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|
/*----------------------------------------------------------------------*
* File: rxvtimg.C
*----------------------------------------------------------------------*
*
* All portions of code are copyright by their respective author/s.
* Copyright (c) 2012 Marc Lehmann <schmorp@schmorp.de>
* Copyright (c) 2012 Emanuele Giaquinta <e.giaquinta@glauco.it>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*---------------------------------------------------------------------*/
#include <string.h>
#include <math.h>
#include "../config.h"
#include "rxvt.h"
#if HAVE_IMG
typedef rxvt_img::nv nv;
namespace
{
struct mat3x3
{
nv v[3][3];
mat3x3 ()
{
}
mat3x3 (const nv *matrix)
{
memcpy (v, matrix, sizeof (v));
}
mat3x3 (nv v11, nv v12, nv v13, nv v21, nv v22, nv v23, nv v31, nv v32, nv v33)
{
v[0][0] = v11; v[0][1] = v12; v[0][2] = v13;
v[1][0] = v21; v[1][1] = v22; v[1][2] = v23;
v[2][0] = v31; v[2][1] = v32; v[2][2] = v33;
}
mat3x3 inverse ();
nv *operator [](int i) { return &v[i][0]; }
const nv *operator [](int i) const { return &v[i][0]; }
operator const nv * () const { return &v[0][0]; }
operator nv * () { return &v[0][0]; }
// quite inefficient, hopefully gcc pulls the w calc out of any loops
nv apply1 (int i, nv x, nv y)
{
mat3x3 &m = *this;
nv v = m[i][0] * x + m[i][1] * y + m[i][2];
nv w = m[2][0] * x + m[2][1] * y + m[2][2];
return v * (1. / w);
}
static mat3x3 translate (nv x, nv y);
static mat3x3 scale (nv s, nv t);
static mat3x3 rotate (nv phi);
};
mat3x3
mat3x3::inverse ()
{
mat3x3 &m = *this;
mat3x3 inv;
nv s0 = m[2][2] * m[1][1] - m[2][1] * m[1][2];
nv s1 = m[2][1] * m[0][2] - m[2][2] * m[0][1];
nv s2 = m[1][2] * m[0][1] - m[1][1] * m[0][2];
nv invdet = 1. / (m[0][0] * s0 + m[1][0] * s1 + m[2][0] * s2);
inv[0][0] = invdet * s0;
inv[0][1] = invdet * s1;
inv[0][2] = invdet * s2;
inv[1][0] = invdet * (m[2][0] * m[1][2] - m[2][2] * m[1][0]);
inv[1][1] = invdet * (m[2][2] * m[0][0] - m[2][0] * m[0][2]);
inv[1][2] = invdet * (m[1][0] * m[0][2] - m[1][2] * m[0][0]);
inv[2][0] = invdet * (m[2][1] * m[1][0] - m[2][0] * m[1][1]);
inv[2][1] = invdet * (m[2][0] * m[0][1] - m[2][1] * m[0][0]);
inv[2][2] = invdet * (m[1][1] * m[0][0] - m[1][0] * m[0][1]);
return inv;
}
static mat3x3
operator *(const mat3x3 &a, const mat3x3 &b)
{
mat3x3 r;
for (int i = 0; i < 3; ++i)
for (int j = 0; j < 3; ++j)
r[i][j] = a[i][0] * b[0][j]
+ a[i][1] * b[1][j]
+ a[i][2] * b[2][j];
return r;
}
mat3x3
mat3x3::translate (nv x, nv y)
{
return mat3x3 (
1, 0, x,
0, 1, y,
0, 0, 1
);
}
mat3x3
mat3x3::scale (nv s, nv t)
{
return mat3x3 (
s, 0, 0,
0, t, 0,
0, 0, 1
);
}
// clockwise
mat3x3
mat3x3::rotate (nv phi)
{
nv s = sin (phi);
nv c = cos (phi);
return mat3x3 (
c, -s, 0,
s, c, 0,
0, 0, 1
);
}
struct composer
{
rxvt_img *srcimg, *dstimg;
Picture src, dst, msk;
Display *dpy;
ecb_noinline
composer (rxvt_img *srcimg, rxvt_img *dstimg = 0)
: srcimg (srcimg), dstimg (dstimg), msk (0)
{
if (!this->dstimg)
this->dstimg = srcimg->new_empty ();
else if (!this->dstimg->pm) // somewhat unsatisfying
this->dstimg->alloc ();
dpy = srcimg->d->dpy;
src = srcimg->picture ();
dst = this->dstimg->picture ();
}
ecb_noinline
