static int
affinei_gen( REGION *or, void *seq, void *a, void *b )
{
REGION *ir = (REGION *) seq;
const IMAGE *in = (IMAGE *) a;
const Affine *affine = (Affine *) b;
const int window_offset =
vips_interpolate_get_window_offset( affine->interpolate );
const VipsInterpolateMethod interpolate =
vips_interpolate_get_method( affine->interpolate );
/* Area we generate in the output image.
*/
const Rect *r = &or->valid;
const int le = r->left;
const int ri = IM_RECT_RIGHT( r );
const int to = r->top;
const int bo = IM_RECT_BOTTOM( r );
const Rect *iarea = &affine->trn.iarea;
const Rect *oarea = &affine->trn.oarea;
int ps = IM_IMAGE_SIZEOF_PEL( in );
int x, y, z;
Rect image, want, need, clipped;
#ifdef DEBUG
printf( "affine: generating left=%d, top=%d, width=%d, height=%d\n",
r->left,
r->top,
r->width,
r->height );
#endif /*DEBUG*/
/* We are generating this chunk of the transformed image.
*/
want = *r;
want.left += oarea->left;
want.top += oarea->top;
/* Find the area of the input image we need.
*/
im__transform_invert_rect( &affine->trn, &want, &need );
/* Now go to space (2) above.
*/
need.left += iarea->left;
need.top += iarea->top;
/* Add a border for interpolation. Plus one for rounding errors.
*/
im_rect_marginadjust( &need, window_offset + 1 );
/* Clip against the size of (2).
*/
image.left = 0;
image.top = 0;
image.width = in->Xsize;
image.height = in->Ysize;
im_rect_intersectrect( &need, &image, &clipped );
/* Outside input image? All black.
*/
if( im_rect_isempty( &clipped ) ) {
im_region_black( or );
return( 0 );
}
/* We do need some pixels from the input image to make our output -
* ask for them.
*/
if( im_prepare( ir, &clipped ) )
return( -1 );
#ifdef DEBUG
printf( "affine: preparing left=%d, top=%d, width=%d, height=%d\n",
clipped.left,
clipped.top,
clipped.width,
clipped.height );
#endif /*DEBUG*/
/* Resample! x/y loop over pixels in the output image (5).
*/
for( y = to; y < bo; y++ ) {
/* Input clipping rectangle.
*/
const int ile = iarea->left;
const int ito = iarea->top;
const int iri = iarea->left + iarea->width;
const int ibo = iarea->top + iarea->height;
/* Derivative of matrix.
*/
const double ddx = affine->trn.ia;
const double ddy = affine->trn.ic;
/* Continuous cods in transformed space.
*/
const double ox = le + oarea->left - affine->trn.dx;
const double oy = y + oarea->top - affine->trn.dy;
/* Continuous cods in input space.
*/
double ix, iy;
PEL *q;
/* To (3).
*/
ix = affine->trn.ia * ox + affine->trn.ib * oy;
iy = affine->trn.ic * ox + affine->trn.id * oy;
/* Now move to (2).
*/
ix += iarea->left;
iy += iarea->top;
q = (PEL *) IM_REGION_ADDR( or, le, y );
for( x = le; x < ri; x++ ) {
int fx, fy;
fx = FLOOR( ix );
fy = FLOOR( iy );
/* Clipping!
*/
if( fx < ile || fx >= iri || fy < ito || fy >= ibo ) {
for( z = 0; z < ps; z++ )
q[z] = 0;
}
else {
interpolate( affine->interpolate,
q, ir, ix, iy );
}
ix += ddx;
iy += ddy;
q += ps;
}
}
return( 0 );
}
static int
vips_affine_gen( VipsRegion *or, void *seq, void *a, void *b, gboolean *stop )
{
VipsRegion *ir = (VipsRegion *) seq;
const VipsAffine *affine = (VipsAffine *) b;
const VipsImage *in = (VipsImage *) a;
const int window_size =
vips_interpolate_get_window_size( affine->interpolate );
const int window_offset =
vips_interpolate_get_window_offset( affine->interpolate );
const VipsInterpolateMethod interpolate =
vips_interpolate_get_method( affine->interpolate );
/* Area we generate in the output image.
