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|
// ==========================================================
// Bitmap rotation by means of 3 shears.
//
// Design and implementation by
// - Hervé Drolon (drolon@infonie.fr)
// - Thorsten Radde (support@IdealSoftware.com)
// - Mihail Naydenov (mnaydenov@users.sourceforge.net)
//
// This file is part of FreeImage 3
//
// COVERED CODE IS PROVIDED UNDER THIS LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTY
// OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION, WARRANTIES
// THAT THE COVERED CODE IS FREE OF DEFECTS, MERCHANTABLE, FIT FOR A PARTICULAR PURPOSE
// OR NON-INFRINGING. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE COVERED
// CODE IS WITH YOU. SHOULD ANY COVERED CODE PROVE DEFECTIVE IN ANY RESPECT, YOU (NOT
// THE INITIAL DEVELOPER OR ANY OTHER CONTRIBUTOR) ASSUME THE COST OF ANY NECESSARY
// SERVICING, REPAIR OR CORRECTION. THIS DISCLAIMER OF WARRANTY CONSTITUTES AN ESSENTIAL
// PART OF THIS LICENSE. NO USE OF ANY COVERED CODE IS AUTHORIZED HEREUNDER EXCEPT UNDER
// THIS DISCLAIMER.
//
// Use at your own risk!
// ==========================================================
/*
============================================================
References :
[1] Paeth A., A Fast Algorithm for General Raster Rotation.
Graphics Gems, p. 179, Andrew Glassner editor, Academic Press, 1990.
[2] Yariv E., High quality image rotation (rotate by shear).
[Online] http://www.codeproject.com/bitmap/rotatebyshear.asp
[3] Treskunov A., Fast and high quality true-color bitmap rotation function.
[Online] http://anton.treskunov.net/Software/doc/fast_and_high_quality_true_color_bitmap_rotation_function.html
============================================================
*/
#include "../stdafx.h"
#define RBLOCK 64 // image blocks of RBLOCK*RBLOCK pixels
// --------------------------------------------------------------------------
/**
Skews a row horizontally (with filtered weights).
Limited to 45 degree skewing only. Filters two adjacent pixels.
Parameter T can be BYTE, WORD of float.
@param src Pointer to source image to rotate
@param dst Pointer to destination image
@param row Row index
@param iOffset Skew offset
@param dWeight Relative weight of right pixel
@param bkcolor Background color
*/
template <class T> void
HorizontalSkewT(FIBITMAP *src, FIBITMAP *dst, int row, int iOffset, double weight, const void *bkcolor = NULL) {
int iXPos;
const unsigned src_width = FreeImage_GetWidth(src);
const unsigned dst_width = FreeImage_GetWidth(dst);
T pxlSrc[4], pxlLeft[4], pxlOldLeft[4]; // 4 = 4*sizeof(T) max
// background
const T pxlBlack[4] = {0, 0, 0, 0 };
const T *pxlBkg = static_cast<const T*>(bkcolor); // assume at least bytespp and 4*sizeof(T) max
if(!pxlBkg) {
// default background color is black
pxlBkg = pxlBlack;
}
// calculate the number of bytes per pixel
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
// calculate the number of samples per pixel
const unsigned samples = bytespp / sizeof(T);
BYTE *src_bits = FreeImage_GetScanLine(src, row);
BYTE *dst_bits = FreeImage_GetScanLine(dst, row);
// fill gap left of skew with background
if(bkcolor) {
for(int k = 0; k < iOffset; k++) {