void mask (bool rgb = true, int w = 1, int h = 1)
{
Pixmap pixmap = XCreatePixmap (dpy, srcimg->pm, w, h, rgb ? 32 : 8);
XRenderPictFormat *format = XRenderFindStandardFormat (dpy, rgb ? PictStandardARGB32 : PictStandardA8);
XRenderPictureAttributes pa;
pa.repeat = RepeatNormal;
pa.component_alpha = rgb;
msk = XRenderCreatePicture (dpy, pixmap, format, CPRepeat | CPComponentAlpha, &pa);
XFreePixmap (dpy, pixmap);
ecb_assume (msk);
}
// CreateSolidFill creates a very very very weird picture
void mask (const rgba &c)
{
// the casts are needed in C++11 (see 8.5.1)
XRenderColor rc = {
(unsigned short)(c.r * c.a / 65535),
(unsigned short)(c.g * c.a / 65535),
(unsigned short)(c.b * c.a / 65535),
c.a
};
msk = XRenderCreateSolidFill (dpy, &rc);
ecb_assume (msk);
}
void fill (const rgba &c)
{
XRenderColor rc = {
(unsigned short)(c.r * c.a / 65535),
(unsigned short)(c.g * c.a / 65535),
(unsigned short)(c.b * c.a / 65535),
c.a
};
XRenderFillRectangle (dpy, PictOpSrc, msk, &rc, 0, 0, 1, 1);
}
operator rxvt_img *()
{
return dstimg;
}
ecb_noinline
~composer ()
{
XRenderFreePicture (dpy, src);
XRenderFreePicture (dpy, dst);
if (msk) XRenderFreePicture (dpy, msk);
}
};
}
static XRenderPictFormat *
find_alpha_format_for (Display *dpy, XRenderPictFormat *format)
{
if (format->direct.alphaMask)
return format; // already has alpha
// try to find a suitable alpha format, one bit alpha is enough for our purposes
if (format->type == PictTypeDirect)
for (int n = 0; XRenderPictFormat *f = XRenderFindFormat (dpy, 0, 0, n); ++n)
if (f->direct.alphaMask
&& f->type == PictTypeDirect
&& ecb_popcount32 (f->direct.redMask ) >= ecb_popcount32 (format->direct.redMask )
&& ecb_popcount32 (f->direct.greenMask) >= ecb_popcount32 (format->direct.greenMask)
&& ecb_popcount32 (f->direct.blueMask ) >= ecb_popcount32 (format->direct.blueMask ))
return f;
// should be a very good fallback
return XRenderFindStandardFormat (dpy, PictStandardARGB32);
}
rxvt_img::rxvt_img (rxvt_screen *screen, XRenderPictFormat *format, int x, int y, int width, int height, int repeat)
: d(screen->display), x(x), y(y), w(width), h(height), format(format), repeat(repeat),
pm(0), ref(0)
{
}
rxvt_img::rxvt_img (rxvt_display *display, XRenderPictFormat *format, int x, int y, int width, int height, int repeat)
: d(display), x(x), y(y), w(width), h(height), format(format), repeat(repeat),
pm(0), ref(0)
{
}
rxvt_img::rxvt_img (const rxvt_img &img)
: d(img.d), x(img.x), y(img.y), w(img.w), h(img.h), format(img.format), repeat(img.repeat), pm(img.pm), ref(img.ref)
{
++ref->cnt;
}
rxvt_img *
rxvt_img::new_from_root (rxvt_screen *s)
{
Display *dpy = s->dpy;
unsigned int root_pm_w, root_pm_h;
Pixmap root_pixmap = s->display->get_pixmap_property (s->display->xa [XA_XROOTPMAP_ID]);
if (root_pixmap == None)
root_pixmap = s->display->get_pixmap_property (s->display->xa [XA_ESETROOT_PMAP_ID]);
if (root_pixmap == None)
return 0;
Window wdummy;
int idummy;
unsigned int udummy;
if (!XGetGeometry (dpy, root_pixmap, &wdummy, &idummy, &idummy, &root_pm_w, &root_pm_h, &udummy, &udummy))
return 0;
rxvt_img *img = new rxvt_img (
s,
XRenderFindVisualFormat (dpy, DefaultVisual (dpy, s->display->screen)),
0,
0,
root_pm_w,
root_pm_h
