libcmo21/LibCmo/VxMath/VxMath.cpp

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#include "VxMath.hpp"
#include <cmath>
#include <stb_image_resize.h>
namespace LibCmo::VxMath {
#pragma region Structure copying
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void VxFillStructure(CKDWORD Count, void* Dst, CKDWORD Stride, CKDWORD SizeSrc, const void* Src) {
VxCopyStructure(Count, Dst, Stride, SizeSrc, Src, SizeSrc);
}
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void VxCopyStructure(CKDWORD Count, void* Dst, CKDWORD OutStride, CKDWORD SizeSrc, const void* Src, CKDWORD InStride) {
if (Dst == nullptr || Src == nullptr) return;
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CKBYTE* cdst = static_cast<CKBYTE*>(Dst);
const CKBYTE* csrc = static_cast<const CKBYTE*>(Src);
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for (CKDWORD i = 0; i < Count; ++i) {
std::memcpy(cdst, csrc, SizeSrc);
cdst += OutStride;
csrc += InStride;
}
}
#pragma endregion
#pragma region Graphic Utilities
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void VxDoBlit(const VxImageDescEx* origin, VxImageDescEx* dst) {
if (dst == nullptr || origin == nullptr) return;
if (!dst->IsValid() || !origin->IsValid()) return;
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// if have same size, directly copy it
if (dst->IsHWEqual(*origin)) {
std::memcpy(dst->GetMutableImage(), origin->GetImage(), dst->GetImageSize());
return;
}
// perform resize by stb
stbir_resize(
origin->GetImage(), static_cast<int>(origin->GetWidth()), static_cast<int>(origin->GetHeight()), 0,
dst->GetMutableImage(), static_cast<int>(dst->GetWidth()), static_cast<int>(dst->GetHeight()), 0,
STBIR_TYPE_UINT8, 4, STBIR_ALPHA_CHANNEL_NONE, 0, // no alpha channel, mean we treat alpha channel as a normal color factor.
STBIR_EDGE_CLAMP, STBIR_EDGE_CLAMP,
STBIR_FILTER_BOX, STBIR_FILTER_BOX,
STBIR_COLORSPACE_SRGB, nullptr
);
}
void VxDoBlitUpsideDown(const VxImageDescEx* origin, VxImageDescEx* dst) {
if (dst == nullptr || origin == nullptr) return;
if (!dst->IsValid() || !origin->IsValid()) return;
// if size is not matched, return
if (!dst->IsHWEqual(*origin)) {
return;
}
// copy and swap data by line
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CKDWORD height = dst->GetHeight(),
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rowsize = VxImageDescEx::PixelSize * dst->GetWidth();
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for (CKDWORD row = 0; row < height; ++row) {
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std::memcpy(
dst->GetMutableImage() + (row * rowsize),
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origin->GetImage() + ((height - row - 1) * rowsize),
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rowsize
);
}
}
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CKDWORD VxGetBitCount(CKDWORD dwMask) {
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if (dwMask == 0u) return 0;
dwMask >>= VxGetBitShift(dwMask);
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CKDWORD count = 0;
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while ((dwMask & 1u) == 0u) {
dwMask >>= 1u;
++count;
}
return count;
}
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CKDWORD VxGetBitShift(CKDWORD dwMask) {
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if (dwMask == 0u) return 0;
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CKDWORD count = 0;
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while ((dwMask & 1u) != 0u) {
dwMask >>= 1u;
++count;
}
return count;
}
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//CKDWORD VxScaleFactor(CKDWORD val, CKDWORD srcBitCount, CKDWORD dstBitCount) {
// if (srcBitCount == dstBitCount) return val;
// if (srcBitCount > dstBitCount) {
// return val >> (srcBitCount - dstBitCount);
// } else {
// return val << (dstBitCount - srcBitCount);
// }
//}
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void VxDoAlphaBlit(VxImageDescEx* dst_desc, CKBYTE AlphaValue) {
if (dst_desc == nullptr) return;
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CKDWORD* pixels = dst_desc->GetMutablePixels();
CKDWORD pixelcount = dst_desc->GetPixelCount();
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for (CKDWORD i = 0; i < pixelcount; ++i) {
*pixels = (*pixels) & 0x00FFFFFF | (static_cast<CKDWORD>(AlphaValue) << 24);
++pixels;
}
}
void VxDoAlphaBlit(VxImageDescEx* dst_desc, const CKBYTE* AlphaValues) {
if (dst_desc == nullptr) return;
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CKDWORD* pixels = dst_desc->GetMutablePixels();
CKDWORD pixelcount = dst_desc->GetPixelCount();
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for (CKDWORD i = 0; i < pixelcount; ++i) {
*pixels = (*pixels) & 0x00FFFFFF | (static_cast<CKDWORD>(*AlphaValues) << 24);
++pixels;
++AlphaValues;
}
}
#pragma endregion
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#pragma region Patched
namespace NSVxVector {
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float DotProduct(const VxVector2& lhs, const VxVector2& rhs) {
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return lhs * rhs;
}
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float DotProduct(const VxVector3& lhs, const VxVector3& rhs) {
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return lhs * rhs;
}
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float DotProduct(const VxVector4& lhs, const VxVector4& rhs) {
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return lhs * rhs;
}
VxVector3 CrossProduct(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(
lhs.y * rhs.z - lhs.z * rhs.y,
lhs.z * rhs.x - lhs.x * rhs.z,
lhs.x * rhs.y - lhs.y * rhs.x
);
}
void Abs(VxVector3& lhs) {
lhs.x = std::fabs(lhs.x);
lhs.y = std::fabs(lhs.y);
lhs.z = std::fabs(lhs.z);
}
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}
#pragma endregion
}