*/
const VipsRect *r = &or->valid;
const int le = r->left;
const int ri = VIPS_RECT_RIGHT( r );
const int to = r->top;
const int bo = VIPS_RECT_BOTTOM( r );
const VipsRect *iarea = &affine->trn.iarea;
const VipsRect *oarea = &affine->trn.oarea;
int ps = VIPS_IMAGE_SIZEOF_PEL( in );
int x, y, z;
VipsRect image, want, need, clipped;
#ifdef DEBUG_VERBOSE
printf( "vips_affine_gen: "
"generating left=%d, top=%d, width=%d, height=%d\n",
r->left,
r->top,
r->width,
r->height );
#endif /*DEBUG_VERBOSE*/
/* We are generating this chunk of the transformed image. This takes
* us to space 4.
*/
want = *r;
want.left += oarea->left;
want.top += oarea->top;
/* Find the area of the input image we need. This takes us to space 3.
*/
vips__transform_invert_rect( &affine->trn, &want, &need );
/* That does round-to-nearest, because it has to stop rounding errors
* growing images unexpectedly. We need round-down, so we must
* add half a pixel along the left and top. But we are int :( so add 1
* pixel.
*
* Add an extra line along the right and bottom as well, for rounding.
*/
vips_rect_marginadjust( &need, 1 );
/* We need to fetch a larger area for the interpolator.
*/
need.left -= window_offset;
need.top -= window_offset;
need.width += window_size - 1;
need.height += window_size - 1;
/* Now go to space 2, the expanded input image. This is the one we
* read pixels from.
*/
need.left += window_offset;
need.top += window_offset;
/* Clip against the size of (2).
*/
image.left = 0;
image.top = 0;
image.width = in->Xsize;
image.height = in->Ysize;
vips_rect_intersectrect( &need, &image, &clipped );
#ifdef DEBUG_VERBOSE
printf( "vips_affine_gen: "
"preparing left=%d, top=%d, width=%d, height=%d\n",
clipped.left,
clipped.top,
clipped.width,
clipped.height );
#endif /*DEBUG_VERBOSE*/
if( vips_rect_isempty( &clipped ) ) {
vips_region_black( or );
return( 0 );
}
if( vips_region_prepare( ir, &clipped ) )
return( -1 );
VIPS_GATE_START( "vips_affine_gen: work" );
/* Resample! x/y loop over pixels in the output image (5).
*/
for( y = to; y < bo; y++ ) {
/* Input clipping rectangle. We offset this so we can clip in
* space 2.
*/
const int ile = iarea->left + window_offset;
const int ito = iarea->top + window_offset;
const int iri = ile + iarea->width;
const int ibo = ito + iarea->height;
/* Derivative of matrix.
*/
const double ddx = affine->trn.ia;
const double ddy = affine->trn.ic;
/* Continuous cods in transformed space.
*/
const double ox = le + oarea->left - affine->trn.odx;
const double oy = y + oarea->top - affine->trn.ody;
/* Continuous cods in input space.
*/
double ix, iy;
VipsPel *q;
/* To (3).
*/
ix = affine->trn.ia * ox + affine->trn.ib * oy;
iy = affine->trn.ic * ox + affine->trn.id * oy;
/* And the input offset in (3).
*/
ix -= affine->trn.idx;
iy -= affine->trn.idy;
/* Finally to 2.
*/
ix += window_offset;
iy += window_offset;
q = VIPS_REGION_ADDR( or, le, y );
for( x = le; x < ri; x++ ) {
int fx, fy;
fx = FAST_PSEUDO_FLOOR( ix );
fy = FAST_PSEUDO_FLOOR( iy );
/* Clip against iarea.
*/
if( fx >= ile &&
fx < iri &&
fy >= ito &&
fy < ibo ) {
/* Verify that we can read the whole stencil.