);
img->pm = root_pixmap;
img->ref = new pixref (root_pm_w, root_pm_h);
img->ref->ours = false;
return img;
}
# if HAVE_PIXBUF
rxvt_img *
rxvt_img::new_from_pixbuf (rxvt_screen *s, GdkPixbuf *pb)
{
Display *dpy = s->dpy;
int width = gdk_pixbuf_get_width (pb);
int height = gdk_pixbuf_get_height (pb);
if (width > 32767 || height > 32767) // well, we *could* upload in chunks
rxvt_fatal ("rxvt_img::new_from_pixbuf: image too big (maximum size 32768x32768).\n");
// since we require rgb24/argb32 formats from xrender we assume
// that both 24 and 32 bpp MUST be supported by any screen that supports xrender
int byte_order = ecb_big_endian () ? MSBFirst : LSBFirst;
XImage xi;
xi.width = width;
xi.height = height;
xi.xoffset = 0;
xi.format = ZPixmap;
xi.byte_order = ImageByteOrder (dpy);
xi.bitmap_unit = 0; //XY only, unused
xi.bitmap_bit_order = 0; //XY only, unused
xi.bitmap_pad = BitmapPad (dpy);
xi.depth = 32;
xi.bytes_per_line = 0;
xi.bits_per_pixel = 32; //Z only
xi.red_mask = 0x00000000; //Z only, unused
xi.green_mask = 0x00000000; //Z only, unused
xi.blue_mask = 0x00000000; //Z only, unused
xi.obdata = 0; // probably unused
bool byte_order_mismatch = byte_order != xi.byte_order;
if (!XInitImage (&xi))
rxvt_fatal ("unable to initialise ximage, please report.\n");
if (height > INT_MAX / xi.bytes_per_line)
rxvt_fatal ("rxvt_img::new_from_pixbuf: image too big for Xlib.\n");
xi.data = (char *)rxvt_malloc (height * xi.bytes_per_line);
int rowstride = gdk_pixbuf_get_rowstride (pb);
bool pb_has_alpha = gdk_pixbuf_get_has_alpha (pb);
unsigned char *row = gdk_pixbuf_get_pixels (pb);
char *line = xi.data;
for (int y = 0; y < height; y++)
{
unsigned char *src = row;
uint32_t *dst = (uint32_t *)line;
for (int x = 0; x < width; x++)
{
uint8_t r = *src++;
uint8_t g = *src++;
uint8_t b = *src++;
uint8_t a = *src;
// this is done so it can be jump-free, but newer gcc's clone inner the loop
a = pb_has_alpha ? a : 255;
src += pb_has_alpha;
r = (r * a + 127) / 255;
g = (g * a + 127) / 255;
b = (b * a + 127) / 255;
uint32_t v = (a << 24) | (r << 16) | (g << 8) | b;
if (ecb_big_endian () ? !byte_order_mismatch : byte_order_mismatch)
v = ecb_bswap32 (v);
*dst++ = v;
}
row += rowstride;
line += xi.bytes_per_line;
}
rxvt_img *img = new rxvt_img (s, XRenderFindStandardFormat (dpy, PictStandardARGB32), 0, 0, width, height);
img->alloc ();
GC gc = XCreateGC (dpy, img->pm, 0, 0);
XPutImage (dpy, img->pm, gc, &xi, 0, 0, 0, 0, width, height);
XFreeGC (dpy, gc);
free (xi.data);
return img;
}
rxvt_img *
rxvt_img::new_from_file (rxvt_screen *s, const char *filename)
{
GError *err = 0;
GdkPixbuf *pb = gdk_pixbuf_new_from_file (filename, &err);
if (!pb)
rxvt_fatal ("rxvt_img::new_from_file: %s\n", err->message);
rxvt_img *img = new_from_pixbuf (s, pb);
g_object_unref (pb);
return img;
}
# endif
void
rxvt_img::destroy ()
{
if (--ref->cnt)
return;
if (pm && ref->ours)
XFreePixmap (d->dpy, pm);
delete ref;
}
rxvt_img::~rxvt_img ()
{
destroy ();
}
void
rxvt_img::alloc ()
{
pm = XCreatePixmap (d->dpy, d->root, w, h, format->depth);
ref = new pixref (w, h);
}
rxvt_img *
rxvt_img::new_empty ()
{
rxvt_img *img = new rxvt_img (d, format, x, y, w, h, repeat);
img->alloc ();
