Feodor2
/
Mypal
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
Mypal/gfx/cairo/libpixman/src/pixman-combine64.c

2466 lines
68 KiB
C
Raw Blame History

This file contains ambiguous Unicode characters!

This file contains ambiguous Unicode characters that may be confused with others in your current locale. If your use case is intentional and legitimate, you can safely ignore this warning. Use the Escape button to highlight these characters.

/* WARNING: This file is generated by combine.pl from combine.inc.
Please edit one of those files rather than this one. */
#line 1 "pixman-combine.c.template"
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <math.h>
#include <string.h>
#include "pixman-private.h"
#include "pixman-combine64.h"
/*** per channel helper functions ***/
static void
combine_mask_ca (uint64_t *src, uint64_t *mask)
{
uint64_t a = *mask;
uint64_t x;
uint32_t xa;
if (!a)
{
*(src) = 0;
return;
}
x = *(src);
if (a == ~0)
{
x = x >> A_SHIFT;
x |= x << G_SHIFT;
x |= x << R_SHIFT;
*(mask) = x;
return;
}
xa = x >> A_SHIFT;
UN16x4_MUL_UN16x4 (x, a);
*(src) = x;
UN16x4_MUL_UN16 (a, xa);
*(mask) = a;
}
static void
combine_mask_value_ca (uint64_t *src, const uint64_t *mask)
{
uint64_t a = *mask;
uint64_t x;
if (!a)
{
*(src) = 0;
return;
}
if (a == ~0)
return;
x = *(src);
UN16x4_MUL_UN16x4 (x, a);
*(src) = x;
}
static void
combine_mask_alpha_ca (const uint64_t *src, uint64_t *mask)
{
uint64_t a = *(mask);
uint64_t x;
if (!a)
return;
x = *(src) >> A_SHIFT;
if (x == MASK)
return;
if (a == ~0)
{
x |= x << G_SHIFT;
x |= x << R_SHIFT;
*(mask) = x;
return;
}
UN16x4_MUL_UN16 (a, x);
*(mask) = a;
}
/*
* There are two ways of handling alpha -- either as a single unified value or
* a separate value for each component, hence each macro must have two
* versions. The unified alpha version has a 'U' at the end of the name,
* the component version has a 'C'. Similarly, functions which deal with
* this difference will have two versions using the same convention.
*/
/*
* All of the composing functions
*/
static force_inline uint64_t
combine_mask (const uint64_t *src, const uint64_t *mask, int i)
{
uint64_t s, m;
if (mask)
{
m = *(mask + i) >> A_SHIFT;
if (!m)
return 0;
}
s = *(src + i);
if (mask)
UN16x4_MUL_UN16 (s, m);
return s;
}
static void
combine_clear (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
memset (dest, 0, width * sizeof(uint64_t));
}
static void
combine_dst (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
return;
}
static void
combine_src_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
if (!mask)
memcpy (dest, src, width * sizeof (uint64_t));
else
{
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
*(dest + i) = s;
}
}
}
/* if the Src is opaque, call combine_src_u */
static void
combine_over_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t ia = ALPHA_16 (~s);
UN16x4_MUL_UN16_ADD_UN16x4 (d, ia, s);
*(dest + i) = d;
}
}
/* if the Dst is opaque, this is a noop */
static void
combine_over_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t ia = ALPHA_16 (~*(dest + i));
UN16x4_MUL_UN16_ADD_UN16x4 (s, ia, d);
*(dest + i) = s;
}
}
/* if the Dst is opaque, call combine_src_u */
static void
combine_in_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t a = ALPHA_16 (*(dest + i));
UN16x4_MUL_UN16 (s, a);
*(dest + i) = s;
}
}
/* if the Src is opaque, this is a noop */
static void
combine_in_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t a = ALPHA_16 (s);
UN16x4_MUL_UN16 (d, a);
*(dest + i) = d;
}
}
/* if the Dst is opaque, call combine_clear */
static void
combine_out_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t a = ALPHA_16 (~*(dest + i));
UN16x4_MUL_UN16 (s, a);
*(dest + i) = s;
}
}
/* if the Src is opaque, call combine_clear */
static void
combine_out_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t a = ALPHA_16 (~s);