memcpy(&dst_bits[k * bytespp], bkcolor, bytespp);
}
AssignPixel((BYTE*)&pxlOldLeft[0], (BYTE*)bkcolor, bytespp);
} else {
if(iOffset > 0) {
memset(dst_bits, 0, iOffset * bytespp);
}
memset(&pxlOldLeft[0], 0, bytespp);
}
for(unsigned i = 0; i < src_width; i++) {
// loop through row pixels
AssignPixel((BYTE*)&pxlSrc[0], (BYTE*)src_bits, bytespp);
// calculate weights
for(unsigned j = 0; j < samples; j++) {
pxlLeft[j] = static_cast<T>(pxlBkg[j] + (pxlSrc[j] - pxlBkg[j]) * weight + 0.5);
}
// check boundaries
iXPos = i + iOffset;
if((iXPos >= 0) && (iXPos < (int)dst_width)) {
// update left over on source
for(unsigned j = 0; j < samples; j++) {
pxlSrc[j] = pxlSrc[j] - (pxlLeft[j] - pxlOldLeft[j]);
}
AssignPixel((BYTE*)&dst_bits[iXPos*bytespp], (BYTE*)&pxlSrc[0], bytespp);
}
// save leftover for next pixel in scan
AssignPixel((BYTE*)&pxlOldLeft[0], (BYTE*)&pxlLeft[0], bytespp);
// next pixel in scan
src_bits += bytespp;
}
// go to rightmost point of skew
iXPos = src_width + iOffset;
if((iXPos >= 0) && (iXPos < (int)dst_width)) {
dst_bits = FreeImage_GetScanLine(dst, row) + iXPos * bytespp;
// If still in image bounds, put leftovers there
AssignPixel((BYTE*)dst_bits, (BYTE*)&pxlOldLeft[0], bytespp);
// clear to the right of the skewed line with background
dst_bits += bytespp;
if(bkcolor) {
for(unsigned i = 0; i < dst_width - iXPos - 1; i++) {
memcpy(&dst_bits[i * bytespp], bkcolor, bytespp);
}
} else {
memset(dst_bits, 0, bytespp * (dst_width - iXPos - 1));
}
}
}
/**
Skews a row horizontally (with filtered weights).
Limited to 45 degree skewing only. Filters two adjacent pixels.
@param src Pointer to source image to rotate
@param dst Pointer to destination image
@param row Row index
@param iOffset Skew offset
@param dWeight Relative weight of right pixel
@param bkcolor Background color
*/
static void
HorizontalSkew(FIBITMAP *src, FIBITMAP *dst, int row, int iOffset, double dWeight, const void *bkcolor) {
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
switch(image_type) {
case FIT_BITMAP:
switch(FreeImage_GetBPP(src)) {
case 8:
case 24:
case 32:
HorizontalSkewT<BYTE>(src, dst, row, iOffset, dWeight, bkcolor);
break;
}
break;
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
HorizontalSkewT<WORD>(src, dst, row, iOffset, dWeight, bkcolor);
break;
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
HorizontalSkewT<float>(src, dst, row, iOffset, dWeight, bkcolor);
break;
}
}
/**
Skews a column vertically (with filtered weights).
Limited to 45 degree skewing only. Filters two adjacent pixels.
Parameter T can be BYTE, WORD of float.
@param src Pointer to source image to rotate
@param dst Pointer to destination image
@param col Column index
@param iOffset Skew offset
@param dWeight Relative weight of upper pixel
@param bkcolor Background color
*/
template <class T> void
VerticalSkewT(FIBITMAP *src, FIBITMAP *dst, int col, int iOffset, double weight, const void *bkcolor = NULL) {
int iYPos;
unsigned src_height = FreeImage_GetHeight(src);
unsigned dst_height = FreeImage_GetHeight(dst);
T pxlSrc[4], pxlLeft[4], pxlOldLeft[4]; // 4 = 4*sizeof(T) max
// background
const T pxlBlack[4] = {0, 0, 0, 0 };