return img;
}
Picture
rxvt_img::picture ()
{
Display *dpy = d->dpy;
XRenderPictureAttributes pa;
pa.repeat = repeat;
Picture pic = XRenderCreatePicture (dpy, pm, format, CPRepeat, &pa);
return pic;
}
void
rxvt_img::unshare ()
{
if (ref->cnt == 1 && ref->ours)
return;
Pixmap pm2 = XCreatePixmap (d->dpy, d->root, ref->w, ref->h, format->depth);
GC gc = XCreateGC (d->dpy, pm, 0, 0);
XCopyArea (d->dpy, pm, pm2, gc, 0, 0, ref->w, ref->h, 0, 0);
XFreeGC (d->dpy, gc);
destroy ();
pm = pm2;
ref = new pixref (ref->w, ref->h);
}
void
rxvt_img::fill (const rgba &c, int x, int y, int w, int h)
{
XRenderColor rc = { c.r, c.g, c.b, c.a };
Display *dpy = d->dpy;
Picture src = picture ();
XRenderFillRectangle (dpy, PictOpSrc, src, &rc, x, y, w, h);
XRenderFreePicture (dpy, src);
}
void
rxvt_img::fill (const rgba &c)
{
fill (c, 0, 0, w, h);
}
void
rxvt_img::add_alpha ()
{
if (format->direct.alphaMask)
return;
composer cc (this, new rxvt_img (d, find_alpha_format_for (d->dpy, format), x, y, w, h, repeat));
XRenderComposite (cc.dpy, PictOpSrc, cc.src, None, cc.dst, 0, 0, 0, 0, 0, 0, w, h);
rxvt_img *img = cc;
::swap (img->ref, ref);
::swap (img->pm , pm );
delete img;
}
static void
get_gaussian_kernel (int radius, int width, nv *kernel, XFixed *params)
{
nv sigma = radius / 2.0;
nv scale = sqrt (2.0 * M_PI) * sigma;
nv sum = 0.0;
for (int i = 0; i < width; i++)
{
nv x = i - width / 2;
kernel[i] = exp (-(x * x) / (2.0 * sigma * sigma)) / scale;
sum += kernel[i];
}
params[0] = XDoubleToFixed (width);
params[1] = XDoubleToFixed (1);
for (int i = 0; i < width; i++)
params[i+2] = XDoubleToFixed (kernel[i] / sum);
}
rxvt_img *
rxvt_img::blur (int rh, int rv)
{
if (!(d->flags & DISPLAY_HAS_RENDER_CONV))
return clone ();
Display *dpy = d->dpy;
int size = max (rh, rv) * 2 + 1;
nv *kernel = (nv *)malloc (size * sizeof (nv));
XFixed *params = rxvt_temp_buf<XFixed> (size + 2);
rxvt_img *img = new_empty ();
XRenderPictureAttributes pa;
pa.repeat = RepeatPad;
Picture src = XRenderCreatePicture (dpy, pm, format, CPRepeat, &pa);
Picture dst = XRenderCreatePicture (dpy, img->pm, format, 0, 0);
Pixmap tmp_pm = XCreatePixmap (dpy, pm, w, h, format->depth);
Picture tmp = XRenderCreatePicture (dpy, tmp_pm , format, CPRepeat, &pa);
XFreePixmap (dpy, tmp_pm);
if (kernel && params)
{
size = rh * 2 + 1;
get_gaussian_kernel (rh, size, kernel, params);
XRenderSetPictureFilter (dpy, src, FilterConvolution, params, size+2);
XRenderComposite (dpy,
PictOpSrc,
src,
None,
tmp,
0, 0,
0, 0,
0, 0,
w, h);
size = rv * 2 + 1;
get_gaussian_kernel (rv, size, kernel, params);
::swap (params[0], params[1]);
XRenderSetPictureFilter (dpy, tmp, FilterConvolution, params, size+2);
XRenderComposite (dpy,
PictOpSrc,
tmp,
None,
dst,
0, 0,
0, 0,
0, 0,
w, h);
}
free (kernel);
XRenderFreePicture (dpy, src);
XRenderFreePicture (dpy, dst);
XRenderFreePicture (dpy, tmp);
return img;
}
rxvt_img *
rxvt_img::muladd (nv mul, nv add)
{
// STEP 1: double the image width, fill all odd columns with white (==1)
composer cc (this, new rxvt_img (d, format, 0, 0, w * 2, h, repeat));
// why the hell does XRenderSetPictureTransform want a writable matrix :(
// that keeps us from just static const'ing this matrix.
