src/Common.h - external/github.com/GPUOpen-LibrariesAndSDKs/VulkanMemoryAllocator - Git at Google

 #ifndef COMMON_H_
 #define COMMON_H_

 #include "VmaUsage.h"

 #ifdef _WIN32

 #include <iostream>
 #include <fstream>
 #include <vector>
 #include <memory>
 #include <algorithm>
 #include <numeric>
 #include <array>
 #include <type_traits>
 #include <utility>
 #include <chrono>
 #include <string>

 #include <cassert>
 #include <cstdlib>
 #include <cstdio>
 #include <cstdarg>

 typedef std::chrono::high_resolution_clock::time_point time_point;
 typedef std::chrono::high_resolution_clock::duration duration;

 #define ERR_GUARD_VULKAN(Expr) do { VkResult res__ = (Expr); if (res__ < 0) assert(0); } while(0)

 extern VkPhysicalDevice g_hPhysicalDevice;
 extern VkDevice g_hDevice;
 extern VmaAllocator g_hAllocator;
 extern bool g_MemoryAliasingWarningEnabled;

 inline float ToFloatSeconds(duration d)
 {
     return std::chrono::duration_cast<std::chrono::duration<float>>(d).count();
 }

 template <typename T>
 inline T ceil_div(T x, T y)
 {
     return (x+y-1) / y;
 }

 template <typename T>
 static inline T align_up(T val, T align)
 {
     return (val + align - 1) / align * align;
 }

 static const float PI = 3.14159265358979323846264338327950288419716939937510582f;

 struct vec3
 {
     float x, y, z;

     vec3() { }
     vec3(float x, float y, float z) : x(x), y(y), z(z) { }

     float& operator[](uint32_t index) { return *(&x + index); }
     const float& operator[](uint32_t index) const { return *(&x + index); }

     vec3 operator+(const vec3& rhs) const { return vec3(x + rhs.x, y + rhs.y, z + rhs.z); }
     vec3 operator-(const vec3& rhs) const { return vec3(x - rhs.x, y - rhs.y, z - rhs.z); }
     vec3 operator*(float s) const { return vec3(x * s, y * s, z * s); }

     vec3 Normalized() const
     {
         return (*this) * (1.f / sqrt(x * x + y * y + z * z));
     }
 };

 inline float Dot(const vec3& lhs, const vec3& rhs)
 {
     return lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z;
 }
 inline vec3 Cross(const vec3& lhs, const vec3& rhs)
 {
     return vec3(
         lhs.y * rhs.z - lhs.z * rhs.y,
 	    lhs.z * rhs.x - lhs.x * rhs.z,
 	    lhs.x * rhs.y - lhs.y * rhs.x);
 }

 struct vec4
 {
     float x, y, z, w;

     vec4() { }
     vec4(float x, float y, float z, float w) : x(x), y(y), z(z), w(w) { }
     vec4(const vec3& v, float w) : x(v.x), y(v.y), z(v.z), w(w) { }

     float& operator[](uint32_t index) { return *(&x + index); }
     const float& operator[](uint32_t index) const { return *(&x + index); }
 };

 struct mat4
 {
     union
     {
         struct
         {
             float _11, _12, _13, _14;
             float _21, _22, _23, _24;
             float _31, _32, _33, _34;
             float _41, _42, _43, _44;
         };
         float m[4][4]; // [row][column]
     };

     mat4() { }

     mat4(
         float _11, float _12, float _13, float _14,
         float _21, float _22, float _23, float _24,
         float _31, float _32, float _33, float _34,
         float _41, float _42, float _43, float _44) :
         _11(_11), _12(_12), _13(_13), _14(_14),
         _21(_21), _22(_22), _23(_23), _24(_24),
         _31(_31), _32(_32), _33(_33), _34(_34),
         _41(_41), _42(_42), _43(_43), _44(_44)
     {
     }

     mat4(
         const vec4& row1,
         const vec4& row2,
         const vec4& row3,
         const vec4& row4) :
         _11(row1.x), _12(row1.y), _13(row1.z), _14(row1.w),
         _21(row2.x), _22(row2.y), _23(row2.z), _24(row2.w),
         _31(row3.x), _32(row3.y), _33(row3.z), _34(row3.w),
         _41(row4.x), _42(row4.y), _43(row4.z), _44(row4.w)
     {
     }

