libcmo21/LibCmo/VxMath/VxTypes.hpp

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#pragma once
#include "../VTUtils.hpp"
#include "../CK2/CKTypes.hpp"
#include "VxEnums.hpp"
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#include <string>
#include <vector>
#include <cstring>
#include <cinttypes>
/**
* @brief The VxMath part of LibCmo.
* These classes are prefixed with Vx in original Virtools SDK.
*/
namespace LibCmo::VxMath {
// ========== Type Definition ==========
// ========== Class List ==========
//--- Important classes
class VxMemoryMappedFile;
//---- Misc
/**
* @brief Class representation of a Vector in 3 dimensions
*/
struct VxVector {
float x, y, z;
VxVector() : x(0.0f), y(0.0f), z(0.0f) {}
VxVector(float f) : x(f), y(f), z(f) {}
VxVector(float _x, float _y, float _z) : x(_x), y(_y), z(_z) {}
VxVector(const float f[3]) : x(f[0]), y(f[1]), z(f[2]) {}
};
/**
* @brief Class representation of a Vector in 2 dimensions
*/
struct Vx2DVector {
float x, y;
Vx2DVector() : x(0.0f), y(0.0f) {}
Vx2DVector(float f) : x(f), y(f) {}
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Vx2DVector(float _x, float _y) : x(_x), y(_y) {}
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Vx2DVector(CK2::CKINT iX, CK2::CKINT iY) : x((float)iX), y((float)iY) {}
Vx2DVector(const float f[2]) : x(f[0]), y(f[1]) {}
};
/**
* @brief Class representation of a Quaternion
*/
struct VxQuaternion {
float x, y, z, w;
VxQuaternion() : x(0.0f), y(0.0f), z(0.0f), w(1.0f) {}
VxQuaternion(float X, float Y, float Z, float W) : x(X), y(Y), z(Z), w(W) {}
};
struct VxMatrix {
float m_Data[4][4];
VxMatrix() : m_Data() {
std::memset(m_Data, 0, sizeof(m_Data));
m_Data[0][0] = m_Data[1][1] = m_Data[2][2] = m_Data[3][3] = 1.0f;
}
VxMatrix(float m[4][4]) : m_Data() { std::memcpy(m_Data, m, sizeof(m_Data)); }
};
/**
* VxImageDescEx describe the height, width,
* and etc for image.
* Also it hold a pointer to raw image data.
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* The image data must be 32bit ARGB8888 format.
* Thus the size of Image must be 4 * Width * Height.
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*/
class VxImageDescEx {
public:
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VxImageDescEx() :
m_Width(0), m_Height(0), m_Image(nullptr) {}
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VxImageDescEx(CK2::CKDWORD width, CK2::CKDWORD height) :
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m_Width(width), m_Height(height), m_Image(nullptr) {
CreateImage(width, height);
}
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VxImageDescEx(const VxImageDescEx& rhs) :
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m_Width(rhs.m_Width), m_Height(rhs.m_Height), m_Image(nullptr) {
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// copy image
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if (rhs.m_Image != nullptr) {
CreateImage(rhs.m_Width, rhs.m_Height, rhs.m_Image);
}
}
VxImageDescEx(VxImageDescEx&& rhs) :
m_Width(rhs.m_Width), m_Height(rhs.m_Height), m_Image(rhs.m_Image) {
// move image
rhs.m_Height = 0;
rhs.m_Width = 0;
rhs.m_Image = nullptr;
}
VxImageDescEx& operator=(const VxImageDescEx& rhs) {
FreeImage();
m_Width = rhs.m_Width;
m_Height = rhs.m_Height;
if (rhs.m_Image != nullptr) {
CreateImage(rhs.m_Width, rhs.m_Height, rhs.m_Image);
}
return *this;
}
VxImageDescEx& operator=(VxImageDescEx&& rhs) {
FreeImage();
m_Height = rhs.m_Height;
m_Width = rhs.m_Width;
m_Image = rhs.m_Image;
rhs.m_Height = 0;
rhs.m_Width = 0;
rhs.m_Image = nullptr;
return *this;
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}
~VxImageDescEx() {
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FreeImage();
}
void CreateImage(CK2::CKDWORD Width, CK2::CKDWORD Height) {
FreeImage();
m_Width = Width;
m_Height = Height;
m_Image = new CK2::CKBYTE[GetImageSize()];
}
void CreateImage(CK2::CKDWORD Width, CK2::CKDWORD Height, void* dataptr) {
CreateImage(Width, Height);
std::memcpy(m_Image, dataptr, GetImageSize());
}
void FreeImage() {
m_Width = 0;
m_Height = 0;
if (m_Image != nullptr) {
delete[] m_Image;
m_Image = nullptr;
}
}
CK2::CKDWORD GetImageSize() const {
return static_cast<CK2::CKDWORD>(sizeof(uint32_t) * m_Width * m_Height);
}
const CK2::CKBYTE* GetImage() const {
return m_Image;
}
CK2::CKBYTE* GetMutableImage() {
return m_Image;
}
CK2::CKDWORD GetPixelCount() const {
return static_cast<CK2::CKDWORD>(m_Width * m_Height);
}
const CK2::CKDWORD* GetPixels() const {
return reinterpret_cast<CK2::CKDWORD*>(m_Image);
}
CK2::CKDWORD* GetMutablePixels() {
return reinterpret_cast<CK2::CKDWORD*>(m_Image);
}
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CK2::CKDWORD GetWidth() const {
return m_Width;
}
CK2::CKDWORD GetHeight() const {
return m_Height;
}
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bool IsValid() const {
return (
m_Width != 0u &&
m_Height != 0u &&
m_Image != nullptr
);
}
bool IsHWEqual(const VxImageDescEx& rhs) const {
return (m_Width == rhs.m_Width && m_Height == rhs.m_Height);
}
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// bool IsMaskEqual(const VxImageDescEx& rhs) const {
// return (
// m_RedMask == rhs.m_RedMask &&
// m_GreenMask == rhs.m_GreenMask &&
// m_BlueMask == rhs.m_BlueMask &&
// m_AlphaMask == rhs.m_AlphaMask
// );
// }
//public:
// CK2::CKDWORD m_RedMask;
// CK2::CKDWORD m_GreenMask;
// CK2::CKDWORD m_BlueMask;
// CK2::CKDWORD m_AlphaMask;
protected:
CK2::CKDWORD m_Width; /**< Width in pixel of the image */
CK2::CKDWORD m_Height; /**< Height in pixel of the image */
CK2::CKBYTE* m_Image; /**< A pointer point to current processing image */
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};
}