XTransform h_double = {
0x08000, 0, 0,
0, 0x10000, 0,
0, 0, 0x10000
};
XRenderSetPictureFilter (cc.dpy, cc.src, "nearest", 0, 0);
XRenderSetPictureTransform (cc.dpy, cc.src, &h_double);
XRenderComposite (cc.dpy, PictOpSrc, cc.src, None, cc.dst, 0, 0, 0, 0, 0, 0, w * 2, h);
cc.mask (false, 2, 1);
static const XRenderColor c0 = { 0, 0, 0, 0 };
XRenderFillRectangle (cc.dpy, PictOpSrc, cc.msk, &c0, 0, 0, 1, 1);
static const XRenderColor c1 = { 65535, 65535, 65535, 65535 };
XRenderFillRectangle (cc.dpy, PictOpSrc, cc.msk, &c1, 1, 0, 1, 1);
Picture white = XRenderCreateSolidFill (cc.dpy, &c1);
XRenderComposite (cc.dpy, PictOpOver, white, cc.msk, cc.dst, 0, 0, 0, 0, 0, 0, w * 2, h);
XRenderFreePicture (cc.dpy, white);
// STEP 2: convolve the image with a 3x1 filter
// a 2x1 filter would obviously suffice, but given the total lack of specification
// for xrender, I expect different xrender implementations to randomly diverge.
// we also halve the image, and hope for the best (again, for lack of specs).
composer cc2 (cc.dstimg);
XFixed kernel [] = {
XDoubleToFixed (3), XDoubleToFixed (1),
XDoubleToFixed (0), XDoubleToFixed (mul), XDoubleToFixed (add)
};
XTransform h_halve = {
0x20000, 0, 0,
0, 0x10000, 0,
0, 0, 0x10000
};
XRenderSetPictureFilter (cc.dpy, cc2.src, "nearest", 0, 0);
XRenderSetPictureTransform (cc.dpy, cc2.src, &h_halve);
XRenderSetPictureFilter (cc.dpy, cc2.src, FilterConvolution, kernel, ecb_array_length (kernel));
XRenderComposite (cc.dpy, PictOpSrc, cc2.src, None, cc2.dst, 0, 0, 0, 0, 0, 0, w * 2, h);
return cc2;
}
ecb_noinline static void
extract (int32_t cl0, int32_t cl1, int32_t &c, unsigned short &xc)
{
int32_t x = clamp (c, cl0, cl1);
c -= x;
xc = x;
}
ecb_noinline static bool
extract (int32_t cl0, int32_t cl1, int32_t &r, int32_t &g, int32_t &b, int32_t &a, unsigned short &xr, unsigned short &xg, unsigned short &xb, unsigned short &xa)
{
extract (cl0, cl1, r, xr);
extract (cl0, cl1, g, xg);
extract (cl0, cl1, b, xb);
extract (cl0, cl1, a, xa);
return xr | xg | xb | xa;
}
void
rxvt_img::brightness (int32_t r, int32_t g, int32_t b, int32_t a)
{
unshare ();
Display *dpy = d->dpy;
Picture dst = XRenderCreatePicture (dpy, pm, format, 0, 0);
// loop should not be needed for brightness, as only -1..1 makes sense
//while (r | g | b | a)
{
unsigned short xr, xg, xb, xa;
XRenderColor mask_c;
if (extract (0, 65535, r, g, b, a, mask_c.red, mask_c.green, mask_c.blue, mask_c.alpha))
XRenderFillRectangle (dpy, PictOpAdd, dst, &mask_c, 0, 0, w, h);
if (extract (-65535, 0, r, g, b, a, mask_c.red, mask_c.green, mask_c.blue, mask_c.alpha))
{
XRenderColor mask_w = { 65535, 65535, 65535, 65535 };
XRenderFillRectangle (dpy, PictOpDifference, dst, &mask_w, 0, 0, w, h);
mask_c.red = -mask_c.red; //TODO: verify that doing clamp, assign, and negation does the right thing
mask_c.green = -mask_c.green;
mask_c.blue = -mask_c.blue;
mask_c.alpha = -mask_c.alpha;