     mat4 operator*(const mat4 &rhs) const
     {
         return mat4(
             _11 * rhs._11 + _12 * rhs._21 + _13 * rhs._31 + _14 * rhs._41,
             _11 * rhs._12 + _12 * rhs._22 + _13 * rhs._32 + _14 * rhs._42,
             _11 * rhs._13 + _12 * rhs._23 + _13 * rhs._33 + _14 * rhs._43,
             _11 * rhs._14 + _12 * rhs._24 + _13 * rhs._34 + _14 * rhs._44,

             _21 * rhs._11 + _22 * rhs._21 + _23 * rhs._31 + _24 * rhs._41,
             _21 * rhs._12 + _22 * rhs._22 + _23 * rhs._32 + _24 * rhs._42,
             _21 * rhs._13 + _22 * rhs._23 + _23 * rhs._33 + _24 * rhs._43,
             _21 * rhs._14 + _22 * rhs._24 + _23 * rhs._34 + _24 * rhs._44,

             _31 * rhs._11 + _32 * rhs._21 + _33 * rhs._31 + _34 * rhs._41,
             _31 * rhs._12 + _32 * rhs._22 + _33 * rhs._32 + _34 * rhs._42,
             _31 * rhs._13 + _32 * rhs._23 + _33 * rhs._33 + _34 * rhs._43,
             _31 * rhs._14 + _32 * rhs._24 + _33 * rhs._34 + _34 * rhs._44,

             _41 * rhs._11 + _42 * rhs._21 + _43 * rhs._31 + _44 * rhs._41,
             _41 * rhs._12 + _42 * rhs._22 + _43 * rhs._32 + _44 * rhs._42,
             _41 * rhs._13 + _42 * rhs._23 + _43 * rhs._33 + _44 * rhs._43,
             _41 * rhs._14 + _42 * rhs._24 + _43 * rhs._34 + _44 * rhs._44);
     }

     static mat4 RotationY(float angle)
     {
         const float s = sin(angle), c = cos(angle);
         return mat4(
             c,   0.f, -s,  0.f,
             0.f, 1.f, 0.f, 0.f,
             s,   0.f, c,   0.f,
             0.f, 0.f, 0.f, 1.f);
     }

     static mat4 Perspective(float fovY, float aspectRatio, float zNear, float zFar)
     {
         float yScale = 1.0f / tan(fovY * 0.5f);
         float xScale = yScale / aspectRatio;
         return mat4(
             xScale, 0.0f, 0.0f, 0.0f,
             0.0f, yScale, 0.0f, 0.0f,
             0.0f, 0.0f, zFar / (zFar - zNear), 1.0f,
             0.0f, 0.0f, -zNear * zFar / (zFar - zNear), 0.0f);
     }

     static mat4 LookAt(vec3 at, vec3 eye, vec3 up)
     {
         vec3 zAxis = (at - eye).Normalized();
         vec3 xAxis = Cross(up, zAxis).Normalized();
         vec3 yAxis = Cross(zAxis, xAxis);
         return mat4(
             xAxis.x, yAxis.x, zAxis.x, 0.0f,
             xAxis.y, yAxis.y, zAxis.y, 0.0f,
             xAxis.z, yAxis.z, zAxis.z, 0.0f,
             -Dot(xAxis, eye), -Dot(yAxis, eye), -Dot(zAxis, eye), 1.0f);
     }
 };

 class RandomNumberGenerator
 {
 public:
     RandomNumberGenerator() : m_Value{GetTickCount()} {}
     RandomNumberGenerator(uint32_t seed) : m_Value{seed} { }
     void Seed(uint32_t seed) { m_Value = seed; }
     uint32_t Generate() { return GenerateFast() ^ (GenerateFast() >> 7); }

 private:
     uint32_t m_Value;
     uint32_t GenerateFast() { return m_Value = (m_Value * 196314165 + 907633515); }
 };

