from pointer
-    | NOTE: **@src** must contain at least 4 elements.
+    .. note:: **@src** must contain at least 4 elements.
    Parameters:
      | *[in]*  **src**  pointer to an array of floats
      | *[out]* **dest** destination vector
 .. c:function:: void glm_vec4_reflect(vec4 I, vec4 N, vec4 dest) 
    Reflection vector using an incident ray and a surface normal
    Parameters:
      | *[in]*  **I**     incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[out]* **dest**  destination: reflection result
 .. c:function:: void glm_vec4_refract(vec4 I, vec4 N, float eta, vec4 dest)
    Refraction vector using entering ray, surface normal and refraction index
    If the angle between the entering ray I and the surface normal N is too 
    great for a given refraction index, the return value is zero
    this implementation does not explicitly preserve the 'w' component of the
    incident vector 'I' in the output 'dest', users requiring the preservation of
    the 'w' component should manually adjust 'dest' after calling this function.
    Parameters:
      | *[in]*  **I**     *❗️ normalized ❗️* incident vector
      | *[in]*  **N**     *❗️ normalized ❗️* normal vector
      | *[in]*  **eta**   ratio of indices of refraction ( η )
      | *[out]* **dest**  destination: refraction result
--- a/include/cglm/aabb2d.h
+++ b/include/cglm/aabb2d.h
@@ -10,9 +10,23 @@
 #include "common.h"
 #include "vec2.h"
 #include "vec4.h"
 #include "util.h"
 /* DEPRECATED! use _diag */
 #define glm_aabb2d_size(aabb)         glm_aabb2d_diag(aabb)
 /*!
 * @brief make [aabb] zero
 *
 * @param[in, out]  aabb aabb
 */
 CGLM_INLINE
 void
 glm_aabb2d_zero(vec2 aabb[2]) {
  glm_vec2_zero(aabb[0]);
  glm_vec2_zero(aabb[1]);
 }
 /*!
 * @brief copy all members of [aabb] to [dest]
 *
@@ -108,7 +122,7 @@ glm_aabb2d_crop(vec2 aabb[2], vec2 cropAabb[2], vec2 dest[2]) {
 *
 * @param[in]  aabb      bounding aabb
 * @param[in]  cropAabb  crop aabb
- * @param[in]  clampAabb miniumum aabb
+ * @param[in]  clampAabb minimum aabb
 * @param[out] dest      cropped bounding aabb
 */
 CGLM_INLINE
@@ -152,10 +166,22 @@ glm_aabb2d_isvalid(vec2 aabb[2]) {
 */
 CGLM_INLINE
 float
-glm_aabb2d_size(vec2 aabb[2]) {
+glm_aabb2d_diag(vec2 aabb[2]) {
  return glm_vec2_distance(aabb[0], aabb[1]);
 }
 /*!
 * @brief size of aabb
 *
 * @param[in]  aabb bounding aabb
 * @param[out]  dest size
 */
 CGLM_INLINE
 void
 glm_aabb2d_sizev(vec2 aabb[2], vec2 dest) {
  glm_vec2_sub(aabb[1], aabb[0], dest); 
 }
 /*!
 * @brief radius of sphere which surrounds AABB
 *
@@ -164,7 +190,7 @@ glm_aabb2d_size(vec2 aabb[2]) {
 CGLM_INLINE
 float
 glm_aabb2d_radius(vec2 aabb[2]) {
-  return glm_aabb2d_size(aabb) * 0.5f;
+  return glm_aabb2d_diag(aabb) * 0.5f;
 }
 /*!
--- a/include/cglm/affine-post.h
+++ b/include/cglm/affine-post.h
@@ -34,9 +34,9 @@
 * @brief translate existing transform matrix by v vector
 *        and stores result in same matrix
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       v  translate vector [x, y, z]
 */
 CGLM_INLINE
@@ -51,9 +51,9 @@ glm_translated(mat4 m, vec3 v) {
 *
 * source matrix will remain same
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in]  m    affine transfrom
+ * @param[in]  m    affine transform
 * @param[in]  v    translate vector [x, y, z]
 * @param[out] dest translated matrix
 */
@@ -67,9 +67,9 @@ glm_translated_to(mat4 m, vec3 v, mat4 dest) {
 /*!
 * @brief translate existing transform matrix by x factor
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       x  x factor
 */
 CGLM_INLINE
@@ -81,9 +81,9 @@ glm_translated_x(mat4 m, float x) {
 /*!
 * @brief translate existing transform matrix by y factor
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       y  y factor
 */
 CGLM_INLINE
@@ -95,9 +95,9 @@ glm_translated_y(mat4 m, float y) {
 /*!
 * @brief translate existing transform matrix by z factor
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       z  z factor
 */
 CGLM_INLINE
@@ -110,9 +110,9 @@ glm_translated_z(mat4 m, float z) {
 * @brief rotate existing transform matrix around X axis by angle
 *        and store result in dest
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -137,9 +137,9 @@ glm_rotated_x(mat4 m, float angle, mat4 dest) {
 * @brief rotate existing transform matrix around Y axis by angle
 *        and store result in dest
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -164,9 +164,9 @@ glm_rotated_y(mat4 m, float angle, mat4 dest) {
 * @brief rotate existing transform matrix around Z axis by angle
 *        and store result in dest
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -190,9 +190,9 @@ glm_rotated_z(mat4 m, float angle, mat4 dest) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
 */
@@ -208,9 +208,9 @@ glm_rotated(mat4 m, float angle, vec3 axis) {
 * @brief rotate existing transform
 *        around given axis by angle at given pivot point (rotation center)
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       pivot  rotation center
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
@@ -230,9 +230,9 @@ glm_rotated_at(mat4 m, vec3 pivot, float angle, vec3 axis) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
 *
- *  this is POST transform, applies to existing transform as last transfrom
+ *  this is POST transform, applies to existing transform as last transform
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
 */
--- a/include/cglm/affine-pre.h
+++ b/include/cglm/affine-pre.h
@@ -35,7 +35,7 @@
 * @brief translate existing transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       v  translate vector [x, y, z]
 */
 CGLM_INLINE
@@ -66,7 +66,7 @@ glm_translate(mat4 m, vec3 v) {
 *
 * source matrix will remain same
 *
- * @param[in]  m    affine transfrom
+ * @param[in]  m    affine transform
 * @param[in]  v    translate vector [x, y, z]
 * @param[out] dest translated matrix
 */
@@ -80,7 +80,7 @@ glm_translate_to(mat4 m, vec3 v, mat4 dest) {
 /*!
 * @brief translate existing transform matrix by x factor
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       x  x factor
 */
 CGLM_INLINE
@@ -98,7 +98,7 @@ glm_translate_x(mat4 m, float x) {
 /*!
 * @brief translate existing transform matrix by y factor
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       y  y factor
 */
 CGLM_INLINE
@@ -116,7 +116,7 @@ glm_translate_y(mat4 m, float y) {
 /*!
 * @brief translate existing transform matrix by z factor
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       z  z factor
 */
 CGLM_INLINE
@@ -135,7 +135,7 @@ glm_translate_z(mat4 m, float z) {
 * @brief rotate existing transform matrix around X axis by angle
 *        and store result in dest
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -160,7 +160,7 @@ glm_rotate_x(mat4 m, float angle, mat4 dest) {
 * @brief rotate existing transform matrix around Y axis by angle
 *        and store result in dest
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -185,7 +185,7 @@ glm_rotate_y(mat4 m, float angle, mat4 dest) {
 * @brief rotate existing transform matrix around Z axis by angle
 *        and store result in dest
 *
- * @param[in]   m      affine transfrom
+ * @param[in]   m      affine transform
 * @param[in]   angle  angle (radians)
 * @param[out]  dest   rotated matrix
 */
@@ -207,9 +207,27 @@ glm_rotate_z(mat4 m, float angle, mat4 dest) {
 }
 /*!
- * @brief rotate existing transform matrix around given axis by angle
+ * @brief rotate existing transform matrix 
 *        around given axis by angle at ORIGIN (0,0,0)
 *
- * @param[in, out]  m      affine transfrom
+ *   **❗️IMPORTANT ❗️**
 *
 *   If you need to rotate object around itself e.g. center of object or at
 *   some point [of object] then `glm_rotate_at()` would be better choice to do so.
 *
 *   Even if object's model transform is identiy, rotation may not be around
 *   center of object if object does not lay out at ORIGIN perfectly.
 *
 *   Using `glm_rotate_at()` with center of bounding shape ( AABB, Sphere ... )
 *   would be an easy option to rotate around object if object is not at origin.
 *
 *   One another option to rotate around itself at any point is `glm_spin()`
 *   which is perfect if only rotating around model position is desired e.g. not
 *   specific point on model for instance center of geometry or center of mass,
 *   again if geometry is not perfectly centered at origin at identity transform,
 *   rotation may not be around geometry.
 *
 * @param[in, out]  m      affine transform
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
 */
@@ -225,7 +243,7 @@ glm_rotate(mat4 m, float angle, vec3 axis) {
 * @brief rotate existing transform
 *        around given axis by angle at given pivot point (rotation center)
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       pivot  rotation center
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
@@ -250,7 +268,7 @@ glm_rotate_at(mat4 m, vec3 pivot, float angle, vec3 axis) {
 * this should work faster than glm_rotate_at because it reduces
 * one glm_translate.