XRenderFillRectangle (dpy, PictOpAdd, dst, &mask_c, 0, 0, w, h);
XRenderFillRectangle (dpy, PictOpDifference, dst, &mask_w, 0, 0, w, h);
}
}
XRenderFreePicture (dpy, dst);
}
void
rxvt_img::contrast (int32_t r, int32_t g, int32_t b, int32_t a)
{
if (r < 0 || g < 0 || b < 0 || a < 0)
rxvt_fatal ("rxvt_img::contrast does not support negative values.\n");
// premultiply (yeah, these are not exact, sue me or fix it)
r = (r * (a >> 8)) >> 8;
g = (g * (a >> 8)) >> 8;
b = (b * (a >> 8)) >> 8;
composer cc (this);
rxvt_img *img = cc;
img->fill (rgba (0, 0, 0, 0));
cc.mask (true);
//TODO: this operator does not yet implement some useful contrast
while (r | g | b | a)
{
unsigned short xr, xg, xb, xa;
XRenderColor mask_c;
if (extract (0, 65535, r, g, b, a, mask_c.red, mask_c.green, mask_c.blue, mask_c.alpha))
{
XRenderFillRectangle (cc.dpy, PictOpSrc, cc.msk, &mask_c, 0, 0, 1, 1);
XRenderComposite (cc.dpy, PictOpAdd, cc.src, cc.msk, cc.dst, 0, 0, 0, 0, 0, 0, w, h);
}
}
::swap (img->ref, ref);
::swap (img->pm , pm );
delete img;
}
void
rxvt_img::draw (rxvt_img *img, int op, nv mask)
{
unshare ();
composer cc (img, this);
if (mask != 1.)
cc.mask (rgba (0, 0, 0, float_to_component (mask)));
XRenderComposite (cc.dpy, op, cc.src, cc.msk, cc.dst, x - img->x, y - img->y, 0, 0, 0, 0, w, h);
}
rxvt_img *
rxvt_img::clone ()
{
return new rxvt_img (*this);
}
rxvt_img *
rxvt_img::reify ()
{
if (x == 0 && y == 0 && w == ref->w && h == ref->h)
return clone ();
// add an alpha channel if...
bool alpha = !format->direct.alphaMask // pixmap has none yet
&& (x || y) // we need one because of non-zero offset
&& repeat == RepeatNone; // and we have no good pixels to fill with
composer cc (this, new rxvt_img (d, alpha ? find_alpha_format_for (d->dpy, format) : format,
0, 0, w, h, repeat));
if (repeat == RepeatNone)
{
XRenderColor rc = { 0, 0, 0, 0 };
XRenderFillRectangle (cc.dpy, PictOpSrc, cc.dst, &rc, 0, 0, w, h);//TODO: split into four fillrectangles
XRenderComposite (cc.dpy, PictOpSrc, cc.src, None, cc.dst, 0, 0, 0, 0, x, y, ref->w, ref->h);
}
else
XRenderComposite (cc.dpy, PictOpSrc, cc.src, None, cc.dst, -x, -y, 0, 0, 0, 0, w, h);
return cc;
}
rxvt_img *
rxvt_img::sub_rect (int x, int y, int width, int height)
{
rxvt_img *img = clone ();
img->x -= x;
img->y -= y;
if (w != width || h != height)
{
img->w = width;
img->h = height;
rxvt_img *img2 = img->reify ();
delete img;
img = img2;
}
return img;
}
rxvt_img *
rxvt_img::transform (const nv matrix[3][3])
{
return transform (mat3x3 (&matrix[0][0]));
}
rxvt_img *
rxvt_img::transform (const nv *matrix)
{
mat3x3 m (matrix);
// calculate new pixel bounding box coordinates
nv rmin[2], rmax[2];
for (int i = 0; i < 2; ++i)
{
nv v;
v = m.apply1 (i, 0+x, 0+y); rmin [i] = rmax [i] = v;
v = m.apply1 (i, w+x, 0+y); min_it (rmin [i], v); max_it (rmax [i], v);
v = m.apply1 (i, 0+x, h+y); min_it (rmin [i], v); max_it (rmax [i], v);
v = m.apply1 (i, w+x, h+y); min_it (rmin [i], v); max_it (rmax [i], v);
