CloverBootloader/rEFIt_UEFI/libeg/XImage.cpp

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#include "XImage.h"
#include "lodepng.h"
#include "nanosvg.h"
#ifndef DEBUG_ALL
#define DEBUG_XIMAGE 1
#else
#define DEBUG_XIMAGE DEBUG_ALL
#endif
#if DEBUG_XIMAGE == 0
#define DBG(...)
#else
#define DBG(...) DebugLog(DEBUG_XIMAGE, __VA_ARGS__)
#endif
XImage::XImage()
{
Width = 0;
Height = 0;
}
XImage::XImage(UINTN W, UINTN H)
{
Width = W;
Height = H;
PixelData.CheckSize(GetWidth()*GetHeight());
}
XImage::XImage(EG_IMAGE* egImage)
{
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if ( egImage) {
Width = egImage->Width;
Height = egImage->Height;
}else{
Width = 0;
Height = 0;
}
PixelData.CheckSize(GetWidth()*GetHeight()); // change the allocated size, but not the size.
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PixelData.SetLength(GetWidth()*GetHeight()); // change the size, ie the number of element in the array
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if ( GetWidth()*GetHeight() > 0 ) {
CopyMem(&PixelData[0], egImage->PixelData, PixelData.size() * sizeof(*egImage->PixelData));
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}
}
UINT8 Smooth(const UINT8* p, int a01, int a10, int a21, int a12, int dx, int dy, float scale)
{
return (UINT8)((*(p + a01) * (scale - dx) * 3.f + *(p + a10) * (scale - dy) * 3.f + *(p + a21) * dx * 3.f +
*(p + a12) * dy * 3.f + *(p) * 2.f *scale) / (scale * 8.f));
}
XImage::XImage(const XImage& Image, float scale)
{
UINTN SrcWidth = Image.GetWidth();
UINTN SrcHeight = Image.GetHeight();
if (scale < 1.e-4) {
Width = SrcWidth;
Height = SrcHeight;
PixelData.CheckSize(GetWidth()*GetHeight());
PixelData.SetLength(GetWidth()*GetHeight());
for (UINTN y = 0; y < Height; ++y)
for (UINTN x = 0; x < Width; ++x)
PixelData[y * Width + x] = Image.GetPixel(x, y);
} else {
Width = (UINTN)(SrcWidth * scale);
Height = (UINTN)(SrcHeight * scale);
PixelData.CheckSize(Width * Height);
PixelData.SetLength(Width * Height);
CopyScaled(Image, scale);
}
}
#if 0
UINTN Offset = OFFSET_OF(EFI_GRAPHICS_OUTPUT_BLT_PIXEL, Blue);
dst.Blue = Smooth(&src.Blue, a01, a10, a11, a21, a12, dx, dy, scale);
#define SMOOTH(P) \
do { \
((PIXEL*)dst_ptr)->P = (BYTE)((a01.P * (cx - dx) * 3 + a10.P * (cy - dy) * 3 + \
a21.P * dx * 3 + a12.P * dy * 3 + a11.P * (cx + cy)) / ((cx + cy) * 4)); \
} while(0)
UINT x, y, z;
PIXEL a10, a11, a12, a01, a21;
int fx, cx, lx, dx, fy, cy, ly, dy;
fx = (dst_size->width << PRECISION) / src_size->width;
fy = (dst_size->height << PRECISION) / src_size->height;
if (!fx || !fy) {
return;
}
cx = ((fx - 1) >> PRECISION) + 1;
cy = ((fy - 1) >> PRECISION) + 1;
for (z = 0; z < dst_size->depth; z++)
{
BYTE * dst_slice_ptr = dst + z * dst_slice_pitch;
const BYTE *src_slice_ptr = src + src_slice_pitch * (z * src_size->depth / dst_size->depth);
for (y = 0; y < dst_size->height; y++)
{
BYTE * dst_ptr = dst_slice_ptr + y * dst_row_pitch;
const BYTE *src_row_ptr = src_slice_ptr + src_row_pitch * (y * src_size->height / dst_size->height);
ly = (y << PRECISION) / fy;
dy = y - ((ly * fy) >> PRECISION);
for (x = 0; x < dst_size->width; x++)
{