 *
- * @param[out] m      affine transfrom
+ * @param[out] m      affine transform
 * @param[in]  pivot  rotation center
 * @param[in]  angle  angle (radians)
 * @param[in]  axis   axis
@@ -268,9 +286,10 @@ glm_rotate_atm(mat4 m, vec3 pivot, float angle, vec3 axis) {
 }
 /*!
- * @brief rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
+ * @brief rotate existing transform matrix 
 *        around given axis by angle around self (doesn't affected by position)
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       angle  angle (radians)
 * @param[in]       axis   axis
 */
--- a/include/cglm/affine.h
+++ b/include/cglm/affine.h
@@ -44,7 +44,7 @@
 /*!
 * @brief creates NEW translate transform matrix by v vector
 *
- * @param[out]  m  affine transfrom
+ * @param[out]  m  affine transform
 * @param[in]   v  translate vector [x, y, z]
 */
 CGLM_INLINE
@@ -58,7 +58,7 @@ glm_translate_make(mat4 m, vec3 v) {
 * @brief scale existing transform matrix by v vector
 *        and store result in dest
 *
- * @param[in]  m    affine transfrom
+ * @param[in]  m    affine transform
 * @param[in]  v    scale vector [x, y, z]
 * @param[out] dest scaled matrix
 */
@@ -75,7 +75,7 @@ glm_scale_to(mat4 m, vec3 v, mat4 dest) {
 /*!
 * @brief creates NEW scale matrix by v vector
 *
- * @param[out]  m  affine transfrom
+ * @param[out]  m  affine transform
 * @param[in]   v  scale vector [x, y, z]
 */
 CGLM_INLINE
@@ -91,7 +91,7 @@ glm_scale_make(mat4 m, vec3 v) {
 * @brief scales existing transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       v  scale vector [x, y, z]
 */
 CGLM_INLINE
@@ -104,7 +104,7 @@ glm_scale(mat4 m, vec3 v) {
 * @brief applies uniform scale to existing transform matrix v = [s, s, s]
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       s  scale factor
 */
 CGLM_INLINE
@@ -119,7 +119,7 @@ glm_scale_uni(mat4 m, float s) {
 *
 * axis will be normalized so you don't need to normalize it
 *
- * @param[out] m     affine transfrom
+ * @param[out] m     affine transform
 * @param[in]  angle angle (radians)
 * @param[in]  axis  axis
 */
@@ -220,7 +220,7 @@ glm_decompose_rs(mat4 m, mat4 r, vec3 s) {
 * @brief decompose affine transform, TODO: extract shear factors.
 *        DON'T pass projected matrix here
 *
- * @param[in]  m affine transfrom
+ * @param[in]  m affine transform
 * @param[out] t translation vector
 * @param[out] r rotation matrix (mat4)
 * @param[out] s scaling vector [X, Y, Z]
--- a/include/cglm/affine2d.h
+++ b/include/cglm/affine2d.h
@@ -33,7 +33,7 @@
 * @brief translate existing 2d transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       v  translate vector [x, y]
 */
 CGLM_INLINE
@@ -50,7 +50,7 @@ glm_translate2d(mat3 m, vec2 v) {
 *
 * source matrix will remain same
 *
- * @param[in]  m    affine transfrom
+ * @param[in]  m    affine transform
 * @param[in]  v    translate vector [x, y]
 * @param[out] dest translated matrix
 */
@@ -64,7 +64,7 @@ glm_translate2d_to(mat3 m, vec2 v, mat3 dest) {
 /*!
 * @brief translate existing 2d transform matrix by x factor
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       x  x factor
 */
 CGLM_INLINE
@@ -78,7 +78,7 @@ glm_translate2d_x(mat3 m, float x) {
 /*!
 * @brief translate existing 2d transform matrix by y factor
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       y  y factor
 */
 CGLM_INLINE
@@ -92,7 +92,7 @@ glm_translate2d_y(mat3 m, float y) {
 /*!
 * @brief creates NEW translate 2d transform matrix by v vector
 *
- * @param[out]  m  affine transfrom
+ * @param[out]  m  affine transform
 * @param[in]   v  translate vector [x, y]
 */
 CGLM_INLINE
@@ -107,7 +107,7 @@ glm_translate2d_make(mat3 m, vec2 v) {
 * @brief scale existing 2d transform matrix by v vector
 *        and store result in dest
 *
- * @param[in]  m    affine transfrom
+ * @param[in]  m    affine transform
 * @param[in]  v    scale vector [x, y]
 * @param[out] dest scaled matrix
 */
@@ -130,7 +130,7 @@ glm_scale2d_to(mat3 m, vec2 v, mat3 dest) {
 /*!
 * @brief creates NEW 2d scale matrix by v vector
 *
- * @param[out]  m  affine transfrom
+ * @param[out]  m  affine transform
 * @param[in]   v  scale vector [x, y]
 */
 CGLM_INLINE
@@ -145,7 +145,7 @@ glm_scale2d_make(mat3 m, vec2 v) {
 * @brief scales existing 2d transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       v  scale vector [x, y]
 */
 CGLM_INLINE
@@ -164,7 +164,7 @@ glm_scale2d(mat3 m, vec2 v) {
 * @brief applies uniform scale to existing 2d transform matrix v = [s, s]
 *        and stores result in same matrix
 *
- * @param[in, out]  m  affine transfrom
+ * @param[in, out]  m  affine transform
 * @param[in]       s  scale factor
 */
 CGLM_INLINE
@@ -182,7 +182,7 @@ glm_scale2d_uni(mat3 m, float s) {
 /*!
 * @brief creates NEW rotation matrix by angle around Z axis
 *
- * @param[out] m     affine transfrom
+ * @param[out] m     affine transform
 * @param[in]  angle angle (radians)
 */
 CGLM_INLINE
@@ -210,7 +210,7 @@ glm_rotate2d_make(mat3 m, float angle) {
 * @brief rotate existing 2d transform matrix around Z axis by angle
 *         and store result in same matrix
 *
- * @param[in, out]  m      affine transfrom
+ * @param[in, out]  m      affine transform
 * @param[in]       angle  angle (radians)
 */
 CGLM_INLINE
@@ -237,7 +237,7 @@ glm_rotate2d(mat3 m, float angle) {
 * @brief rotate existing 2d transform matrix around Z axis by angle
 *        and store result in dest
 *
- * @param[in]  m      affine transfrom
+ * @param[in]  m      affine transform
 * @param[in]  angle  angle (radians)
 * @param[out] dest   destination
 */
--- a/include/cglm/box.h
+++ b/include/cglm/box.h
@@ -104,7 +104,7 @@ glm_aabb_crop(vec3 box[2], vec3 cropBox[2], vec3 dest[2]) {
 *
 * @param[in]  box      bounding box
 * @param[in]  cropBox  crop box
- * @param[in]  clampBox miniumum box
+ * @param[in]  clampBox minimum box
 * @param[out] dest     cropped bounding box
 */
 CGLM_INLINE
--- a/include/cglm/call/aabb2d.h
+++ b/include/cglm/call/aabb2d.h
@@ -13,6 +13,13 @@ extern "C" {
 #include "../cglm.h"
 /* DEPRECATED! use _diag */
 #define glmc_aabb2d_size(aabb) glmc_aabb2d_diag(aabb)
 CGLM_EXPORT
 void
 glmc_aabb2d_zero(vec2 aabb[2]);
 CGLM_EXPORT
 void
 glmc_aabb2d_copy(vec2 aabb[2], vec2 dest[2]);
@@ -46,7 +53,11 @@ glmc_aabb2d_isvalid(vec2 aabb[2]);
 CGLM_EXPORT
 float
-glmc_aabb2d_size(vec2 aabb[2]);
+glmc_aabb2d_diag(vec2 aabb[2]);
 CGLM_EXPORT
 void
 glmc_aabb2d_sizev(vec2 aabb[2], vec2 dest);
 CGLM_EXPORT
 float
--- a/include/cglm/call/ivec2.h
+++ b/include/cglm/call/ivec2.h
@@ -29,6 +29,14 @@ CGLM_EXPORT
 void
 glmc_ivec2_one(ivec2 v);
 CGLM_EXPORT
 int
 glmc_ivec2_dot(ivec2 a, ivec2 b);
 CGLM_EXPORT
 int
 glmc_ivec2_cross(ivec2 a, ivec2 b);
 CGLM_EXPORT
 void
 glmc_ivec2_add(ivec2 a, ivec2 b, ivec2 dest);
@@ -53,6 +61,18 @@ CGLM_EXPORT
 void
 glmc_ivec2_scale(ivec2 v, int s, ivec2 dest);
 CGLM_EXPORT
 void
 glmc_ivec2_div(ivec2 a, ivec2 b, ivec2 dest);
 CGLM_EXPORT
 void
 glmc_ivec2_divs(ivec2 v, int s, ivec2 dest);
 CGLM_EXPORT
 void
 glmc_ivec2_mod(ivec2 a, ivec2 b, ivec2 dest);
 CGLM_EXPORT 
 void 
 glmc_ivec2_addadd(ivec2 a, ivec2 b, ivec2 dest);
--- a/include/cglm/call/ivec3.h