}
float sx = rmin [0] - x;
float sy = rmin [1] - y;
// TODO: adjust matrix for subpixel accuracy
int nx = floor (rmin [0]);
int ny = floor (rmin [1]);
int new_width = ceil (rmax [0] - rmin [0]);
int new_height = ceil (rmax [1] - rmin [1]);
mat3x3 inv = (mat3x3::translate (-x, -y) * m * mat3x3::translate (x, y)).inverse ();
composer cc (this, new rxvt_img (d, format, nx, ny, new_width, new_height, repeat));
XTransform xfrm;
for (int i = 0; i < 3; ++i)
for (int j = 0; j < 3; ++j)
xfrm.matrix [i][j] = XDoubleToFixed (inv [i][j]);
XRenderSetPictureFilter (cc.dpy, cc.src, "good", 0, 0);
XRenderSetPictureTransform (cc.dpy, cc.src, &xfrm);
XRenderComposite (cc.dpy, PictOpSrc, cc.src, None, cc.dst, sx, sy, 0, 0, 0, 0, new_width, new_height);
return cc;
}
rxvt_img *
rxvt_img::scale (int new_width, int new_height)
{
if (w == new_width && h == new_height)
return clone ();
int old_repeat_mode = repeat;
repeat = RepeatPad; // not right, but xrender can't properly scale it seems
rxvt_img *img = transform (mat3x3::scale (new_width / (nv)w, new_height / (nv)h));
repeat = old_repeat_mode;
img->repeat = repeat;
return img;
}
rxvt_img *
rxvt_img::rotate (int cx, int cy, nv phi)
{
move (-cx, -cy);
rxvt_img *img = transform (mat3x3::rotate (phi));
move ( cx, cy);
img->move (cx, cy);
return img;
}
rxvt_img *
rxvt_img::convert_format (XRenderPictFormat *new_format, const rgba &bg)
{
if (new_format == format)
return clone ();
composer cc (this, new rxvt_img (d, new_format, x, y, w, h, repeat));
int op = PictOpSrc;
if (format->direct.alphaMask && !new_format->direct.alphaMask)
{
// does it have to be that complicated
XRenderColor rc = { bg.r, bg.g, bg.b, bg.a };
XRenderFillRectangle (cc.dpy, PictOpSrc, cc.dst, &rc, 0, 0, w, h);
op = PictOpOver;
}
XRenderComposite (cc.dpy, op, cc.src, None, cc.dst, 0, 0, 0, 0, 0, 0, w, h);
return cc;
}
rxvt_img *
rxvt_img::tint (const rgba &c)
{
composer cc (this);
cc.mask (true);
cc.fill (c);
XRenderComposite (cc.dpy, PictOpSrc, cc.src, cc.msk, cc.dst, 0, 0, 0, 0, 0, 0, w, h);
return cc;
}
rxvt_img *
rxvt_img::shade (nv factor, rgba c)
{
clamp_it (factor, -1., 1.);
factor++;
if (factor > 1)
{
c.r = c.r * (2 - factor);
c.g = c.g * (2 - factor);
c.b = c.b * (2 - factor);
}
else
{
c.r = c.r * factor;
c.g = c.g * factor;
c.b = c.b * factor;
}
rxvt_img *img = this->tint (c);
if (factor > 1)
{
c.a = 0xffff;
c.r =
c.g =
c.b = 0xffff * (factor - 1);
img->brightness (c.r, c.g, c.b, c.a);
}
return img;
}
rxvt_img *
rxvt_img::filter (const char *name, int nparams, nv *params)
{
composer cc (this);
XFixed *xparams = rxvt_temp_buf<XFixed> (nparams);
for (int i = 0; i < nparams; ++i)
xparams [i] = XDoubleToFixed (params [i]);
XRenderSetPictureFilter (cc.dpy, cc.src, name, xparams, nparams);
XRenderComposite (cc.dpy, PictOpSrc, cc.src, 0, cc.dst, 0, 0, 0, 0, 0, 0, w, h);
return cc;
}
#endif
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