const BYTE *src_ptr = src_row_ptr + (x * src_size->width / dst_size->width) * src_format->bytes_per_pixel;
lx = (x << PRECISION) / fx;
dx = x - ((lx * fx) >> PRECISION);
a11 = *(PIXEL*)src_ptr;
a10 = (y == 0) ? a11 : (*(PIXEL*)(src_ptr - src_row_pitch));
a01 = (x == 0) ? a11 : (*(PIXEL*)(src_ptr - src_format->bytes_per_pixel));
a21 = (x == dst_size->width) ? a11 : (*(PIXEL*)(src_ptr + src_format->bytes_per_pixel));
a12 = (y == dst_size->height) ? a11 : (*(PIXEL*)(src_ptr + src_row_pitch));
SMOOTH(r);
SMOOTH(g);
SMOOTH(b);
SMOOTH(a);
dst_ptr += dst_format->bytes_per_pixel;
}
}
}
#endif
XImage::~XImage()
{
}
const XArray<EFI_GRAPHICS_OUTPUT_BLT_PIXEL>& XImage::GetData() const
{
return PixelData;
}
EFI_GRAPHICS_OUTPUT_BLT_PIXEL* XImage::GetPixelPtr(UINTN x, UINTN y)
{
return &PixelData[x + y * Width];
}
const EFI_GRAPHICS_OUTPUT_BLT_PIXEL& XImage::GetPixel(UINTN x, UINTN y) const
{
return PixelData[x + y * Width];
}
UINTN XImage::GetWidth() const
{
return Width;
}
UINTN XImage::GetHeight() const
{
return Height;
}
UINTN XImage::GetSize() const
{
return Width * Height * sizeof(EFI_GRAPHICS_OUTPUT_BLT_PIXEL);
}
void XImage::Fill(const EFI_GRAPHICS_OUTPUT_BLT_PIXEL& Color)
{
for (UINTN y = 0; y < Height; ++y)
for (UINTN x = 0; x < Width; ++x)
PixelData[y * Width + x] = Color;
}
void XImage::FillArea(const EFI_GRAPHICS_OUTPUT_BLT_PIXEL& Color, const EgRect& Rect)
{
for (UINTN y = Rect.Ypos; y < Height && (y - Rect.Ypos) < Rect.Height; ++y) {
// EFI_GRAPHICS_OUTPUT_BLT_PIXEL* Ptr = PixelData + y * Width + Rect.Xpos;
for (UINTN x = Rect.Xpos; x < Width && (x - Rect.Xpos) < Rect.Width; ++x)
// *Ptr++ = Color;
PixelData[y * Width + x] = Color;
}
}
void XImage::CopyScaled(const XImage& Image, float scale)
{
UINTN SrcWidth = Image.GetWidth();
int Pixel = sizeof(EFI_GRAPHICS_OUTPUT_BLT_PIXEL);
int Row = (int)SrcWidth * sizeof(EFI_GRAPHICS_OUTPUT_BLT_PIXEL);
const XArray<EFI_GRAPHICS_OUTPUT_BLT_PIXEL>& Source = Image.GetData();
for (UINTN y = 0; y < Height; y++)
{
int ly = (int)(y / scale);
int dy = (int)(y - ly * scale);
for (UINTN x = 0; x < Width; x++)
{
int lx = (int)(x / scale);
int dx = (int)(x - lx * scale);
int a01 = (x == 0) ? 0 : -Pixel;
int a10 = (y == 0) ? 0 : -Row;
int a21 = (x == Width - 1) ? 0 : Pixel;
int a12 = (y == Height - 1) ? 0 : Row;
EFI_GRAPHICS_OUTPUT_BLT_PIXEL& dst = *GetPixelPtr(x, y);
dst.Blue = Smooth(&Source[lx + ly * SrcWidth].Blue, a01, a10, a21, a12, dx, dy, scale);
dst.Green = Smooth(&Source[lx + ly * SrcWidth].Green, a01, a10, a21, a12, dx, dy, scale);
dst.Red = Smooth(&Source[lx + ly * SrcWidth].Red, a01, a10, a21, a12, dx, dy, scale);
dst.Reserved = Source[lx + ly * SrcWidth].Reserved;
}
}
}
/* Place Top image over this image at PosX,PosY
* Lowest means final image is opaque
* else transparency will be multiplied
*/
void XImage::Compose(INTN PosX, INTN PosY, const XImage& TopImage, bool Lowest)
{
UINT32 TopAlpha;
UINT32 RevAlpha;
UINT32 FinalAlpha;
UINT32 Temp;
for (UINTN y = PosY; y < Height && (y - PosY) < TopImage.GetHeight(); ++y) {
// EFI_GRAPHICS_OUTPUT_BLT_PIXEL& CompPtr = *GetPixelPtr(PosX, y); // I assign a ref to avoid the operator ->. Compiler will produce the same anyway.