+++ b/include/cglm/call/ivec3.h
@@ -29,6 +29,18 @@ CGLM_EXPORT
 void
 glmc_ivec3_one(ivec3 v);
 CGLM_EXPORT
 int
 glmc_ivec3_dot(ivec3 a, ivec3 b);
 CGLM_EXPORT
 int
 glmc_ivec3_norm2(ivec3 v);
 CGLM_EXPORT
 int
 glmc_ivec3_norm(ivec3 v);
 CGLM_EXPORT
 void
 glmc_ivec3_add(ivec3 a, ivec3 b, ivec3 dest);
@@ -53,6 +65,18 @@ CGLM_EXPORT
 void
 glmc_ivec3_scale(ivec3 v, int s, ivec3 dest);
 CGLM_EXPORT
 void
 glmc_ivec3_div(ivec3 a, ivec3 b, ivec3 dest);
 CGLM_EXPORT
 void
 glmc_ivec3_divs(ivec3 v, int s, ivec3 dest);
 CGLM_EXPORT
 void
 glmc_ivec3_mod(ivec3 a, ivec3 b, ivec3 dest);
 CGLM_EXPORT 
 void 
 glmc_ivec3_addadd(ivec3 a, ivec3 b, ivec3 dest);
--- a/include/cglm/call/mat2.h
+++ b/include/cglm/call/mat2.h
@@ -75,7 +75,7 @@ glmc_mat2_rmc(vec2 r, mat2 m, vec2 c);
 CGLM_EXPORT
 void
-glmc_mat2_make(float * __restrict src, mat2 dest);
+glmc_mat2_make(const float * __restrict src, mat2 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/mat2x3.h
+++ b/include/cglm/call/mat2x3.h
@@ -23,7 +23,7 @@ glmc_mat2x3_zero(mat2x3 mat);
 CGLM_EXPORT
 void
-glmc_mat2x3_make(float * __restrict src, mat2x3 dest);
+glmc_mat2x3_make(const float * __restrict src, mat2x3 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/mat2x4.h
+++ b/include/cglm/call/mat2x4.h
@@ -23,7 +23,7 @@ glmc_mat2x4_zero(mat2x4 mat);
 CGLM_EXPORT
 void
-glmc_mat2x4_make(float * __restrict src, mat2x4 dest);
+glmc_mat2x4_make(const float * __restrict src, mat2x4 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/mat3.h
+++ b/include/cglm/call/mat3.h
@@ -82,7 +82,7 @@ glmc_mat3_rmc(vec3 r, mat3 m, vec3 c);
 CGLM_EXPORT
 void
-glmc_mat3_make(float * __restrict src, mat3 dest);
+glmc_mat3_make(const float * __restrict src, mat3 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/mat3x2.h
+++ b/include/cglm/call/mat3x2.h
@@ -23,7 +23,7 @@ glmc_mat3x2_zero(mat3x2 mat);
 CGLM_EXPORT
 void
-glmc_mat3x2_make(float * __restrict src, mat3x2 dest);
+glmc_mat3x2_make(const float * __restrict src, mat3x2 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/mat3x4.h
+++ b/include/cglm/call/mat3x4.h
@@ -23,7 +23,7 @@ glmc_mat3x4_zero(mat3x4 mat);
 CGLM_EXPORT
 void
-glmc_mat3x4_make(float * __restrict src, mat3x4 dest);
+glmc_mat3x4_make(const float * __restrict src, mat3x4 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/mat4.h
+++ b/include/cglm/call/mat4.h
@@ -123,7 +123,7 @@ glmc_mat4_rmc(vec4 r, mat4 m, vec4 c);
 CGLM_EXPORT
 void
-glmc_mat4_make(float * __restrict src, mat4 dest);
+glmc_mat4_make(const float * __restrict src, mat4 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/mat4x2.h
+++ b/include/cglm/call/mat4x2.h
@@ -23,7 +23,7 @@ glmc_mat4x2_zero(mat4x2 mat);
 CGLM_EXPORT
 void
-glmc_mat4x2_make(float * __restrict src, mat4x2 dest);
+glmc_mat4x2_make(const float * __restrict src, mat4x2 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/mat4x3.h
+++ b/include/cglm/call/mat4x3.h
@@ -23,7 +23,7 @@ glmc_mat4x3_zero(mat4x3 mat);
 CGLM_EXPORT
 void
-glmc_mat4x3_make(float * __restrict src, mat4x3 dest);
+glmc_mat4x3_make(const float * __restrict src, mat4x3 dest);
 CGLM_EXPORT
 void
--- a/include/cglm/call/quat.h
+++ b/include/cglm/call/quat.h
@@ -163,7 +163,7 @@ glmc_quat_rotate_atm(mat4 m, versor q, vec3 pivot);
 CGLM_EXPORT
 void
-glmc_quat_make(float * __restrict src, versor dest);
+glmc_quat_make(const float * __restrict src, versor dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/ray.h
+++ b/include/cglm/call/ray.h
@@ -20,7 +20,19 @@ glmc_ray_triangle(vec3   origin,
                  vec3   v1,
                  vec3   v2,
                  float *d);
-    
+
 CGLM_EXPORT
 bool
 glmc_ray_sphere(vec3 origin,
                vec3 dir,
                vec4 s,
                float * __restrict t1,
                float * __restrict t2);
 CGLM_EXPORT
 void
 glmc_ray_at(vec3 orig, vec3 dir, float t, vec3 point);
 #ifdef __cplusplus
 }
 #endif
--- a/include/cglm/call/vec2.h
+++ b/include/cglm/call/vec2.h
@@ -195,7 +195,15 @@ glmc_vec2_complex_conjugate(vec2 a, vec2 dest);
 CGLM_EXPORT
 void
-glmc_vec2_make(float * __restrict src, vec2 dest);
+glmc_vec2_make(const float * __restrict src, vec2 dest);
 CGLM_EXPORT
 void
 glmc_vec2_reflect(vec2 I, vec2 N, vec2 dest);
 CGLM_EXPORT
 void
 glmc_vec2_refract(vec2 I, vec2 N, float eta, vec2 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/vec3.h
+++ b/include/cglm/call/vec3.h
@@ -332,7 +332,19 @@ glmc_vec3_sqrt(vec3 v, vec3 dest);
 CGLM_EXPORT
 void
-glmc_vec3_make(float * __restrict src, vec3 dest);
+glmc_vec3_make(const float * __restrict src, vec3 dest);
 CGLM_EXPORT
 void
 glmc_vec3_faceforward(vec3 N, vec3 I, vec3 Nref, vec3 dest);
 CGLM_EXPORT
 void
 glmc_vec3_reflect(vec3 I, vec3 N, vec3 dest);
 CGLM_EXPORT
 void
 glmc_vec3_refract(vec3 I, vec3 N, float eta, vec3 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/call/vec4.h
+++ b/include/cglm/call/vec4.h
@@ -309,7 +309,15 @@ glmc_vec4_sqrt(vec4 v, vec4 dest);
 CGLM_EXPORT
 void
-glmc_vec4_make(float * __restrict src, vec4 dest);
+glmc_vec4_make(const float * __restrict src, vec4 dest);
 CGLM_EXPORT
 void
 glmc_vec4_reflect(vec4 I, vec4 N, vec4 dest);
 CGLM_EXPORT
 void
 glmc_vec4_refract(vec4 I, vec4 N, float eta, vec4 dest);
 #ifdef __cplusplus
 }
--- a/include/cglm/cam.h
+++ b/include/cglm/cam.h
@@ -474,7 +474,7 @@ glm_persp_decomp_x(mat4 proj,
 /*!
 * @brief decomposes top and bottom values of perspective projection.
- *        y stands for y axis (top / botom axis)
+ *        y stands for y axis (top / bottom axis)
 *
 * @param[in]  proj   perspective projection matrix
 * @param[out] top    top
--- a/include/cglm/clipspace/persp_lh_no.h
+++ b/include/cglm/clipspace/persp_lh_no.h
@@ -266,7 +266,7 @@ glm_persp_decomp_x_lh_no(mat4 proj,
 * @brief decomposes top and bottom values of perspective projection
 *        with a left-hand coordinate system and a
 *        clip-space of [-1, 1].
- *        y stands for y axis (top / botom axis)
+ *        y stands for y axis (top / bottom axis)
 *
 * @param[in]  proj   perspective projection matrix
 * @param[out] top    top
--- a/include/cglm/clipspace/persp_rh_no.h
+++ b/include/cglm/clipspace/persp_rh_no.h
@@ -266,7 +266,7 @@ glm_persp_decomp_x_rh_no(mat4 proj,
 * @brief decomposes top and bottom values of perspective projection
 *        with a right-hand coordinate system and a
 *        clip-space of [-1, 1].
- *        y stands for y axis (top / botom axis)
+ *        y stands for y axis (top / bottom axis)
 *
 * @param[in]  proj   perspective projection matrix
 * @param[out] top    top
--- a/include/cglm/ease.h
+++ b/include/cglm/ease.h
@@ -235,7 +235,7 @@ glm_ease_back_inout(float t) {
  o = 1.70158f;
  s = o * 1.525f;
-  x = 0.5;
+  x = 0.5f;
  n = t / 0.5f;
  if (n < 1.0f) {
--- a/include/cglm/euler.h
+++ b/include/cglm/euler.h
@@ -9,7 +9,7 @@
 NOTE:
  angles must be passed as [X-Angle, Y-Angle, Z-angle] order
  For instance you don't pass angles as [Z-Angle, X-Angle, Y-angle] to
-  glm_euler_zxy funciton, All RELATED functions accept angles same order
+  glm_euler_zxy function, All RELATED functions accept angles same order
  which is [X, Y, Z].