const T *pxlBkg = static_cast<const T*>(bkcolor); // assume at least bytespp and 4*sizeof(T) max
if(!pxlBkg) {
// default background color is black
pxlBkg = pxlBlack;
}
// calculate the number of bytes per pixel
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
// calculate the number of samples per pixel
const unsigned samples = bytespp / sizeof(T);
const unsigned src_pitch = FreeImage_GetPitch(src);
const unsigned dst_pitch = FreeImage_GetPitch(dst);
const unsigned index = col * bytespp;
BYTE *src_bits = FreeImage_GetBits(src) + index;
BYTE *dst_bits = FreeImage_GetBits(dst) + index;
// fill gap above skew with background
if(bkcolor) {
for(int k = 0; k < iOffset; k++) {
memcpy(dst_bits, bkcolor, bytespp);
dst_bits += dst_pitch;
}
memcpy(&pxlOldLeft[0], bkcolor, bytespp);
} else {
for(int k = 0; k < iOffset; k++) {
memset(dst_bits, 0, bytespp);
dst_bits += dst_pitch;
}
memset(&pxlOldLeft[0], 0, bytespp);
}
for(unsigned i = 0; i < src_height; i++) {
// loop through column pixels
AssignPixel((BYTE*)(&pxlSrc[0]), src_bits, bytespp);
// calculate weights
for(unsigned j = 0; j < samples; j++) {
pxlLeft[j] = static_cast<T>(pxlBkg[j] + (pxlSrc[j] - pxlBkg[j]) * weight + 0.5);
}
// check boundaries
iYPos = i + iOffset;
if((iYPos >= 0) && (iYPos < (int)dst_height)) {
// update left over on source
for(unsigned j = 0; j < samples; j++) {
pxlSrc[j] = pxlSrc[j] - (pxlLeft[j] - pxlOldLeft[j]);
}
dst_bits = FreeImage_GetScanLine(dst, iYPos) + index;
AssignPixel(dst_bits, (BYTE*)(&pxlSrc[0]), bytespp);
}
// save leftover for next pixel in scan
AssignPixel((BYTE*)(&pxlOldLeft[0]), (BYTE*)(&pxlLeft[0]), bytespp);
// next pixel in scan
src_bits += src_pitch;
}
// go to bottom point of skew
iYPos = src_height + iOffset;
if((iYPos >= 0) && (iYPos < (int)dst_height)) {
dst_bits = FreeImage_GetScanLine(dst, iYPos) + index;
// if still in image bounds, put leftovers there
AssignPixel((BYTE*)(dst_bits), (BYTE*)(&pxlOldLeft[0]), bytespp);
// clear below skewed line with background
if(bkcolor) {
while(++iYPos < (int)dst_height) {
dst_bits += dst_pitch;
AssignPixel((BYTE*)(dst_bits), (BYTE*)(bkcolor), bytespp);
}
} else {
while(++iYPos < (int)dst_height) {
dst_bits += dst_pitch;
memset(dst_bits, 0, bytespp);
}
}
}
}
/**
Skews a column vertically (with filtered weights).
Limited to 45 degree skewing only. Filters two adjacent pixels.
@param src Pointer to source image to rotate
@param dst Pointer to destination image
@param col Column index
@param iOffset Skew offset
@param dWeight Relative weight of upper pixel
@param bkcolor Background color
*/
static void
VerticalSkew(FIBITMAP *src, FIBITMAP *dst, int col, int iOffset, double dWeight, const void *bkcolor) {
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
switch(image_type) {
case FIT_BITMAP:
switch(FreeImage_GetBPP(src)) {
case 8:
case 24:
case 32:
VerticalSkewT<BYTE>(src, dst, col, iOffset, dWeight, bkcolor);
break;
}
break;
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
VerticalSkewT<WORD>(src, dst, col, iOffset, dWeight, bkcolor);
break;
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
VerticalSkewT<float>(src, dst, col, iOffset, dWeight, bkcolor);
break;
}
}
/**
Rotates an image by 90 degrees (counter clockwise).