 // Wrapper for RandomNumberGenerator compatible with STL "UniformRandomNumberGenerator" idea.
 struct MyUniformRandomNumberGenerator
 {
     typedef uint32_t result_type;
     MyUniformRandomNumberGenerator(RandomNumberGenerator& gen) : m_Gen(gen) { }
     static uint32_t min() { return 0; }
     static uint32_t max() { return UINT32_MAX; }
     uint32_t operator()() { return m_Gen.Generate(); }

 private:
     RandomNumberGenerator& m_Gen;
 };

 void ReadFile(std::vector<char>& out, const char* fileName);

 enum class CONSOLE_COLOR
 {
     INFO,
     NORMAL,
     WARNING,
     ERROR_,
     COUNT
 };

 void SetConsoleColor(CONSOLE_COLOR color);

 void PrintMessage(CONSOLE_COLOR color, const char* msg);
 void PrintMessage(CONSOLE_COLOR color, const wchar_t* msg);

 inline void Print(const char* msg) { PrintMessage(CONSOLE_COLOR::NORMAL, msg); }
 inline void Print(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::NORMAL, msg); }
 inline void PrintWarning(const char* msg) { PrintMessage(CONSOLE_COLOR::WARNING, msg); }
 inline void PrintWarning(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::WARNING, msg); }
 inline void PrintError(const char* msg) { PrintMessage(CONSOLE_COLOR::ERROR_, msg); }
 inline void PrintError(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::ERROR_, msg); }

 void PrintMessageV(CONSOLE_COLOR color, const char* format, va_list argList);
 void PrintMessageV(CONSOLE_COLOR color, const wchar_t* format, va_list argList);
 void PrintMessageF(CONSOLE_COLOR color, const char* format, ...);
 void PrintMessageF(CONSOLE_COLOR color, const wchar_t* format, ...);
 void PrintWarningF(const char* format, ...);
 void PrintWarningF(const wchar_t* format, ...);
 void PrintErrorF(const char* format, ...);
 void PrintErrorF(const wchar_t* format, ...);

 void SaveFile(const wchar_t* filePath, const void* data, size_t dataSize);

 #endif // #ifdef _WIN32

 #endif
	#ifndef COMMON_H_
	#define COMMON_H_

	#include "VmaUsage.h"

	#ifdef _WIN32

	#include <iostream>
	#include <fstream>
	#include <vector>
	#include <memory>
	#include <algorithm>
	#include <numeric>
	#include <array>
	#include <type_traits>
	#include <utility>
	#include <chrono>
	#include <string>

	#include <cassert>
	#include <cstdlib>
	#include <cstdio>
	#include <cstdarg>

	typedef std::chrono::high_resolution_clock::time_point time_point;
	typedef std::chrono::high_resolution_clock::duration duration;

	#define ERR_GUARD_VULKAN(Expr) do { VkResult res__ = (Expr); if (res__ < 0) assert(0); } while(0)

	extern VkPhysicalDevice g_hPhysicalDevice;
	extern VkDevice g_hDevice;
	extern VmaAllocator g_hAllocator;
	extern bool g_MemoryAliasingWarningEnabled;

	inline float ToFloatSeconds(duration d)
	{
	return std::chrono::duration_cast<std::chrono::duration<float>>(d).count();
	}

	template <typename T>
	inline T ceil_div(T x, T y)
	{
	return (x+y-1) / y;
	}

	template <typename T>
	static inline T align_up(T val, T align)
	{
	return (val + align - 1) / align * align;
	}

	static const float PI = 3.14159265358979323846264338327950288419716939937510582f;

	struct vec3
	{
	float x, y, z;

	vec3() { }
	vec3(float x, float y, float z) : x(x), y(y), z(z) { }

	float& operator[](uint32_t index) { return *(&x + index); }
	const float& operator[](uint32_t index) const { return *(&x + index); }

	vec3 operator+(const vec3& rhs) const { return vec3(x + rhs.x, y + rhs.y, z + rhs.z); }
	vec3 operator-(const vec3& rhs) const { return vec3(x - rhs.x, y - rhs.y, z - rhs.z); }
	vec3 operator(float s) const { return vec3(x s, y * s, z * s); }