 */
--- a/include/cglm/io.h
+++ b/include/cglm/io.h
@@ -38,7 +38,7 @@
 #ifndef cglm_io_h
 #define cglm_io_h
-#if defined(DEBUG) || defined(_DEBUG) \
+#if !defined(NDEBUG) \
   || defined(CGLM_DEFINE_PRINTS) || defined(CGLM_LIB_SRC) \
   || defined(CGLM_NO_PRINTS_NOOP)
--- a/include/cglm/ivec2.h
+++ b/include/cglm/ivec2.h
@@ -17,12 +17,17 @@
  CGLM_INLINE void glm_ivec2_copy(ivec2 a, ivec2 dest)
  CGLM_INLINE void glm_ivec2_zero(ivec2 v)
  CGLM_INLINE void glm_ivec2_one(ivec2 v)
  CGLM_INLINE int glm_ivec2_dot(ivec2 a, ivec2 b)
  CGLM_INLINE int glm_ivec2_cross(ivec2 a, ivec2 b)
  CGLM_INLINE void glm_ivec2_add(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_adds(ivec2 v, int s, ivec2 dest)
  CGLM_INLINE void glm_ivec2_sub(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_subs(ivec2 v, int s, ivec2 dest)
  CGLM_INLINE void glm_ivec2_mul(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_scale(ivec2 v, int s, ivec2 dest)
  CGLM_INLINE void glm_ivec2_div(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_divs(ivec2 v, int s, ivec2 dest)
  CGLM_INLINE void glm_ivec2_mod(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_addadd(ivec2 a, ivec2 b, ivec2 dest)
  CGLM_INLINE void glm_ivec2_addadds(ivec2 a, int s, ivec2 dest)
  CGLM_INLINE void glm_ivec2_subadd(ivec2 a, ivec2 b, ivec2 dest)
@@ -110,6 +115,36 @@ glm_ivec2_one(ivec2 v) {
  v[0] = v[1] = 1;
 }
 /*!
 * @brief ivec2 dot product
 *
 * @param[in] a vector1
 * @param[in] b vector2
 *
 * @return dot product
 */
 CGLM_INLINE
 int
 glm_ivec2_dot(ivec2 a, ivec2 b) {
  return a[0] * b[0] + a[1] * b[1];
 }
 /*!
 * @brief ivec2 cross product
 *
 * REF: http://allenchou.net/2013/07/cross-product-of-2d-vectors/
 *
 * @param[in]  a vector1
 * @param[in]  b vector2
 *
 * @return Z component of cross product
 */
 CGLM_INLINE
 int
 glm_ivec2_cross(ivec2 a, ivec2 b) {
  return a[0] * b[1] - a[1] * b[0];
 }
 /*!
 * @brief add vector [a] to vector [b] and store result in [dest]
 *
@@ -169,7 +204,7 @@ glm_ivec2_subs(ivec2 v, int s, ivec2 dest) {
 /*!
 * @brief multiply vector [a] with vector [b] and store result in [dest]
 *
- * @param[in]  a    frist vector
+ * @param[in]  a    first vector
 * @param[in]  b    second vector
 * @param[out] dest destination
 */
@@ -194,6 +229,48 @@ glm_ivec2_scale(ivec2 v, int s, ivec2 dest) {
  dest[1] = v[1] * s;
 }
 /*!
 * @brief div vector with another component-wise division: d = a / b
 *
 * @param[in]  a    vector 1
 * @param[in]  b    vector 2
 * @param[out] dest result = (a[0]/b[0], a[1]/b[1])
 */
 CGLM_INLINE
 void
 glm_ivec2_div(ivec2 a, ivec2 b, ivec2 dest) {
  dest[0] = a[0] / b[0];
  dest[1] = a[1] / b[1];
 }
 /*!
 * @brief div vector with scalar: d = v / s
 *
 * @param[in]  v    vector
 * @param[in]  s    scalar
 * @param[out] dest result = (a[0]/s, a[1]/s)
 */
 CGLM_INLINE
 void
 glm_ivec2_divs(ivec2 v, int s, ivec2 dest) {
  dest[0] = v[0] / s;
  dest[1] = v[1] / s;
 }
 /*!
 * @brief mod vector with another component-wise modulo: d = a % b
 *
 * @param[in]  a    vector 1
 * @param[in]  b    vector 2
 * @param[out] dest result = (a[0]%b[0], a[1]%b[1])
 */
 CGLM_INLINE
 void
 glm_ivec2_mod(ivec2 a, ivec2 b, ivec2 dest) {
  dest[0] = a[0] % b[0];
  dest[1] = a[1] % b[1];
 }
 /*!
 * @brief add vector [a] with vector [b] and add result to vector [dest]
 *
--- a/include/cglm/ivec3.h
+++ b/include/cglm/ivec3.h
@@ -17,12 +17,18 @@
  CGLM_INLINE void glm_ivec3_copy(ivec3 a, ivec3 dest)
  CGLM_INLINE void glm_ivec3_zero(ivec3 v)
  CGLM_INLINE void glm_ivec3_one(ivec3 v)
  CGLM_INLINE int glm_ivec3_dot(ivec3 a, ivec3 b)
  CGLM_INLINE int glm_ivec3_norm2(ivec3 v)
  CGLM_INLINE int glm_ivec3_norm(ivec3 v)
  CGLM_INLINE void glm_ivec3_add(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_adds(ivec3 v, int s, ivec3 dest)
  CGLM_INLINE void glm_ivec3_sub(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_subs(ivec3 v, int s, ivec3 dest)
  CGLM_INLINE void glm_ivec3_mul(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_scale(ivec3 v, int s, ivec3 dest)
  CGLM_INLINE void glm_ivec3_div(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_divs(ivec3 v, int s, ivec3 dest)
  CGLM_INLINE void glm_ivec3_mod(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_addadd(ivec3 a, ivec3 b, ivec3 dest)
  CGLM_INLINE void glm_ivec3_addadds(ivec3 a, int s, ivec3 dest)
  CGLM_INLINE void glm_ivec3_subadd(ivec3 a, ivec3 b, ivec3 dest)
@@ -112,6 +118,51 @@ glm_ivec3_one(ivec3 v) {
  v[0] = v[1] = v[2] = 1;
 }
 /*!
 * @brief ivec3 dot product
 *
 * @param[in] a vector1
 * @param[in] b vector2
 *
 * @return dot product
 */
 CGLM_INLINE
 int
 glm_ivec3_dot(ivec3 a, ivec3 b) {
  return a[0] * b[0] + a[1] * b[1] + a[2] * b[2];
 }
 /*!
 * @brief norm * norm (magnitude) of vec
 *
 * we can use this func instead of calling norm * norm, because it would call
 * sqrtf function twice but with this func we can avoid func call, maybe this is
 * not good name for this func
 *
 * @param[in] v vector
 *
 * @return norm * norm
 */
 CGLM_INLINE
 int
 glm_ivec3_norm2(ivec3 v) {
  return glm_ivec3_dot(v, v);
 }
 /*!
 * @brief euclidean norm (magnitude), also called L2 norm
 *        this will give magnitude of vector in euclidean space
 *
 * @param[in] v vector
 *
 * @return norm
 */
 CGLM_INLINE
 int
 glm_ivec3_norm(ivec3 v) {
  return (int)sqrtf((float)glm_ivec3_norm2(v));
 }
 /*!
 * @brief add vector [a] to vector [b] and store result in [dest]
 *
@@ -175,7 +226,7 @@ glm_ivec3_subs(ivec3 v, int s, ivec3 dest) {
 /*!
 * @brief multiply vector [a] with vector [b] and store result in [dest]
 *
- * @param[in]  a    frist vector
+ * @param[in]  a    first vector
 * @param[in]  b    second vector
 * @param[out] dest destination
 */
@@ -202,6 +253,53 @@ glm_ivec3_scale(ivec3 v, int s, ivec3 dest) {
  dest[2] = v[2] * s;
 }
 /*!
 * @brief div vector with another component-wise division: d = a / b
 *
 * @param[in]  a    vector 1
 * @param[in]  b    vector 2
 * @param[out] dest result = (a[0]/b[0], a[1]/b[1], a[2]/b[2])
 */
 CGLM_INLINE
 void
 glm_ivec3_div(ivec3 a, ivec3 b, ivec3 dest) {
  dest[0] = a[0] / b[0];
  dest[1] = a[1] / b[1];
  dest[2] = a[2] / b[2];
 }
 /*!
 * @brief div vector with scalar: d = v / s
 *
 * @param[in]  v    vector
 * @param[in]  s    scalar
 * @param[out] dest result = (a[0]/s, a[1]/s, a[2]/s)
 */
 CGLM_INLINE
 void
 glm_ivec3_divs(ivec3 v, int s, ivec3 dest) {
  dest[0] = v[0] / s;
  dest[1] = v[1] / s;
  dest[2] = v[2] / s;
 }
 /*!
 * @brief Element-wise modulo operation on ivec3 vectors: dest = a % b
 *
 * Performs element-wise modulo on each component of vectors `a` and `b`.