Precise rotation, no filters required.<br>
Code adapted from CxImage (http://www.xdp.it/cximage.htm)
@param src Pointer to source image to rotate
@return Returns a pointer to a newly allocated rotated image if successful, returns NULL otherwise
*/
static FIBITMAP*
Rotate90(FIBITMAP *src) {
const unsigned bpp = FreeImage_GetBPP(src);
const unsigned src_width = FreeImage_GetWidth(src);
const unsigned src_height = FreeImage_GetHeight(src);
const unsigned dst_width = src_height;
const unsigned dst_height = src_width;
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
// allocate and clear dst image
FIBITMAP *dst = FreeImage_AllocateT(image_type, dst_width, dst_height, bpp);
if(NULL == dst) return NULL;
// get src and dst scan width
const unsigned src_pitch = FreeImage_GetPitch(src);
const unsigned dst_pitch = FreeImage_GetPitch(dst);
switch(image_type) {
case FIT_BITMAP:
if(bpp == 1) {
// speedy rotate for BW images
BYTE *bsrc = FreeImage_GetBits(src);
BYTE *bdest = FreeImage_GetBits(dst);
BYTE *dbitsmax = bdest + dst_height * dst_pitch - 1;
for(unsigned y = 0; y < src_height; y++) {
// figure out the column we are going to be copying to
const div_t div_r = div(y, 8);
// set bit pos of src column byte
const BYTE bitpos = (BYTE)(128 >> div_r.rem);
BYTE *srcdisp = bsrc + y * src_pitch;
for(unsigned x = 0; x < src_pitch; x++) {
// get source bits
BYTE *sbits = srcdisp + x;
// get destination column
BYTE *nrow = bdest + (dst_height - 1 - (x * 8)) * dst_pitch + div_r.quot;
for (int z = 0; z < 8; z++) {
// get destination byte
BYTE *dbits = nrow - z * dst_pitch;
if ((dbits < bdest) || (dbits > dbitsmax)) break;
if (*sbits & (128 >> z)) *dbits |= bitpos;
}
}
}
}
else if((bpp == 8) || (bpp == 24) || (bpp == 32)) {
// anything other than BW :
// This optimized version of rotation rotates image by smaller blocks. It is quite
// a bit faster than obvious algorithm, because it produces much less CPU cache misses.
// This optimization can be tuned by changing block size (RBLOCK). 96 is good value for current
// CPUs (tested on Athlon XP and Celeron D). Larger value (if CPU has enough cache) will increase
// speed somehow, but once you drop out of CPU's cache, things will slow down drastically.
// For older CPUs with less cache, lower value would yield better results.
BYTE *bsrc = FreeImage_GetBits(src); // source pixels
BYTE *bdest = FreeImage_GetBits(dst); // destination pixels
// calculate the number of bytes per pixel (1 for 8-bit, 3 for 24-bit or 4 for 32-bit)
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
// for all image blocks of RBLOCK*RBLOCK pixels
// x-segment
for(unsigned xs = 0; xs < dst_width; xs += RBLOCK) {
// y-segment
for(unsigned ys = 0; ys < dst_height; ys += RBLOCK) {
for(unsigned y = ys; y < MIN(dst_height, ys + RBLOCK); y++) { // do rotation
const unsigned y2 = dst_height - y - 1;
// point to src pixel at (y2, xs)
BYTE *src_bits = bsrc + (xs * src_pitch) + (y2 * bytespp);
// point to dst pixel at (xs, y)
BYTE *dst_bits = bdest + (y * dst_pitch) + (xs * bytespp);
for(unsigned x = xs; x < MIN(dst_width, xs + RBLOCK); x++) {
// dst.SetPixel(x, y, src.GetPixel(y2, x));
AssignPixel(dst_bits, src_bits, bytespp);
dst_bits += bytespp;
src_bits += src_pitch;
}
}
}
}
}
break;
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
{
BYTE *bsrc = FreeImage_GetBits(src); // source pixels
BYTE *bdest = FreeImage_GetBits(dst); // destination pixels
// calculate the number of bytes per pixel
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
for(unsigned y = 0; y < dst_height; y++) {
BYTE *src_bits = bsrc + (src_width - 1 - y) * bytespp;
BYTE *dst_bits = bdest + (y * dst_pitch);
for(unsigned x = 0; x < dst_width; x++) {
AssignPixel(dst_bits, src_bits, bytespp);
src_bits += src_pitch;
dst_bits += bytespp;
}
}
}
break;
}
return dst;
}
/**
Rotates an image by 180 degrees (counter clockwise).