	vec3 Normalized() const
	{
	return (this) (1.f / sqrt(x * x + y * y + z * z));
	}
	};

	inline float Dot(const vec3& lhs, const vec3& rhs)
	{
	return lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z;
	}
	inline vec3 Cross(const vec3& lhs, const vec3& rhs)
	{
	return vec3(
	lhs.y * rhs.z - lhs.z * rhs.y,
	lhs.z * rhs.x - lhs.x * rhs.z,
	lhs.x * rhs.y - lhs.y * rhs.x);
	}

	struct vec4
	{
	float x, y, z, w;

	vec4() { }
	vec4(float x, float y, float z, float w) : x(x), y(y), z(z), w(w) { }
	vec4(const vec3& v, float w) : x(v.x), y(v.y), z(v.z), w(w) { }

	float& operator[](uint32_t index) { return *(&x + index); }
	const float& operator[](uint32_t index) const { return *(&x + index); }
	};

	struct mat4
	{
	union
	{
	struct
	{
	float _11, _12, _13, _14;
	float _21, _22, _23, _24;
	float _31, _32, _33, _34;
	float _41, _42, _43, _44;
	};
	float m[4][4]; // [row][column]
	};

	mat4() { }

	mat4(
	float _11, float _12, float _13, float _14,
	float _21, float _22, float _23, float _24,
	float _31, float _32, float _33, float _34,
	float _41, float _42, float _43, float _44) :
	_11(_11), _12(_12), _13(_13), _14(_14),
	_21(_21), _22(_22), _23(_23), _24(_24),
	_31(_31), _32(_32), _33(_33), _34(_34),
	_41(_41), _42(_42), _43(_43), _44(_44)
	{
	}

	mat4(
	const vec4& row1,
	const vec4& row2,
	const vec4& row3,
	const vec4& row4) :
	_11(row1.x), _12(row1.y), _13(row1.z), _14(row1.w),
	_21(row2.x), _22(row2.y), _23(row2.z), _24(row2.w),
	_31(row3.x), _32(row3.y), _33(row3.z), _34(row3.w),
	_41(row4.x), _42(row4.y), _43(row4.z), _44(row4.w)
	{
	}

	mat4 operator*(const mat4 &rhs) const
	{
	return mat4(
	_11 * rhs._11 + _12 * rhs._21 + _13 * rhs._31 + _14 * rhs._41,
	_11 * rhs._12 + _12 * rhs._22 + _13 * rhs._32 + _14 * rhs._42,
	_11 * rhs._13 + _12 * rhs._23 + _13 * rhs._33 + _14 * rhs._43,
	_11 * rhs._14 + _12 * rhs._24 + _13 * rhs._34 + _14 * rhs._44,

	_21 * rhs._11 + _22 * rhs._21 + _23 * rhs._31 + _24 * rhs._41,
	_21 * rhs._12 + _22 * rhs._22 + _23 * rhs._32 + _24 * rhs._42,
	_21 * rhs._13 + _22 * rhs._23 + _23 * rhs._33 + _24 * rhs._43,
	_21 * rhs._14 + _22 * rhs._24 + _23 * rhs._34 + _24 * rhs._44,

	_31 * rhs._11 + _32 * rhs._21 + _33 * rhs._31 + _34 * rhs._41,
	_31 * rhs._12 + _32 * rhs._22 + _33 * rhs._32 + _34 * rhs._42,
	_31 * rhs._13 + _32 * rhs._23 + _33 * rhs._33 + _34 * rhs._43,
	_31 * rhs._14 + _32 * rhs._24 + _33 * rhs._34 + _34 * rhs._44,