 *
 * @param[in]  a    vector 1
 * @param[in]  b    vector 2
 * @param[out] dest result = (a[0]%b[0], a[1]%b[1], a[2]%b[2])
 */
 CGLM_INLINE
 void
 glm_ivec3_mod(ivec3 a, ivec3 b, ivec3 dest) {
  dest[0] = a[0] % b[0];
  dest[1] = a[1] % b[1];
  dest[2] = a[2] % b[2];
 }
 /*!
 * @brief add vector [a] with vector [b] and add result to vector [dest]
 *
--- a/include/cglm/ivec4.h
+++ b/include/cglm/ivec4.h
@@ -179,7 +179,7 @@ glm_ivec4_subs(ivec4 v, int s, ivec4 dest) {
 /*!
 * @brief multiply vector [a] with vector [b] and store result in [dest]
 *
- * @param[in]  a    frist vector
+ * @param[in]  a    first vector
 * @param[in]  b    second vector
 * @param[out] dest destination
 */
--- a/include/cglm/mat2.h
+++ b/include/cglm/mat2.h
@@ -180,7 +180,7 @@ glm_mat2_transpose_to(mat2 m, mat2 dest) {
 }
 /*!
- * @brief tranpose mat2 and store result in same matrix
+ * @brief transpose mat2 and store result in same matrix
 *
 * @param[in, out] m source and dest
 */
@@ -354,7 +354,7 @@ glm_mat2_rmc(vec2 r, mat2 m, vec2 c) {
 */
 CGLM_INLINE
 void
-glm_mat2_make(float * __restrict src, mat2 dest) {
+glm_mat2_make(const float * __restrict src, mat2 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[1][0] = src[2];
--- a/include/cglm/mat2x3.h
+++ b/include/cglm/mat2x3.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat2x3_copy(mat2x3 mat, mat2x3 dest);
   CGLM_INLINE void glm_mat2x3_zero(mat2x3 mat);
-   CGLM_INLINE void glm_mat2x3_make(float * __restrict src, mat2x3 dest);
+   CGLM_INLINE void glm_mat2x3_make(const float * __restrict src, mat2x3 dest);
   CGLM_INLINE void glm_mat2x3_mul(mat2x3 m1, mat3x2 m2, mat2 dest);
   CGLM_INLINE void glm_mat2x3_mulv(mat2x3 m, vec3 v, vec2 dest);
   CGLM_INLINE void glm_mat2x3_transpose(mat2x3 m, mat3x2 dest);
@@ -68,7 +68,7 @@ glm_mat2x3_zero(mat2x3 mat) {
 */
 CGLM_INLINE
 void
-glm_mat2x3_make(float * __restrict src, mat2x3 dest) {
+glm_mat2x3_make(const float * __restrict src, mat2x3 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[0][2] = src[2];
--- a/include/cglm/mat2x4.h
+++ b/include/cglm/mat2x4.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat2x4_copy(mat2x4 mat, mat2x4 dest);
   CGLM_INLINE void glm_mat2x4_zero(mat2x4 mat);
-   CGLM_INLINE void glm_mat2x4_make(float * __restrict src, mat2x4 dest);
+   CGLM_INLINE void glm_mat2x4_make(const float * __restrict src, mat2x4 dest);
   CGLM_INLINE void glm_mat2x4_mul(mat2x4 m1, mat4x2 m2, mat2 dest);
   CGLM_INLINE void glm_mat2x4_mulv(mat2x4 m, vec4 v, vec2 dest);
   CGLM_INLINE void glm_mat2x4_transpose(mat2x4 m, mat4x2 dest);
@@ -64,7 +64,7 @@ glm_mat2x4_zero(mat2x4 mat) {
 */
 CGLM_INLINE
 void
-glm_mat2x4_make(float * __restrict src, mat2x4 dest) {
+glm_mat2x4_make(const float * __restrict src, mat2x4 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[0][2] = src[2];
--- a/include/cglm/mat3.h
+++ b/include/cglm/mat3.h
@@ -201,7 +201,7 @@ glm_mat3_transpose_to(mat3 m, mat3 dest) {
 }
 /*!
- * @brief tranpose mat3 and store result in same matrix
+ * @brief transpose mat3 and store result in same matrix
 *
 * @param[in, out] m source and dest
 */
@@ -436,7 +436,7 @@ glm_mat3_rmc(vec3 r, mat3 m, vec3 c) {
 */
 CGLM_INLINE
 void
-glm_mat3_make(float * __restrict src, mat3 dest) {
+glm_mat3_make(const float * __restrict src, mat3 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[0][2] = src[2];
--- a/include/cglm/mat3x2.h
+++ b/include/cglm/mat3x2.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat3x2_copy(mat3x2 mat, mat3x2 dest);
   CGLM_INLINE void glm_mat3x2_zero(mat3x2 mat);
-   CGLM_INLINE void glm_mat3x2_make(float * __restrict src, mat3x2 dest);
+   CGLM_INLINE void glm_mat3x2_make(const float * __restrict src, mat3x2 dest);
   CGLM_INLINE void glm_mat3x2_mul(mat3x2 m1, mat2x3 m2, mat3 dest);
   CGLM_INLINE void glm_mat3x2_mulv(mat3x2 m, vec2 v, vec3 dest);
   CGLM_INLINE void glm_mat3x2_transpose(mat3x2 m, mat2x3 dest);
@@ -69,7 +69,7 @@ glm_mat3x2_zero(mat3x2 mat) {
 */
 CGLM_INLINE
 void
-glm_mat3x2_make(float * __restrict src, mat3x2 dest) {
+glm_mat3x2_make(const float * __restrict src, mat3x2 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
--- a/include/cglm/mat3x4.h
+++ b/include/cglm/mat3x4.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat3x4_copy(mat3x4 mat, mat3x4 dest);
   CGLM_INLINE void glm_mat3x4_zero(mat3x4 mat);
-   CGLM_INLINE void glm_mat3x4_make(float * __restrict src, mat3x4 dest);
+   CGLM_INLINE void glm_mat3x4_make(const float * __restrict src, mat3x4 dest);
   CGLM_INLINE void glm_mat3x4_mul(mat3x4 m1, mat4x3 m2, mat3 dest);
   CGLM_INLINE void glm_mat3x4_mulv(mat3x4 m, vec4 v, vec3 dest);
   CGLM_INLINE void glm_mat3x4_transpose(mat3x4 m, mat4x3 dest);
@@ -66,7 +66,7 @@ glm_mat3x4_zero(mat3x4 mat) {
 */
 CGLM_INLINE
 void
-glm_mat3x4_make(float * __restrict src, mat3x4 dest) {
+glm_mat3x4_make(const float * __restrict src, mat3x4 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[0][2] = src[2];
--- a/include/cglm/mat4.h
+++ b/include/cglm/mat4.h
@@ -69,7 +69,7 @@
 #  include "simd/wasm/mat4.h"
 #endif
-#ifdef DEBUG
+#ifndef NDEBUG
 # include <assert.h>
 #endif
@@ -376,7 +376,7 @@ void
 glm_mat4_mulN(mat4 * __restrict matrices[], uint32_t len, mat4 dest) {
  uint32_t i;
-#ifdef DEBUG
+#ifndef NDEBUG
  assert(len > 1 && "there must be least 2 matrices to go!");
 #endif
@@ -537,7 +537,7 @@ glm_mat4_transpose_to(mat4 m, mat4 dest) {
 }
 /*!