Precise rotation, no filters required.
@param src Pointer to source image to rotate
@return Returns a pointer to a newly allocated rotated image if successful, returns NULL otherwise
*/
static FIBITMAP*
Rotate180(FIBITMAP *src) {
int x, y, k, pos;
const int bpp = FreeImage_GetBPP(src);
const int src_width = FreeImage_GetWidth(src);
const int src_height = FreeImage_GetHeight(src);
const int dst_width = src_width;
const int dst_height = src_height;
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
FIBITMAP *dst = FreeImage_AllocateT(image_type, dst_width, dst_height, bpp);
if(NULL == dst) return NULL;
switch(image_type) {
case FIT_BITMAP:
if(bpp == 1) {
for(int y = 0; y < src_height; y++) {
BYTE *src_bits = FreeImage_GetScanLine(src, y);
BYTE *dst_bits = FreeImage_GetScanLine(dst, dst_height - y - 1);
for(int x = 0; x < src_width; x++) {
// get bit at (x, y)
k = (src_bits[x >> 3] & (0x80 >> (x & 0x07))) != 0;
// set bit at (dst_width - x - 1, dst_height - y - 1)
pos = dst_width - x - 1;
k ? dst_bits[pos >> 3] |= (0x80 >> (pos & 0x7)) : dst_bits[pos >> 3] &= (0xFF7F >> (pos & 0x7));
}
}
break;
}
// else if((bpp == 8) || (bpp == 24) || (bpp == 32)) FALL TROUGH
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
{
// Calculate the number of bytes per pixel
const int bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
for(y = 0; y < src_height; y++) {
BYTE *src_bits = FreeImage_GetScanLine(src, y);
BYTE *dst_bits = FreeImage_GetScanLine(dst, dst_height - y - 1) + (dst_width - 1) * bytespp;
for(x = 0; x < src_width; x++) {
// get pixel at (x, y)
// set pixel at (dst_width - x - 1, dst_height - y - 1)
AssignPixel(dst_bits, src_bits, bytespp);
src_bits += bytespp;
dst_bits -= bytespp;
}
}
}
break;
}
return dst;
}
/**
Rotates an image by 270 degrees (counter clockwise).
Precise rotation, no filters required.<br>
Code adapted from CxImage (http://www.xdp.it/cximage.htm)
@param src Pointer to source image to rotate
@return Returns a pointer to a newly allocated rotated image if successful, returns NULL otherwise
*/
static FIBITMAP*
Rotate270(FIBITMAP *src) {
int x2, dlineup;
const unsigned bpp = FreeImage_GetBPP(src);
const unsigned src_width = FreeImage_GetWidth(src);
const unsigned src_height = FreeImage_GetHeight(src);
const unsigned dst_width = src_height;
const unsigned dst_height = src_width;
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
// allocate and clear dst image
FIBITMAP *dst = FreeImage_AllocateT(image_type, dst_width, dst_height, bpp);
if(NULL == dst) return NULL;
// get src and dst scan width
const unsigned src_pitch = FreeImage_GetPitch(src);
const unsigned dst_pitch = FreeImage_GetPitch(dst);
switch(image_type) {
case FIT_BITMAP:
if(bpp == 1) {
// speedy rotate for BW images
BYTE *bsrc = FreeImage_GetBits(src);
BYTE *bdest = FreeImage_GetBits(dst);
BYTE *dbitsmax = bdest + dst_height * dst_pitch - 1;
dlineup = 8 * dst_pitch - dst_width;
for(unsigned y = 0; y < src_height; y++) {
// figure out the column we are going to be copying to
const div_t div_r = div(y + dlineup, 8);
// set bit pos of src column byte
const BYTE bitpos = (BYTE)(1 << div_r.rem);
const BYTE *srcdisp = bsrc + y * src_pitch;
for(unsigned x = 0; x < src_pitch; x++) {
// get source bits
const BYTE *sbits = srcdisp + x;
// get destination column
BYTE *nrow = bdest + (x * 8) * dst_pitch + dst_pitch - 1 - div_r.quot;
for(unsigned z = 0; z < 8; z++) {
// get destination byte
BYTE *dbits = nrow + z * dst_pitch;
if ((dbits < bdest) || (dbits > dbitsmax)) break;
if (*sbits & (128 >> z)) *dbits |= bitpos;
}
}
}
}
else if((bpp == 8) || (bpp == 24) || (bpp == 32)) {
// anything other than BW :
// This optimized version of rotation rotates image by smaller blocks. It is quite
// a bit faster than obvious algorithm, because it produces much less CPU cache misses.