UN16x4_MUL_UN16 (d, a);
*(dest + i) = d;
}
}
/* if the Src is opaque, call combine_in_u */
/* if the Dst is opaque, call combine_over_u */
/* if both the Src and Dst are opaque, call combine_src_u */
static void
combine_atop_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t dest_a = ALPHA_16 (d);
uint64_t src_ia = ALPHA_16 (~s);
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (s, dest_a, d, src_ia);
*(dest + i) = s;
}
}
/* if the Src is opaque, call combine_over_reverse_u */
/* if the Dst is opaque, call combine_in_reverse_u */
/* if both the Src and Dst are opaque, call combine_dst_u */
static void
combine_atop_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t src_a = ALPHA_16 (s);
uint64_t dest_ia = ALPHA_16 (~d);
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (s, dest_ia, d, src_a);
*(dest + i) = s;
}
}
/* if the Src is opaque, call combine_over_u */
/* if the Dst is opaque, call combine_over_reverse_u */
/* if both the Src and Dst are opaque, call combine_clear */
static void
combine_xor_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t src_ia = ALPHA_16 (~s);
uint64_t dest_ia = ALPHA_16 (~d);
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (s, dest_ia, d, src_ia);
*(dest + i) = s;
}
}
static void
combine_add_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
UN16x4_ADD_UN16x4 (d, s);
*(dest + i) = d;
}
}
/* if the Src is opaque, call combine_add_u */
/* if the Dst is opaque, call combine_add_u */
/* if both the Src and Dst are opaque, call combine_add_u */
static void
combine_saturate_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint32_t sa, da;
sa = s >> A_SHIFT;
da = ~d >> A_SHIFT;
if (sa > da)
{
sa = DIV_UN16 (da, sa);
UN16x4_MUL_UN16 (s, sa);
}
;
UN16x4_ADD_UN16x4 (d, s);
*(dest + i) = d;
}
}
/*
* PDF blend modes:
* The following blend modes have been taken from the PDF ISO 32000
* specification, which at this point in time is available from
* http://www.adobe.com/devnet/acrobat/pdfs/PDF32000_2008.pdf
* The relevant chapters are 11.3.5 and 11.3.6.
* The formula for computing the final pixel color given in 11.3.6 is:
* αr × Cr = (1 αs) × αb × Cb + (1 αb) × αs × Cs + αb × αs × B(Cb, Cs)
* with B() being the blend function.
* Note that OVER is a special case of this operation, using B(Cb, Cs) = Cs
*
* These blend modes should match the SVG filter draft specification, as
* it has been designed to mirror ISO 32000. Note that at the current point
* no released draft exists that shows this, as the formulas have not been
* updated yet after the release of ISO 32000.
*
* The default implementation here uses the PDF_SEPARABLE_BLEND_MODE and
* PDF_NON_SEPARABLE_BLEND_MODE macros, which take the blend function as an
* argument. Note that this implementation operates on premultiplied colors,
* while the PDF specification does not. Therefore the code uses the formula
* Cra = (1 as) . Dca + (1 ad) . Sca + B(Dca, ad, Sca, as)
*/
/*
* Multiply
* B(Dca, ad, Sca, as) = Dca.Sca
*/
static void
combine_multiply_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t ss = s;
uint64_t src_ia = ALPHA_16 (~s);
uint64_t dest_ia = ALPHA_16 (~d);
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (ss, dest_ia, d, src_ia);
UN16x4_MUL_UN16x4 (d, s);
UN16x4_ADD_UN16x4 (d, ss);
*(dest + i) = d;
}
}
static void
combine_multiply_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t m = *(mask + i);
uint64_t s = *(src + i);
uint64_t d = *(dest + i);
uint64_t r = d;
uint64_t dest_ia = ALPHA_16 (~d);
combine_mask_value_ca (&s, &m);
UN16x4_MUL_UN16x4_ADD_UN16x4_MUL_UN16 (r, ~m, s, dest_ia);
UN16x4_MUL_UN16x4 (d, s);
UN16x4_ADD_UN16x4 (r, d);
*(dest + i) = r;
}
}
#define PDF_SEPARABLE_BLEND_MODE(name) \
static void \
combine_ ## name ## _u (pixman_implementation_t *imp, \
pixman_op_t op, \
uint64_t * dest, \
const uint64_t * src, \
const uint64_t * mask, \
int width) \