* With DEBUG on this will range-check.
*/
g_assert( VIPS_REGION_ADDR( ir,
(int) ix - window_offset,
(int) iy - window_offset ) );
g_assert( VIPS_REGION_ADDR( ir,
(int) ix - window_offset +
window_size - 1,
(int) iy - window_offset +
window_size - 1 ) );
interpolate( affine->interpolate,
q, ir, ix, iy );
}
else {
for( z = 0; z < ps; z++ )
q[z] = 0;
}
ix += ddx;
iy += ddy;
q += ps;
}
}
VIPS_GATE_STOP( "vips_affine_gen: work" );
return( 0 );
}
static int
vips_quadratic_gen( VipsRegion *or, void *vseq,
void *a, void *b, gboolean *stop )
{
VipsRegion *ir = (VipsRegion *) vseq;
VipsQuadratic *quadratic = (VipsQuadratic *) b;
VipsResample *resample = VIPS_RESAMPLE( quadratic );
VipsInterpolateMethod interpolate_fn =
vips_interpolate_get_method( quadratic->interpolate );
/* @in is the enlarged image (borders on, after vips_embed()). Use
* @resample->in for the original, not-expanded image.
*/
const VipsImage *in = (VipsImage *) a;
const int ps = VIPS_IMAGE_SIZEOF_PEL( in );
double *vec = (double *) VIPS_IMAGE_ADDR( quadratic->mat, 0, 0 );
int clip_width = resample->in->Xsize;
int clip_height = resample->in->Ysize;
int xlow = or->valid.left;
int ylow = or->valid.top;
int xhigh = VIPS_RECT_RIGHT( &or->valid );
int yhigh = VIPS_RECT_BOTTOM( &or->valid );
VipsPel *q;
int xo, yo; /* output coordinates, dstimage */
int z;
double fxi, fyi; /* input coordinates */
double dx, dy; /* xo derivative of input coord. */
double ddx, ddy; /* 2nd xo derivative of input coord. */
VipsRect image;
image.left = 0;
image.top = 0;
image.width = in->Xsize;
image.height = in->Ysize;
if( vips_region_image( ir, &image ) )
return( -1 );
for( yo = ylow; yo < yhigh; yo++ ) {
fxi = xlow + vec[0]; /* order 0 */
fyi = yo + vec[1];
dx = 1.0;
dy = 0.0;
switch( quadratic->order ) {
case 3:
fxi += vec[10] * yo * yo + vec[8] * xlow * xlow;
fyi += vec[11] * yo * yo + vec[9] * xlow * xlow;
dx += vec[8];
ddx = vec[8] * 2.0;
dy += vec[9];
ddy = vec[9] * 2.0;
case 2:
fxi += vec[6] * xlow * yo;
fyi += vec[7] * xlow * yo;
dx += vec[6] * yo;
dy += vec[7] * yo;
case 1:
fxi += vec[4] * yo + vec[2] * xlow;
fyi += vec[5] * yo + vec[3] * xlow;
dx += vec[2];
dy += vec[3];
case 0:
/* See above for order 0.
*/
break;
default:
g_assert( 0 );
return(-7);
}
q = VIPS_REGION_ADDR( or, xlow, yo );
for( xo = xlow; xo < xhigh; xo++ ) {
int xi, yi;
xi = fxi;
yi = fyi;
/* Clipping!