	_41 * rhs._11 + _42 * rhs._21 + _43 * rhs._31 + _44 * rhs._41,
	_41 * rhs._12 + _42 * rhs._22 + _43 * rhs._32 + _44 * rhs._42,
	_41 * rhs._13 + _42 * rhs._23 + _43 * rhs._33 + _44 * rhs._43,
	_41 * rhs._14 + _42 * rhs._24 + _43 * rhs._34 + _44 * rhs._44);
	}

	static mat4 RotationY(float angle)
	{
	const float s = sin(angle), c = cos(angle);
	return mat4(
	c, 0.f, -s, 0.f,
	0.f, 1.f, 0.f, 0.f,
	s, 0.f, c, 0.f,
	0.f, 0.f, 0.f, 1.f);
	}

	static mat4 Perspective(float fovY, float aspectRatio, float zNear, float zFar)
	{
	float yScale = 1.0f / tan(fovY * 0.5f);
	float xScale = yScale / aspectRatio;
	return mat4(
	xScale, 0.0f, 0.0f, 0.0f,
	0.0f, yScale, 0.0f, 0.0f,
	0.0f, 0.0f, zFar / (zFar - zNear), 1.0f,
	0.0f, 0.0f, -zNear * zFar / (zFar - zNear), 0.0f);
	}

	static mat4 LookAt(vec3 at, vec3 eye, vec3 up)
	{
	vec3 zAxis = (at - eye).Normalized();
	vec3 xAxis = Cross(up, zAxis).Normalized();
	vec3 yAxis = Cross(zAxis, xAxis);
	return mat4(
	xAxis.x, yAxis.x, zAxis.x, 0.0f,
	xAxis.y, yAxis.y, zAxis.y, 0.0f,
	xAxis.z, yAxis.z, zAxis.z, 0.0f,
	-Dot(xAxis, eye), -Dot(yAxis, eye), -Dot(zAxis, eye), 1.0f);
	}
	};

	class RandomNumberGenerator
	{
	public:
	RandomNumberGenerator() : m_Value{GetTickCount()} {}
	RandomNumberGenerator(uint32_t seed) : m_Value{seed} { }
	void Seed(uint32_t seed) { m_Value = seed; }
	uint32_t Generate() { return GenerateFast() ^ (GenerateFast() >> 7); }

	private:
	uint32_t m_Value;
	uint32_t GenerateFast() { return m_Value = (m_Value * 196314165 + 907633515); }
	};

	// Wrapper for RandomNumberGenerator compatible with STL "UniformRandomNumberGenerator" idea.
	struct MyUniformRandomNumberGenerator
	{
	typedef uint32_t result_type;
	MyUniformRandomNumberGenerator(RandomNumberGenerator& gen) : m_Gen(gen) { }
	static uint32_t min() { return 0; }
	static uint32_t max() { return UINT32_MAX; }
	uint32_t operator()() { return m_Gen.Generate(); }

	private:
	RandomNumberGenerator& m_Gen;
	};

	void ReadFile(std::vector<char>& out, const char* fileName);

	enum class CONSOLE_COLOR
	{
	INFO,
	NORMAL,
	WARNING,
	ERROR_,
	COUNT
	};

	void SetConsoleColor(CONSOLE_COLOR color);

	void PrintMessage(CONSOLE_COLOR color, const char* msg);
	void PrintMessage(CONSOLE_COLOR color, const wchar_t* msg);

	inline void Print(const char* msg) { PrintMessage(CONSOLE_COLOR::NORMAL, msg); }
	inline void Print(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::NORMAL, msg); }
	inline void PrintWarning(const char* msg) { PrintMessage(CONSOLE_COLOR::WARNING, msg); }
	inline void PrintWarning(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::WARNING, msg); }
	inline void PrintError(const char* msg) { PrintMessage(CONSOLE_COLOR::ERROR_, msg); }
	inline void PrintError(const wchar_t* msg) { PrintMessage(CONSOLE_COLOR::ERROR_, msg); }

	void PrintMessageV(CONSOLE_COLOR color, const char* format, va_list argList);
	void PrintMessageV(CONSOLE_COLOR color, const wchar_t* format, va_list argList);
	void PrintMessageF(CONSOLE_COLOR color, const char* format, ...);
	void PrintMessageF(CONSOLE_COLOR color, const wchar_t* format, ...);
	void PrintWarningF(const char* format, ...);
	void PrintWarningF(const wchar_t* format, ...);
	void PrintErrorF(const char* format, ...);
	void PrintErrorF(const wchar_t* format, ...);

	void SaveFile(const wchar_t* filePath, const void* data, size_t dataSize);

	#endif // #ifdef _WIN32

	#endif