- * @brief tranpose mat4 and store result in same matrix
+ * @brief transpose mat4 and store result in same matrix
 *
 * @param[in, out] m source and dest
 */
@@ -790,7 +790,7 @@ glm_mat4_rmc(vec4 r, mat4 m, vec4 c) {
 */
 CGLM_INLINE
 void
-glm_mat4_make(float * __restrict src, mat4 dest) {
+glm_mat4_make(const float * __restrict src, mat4 dest) {
  dest[0][0] = src[0];   dest[1][0] = src[4];
  dest[0][1] = src[1];   dest[1][1] = src[5];
  dest[0][2] = src[2];   dest[1][2] = src[6];
--- a/include/cglm/mat4x2.h
+++ b/include/cglm/mat4x2.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat4x2_copy(mat4x2 mat, mat4x2 dest);
   CGLM_INLINE void glm_mat4x2_zero(mat4x2 mat);
-   CGLM_INLINE void glm_mat4x2_make(float * __restrict src, mat4x2 dest);
+   CGLM_INLINE void glm_mat4x2_make(const float * __restrict src, mat4x2 dest);
   CGLM_INLINE void glm_mat4x2_mul(mat4x2 m1, mat2x4 m2, mat4 dest);
   CGLM_INLINE void glm_mat4x2_mulv(mat4x2 m, vec2 v, vec4 dest);
   CGLM_INLINE void glm_mat4x2_transpose(mat4x2 m, mat2x4 dest);
@@ -72,7 +72,7 @@ glm_mat4x2_zero(mat4x2 mat) {
 */
 CGLM_INLINE
 void
-glm_mat4x2_make(float * __restrict src, mat4x2 dest) {
+glm_mat4x2_make(const float * __restrict src, mat4x2 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
--- a/include/cglm/mat4x3.h
+++ b/include/cglm/mat4x3.h
@@ -13,7 +13,7 @@
 Functions:
   CGLM_INLINE void glm_mat4x3_copy(mat4x3 mat, mat4x3 dest);
   CGLM_INLINE void glm_mat4x3_zero(mat4x3 mat);
-   CGLM_INLINE void glm_mat4x3_make(float * __restrict src, mat4x3 dest);
+   CGLM_INLINE void glm_mat4x3_make(const float * __restrict src, mat4x3 dest);
   CGLM_INLINE void glm_mat4x3_mul(mat4x3 m1, mat3x4 m2, mat4 dest);
   CGLM_INLINE void glm_mat4x3_mulv(mat4x3 m, vec3 v, vec4 dest);
   CGLM_INLINE void glm_mat4x3_transpose(mat4x3 m, mat3x4 dest);
@@ -77,7 +77,7 @@ glm_mat4x3_zero(mat4x3 mat) {
 */
 CGLM_INLINE
 void
-glm_mat4x3_make(float * __restrict src, mat4x3 dest) {
+glm_mat4x3_make(const float * __restrict src, mat4x3 dest) {
  dest[0][0] = src[0];
  dest[0][1] = src[1];
  dest[0][2] = src[2];
--- a/include/cglm/quat.h
+++ b/include/cglm/quat.h
@@ -703,7 +703,7 @@ glm_quat_nlerp(versor from, versor to, float t, versor dest) {
 *
 * @param[in]   from  from
 * @param[in]   to    to
- * @param[in]   t     amout
+ * @param[in]   t     amount
 * @param[out]  dest  result quaternion
 */
 CGLM_INLINE
@@ -894,7 +894,7 @@ glm_quat_rotate_atm(mat4 m, versor q, vec3 pivot) {
 */
 CGLM_INLINE
 void
-glm_quat_make(float * __restrict src, versor dest) {
+glm_quat_make(const float * __restrict src, versor dest) {
  dest[0] = src[0]; dest[1] = src[1];
  dest[2] = src[2]; dest[3] = src[3];
 }
--- a/include/cglm/ray.h
+++ b/include/cglm/ray.h
@@ -7,12 +7,18 @@
 /*
 Functions:
-   CGLM_INLINE bool glm_line_triangle_intersect(vec3   origin,
+   CGLM_INLINE bool glm_ray_triangle(vec3   origin,
-                                                vec3   direction,
+                                     vec3   direction,
-                                                vec3   v0,
+                                     vec3   v0,
-                                                vec3   v1,
+                                     vec3   v1,
-                                                vec3   v2,
+                                     vec3   v2,
-                                                float *d);
+                                     float *d);
 CGLM_INLINE bool glm_ray_sphere(vec3 origin,
                                 vec3 dir,
                                 vec4 s,
                                 float * __restrict t1,
                                 float * __restrict t2)
 CGLM_INLINE void glm_ray_at(vec3 orig, vec3 dir, float t, vec3 point);
 */
 #ifndef cglm_ray_h
@@ -31,7 +37,6 @@
 * @param[in, out] d         distance to intersection
 * @return whether there is intersection
 */
 CGLM_INLINE
 bool
 glm_ray_triangle(vec3   origin,
@@ -74,4 +79,93 @@ glm_ray_triangle(vec3   origin,
  return dist > epsilon;
 }
 /*!
 * @brief ray sphere intersection
 *
 * - t1 > 0, t2 > 0: ray intersects the sphere at t1 and t2 both ahead of the origin
 * - t1 < 0, t2 > 0: ray starts inside the sphere, exits at t2
 * - t1 < 0, t2 < 0: no intersection ahead of the ray
 * - the caller can check if the intersection points (t1 and t2) fall within a
 *   specific range (for example, tmin < t1, t2 < tmax) to determine if the
 *   intersections are within a desired segment of the ray
 *
 * @param[in]  origin ray origin
 * @param[out] dir    normalized ray direction
 * @param[in]  s      sphere  [center.x, center.y, center.z, radii]
 * @param[in]  t1     near point1 (closer to origin)
 * @param[in]  t2     far point2 (farther from origin)
 */
 CGLM_INLINE
 bool 
 glm_ray_sphere(vec3 origin,
               vec3 dir,
               vec4 s,
               float * __restrict t1,
               float * __restrict t2) {
  vec3  dp;
  float r2, ddp, dpp, dscr, q, tmp, _t1, _t2;
  /* ensure dir is normalized */
  glm_vec3_sub(s, origin, dp);
  ddp = glm_vec3_dot(dir, dp);
  dpp = glm_vec3_norm2(dp);
  /* compute the remedy term for numerical stability */
  glm_vec3_mulsubs(dir, ddp, dp); /* dp: remedy term */
  r2   = s[3] * s[3];
  dscr = r2 - glm_vec3_norm2(dp);
  if (dscr < 0.0f) {
    /* no intersection */
    return false;
  }
  dscr = sqrtf(dscr);
  q    = (ddp >= 0.0f) ? (ddp + dscr) : (ddp - dscr);
  /*
     include Press, William H., Saul A. Teukolsky,
     William T. Vetterling, and Brian P. Flannery,
     "Numerical Recipes in C," Cambridge University Press, 1992.
   */
  _t1 = q;
  _t2 = (dpp - r2) / q;
  /* adjust t1 and t2 to ensure t1 is the closer intersection */
  if (_t1 > _t2) {
    tmp = _t1;
    _t1 = _t2;
    _t2 = tmp;
  }
  *t1 = _t1;
  *t2 = _t2;
  /* check if the closest intersection (t1) is behind the ray's origin */
  if (_t1 < 0.0f && _t2 < 0.0f) {
    /* both intersections are behind the ray, no visible intersection */
    return false;
  }
  return true;
 }
 /*!
 * @brief point using t by 𝐏(𝑡)=𝐀+𝑡𝐛
 *
 * @param[in]  orig  origin of ray
 * @param[in]  dir   direction of ray
 * @param[in]  t     parameter
 * @param[out] point point at t
 */
 CGLM_INLINE
 void
 glm_ray_at(vec3 orig, vec3 dir, float t, vec3 point) {
  vec3 dst;
  glm_vec3_scale(dir, t, dst);
  glm_vec3_add(orig, dst, point);
 }
 #endif
--- a/include/cglm/simd/arm.h
+++ b/include/cglm/simd/arm.h
@@ -56,11 +56,9 @@ glmm_float32x4_init(float x, float y, float z, float w) {
 #define glmm_float32x4_SIGNMASK_NPNP glmm_float32x4_init(-0.f,  0.f, -0.f,  0.f)
 #define glmm_float32x4_SIGNMASK_NPPN glmm_float32x4_init(-0.f,  0.f,  0.f, -0.f)
-static inline
+static inline float32x4_t glmm_abs(float32x4_t v)                { return vabsq_f32(v);    }
-float32x4_t
+static inline float32x4_t glmm_min(float32x4_t a, float32x4_t b) { return vminq_f32(a, b); }
-glmm_abs(float32x4_t v) {
+static inline float32x4_t glmm_max(float32x4_t a, float32x4_t b) { return vmaxq_f32(a, b); }
  return vabsq_f32(v);
 }
 static inline
 float32x4_t
--- a/include/cglm/simd/intrin.h
+++ b/include/cglm/simd/intrin.h
@@ -63,7 +63,7 @@
 #endif
 /* ARM Neon */
-#if defined(_WIN32)
+#if defined(_WIN32) && defined(_MSC_VER)
 /* TODO: non-ARM stuff already inported, will this be better option */
 /* #  include <intrin.h> */
--- a/include/cglm/simd/wasm.h
+++ b/include/cglm/simd/wasm.h
@@ -34,13 +34,11 @@
 #define glmm_float32x4_SIGNMASK_PNPN GLMM__SIGNMASKf(0, GLMM_NEGZEROf, 0, GLMM_NEGZEROf)
 #define glmm_float32x4_SIGNMASK_NPNP GLMM__SIGNMASKf(GLMM_NEGZEROf, 0, GLMM_NEGZEROf, 0)
 #define glmm_float32x4_SIGNMASK_NPPN GLMM__SIGNMASKf(GLMM_NEGZEROf, 0, 0, GLMM_NEGZEROf)
-#define glmm_float32x4_SIGNMASK_NEG wasm_i32x4_const_splat(GLMM_NEGZEROf)
+#define glmm_float32x4_SIGNMASK_NEG  wasm_i32x4_const_splat(GLMM_NEGZEROf)
-static inline
+static inline glmm_128 glmm_abs(glmm_128 x)             { return wasm_f32x4_abs(x);     }
-glmm_128
+static inline glmm_128 glmm_min(glmm_128 a, glmm_128 b) { return wasm_f32x4_pmin(b, a); }
-glmm_abs(glmm_128 x) {
+static inline glmm_128 glmm_max(glmm_128 a, glmm_128 b) { return wasm_f32x4_pmax(b, a); }
  return wasm_f32x4_abs(x);
 }
 static inline
 glmm_128
@@ -74,7 +72,7 @@ glmm_128
 glmm_vhmin(glmm_128 v) {
  glmm_128 x0, x1, x2;
  x0 = glmm_shuff1(v, 2, 3, 2, 3);     /* [2, 3, 2, 3] */
-  x1 = wasm_f32x4_pmin(x0, v);   /* [0|2, 1|3, 2|2, 3|3] */
+  x1 = wasm_f32x4_pmin(x0, v);         /* [0|2, 1|3, 2|2, 3|3] */
  x2 = glmm_splat(x1, 1);              /* [1|3, 1|3, 1|3, 1|3] */
  return wasm_f32x4_pmin(x1, x2);
 }
@@ -90,7 +88,7 @@ glmm_128
 glmm_vhmax(glmm_128 v) {
  glmm_128 x0, x1, x2;
  x0 = glmm_shuff1(v, 2, 3, 2, 3);     /* [2, 3, 2, 3] */
-  x1 = wasm_f32x4_pmax(x0, v);   /* [0|2, 1|3, 2|2, 3|3] */
+  x1 = wasm_f32x4_pmax(x0, v);         /* [0|2, 1|3, 2|2, 3|3] */
  x2 = glmm_splat(x1, 1);              /* [1|3, 1|3, 1|3, 1|3] */
  /* _mm_max_ss */
  return wasm_i32x4_shuffle(x1, wasm_f32x4_pmax(x1, x2), 4, 1, 2, 3);
--- a/include/cglm/simd/x86.h
+++ b/include/cglm/simd/x86.h
@@ -74,6 +74,9 @@ glmm_abs(__m128 x) {
  return _mm_andnot_ps(glmm_float32x4_SIGNMASK_NEG, x);
 }
 static inline __m128 glmm_min(__m128 a, __m128 b) { return _mm_min_ps(a, b); }
 static inline __m128 glmm_max(__m128 a, __m128 b) { return _mm_max_ps(a, b); }
 static inline
 __m128
 glmm_vhadd(__m128 v) {
--- a/include/cglm/struct.h
+++ b/include/cglm/struct.h
@@ -16,6 +16,9 @@ extern "C" {
 #include "struct/vec2.h"
 #include "struct/vec3.h"
 #include "struct/vec4.h"
 #include "struct/ivec2.h"
 #include "struct/ivec3.h"
 #include "struct/ivec4.h"
 #include "struct/mat2.h"
 #include "struct/mat2x3.h"
 #include "struct/mat2x4.h"
@@ -38,6 +41,7 @@ extern "C" {
 #include "struct/sphere.h"
 #include "struct/curve.h"
 #include "struct/affine2d.h"
 #include "struct/ray.h"
 #ifdef __cplusplus
 }
--- a/include/cglm/struct/aabb2d.h
+++ b/include/cglm/struct/aabb2d.h
@@ -16,7 +16,7 @@
 #include "mat4.h"
 /* api definition */
-#define glms_aabb2d_(NAME) CGLM_STRUCTAPI(aabb, NAME)
+#define glms_aabb2d_(NAME) CGLM_STRUCTAPI(aabb2d, NAME)
 /*!