*/
if( xi < 0 ||
yi < 0 ||
xi >= clip_width ||
yi >= clip_height ) {
for( z = 0; z < ps; z++ )
q[z] = 0;
}
else
interpolate_fn( quadratic->interpolate,
q, ir, fxi, fyi );
q += ps;
fxi += dx;
fyi += dy;
if( quadratic->order > 2 ) {
dx += ddx;
dy += ddy;
}
}
}
return( 0 );
}
static int
vips_mapim_gen( VipsRegion *or, void *seq, void *a, void *b, gboolean *stop )
{
VipsRect *r = &or->valid;
VipsRegion **ir = (VipsRegion **) seq;
const VipsImage **in_array = (const VipsImage **) a;
const VipsMapim *mapim = (VipsMapim *) b;
const VipsResample *resample = VIPS_RESAMPLE( mapim );
const VipsImage *in = in_array[0];
const int window_size =
vips_interpolate_get_window_size( mapim->interpolate );
const int window_offset =
vips_interpolate_get_window_offset( mapim->interpolate );
const VipsInterpolateMethod interpolate =
vips_interpolate_get_method( mapim->interpolate );
const int ps = VIPS_IMAGE_SIZEOF_PEL( in );
const int clip_width = resample->in->Xsize;
const int clip_height = resample->in->Ysize;
VipsRect bounds, image, clipped;
int x, y, z;
#ifdef DEBUG_VERBOSE
printf( "vips_mapim_gen: "
"generating left=%d, top=%d, width=%d, height=%d\n",
r->left,
r->top,
r->width,
r->height );
#endif /*DEBUG_VERBOSE*/
/* Fetch the chunk of the mapim image we need, and find the max/min in
* x and y.
*/
if( vips_region_prepare( ir[1], r ) )
return( -1 );
VIPS_GATE_START( "vips_mapim_gen: work" );
vips_mapim_region_minmax( ir[1], r, &bounds );
VIPS_GATE_STOP( "vips_mapim_gen: work" );
/* The bounding box of that area is what we will need from @in. Add
* enough for the interpolation stencil as well.
*
*/
bounds.width += window_size - 1;
bounds.height += window_size - 1;
/* Clip against the expanded image.
*/
image.left = 0;
image.top = 0;
image.width = in->Xsize;
image.height = in->Ysize;
vips_rect_intersectrect( &bounds, &image, &clipped );
#ifdef DEBUG_VERBOSE
printf( "vips_mapim_gen: "
"preparing left=%d, top=%d, width=%d, height=%d\n",
clipped.left,
clipped.top,
clipped.width,
clipped.height );
#endif /*DEBUG_VERBOSE*/
if( vips_rect_isempty( &clipped ) ) {
vips_region_black( or );
return( 0 );
}
if( vips_region_prepare( ir[0], &clipped ) )
return( -1 );
VIPS_GATE_START( "vips_mapim_gen: work" );
/* Resample! x/y loop over pixels in the output image (5).
*/
for( y = 0; y < r->height; y++ ) {
VipsPel * restrict p =
VIPS_REGION_ADDR( ir[1], r->left, y + r->top );
VipsPel * restrict q =
VIPS_REGION_ADDR( or, r->left, y + r->top );
switch( ir[1]->im->BandFmt ) {
case VIPS_FORMAT_UCHAR:
ULOOKUP( unsigned char ); break;
case VIPS_FORMAT_CHAR:
LOOKUP( signed char ); break;
case VIPS_FORMAT_USHORT:
ULOOKUP( unsigned short ); break;
case VIPS_FORMAT_SHORT:
LOOKUP( signed short ); break;
case VIPS_FORMAT_UINT:
ULOOKUP( unsigned int ); break;
case VIPS_FORMAT_INT:
LOOKUP( signed int ); break;
case VIPS_FORMAT_FLOAT:
case VIPS_FORMAT_COMPLEX:
LOOKUP( float ); break;
break;
case VIPS_FORMAT_DOUBLE:
case VIPS_FORMAT_DPCOMPLEX:
LOOKUP( double ); break;
default:
g_assert_not_reached();
}
}
VIPS_GATE_STOP( "vips_mapim_gen: work" );
return( 0 );
}
static int
vips_affine_gen( VipsRegion *or, void *seq, void *a, void *b, gboolean *stop )
{
VipsRegion *ir = (VipsRegion *) seq;
const VipsAffine *affine = (VipsAffine *) b;
const VipsImage *in = (VipsImage *) a;
const int window_size =
vips_interpolate_get_window_size( affine->interpolate );
const int window_offset =
vips_interpolate_get_window_offset( affine->interpolate );
const VipsInterpolateMethod interpolate =
vips_interpolate_get_method( affine->interpolate );
/* Area we generate in the output image.
