third_party/glm/glm/glm.hpp - cobalt - Git at Google

 /// @ref core
 /// @file glm/glm.hpp
 ///
 /// @defgroup core GLM Core
 ///
 /// @brief The core of GLM, which implements exactly and only the GLSL specification to the degree possible.
 ///
 /// The GLM core consists of @ref core_types "C++ types that mirror GLSL types" and
 /// C++ functions that mirror the GLSL functions. It also includes
 /// @ref core_precision "a set of precision-based types" that can be used in the appropriate
 /// functions. The C++ types are all based on a basic set of @ref core_template "template types".
 ///
 /// The best documentation for GLM Core is the current GLSL specification,
 /// <a href="http://www.opengl.org/registry/doc/GLSLangSpec.4.20.8.clean.pdf">version 4.2
 /// (pdf file)</a>.
 ///
 /// GLM core functionnalities require <glm/glm.hpp> to be included to be used.
 ///
 /// @defgroup core_types Types
 ///
 /// @brief The standard types defined by the specification.
 ///
 /// These types are all typedefs of more generalized, template types. To see the definition
 /// of these template types, go to @ref core_template.
 ///
 /// @ingroup core
 ///
 /// @defgroup core_precision Precision types
 ///
 /// @brief Non-GLSL types that are used to define precision-based types.
 ///
 /// The GLSL language allows the user to define the precision of a particular variable.
 /// In OpenGL's GLSL, these precision qualifiers have no effect; they are there for compatibility
 /// with OpenGL ES's precision qualifiers, where they @em do have an effect.
 ///
 /// C++ has no language equivalent to precision qualifiers. So GLM provides the next-best thing:
 /// a number of typedefs of the @ref core_template that use a particular precision.
 ///
 /// None of these types make any guarantees about the actual precision used.
 ///
 /// @ingroup core
 ///
 /// @defgroup core_template Template types
 ///
 /// @brief The generic template types used as the basis for the core types.
 ///
 /// These types are all templates used to define the actual @ref core_types.
 /// These templetes are implementation details of GLM types and should not be used explicitly.
 ///
 /// @ingroup core

 #include "detail/_fixes.hpp"

 #pragma once

 #include <cmath>
 #include <climits>
 #include <cfloat>
 #include <limits>
 #include <cassert>
 #include "fwd.hpp"

 #if GLM_MESSAGES == GLM_MESSAGES_ENABLED && !defined(GLM_MESSAGE_CORE_INCLUDED_DISPLAYED)
 #	define GLM_MESSAGE_CORE_INCLUDED_DISPLAYED
 #	pragma message("GLM: Core library included")
 #endif//GLM_MESSAGES

 #include "vec2.hpp"
 #include "vec3.hpp"
 #include "vec4.hpp"
 #include "mat2x2.hpp"
 #include "mat2x3.hpp"
 #include "mat2x4.hpp"
 #include "mat3x2.hpp"
 #include "mat3x3.hpp"
 #include "mat3x4.hpp"
 #include "mat4x2.hpp"
 #include "mat4x3.hpp"
 #include "mat4x4.hpp"

 #include "trigonometric.hpp"
 #include "exponential.hpp"
 #include "common.hpp"
 #include "packing.hpp"
 #include "geometric.hpp"
 #include "matrix.hpp"
 #include "vector_relational.hpp"
 #include "integer.hpp"
	/// @ref core
	/// @file glm/glm.hpp
	///
	/// @defgroup core GLM Core
	///
	/// @brief The core of GLM, which implements exactly and only the GLSL specification to the degree possible.
	///
	/// The GLM core consists of @ref core_types "C++ types that mirror GLSL types" and
	/// C++ functions that mirror the GLSL functions. It also includes
	/// @ref core_precision "a set of precision-based types" that can be used in the appropriate
	/// functions. The C++ types are all based on a basic set of @ref core_template "template types".
	///
	/// The best documentation for GLM Core is the current GLSL specification,
	/// <a href="http://www.opengl.org/registry/doc/GLSLangSpec.4.20.8.clean.pdf">version 4.2
	/// (pdf file)</a>.
	///
	/// GLM core functionnalities require <glm/glm.hpp> to be included to be used.
	///
	/// @defgroup core_types Types
	///
	/// @brief The standard types defined by the specification.
	///
	/// These types are all typedefs of more generalized, template types. To see the definition
	/// of these template types, go to @ref core_template.
	///
	/// @ingroup core
	///
	/// @defgroup core_precision Precision types
	///
	/// @brief Non-GLSL types that are used to define precision-based types.
	///
	/// The GLSL language allows the user to define the precision of a particular variable.
	/// In OpenGL's GLSL, these precision qualifiers have no effect; they are there for compatibility
	/// with OpenGL ES's precision qualifiers, where they @em do have an effect.
	///
	/// C++ has no language equivalent to precision qualifiers. So GLM provides the next-best thing:
	/// a number of typedefs of the @ref core_template that use a particular precision.
	///
	/// None of these types make any guarantees about the actual precision used.
	///
	/// @ingroup core
	///
	/// @defgroup core_template Template types
	///
	/// @brief The generic template types used as the basis for the core types.
	///
	/// These types are all templates used to define the actual @ref core_types.
	/// These templetes are implementation details of GLM types and should not be used explicitly.
	///
	/// @ingroup core

	#include "detail/_fixes.hpp"

	#pragma once

	#include <cmath>
	#include <climits>
	#include <cfloat>
	#include <limits>
	#include <cassert>
	#include "fwd.hpp"

	#if GLM_MESSAGES == GLM_MESSAGES_ENABLED && !defined(GLM_MESSAGE_CORE_INCLUDED_DISPLAYED)
	# define GLM_MESSAGE_CORE_INCLUDED_DISPLAYED
	# pragma message("GLM: Core library included")
	#endif//GLM_MESSAGES

	#include "vec2.hpp"
	#include "vec3.hpp"
	#include "vec4.hpp"
	#include "mat2x2.hpp"
	#include "mat2x3.hpp"
	#include "mat2x4.hpp"
	#include "mat3x2.hpp"
	#include "mat3x3.hpp"
	#include "mat3x4.hpp"
	#include "mat4x2.hpp"
	#include "mat4x3.hpp"
	#include "mat4x4.hpp"

	#include "trigonometric.hpp"
	#include "exponential.hpp"
	#include "common.hpp"
	#include "packing.hpp"
	#include "geometric.hpp"
	#include "matrix.hpp"
	#include "vector_relational.hpp"
	#include "integer.hpp"