 * @brief apply transform to Axis-Aligned Bounding Box
@@ -92,7 +92,7 @@ glms_aabb2d_(crop)(vec2s aabb[2], vec2s cropAabb[2], vec2s dest[2]) {
 *
 * @param[in]  aabb      bounding box
 * @param[in]  cropAabb  crop box
- * @param[in]  clampAabb miniumum box
+ * @param[in]  clampAabb minimum box
 * @param[out] dest     cropped bounding box
 */
 CGLM_INLINE
--- a/include/cglm/struct/affine-post.h
+++ b/include/cglm/struct/affine-post.h
@@ -33,9 +33,9 @@
 * @brief translate existing transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       v   translate vector [x, y, z]
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -47,9 +47,9 @@ glms_translated(mat4s m, vec3s v) {
 /*!
 * @brief translate existing transform matrix by x factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       x   x factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -61,9 +61,9 @@ glms_translated_x(mat4s m, float x) {
 /*!
 * @brief translate existing transform matrix by y factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       y   y factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -75,9 +75,9 @@ glms_translated_y(mat4s m, float y) {
 /*!
 * @brief translate existing transform matrix by z factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       z   z factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -90,7 +90,7 @@ glms_translated_z(mat4s m, float z) {
 * @brief rotate existing transform matrix around X axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -106,7 +106,7 @@ glms_rotated_x(mat4s m, float angle) {
 * @brief rotate existing transform matrix around Y axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -122,7 +122,7 @@ glms_rotated_y(mat4s m, float angle) {
 * @brief rotate existing transform matrix around Z axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -137,10 +137,10 @@ glms_rotated_z(mat4s m, float angle) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                affine transfrom
+ * @returns                affine transform
 */
 CGLM_INLINE
 mat4s
@@ -153,11 +153,11 @@ glms_rotated(mat4s m, float angle, vec3s axis) {
 * @brief rotate existing transform
 *        around given axis by angle at given pivot point (rotation center)
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       pivot   rotation center
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                 affine transfrom
+ * @returns                 affine transform
 */
 CGLM_INLINE
 mat4s
@@ -169,10 +169,10 @@ glms_rotated_at(mat4s m, vec3s pivot, float angle, vec3s axis) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                affine transfrom
+ * @returns                affine transform
 */
 CGLM_INLINE
 mat4s
--- a/include/cglm/struct/affine-pre.h
+++ b/include/cglm/struct/affine-pre.h
@@ -33,9 +33,9 @@
 * @brief translate existing transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       v   translate vector [x, y, z]
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -47,9 +47,9 @@ glms_translate(mat4s m, vec3s v) {
 /*!
 * @brief translate existing transform matrix by x factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       x   x factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -61,9 +61,9 @@ glms_translate_x(mat4s m, float x) {
 /*!
 * @brief translate existing transform matrix by y factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       y   y factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -75,9 +75,9 @@ glms_translate_y(mat4s m, float y) {
 /*!
 * @brief translate existing transform matrix by z factor
 *
- * @param[in]       m   affine transfrom
+ * @param[in]       m   affine transform
 * @param[in]       z   z factor
- * @returns             affine transfrom
+ * @returns             affine transform
 */
 CGLM_INLINE
 mat4s
@@ -90,7 +90,7 @@ glms_translate_z(mat4s m, float z) {
 * @brief rotate existing transform matrix around X axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -106,7 +106,7 @@ glms_rotate_x(mat4s m, float angle) {
 * @brief rotate existing transform matrix around Y axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -122,7 +122,7 @@ glms_rotate_y(mat4s m, float angle) {
 * @brief rotate existing transform matrix around Z axis by angle
 *        and store result in dest
 *
- * @param[in]   m       affine transfrom
+ * @param[in]   m       affine transform
 * @param[in]   angle   angle (radians)
 * @returns             rotated matrix
 */
@@ -137,10 +137,10 @@ glms_rotate_z(mat4s m, float angle) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                affine transfrom
+ * @returns                affine transform
 */
 CGLM_INLINE
 mat4s
@@ -153,11 +153,11 @@ glms_rotate(mat4s m, float angle, vec3s axis) {
 * @brief rotate existing transform
 *        around given axis by angle at given pivot point (rotation center)
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       pivot   rotation center
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                 affine transfrom
+ * @returns                 affine transform
 */
 CGLM_INLINE
 mat4s
@@ -169,10 +169,10 @@ glms_rotate_at(mat4s m, vec3s pivot, float angle, vec3s axis) {
 /*!
 * @brief rotate existing transform matrix around given axis by angle around self (doesn't affected by position)
 *
- * @param[in]       m       affine transfrom
+ * @param[in]       m       affine transform
 * @param[in]       angle   angle (radians)
 * @param[in]       axis    axis
- * @returns                affine transfrom
+ * @returns                affine transform
 */
 CGLM_INLINE
 mat4s
--- a/include/cglm/struct/affine.h
+++ b/include/cglm/struct/affine.h
@@ -45,7 +45,7 @@
 * @brief creates NEW translate transform matrix by v vector
 *
 * @param[in]   v   translate vector [x, y, z]
- * @returns         affine transfrom
+ * @returns         affine transform
 */
 CGLM_INLINE
 mat4s
@@ -59,7 +59,7 @@ glms_translate_make(vec3s v) {
 * @brief creates NEW scale matrix by v vector
 *
 * @param[in]   v  scale vector [x, y, z]
- * @returns affine transfrom
+ * @returns affine transform
 */
 CGLM_INLINE
 mat4s
@@ -73,9 +73,9 @@ glms_scale_make(vec3s v) {
 * @brief scales existing transform matrix by v vector
 *        and stores result in same matrix
 *
- * @param[in]    m   affine transfrom
+ * @param[in]    m   affine transform
 * @param[in]    v   scale vector [x, y, z]
- * @returns          affine transfrom
+ * @returns          affine transform
 */
 CGLM_INLINE
 mat4s
@@ -89,9 +89,9 @@ glms_scale(mat4s m, vec3s v) {
 * @brief applies uniform scale to existing transform matrix v = [s, s, s]
 *        and stores result in same matrix
 *
- * @param[in]    m   affine transfrom
+ * @param[in]    m   affine transform
 * @param[in]    s   scale factor
- * @returns          affine transfrom
+ * @returns          affine transform
 */
 CGLM_INLINE
 mat4s
@@ -107,7 +107,7 @@ glms_scale_uni(mat4s m, float s) {
 *
 * @param[in]  angle  angle (radians)
 * @param[in]  axis   axis
- * @returns           affine transfrom
+ * @returns           affine transform
 */
 CGLM_INLINE
 mat4s
@@ -128,7 +128,7 @@ glms_rotate_make(float angle, vec3s axis) {
 * @param[in]  pivot  rotation center
 * @param[in]  angle  angle (radians)
 * @param[in]  axis   axis
- * @returns           affine transfrom
+ * @returns           affine transform
 */
 CGLM_INLINE
 mat4s
@@ -184,7 +184,7 @@ glms_decompose_rs(mat4s m, mat4s * __restrict r, vec3s * __restrict s) {
 * @brief decompose affine transform, TODO: extract shear factors.