*/
const VipsRect *r = &or->valid;
const int le = r->left;
const int ri = VIPS_RECT_RIGHT( r );
const int to = r->top;
const int bo = VIPS_RECT_BOTTOM( r );
const VipsRect *iarea = &affine->trn.iarea;
const VipsRect *oarea = &affine->trn.oarea;
int ps = VIPS_IMAGE_SIZEOF_PEL( in );
int x, y, z;
VipsRect image, want, need, clipped;
#ifdef DEBUG
printf( "affine: generating left=%d, top=%d, width=%d, height=%d\n",
r->left,
r->top,
r->width,
r->height );
#endif /*DEBUG*/
/* We are generating this chunk of the transformed image.
*/
want = *r;
want.left += oarea->left;
want.top += oarea->top;
/* Find the area of the input image we need.
*/
vips__transform_invert_rect( &affine->trn, &want, &need );
/* That does round-to-nearest, because it has to stop rounding errors
* growing images unexpectedly. We need round-down, so we must
* add half a pixel along the left and top. But we are int :( so add 1
* pixel.
*
* Add an extra line along the right and bottom as well, for rounding.
*/
vips_rect_marginadjust( &need, 1 );
/* Now go to space (2) above.
*/
need.left += iarea->left;
need.top += iarea->top;
/* Add a border for interpolation.
*/
need.width += window_size - 1;
need.height += window_size - 1;
need.left -= window_offset;
need.top -= window_offset;
/* Clip against the size of (2).
*/
image.left = 0;
image.top = 0;
image.width = in->Xsize;
image.height = in->Ysize;
vips_rect_intersectrect( &need, &image, &clipped );
/* Outside input image? All black.
*/
if( vips_rect_isempty( &clipped ) ) {
vips_region_black( or );
return( 0 );
}
/* We do need some pixels from the input image to make our output -
* ask for them.
*/
if( vips_region_prepare( ir, &clipped ) )
return( -1 );
#ifdef DEBUG
printf( "affine: preparing left=%d, top=%d, width=%d, height=%d\n",
clipped.left,
clipped.top,
clipped.width,
clipped.height );
#endif /*DEBUG*/
/* Resample! x/y loop over pixels in the output image (5).
*/
for( y = to; y < bo; y++ ) {
/* Input clipping rectangle.
*/
const int ile = iarea->left;
const int ito = iarea->top;
const int iri = iarea->left + iarea->width;
const int ibo = iarea->top + iarea->height;
/* Derivative of matrix.
*/
const double ddx = affine->trn.ia;
const double ddy = affine->trn.ic;
/* Continuous cods in transformed space.
*/
const double ox = le + oarea->left - affine->trn.odx;
const double oy = y + oarea->top - affine->trn.ody;
/* Continuous cods in input space.
*/
double ix, iy;
VipsPel *q;
/* To (3).
*/
ix = affine->trn.ia * ox + affine->trn.ib * oy;
iy = affine->trn.ic * ox + affine->trn.id * oy;
/* Now move to (2).
*/
ix += iarea->left;
iy += iarea->top;
/* And the input offset.
*/
ix -= affine->trn.idx;
iy -= affine->trn.idy;
q = VIPS_REGION_ADDR( or, le, y );
for( x = le; x < ri; x++ ) {
int fx, fy;
fx = FAST_PSEUDO_FLOOR( ix );
fy = FAST_PSEUDO_FLOOR( iy );
/* Clipping!
*/
if( fx < ile || fx >= iri || fy < ito || fy >= ibo ) {
for( z = 0; z < ps; z++ )
q[z] = 0;
}
else {
interpolate( affine->interpolate,
q, ir, ix, iy );
}
ix += ddx;
iy += ddy;
q += ps;
}
}
return( 0 );
}
