#include "glm_bindings.h" /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * Vec3 Functions * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_copy(lua_State* L) { honey_glm_array *self, *dest; honey_lua_parse_arguments (L, 1, 2, HONEY_USERDATA, &self, HONEY_USERDATA, &dest); if (dest->type != VEC3) honey_lua_throw_error(L, "destination must be VEC3 (%d); got %d instead", dest->type); glm_vec3_copy(self->data, dest->data); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_zero(lua_State* L) { honey_glm_array *self; honey_lua_parse_arguments(L, 1, 1, HONEY_USERDATA, &self); glm_vec3_zero(self->data); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_eye(lua_State* L) { honey_glm_array *self; honey_lua_parse_arguments(L, 1, 1, HONEY_USERDATA, &self); glm_vec3_one(self->data); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_dot(lua_State* L) { honey_glm_array *a, *b; honey_lua_parse_arguments (L, 1, 2, HONEY_USERDATA, &a, HONEY_USERDATA, &b); if (b->type != VEC3) honey_lua_throw_error(L, "destination must be VEC3 (%d); got %d instead", VEC3, b->type); float result = glm_vec3_dot(a->data, b->data); lua_pushnumber(L, result); return 1; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ static bool get_vec3_arrays(lua_State* L, honey_glm_array** a, honey_glm_array** b, honey_glm_array** dest) { int choice = honey_lua_parse_arguments (L, 2, 2, HONEY_USERDATA, a, HONEY_USERDATA, b, 3, HONEY_USERDATA, a, HONEY_USERDATA, b, HONEY_USERDATA, dest); if ((*b)->type != VEC3) honey_lua_throw_error (L, "second argument must be VEC3 (%d); got %d instead", VEC3, (*b)->type); if (choice == 1) { if ((*dest)->type != VEC3) honey_lua_throw_error (L, "third argument must be VEC3 (%d); got %d instead", VEC3, (*dest)->type); } else { honey_glm_new_vec3(L); *dest = lua_touserdata(L, -1); } return choice == 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ static bool get_vec3_scalars(lua_State* L, honey_glm_array** a, float* s, honey_glm_array** dest) { int choice = honey_lua_parse_arguments (L, 2, 2, HONEY_USERDATA, a, HONEY_NUMBER, s, 3, HONEY_USERDATA, a, HONEY_NUMBER, s, HONEY_USERDATA, dest); if (choice == 1) { if ((*dest)->type != VEC3) honey_lua_throw_error (L, "third argument must be VEC3 (%d); got %d instead", VEC3, (*dest)->type); } else { honey_glm_new_vec3(L); *dest = lua_touserdata(L, -1); } return choice == 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_cross(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_cross(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_crossn(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_crossn(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_norm2(lua_State* L) { honey_glm_array *self; honey_lua_parse_arguments(L, 1, 1, HONEY_USERDATA, &self); float result = glm_vec3_norm2(self->data); lua_pushnumber(L, result); return 1; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_norm(lua_State* L) { honey_glm_array *self; honey_lua_parse_arguments(L, 1, 1, HONEY_USERDATA, &self); float result = glm_vec3_norm(self->data); lua_pushnumber(L, result); return 1; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_add(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_add(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_adds(lua_State* L) { honey_glm_array *self, *dest; float s; bool new_dest = get_vec3_scalars(L, &self, &s, &dest); glm_vec3_adds(self->data, s, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_sub(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_sub(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_subs(lua_State* L) { honey_glm_array *self, *dest; float s; bool new_dest = get_vec3_scalars(L, &self, &s, &dest); glm_vec3_subs(self->data, s, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_mul(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_mul(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_scale(lua_State* L) { honey_glm_array *self, *dest; float s; bool new_dest = get_vec3_scalars(L, &self, &s, &dest); glm_vec3_scale(self->data, s, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_scale_as(lua_State* L) { honey_glm_array *self, *dest; float s; bool new_dest = get_vec3_scalars(L, &self, &s, &dest); glm_vec3_scale_as(self->data, s, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_div(lua_State* L) { honey_glm_array *a, *b, *dest; bool new_dest = get_vec3_arrays(L, &a, &b, &dest); glm_vec3_div(a->data, b->data, dest->data); if (new_dest) return 1; return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_negate(lua_State* L) { honey_glm_array *self, *dest; int choice = honey_lua_parse_arguments (L, 2, 1, HONEY_USERDATA, &self, 2, HONEY_USERDATA, &self, HONEY_USERDATA, &dest); if (choice == 0) glm_vec3_negate(self->data); else glm_vec3_negate_to(self->data, dest->data); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_normalize(lua_State* L) { honey_glm_array *self, *dest; int choice = honey_lua_parse_arguments (L, 2, 1, HONEY_USERDATA, &self, 2, HONEY_USERDATA, &self, HONEY_USERDATA, &dest); if (choice == 0) glm_vec3_normalize(self->data); else glm_vec3_normalize_to(self->data, dest->data); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_angle(lua_State* L) { honey_glm_array *a, *b; honey_lua_parse_arguments (L, 1, 2, HONEY_USERDATA, &a, HONEY_USERDATA, &b); if (b->type != VEC3) honey_lua_throw_error (L, "second argument must be VEC3 (%d); got %d instead", VEC3, b->type); float angle = glm_vec3_angle(a->data, b->data); lua_pushnumber(L, angle); return 1; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_clamp(lua_State* L) { honey_glm_array* self; float min, max; honey_lua_parse_arguments(L, 1, 3, HONEY_USERDATA, &self, HONEY_NUMBER, &min, HONEY_NUMBER, &max); glm_vec3_clamp(self->data, min, max); return 0; } /* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ int honey_glm_vec3_lerp(lua_State* L) { honey_glm_array *a, *b, *dest; float s; int choice = honey_lua_parse_arguments (L, 2, 3, HONEY_USERDATA, &a, HONEY_USERDATA, &b, HONEY_NUMBER, &s, 4, HONEY_USERDATA, &a, HONEY_USERDATA, &b, HONEY_NUMBER, &s, HONEY_USERDATA, &dest); if (b->type != VEC3) honey_lua_throw_error (L, "second argument must be VEC3 (%d); got %d instead", VEC3, b->type); if (choice == 1) { if (dest->type != VEC3) honey_lua_throw_error (L, "fourth argument must be VEC3 (%d); got %d instead", VEC3, dest->type); } else { honey_glm_new_vec3(L); dest = lua_touserdata(L, -1); } glm_vec3_lerp(a->data, b->data, s, dest->data); if (choice == 0) return 1; return 0; }