 *        DON'T pass projected matrix here
 *
- * @param[in]  m affine transfrom
+ * @param[in]  m affine transform
 * @param[out] t translation vector
 * @param[out] r rotation matrix (mat4)
 * @param[out] s scaling vector [X, Y, Z]
--- a/Show More
+++ b/Show More
Author	SHA1	Message	Date
Recep Aslantas	e4c38ccc4c	docs: update ray sphere intersection brief	2024-03-22 23:49:05 +03:00
Recep Aslantas	ceaa54aef8	tests: test for ray, reflect, refract and faceforward	2024-03-22 23:44:43 +03:00
Recep Aslantas	da57558078	docs for new ray functions	2024-03-22 22:30:22 +03:00
Recep Aslantas	6ad0aca7e0	fix refract	2024-03-22 21:59:10 +03:00
Recep Aslantas	96e415daa4	build: add missing file	2024-03-22 10:42:29 +03:00
Recep Aslantas	3701305c9e	suppress warnings	2024-03-22 10:36:28 +03:00
Recep Aslantas	2b78f9ab47	refract	2024-03-22 00:18:55 +03:00
Recep Aslantas	41d1a8b9eb	faceforward	2024-03-21 02:21:28 +03:00
Recep Aslantas	8ea2fd1cd1	reflect missing stuff	2024-03-21 02:21:07 +03:00
Recep Aslantas	8c81443f24	reflect	2024-03-21 00:18:02 +03:00
Recep Aslantas	608e7d9c2c	Update CREDITS	2024-03-20 07:33:43 +03:00
Recep Aslantas	73a4fc76d7	ray: point along a ray at a parameter t	2024-03-20 07:24:07 +03:00
Recep Aslantas	aa45d081fc	ray: ray sphere intersection	2024-03-20 07:22:36 +03:00
Recep Aslantas	f1d4aea69b	win: add missing files to vsproj	2024-03-20 07:16:17 +03:00
Recep Aslantas	0ef8ebe84e	Merge pull request #397 from recp/affine-docs clarify some rotation rules	2024-03-20 01:05:18 +03:00
Recep Aslantas	8b6eca29cf	docs: clarify some rotation rules	2024-03-19 23:55:42 +03:00
Recep Aslantas	0fbad944c5	Merge pull request #398 from waywardmonkeys/make-const-floats Allow passing `const float*` to `make` functions.	2024-03-18 16:48:02 +03:00
Bruce Mitchener	182c28faf8	Allow passing `const float*` to `make` functions.	2024-03-18 19:49:50 +07:00
Recep Aslantas	995fb2e347	clarify some rotation rules	2024-03-16 00:34:11 +03:00
Recep Aslantas	838c5078b7	Merge pull request #395 from recp/ndebug Ndebug	2024-03-02 11:15:18 +03:00
Recep Aslantas	772238f53f	update cmake to respect DEBUG	2024-03-01 12:01:58 +03:00
Recep Aslantas	b9e62b6fe5	use NDEBUG to check DEBUG mode	2024-03-01 12:00:01 +03:00
Recep Aslantas	c9e2b81e99	test: fix ivec2 and ivec3 comparison and suppress warnings	2024-02-24 06:55:45 +03:00
Recep Aslantas	ee18e58815	test: fix ivec2 and ivec3 comparison and suppress warnings	2024-02-24 06:50:07 +03:00
Recep Aslantas	85ee366861	move deprecated glmc_aabb2d_size to right place	2024-02-24 06:33:30 +03:00
Recep Aslantas	0e4201b816	suppress warnings: C4244: 'function': conversion from 'int' to 'float'	2024-02-24 06:10:48 +03:00
Recep Aslantas	b7e4c96738	Merge pull request #392 from duarm/master aabb2d_zero, aabb2d_diagonal and aabb2d_size	2024-02-24 05:58:49 +03:00
duarm	0d92bfc722	docs and call api for _aabb2d_zero	2024-02-23 14:07:58 -03:00
duarm	237432969d	macro for call api too	2024-02-23 14:01:26 -03:00
duarm	131ac68ad3	size -> diag, new sizev	2024-02-23 13:53:25 -03:00
duarm	7e6a463256	call api	2024-02-19 14:38:05 -03:00
duarm	e312f282b4	glm_aabb2d_zero, _size -> _diagonal, new _size	2024-02-19 14:34:30 -03:00
Recep Aslantas	78fb330850	Merge pull request #391 from waywardmonkeys/ci-add-arm64-uwp ci: Add ARM64 UWP for WindowsStore.	2024-02-12 12:23:31 +03:00
Recep Aslantas	4896b2ea8d	Merge pull request #390 from waywardmonkeys/doc-improvements Doc improvements	2024-02-12 12:21:59 +03:00
Bruce Mitchener	366e0d44e2	ci: Add ARM64 UWP for WindowsStore. This is one of the core vcpkg targets and I'm trying to enable the cglm port there to support UWP, so we should have it in the CI here.	2024-02-12 09:17:56 +07:00
Bruce Mitchener	47a27f9d07	ci / docs: Turn sphinx warnings into errors. This will help prevent future warnings from sphinx.	2024-02-12 09:01:29 +07:00
Bruce Mitchener	7957179808	docs: Remove duplicate definitions.	2024-02-12 09:00:08 +07:00
Bruce Mitchener	3e79c4d799	docs: Additions and corrections. * Add missing doc for `glm_vec4_one`. * mat4: correct links to some functions.	2024-02-12 08:49:50 +07:00
Bruce Mitchener	af5048595f	docs: Use `.. note::` to display better. Also, make sure the note content has a blank line after it to remove a warning from Sphinx.	2024-02-11 23:43:35 +07:00
Bruce Mitchener	270d2b9d05	docs: Add missing aabb2d, fix broken link.	2024-02-11 23:43:35 +07:00
Recep Aslantas	eb9a200b6c	Merge pull request #389 from waywardmonkeys/aabb2d-struct-api aabb2d: Fix struct api.	2024-02-11 19:09:58 +03:00
Bruce Mitchener	fd661d1b43	aabb2d: Fix struct api.	2024-02-11 06:41:39 +07:00
Recep Aslantas	db6f9641ab	Merge pull request #387 from waywardmonkeys/remove-narrowing-conversion glm_ease_back_inout: Use float constant for float var.	2024-02-10 23:49:37 +03:00
Recep Aslantas	125002cfb3	Merge pull request #388 from waywardmonkeys/remove-appveyor ci: Remove appveyor.	2024-02-10 23:43:25 +03:00
Bruce Mitchener	bb9a35caaf	ci: Remove appveyor. This is now handled by the GitHub Actions CI.	2024-02-10 22:47:33 +07:00
Recep Aslantas	b89315f2c5	Merge pull request #386 from waywardmonkeys/improve-ci Add additional CI via GitHub Actions.	2024-02-10 17:29:42 +03:00
Bruce Mitchener	e80d163d71	glm_ease_back_inout: Use float constant for float var.	2024-02-10 19:47:38 +07:00
Bruce Mitchener	74c5e86d0c	Add additional CI via GitHub Actions.	2024-02-10 14:10:12 +07:00
Recep Aslantas	45134b1265	Merge pull request #384 from waywardmonkeys/fix-more-typos Fix typos.	2024-02-08 17:18:29 +03:00
Recep Aslantas	b63b2b90b3	Merge pull request #383 from tarhses/structapi-ivec Implement struct API for ivec2, ivec3, and ivec4	2024-02-08 17:13:03 +03:00
Bruce Mitchener	e4419c4f18	Fix typos.	2024-02-08 15:12:30 +07:00
Pierre Luycx	17f3ea5fab	Implement struct API for ivec2, ivec3, and ivec4	2024-02-07 20:53:40 +01:00
Recep Aslantas	a8685ed6ab	Merge pull request #381 from vitassuper/vector_improvements Add new functions for ivec2 and ivec3	2024-01-27 19:33:45 +03:00
Vitaliy Klychkov	029bead207	Update ivec2 and ivec3 documentation	2024-01-27 13:45:27 +00:00
Vitaliy Klychkov	30845124b4	Add additional functions for ivec2 and ivec3	2024-01-27 13:11:04 +00:00
Recep Aslantas	80d5064476	docs: update read the docs package versions	2024-01-15 21:44:48 +03:00
Recep Aslantas	2bd97f6599	Merge pull request #379 from recp/simd_min_max simd: min / max helpers	2024-01-11 00:21:10 +03:00
Recep Aslantas	6d8dd42ac2	simd: use new glmm_min/max in vec4 where possible	2024-01-11 00:14:28 +03:00
Recep Aslantas	dab86796a4	simd: min / max helpers	2024-01-09 21:35:39 +03:00
Recep Aslantas	4b93cb3e05	Merge pull request #378 from recp/win32_intrin win32, simd: ensure we are on msvc when checking MSVC specific headers	2024-01-08 00:10:43 +03:00
Recep Aslantas	a682b9e6cf	win32, tests: fix drand48() error on mingw	2024-01-04 12:49:45 +03:00
Recep Aslantas	bca93a379d	win32, simd: ensure we are on msvc when checking MSVC specific headers	2024-01-04 11:54:42 +03:00
Recep Aslantas	34f0d59f5a	now working on v0.9.3	2023-12-31 15:19:36 +03:00