EFI_GRAPHICS_OUTPUT_BLT_PIXEL* CompPtr = GetPixelPtr(PosX, y);
for (UINTN x = PosX; x < Width && (x - PosX) < TopImage.GetWidth(); ++x) {
TopAlpha = TopImage.GetPixel(x-PosX, y-PosY).Reserved;
RevAlpha = 255 - TopAlpha;
FinalAlpha = (255*255 - RevAlpha*(255 - CompPtr->Reserved)) / 255;
//final alpha =(1-(1-x)*(1-y)) =(255*255-(255-topA)*(255-compA))/255
Temp = (CompPtr->Blue * RevAlpha) + (TopImage.GetPixel(x-PosX, y-PosY).Blue * TopAlpha);
CompPtr->Blue = (UINT8)(Temp / 255);
Temp = (CompPtr->Green * RevAlpha) + (TopImage.GetPixel(x-PosX, y-PosY).Green * TopAlpha);
CompPtr->Green = (UINT8)(Temp / 255);
Temp = (CompPtr->Red * RevAlpha) + (TopImage.GetPixel(x-PosX, y-PosY).Red * TopAlpha);
CompPtr->Red = (UINT8)(Temp / 255);
if (Lowest) {
CompPtr->Reserved = 255;
} else {
CompPtr->Reserved = (UINT8)FinalAlpha;
}
CompPtr++; //faster way to move to next pixel
}
}
}
void XImage::FlipRB(bool WantAlpha)
{
UINTN ImageSize = (Width * Height);
EFI_GRAPHICS_OUTPUT_BLT_PIXEL* Pixel = GetPixelPtr(0,0);
for (UINTN i = 0; i < ImageSize; ++i) {
UINT8 Temp = Pixel->Blue;
Pixel->Blue = Pixel->Red;
Pixel->Red = Temp;
if (!WantAlpha) Pixel->Reserved = 0xFF;
Pixel++;
}
}
/*
* The function converted plain array into XImage object
*/
unsigned XImage::FromPNG(const UINT8 * Data, UINTN Length)
{
UINT8 * PixelPtr = (UINT8 *)&PixelData[0];
unsigned Error = eglodepng_decode(&PixelPtr, &Width, &Height, Data, Length);
FlipRB(true);
return Error;
}
/*
* The function creates new array Data and inform about it size to be saved
* as a file.
* The caller is responsible to free the array.
*/
unsigned XImage::ToPNG(UINT8** Data, UINTN& OutSize)
{
size_t FileDataLength = 0;
FlipRB(false);
UINT8 * PixelPtr = (UINT8 *)&PixelData[0];
unsigned Error = eglodepng_encode(Data, &FileDataLength, PixelPtr, Width, Height);
OutSize = FileDataLength;
return Error;
}
/*
* fill XImage object by raster data described in SVG
* caller should create the object with Width and Height and calculate scale
* scale = 1 correspond to fill the rect with the image
* scale = 0.5 will reduce image
*/
unsigned XImage::FromSVG(const CHAR8 *SVGData, UINTN FileDataLength, float scale)
{
NSVGimage *SVGimage;
NSVGparser* p;
NSVGrasterizer* rast = nsvgCreateRasterizer();
if (!rast) return 1;
char *input = (__typeof__(input))AllocateCopyPool(AsciiStrSize(SVGData), SVGData);
if (!input) return 2;
p = nsvgParse(input, 72, 1.f); //the parse will change input contents
SVGimage = p->image;
if (SVGimage) {
float ScaleX = Width / SVGimage->width;
float ScaleY = Height / SVGimage->height;
float Scale = (ScaleX > ScaleY) ? ScaleY : ScaleX;
Scale *= scale;
DBG("Test image width=%d heigth=%d\n", (int)(SVGimage->width), (int)(SVGimage->height));
nsvgRasterize(rast, SVGimage, 0.f, 0.f, Scale, Scale, (UINT8*)&PixelData[0], (int)Width, (int)Height, (int)Width * sizeof(PixelData[0]));
FreePool(SVGimage);
}
nsvg__deleteParser(p);
nsvgDeleteRasterizer(rast);
FreePool(input);
return 0;
}
// Screen operations
/*
* The function to get image from screen. Used in screenshot (full screen), Pointer (small area) and Draw (small area)