// This optimization can be tuned by changing block size (RBLOCK). 96 is good value for current
// CPUs (tested on Athlon XP and Celeron D). Larger value (if CPU has enough cache) will increase
// speed somehow, but once you drop out of CPU's cache, things will slow down drastically.
// For older CPUs with less cache, lower value would yield better results.
BYTE *bsrc = FreeImage_GetBits(src); // source pixels
BYTE *bdest = FreeImage_GetBits(dst); // destination pixels
// Calculate the number of bytes per pixel (1 for 8-bit, 3 for 24-bit or 4 for 32-bit)
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
// for all image blocks of RBLOCK*RBLOCK pixels
// x-segment
for(unsigned xs = 0; xs < dst_width; xs += RBLOCK) {
// y-segment
for(unsigned ys = 0; ys < dst_height; ys += RBLOCK) {
for(unsigned x = xs; x < MIN(dst_width, xs + RBLOCK); x++) { // do rotation
x2 = dst_width - x - 1;
// point to src pixel at (ys, x2)
BYTE *src_bits = bsrc + (x2 * src_pitch) + (ys * bytespp);
// point to dst pixel at (x, ys)
BYTE *dst_bits = bdest + (ys * dst_pitch) + (x * bytespp);
for(unsigned y = ys; y < MIN(dst_height, ys + RBLOCK); y++) {
// dst.SetPixel(x, y, src.GetPixel(y, x2));
AssignPixel(dst_bits, src_bits, bytespp);
src_bits += bytespp;
dst_bits += dst_pitch;
}
}
}
}
}
break;
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
{
BYTE *bsrc = FreeImage_GetBits(src); // source pixels
BYTE *bdest = FreeImage_GetBits(dst); // destination pixels
// calculate the number of bytes per pixel
const unsigned bytespp = FreeImage_GetLine(src) / FreeImage_GetWidth(src);
for(unsigned y = 0; y < dst_height; y++) {
BYTE *src_bits = bsrc + (src_height - 1) * src_pitch + y * bytespp;
BYTE *dst_bits = bdest + (y * dst_pitch);
for(unsigned x = 0; x < dst_width; x++) {
AssignPixel(dst_bits, src_bits, bytespp);
src_bits -= src_pitch;
dst_bits += bytespp;
}
}
}
break;
}
return dst;
}
/**
Rotates an image by a given degree in range [-45 .. +45] (counter clockwise)
using the 3-shear technique.
@param src Pointer to source image to rotate
@param dAngle Rotation angle
@return Returns a pointer to a newly allocated rotated image if successful, returns NULL otherwise
*/
static FIBITMAP*
Rotate45(FIBITMAP *src, double dAngle, const void *bkcolor) {
const double ROTATE_PI = double(3.1415926535897932384626433832795);
unsigned u;
const unsigned bpp = FreeImage_GetBPP(src);
const double dRadAngle = dAngle * ROTATE_PI / double(180); // Angle in radians
const double dSinE = sin(dRadAngle);
const double dTan = tan(dRadAngle / 2);
const unsigned src_width = FreeImage_GetWidth(src);
const unsigned src_height = FreeImage_GetHeight(src);
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(src);
// Calc first shear (horizontal) destination image dimensions
const unsigned width_1 = src_width + unsigned((double)src_height * fabs(dTan) + 0.5);
const unsigned height_1 = src_height;
// Perform 1st shear (horizontal)
// ----------------------------------------------------------------------
// Allocate image for 1st shear
FIBITMAP *dst1 = FreeImage_AllocateT(image_type, width_1, height_1, bpp);
if(NULL == dst1) {
return NULL;
}
for(u = 0; u < height_1; u++) {
double dShear;
if(dTan >= 0) {
// Positive angle
dShear = (u + 0.5) * dTan;
}
else {
// Negative angle
dShear = (double(u) - height_1 + 0.5) * dTan;
}
int iShear = int(floor(dShear));
HorizontalSkew(src, dst1, u, iShear, dShear - double(iShear), bkcolor);
}
// Perform 2nd shear (vertical)
// ----------------------------------------------------------------------
// Calc 2nd shear (vertical) destination image dimensions
const unsigned width_2 = width_1;
unsigned height_2 = unsigned((double)src_width * fabs(dSinE) + (double)src_height * cos(dRadAngle) + 0.5) + 1;
// Allocate image for 2nd shear
FIBITMAP *dst2 = FreeImage_AllocateT(image_type, width_2, height_2, bpp);
if(NULL == dst2) {
FreeImage_Unload(dst1);
return NULL;
}
double dOffset; // Variable skew offset
if(dSinE > 0) {
// Positive angle
dOffset = (src_width - 1.0) * dSinE;
}
else {
// Negative angle
dOffset = -dSinE * (double(src_width) - width_2);
}
for(u = 0; u < width_2; u++, dOffset -= dSinE) {
int iShear = int(floor(dOffset));
VerticalSkew(dst1, dst2, u, iShear, dOffset - double(iShear), bkcolor);
}
// Perform 3rd shear (horizontal)
// ----------------------------------------------------------------------
// Free result of 1st shear
FreeImage_Unload(dst1);
// Calc 3rd shear (horizontal) destination image dimensions
const unsigned width_3 = unsigned(double(src_height) * fabs(dSinE) + double(src_width) * cos(dRadAngle) + 0.5) + 1;
const unsigned height_3 = height_2;
// Allocate image for 3rd shear
FIBITMAP *dst3 = FreeImage_AllocateT(image_type, width_3, height_3, bpp);
if(NULL == dst3) {
FreeImage_Unload(dst2);
return NULL;
}
if(dSinE >= 0) {
// Positive angle
dOffset = (src_width - 1.0) * dSinE * -dTan;
}
else {
// Negative angle
dOffset = dTan * ( (src_width - 1.0) * -dSinE + (1.0 - height_3) );
}
for(u = 0; u < height_3; u++, dOffset += dTan) {
int iShear = int(floor(dOffset));
HorizontalSkew(dst2, dst3, u, iShear, dOffset - double(iShear), bkcolor);
}
// Free result of 2nd shear
FreeImage_Unload(dst2);
// Return result of 3rd shear
return dst3;
}
/**
Rotates a 1-, 8-, 24- or 32-bit image by a given angle (given in degree).
Angle is unlimited, except for 1-bit images (limited to integer multiples of 90 degree).
3-shears technique is used.
@param src Pointer to source image to rotate
@param dAngle Rotation angle
@return Returns a pointer to a newly allocated rotated image if successful, returns NULL otherwise
*/
static FIBITMAP*
RotateAny(FIBITMAP *src, double dAngle, const void *bkcolor) {
if(NULL == src) {
return NULL;
}
FIBITMAP *image = src;
while(dAngle >= 360) {
// Bring angle to range of (-INF .. 360)
dAngle -= 360;
}
while(dAngle < 0) {
// Bring angle to range of [0 .. 360)
dAngle += 360;
}
if((dAngle > 45) && (dAngle <= 135)) {
// Angle in (45 .. 135]
// Rotate image by 90 degrees into temporary image,
// so it requires only an extra rotation angle
// of -45 .. +45 to complete rotation.
image = Rotate90(src);
dAngle -= 90;
}
else if((dAngle > 135) && (dAngle <= 225)) {
// Angle in (135 .. 225]
// Rotate image by 180 degrees into temporary image,
// so it requires only an extra rotation angle
// of -45 .. +45 to complete rotation.