* XImage must be created with Width, Height of Rect
* the rect will be clipped if it intersects the screen edge
*
* be careful about alpha. This procedure can produce alpha = 0 which means full transparent
*/
void XImage::GetArea(const EG_RECT& Rect)
{
GetArea(Rect.XPos, Rect.YPos, Rect.Width, Rect.Height);
}
void XImage::GetArea(INTN x, INTN y, UINTN W, UINTN H)
{
EFI_STATUS Status;
EFI_GUID UgaDrawProtocolGuid = EFI_UGA_DRAW_PROTOCOL_GUID;
EFI_UGA_DRAW_PROTOCOL *UgaDraw = NULL;
EFI_GUID GraphicsOutputProtocolGuid = EFI_GRAPHICS_OUTPUT_PROTOCOL_GUID;
EFI_GRAPHICS_OUTPUT_PROTOCOL *GraphicsOutput = NULL;
Status = EfiLibLocateProtocol(&GraphicsOutputProtocolGuid, (VOID **)&GraphicsOutput);
if (EFI_ERROR(Status)) {
GraphicsOutput = NULL;
Status = EfiLibLocateProtocol(&UgaDrawProtocolGuid, (VOID **)&UgaDraw);
if (EFI_ERROR(Status))
UgaDraw = NULL;
}
if (W == 0) W = Width;
if (H == 0) H = Height;
Width = (x + W > (UINTN)UGAWidth) ? (UGAWidth - x) : W;
Height = (y + H > (UINTN)UGAHeight) ? ((UINTN)UGAHeight - y) : H;
// DBG("x=%d y=%d W=%d h=%d Width=%d Height=%d\n", x,y,W,H,Width,Height);
// INTN LineBytes = Width * sizeof(EFI_GRAPHICS_OUTPUT_BLT_PIXEL);
PixelData.SetLength(Width * Height); // setLength BEFORE, so &PixelData[0]
if (GraphicsOutput != NULL) {
GraphicsOutput->Blt(GraphicsOutput,
(EFI_GRAPHICS_OUTPUT_BLT_PIXEL *)&PixelData[0],
EfiBltVideoToBltBuffer,
x, y, 0, 0, Width, Height, 0);
}
else if (UgaDraw != NULL) {
UgaDraw->Blt(UgaDraw,
(EFI_UGA_PIXEL *)GetPixelPtr(0,0),
EfiUgaVideoToBltBuffer,
x, y, 0, 0, Width, Height, 0);
}
}
void XImage::Draw(INTN x, INTN y, float scale)
{
//prepare images
DBG("1\n");
XImage Top(*this, scale);
DBG("2\n");
XImage Background(Width, Height);
DBG("3\n");
Background.GetArea(x, y, Width, Height);
DBG("4\n");
Background.Compose(0, 0, Top, true);
DBG("5\n");
UINTN AreaWidth = (x + Width > (UINTN)UGAWidth) ? (UGAWidth - x) : Width;
UINTN AreaHeight = (y + Height > (UINTN)UGAHeight) ? (UGAHeight - y) : Height;
DBG("area=%d,%d\n", AreaWidth, AreaHeight);
// prepare protocols
EFI_STATUS Status;
EFI_GUID UgaDrawProtocolGuid = EFI_UGA_DRAW_PROTOCOL_GUID;
EFI_UGA_DRAW_PROTOCOL *UgaDraw = NULL;
EFI_GUID GraphicsOutputProtocolGuid = EFI_GRAPHICS_OUTPUT_PROTOCOL_GUID;
EFI_GRAPHICS_OUTPUT_PROTOCOL *GraphicsOutput = NULL;
Status = EfiLibLocateProtocol(&GraphicsOutputProtocolGuid, (VOID **)&GraphicsOutput);
if (EFI_ERROR(Status)) {
GraphicsOutput = NULL;
Status = EfiLibLocateProtocol(&UgaDrawProtocolGuid, (VOID **)&UgaDraw);
if (EFI_ERROR(Status))
UgaDraw = NULL;
}
//output combined image
if (GraphicsOutput != NULL) {
GraphicsOutput->Blt(GraphicsOutput, (EFI_GRAPHICS_OUTPUT_BLT_PIXEL *)Background.GetPixelPtr(0, 0),
EfiBltBufferToVideo,
0, 0, x, y, AreaWidth, AreaHeight, 0);
//Background.GetWidth() * sizeof(EFI_GRAPHICS_OUTPUT_BLT_PIXEL));
}
else if (UgaDraw != NULL) {
UgaDraw->Blt(UgaDraw, (EFI_UGA_PIXEL *)Background.GetPixelPtr(0, 0), EfiUgaBltBufferToVideo,
0, 0, x, y, AreaWidth, AreaHeight, 0);
// Background.GetWidth() * sizeof(EFI_UGA_PIXEL));
}
}