image = Rotate180(src);
dAngle -= 180;
}
else if((dAngle > 225) && (dAngle <= 315)) {
// Angle in (225 .. 315]
// Rotate image by 270 degrees into temporary image,
// so it requires only an extra rotation angle
// of -45 .. +45 to complete rotation.
image = Rotate270(src);
dAngle -= 270;
}
// If we got here, angle is in (-45 .. +45]
if(NULL == image) {
// Failed to allocate middle image
return NULL;
}
if(0 == dAngle) {
if(image == src) {
// Nothing to do ...
return FreeImage_Clone(src);
} else {
// No more rotation needed
return image;
}
}
else {
// Perform last rotation
FIBITMAP *dst = Rotate45(image, dAngle, bkcolor);
if(src != image) {
// Middle image was required, free it now.
FreeImage_Unload(image);
}
return dst;
}
}
// ==========================================================
FIBITMAP *DLL_CALLCONV
FreeImage_Rotate(FIBITMAP *dib, double angle, const void *bkcolor) {
if(!FreeImage_HasPixels(dib)) return NULL;
if(0 == angle) {
return FreeImage_Clone(dib);
}
// DIB are stored upside down ...
angle *= -1;
try {
unsigned bpp = FreeImage_GetBPP(dib);
FREE_IMAGE_TYPE image_type = FreeImage_GetImageType(dib);
switch(image_type) {
case FIT_BITMAP:
if(bpp == 1) {
// only rotate for integer multiples of 90 degree
if(fmod(angle, 90) != 0)
return NULL;
// perform the rotation
FIBITMAP *dst = RotateAny(dib, angle, bkcolor);
if(!dst) throw(1);
// build a greyscale palette
RGBQUAD *dst_pal = FreeImage_GetPalette(dst);
if(FreeImage_GetColorType(dib) == FIC_MINISBLACK) {
dst_pal[0].rgbRed = dst_pal[0].rgbGreen = dst_pal[0].rgbBlue = 0;
dst_pal[1].rgbRed = dst_pal[1].rgbGreen = dst_pal[1].rgbBlue = 255;
} else {
dst_pal[0].rgbRed = dst_pal[0].rgbGreen = dst_pal[0].rgbBlue = 255;
dst_pal[1].rgbRed = dst_pal[1].rgbGreen = dst_pal[1].rgbBlue = 0;
}
// copy metadata from src to dst
FreeImage_CloneMetadata(dst, dib);
return dst;
}
else if((bpp == 8) || (bpp == 24) || (bpp == 32)) {
FIBITMAP *dst = RotateAny(dib, angle, bkcolor);
if(!dst) throw(1);
if(bpp == 8) {
// copy original palette to rotated bitmap
RGBQUAD *src_pal = FreeImage_GetPalette(dib);
RGBQUAD *dst_pal = FreeImage_GetPalette(dst);
memcpy(&dst_pal[0], &src_pal[0], 256 * sizeof(RGBQUAD));
// copy transparency table
FreeImage_SetTransparencyTable(dst, FreeImage_GetTransparencyTable(dib), FreeImage_GetTransparencyCount(dib));
// copy background color
RGBQUAD bkcolor;
if( FreeImage_GetBackgroundColor(dib, &bkcolor) ) {
FreeImage_SetBackgroundColor(dst, &bkcolor);
}
}
// copy metadata from src to dst
FreeImage_CloneMetadata(dst, dib);
return dst;
}
break;
case FIT_UINT16:
case FIT_RGB16:
case FIT_RGBA16:
case FIT_FLOAT:
case FIT_RGBF:
case FIT_RGBAF:
{
FIBITMAP *dst = RotateAny(dib, angle, bkcolor);
if(!dst) throw(1);
// copy metadata from src to dst
FreeImage_CloneMetadata(dst, dib);
return dst;
}
break;
}
} catch(int) {
return NULL;
}
return NULL;
}
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