{ \
int i; \
for (i = 0; i < width; ++i) { \
uint64_t s = combine_mask (src, mask, i); \
uint64_t d = *(dest + i); \
uint16_t sa = ALPHA_16 (s); \
uint16_t isa = ~sa; \
uint16_t da = ALPHA_16 (d); \
uint16_t ida = ~da; \
uint64_t result; \
\
result = d; \
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (result, isa, s, ida); \
\
*(dest + i) = result + \
(DIV_ONE_UN16 (sa * (uint64_t)da) << A_SHIFT) + \
(blend_ ## name (RED_16 (d), da, RED_16 (s), sa) << R_SHIFT) + \
(blend_ ## name (GREEN_16 (d), da, GREEN_16 (s), sa) << G_SHIFT) + \
(blend_ ## name (BLUE_16 (d), da, BLUE_16 (s), sa)); \
} \
} \
\
static void \
combine_ ## name ## _ca (pixman_implementation_t *imp, \
pixman_op_t op, \
uint64_t * dest, \
const uint64_t * src, \
const uint64_t * mask, \
int width) \
{ \
int i; \
for (i = 0; i < width; ++i) { \
uint64_t m = *(mask + i); \
uint64_t s = *(src + i); \
uint64_t d = *(dest + i); \
uint16_t da = ALPHA_16 (d); \
uint16_t ida = ~da; \
uint64_t result; \
\
combine_mask_value_ca (&s, &m); \
\
result = d; \
UN16x4_MUL_UN16x4_ADD_UN16x4_MUL_UN16 (result, ~m, s, ida); \
\
result += \
(DIV_ONE_UN16 (ALPHA_16 (m) * (uint64_t)da) << A_SHIFT) + \
(blend_ ## name (RED_16 (d), da, RED_16 (s), RED_16 (m)) << R_SHIFT) + \
(blend_ ## name (GREEN_16 (d), da, GREEN_16 (s), GREEN_16 (m)) << G_SHIFT) + \
(blend_ ## name (BLUE_16 (d), da, BLUE_16 (s), BLUE_16 (m))); \
\
*(dest + i) = result; \
} \
}
/*
* Screen
* B(Dca, ad, Sca, as) = Dca.sa + Sca.da - Dca.Sca
*/
static inline uint64_t
blend_screen (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
return DIV_ONE_UN16 (sca * da + dca * sa - sca * dca);
}
PDF_SEPARABLE_BLEND_MODE (screen)
/*
* Overlay
* B(Dca, Da, Sca, Sa) =
* if 2.Dca < Da
* 2.Sca.Dca
* otherwise
* Sa.Da - 2.(Da - Dca).(Sa - Sca)
*/
static inline uint64_t
blend_overlay (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
uint64_t rca;
if (2 * dca < da)
rca = 2 * sca * dca;
else
rca = sa * da - 2 * (da - dca) * (sa - sca);
return DIV_ONE_UN16 (rca);
}
PDF_SEPARABLE_BLEND_MODE (overlay)
/*
* Darken
* B(Dca, Da, Sca, Sa) = min (Sca.Da, Dca.Sa)
*/
static inline uint64_t
blend_darken (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
uint64_t s, d;
s = sca * da;
d = dca * sa;
return DIV_ONE_UN16 (s > d ? d : s);
}
PDF_SEPARABLE_BLEND_MODE (darken)
/*
* Lighten
* B(Dca, Da, Sca, Sa) = max (Sca.Da, Dca.Sa)
*/
static inline uint64_t
blend_lighten (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
uint64_t s, d;
s = sca * da;
d = dca * sa;
return DIV_ONE_UN16 (s > d ? s : d);
}
PDF_SEPARABLE_BLEND_MODE (lighten)
/*
* Color dodge
* B(Dca, Da, Sca, Sa) =
* if Dca == 0
* 0
* if Sca == Sa
* Sa.Da
* otherwise
* Sa.Da. min (1, Dca / Da / (1 - Sca/Sa))
*/
static inline uint64_t
blend_color_dodge (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
if (sca >= sa)
{
return dca == 0 ? 0 : DIV_ONE_UN16 (sa * da);
}
else
{
uint64_t rca = dca * sa / (sa - sca);
return DIV_ONE_UN16 (sa * MIN (rca, da));
}
}
PDF_SEPARABLE_BLEND_MODE (color_dodge)
/*
* Color burn
* B(Dca, Da, Sca, Sa) =
* if Dca == Da
* Sa.Da
* if Sca == 0
* 0
* otherwise
* Sa.Da.(1 - min (1, (1 - Dca/Da).Sa / Sca))
*/
static inline uint64_t
blend_color_burn (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
if (sca == 0)
{
return dca < da ? 0 : DIV_ONE_UN16 (sa * da);
}
else
{
uint64_t rca = (da - dca) * sa / sca;
return DIV_ONE_UN16 (sa * (MAX (rca, da) - rca));
}
}
PDF_SEPARABLE_BLEND_MODE (color_burn)
/*
* Hard light
* B(Dca, Da, Sca, Sa) =
* if 2.Sca < Sa
* 2.Sca.Dca
* otherwise
* Sa.Da - 2.(Da - Dca).(Sa - Sca)
*/
static inline uint64_t
blend_hard_light (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
if (2 * sca < sa)
return DIV_ONE_UN16 (2 * sca * dca);
else
return DIV_ONE_UN16 (sa * da - 2 * (da - dca) * (sa - sca));
}
PDF_SEPARABLE_BLEND_MODE (hard_light)
/*
* Soft light
* B(Dca, Da, Sca, Sa) =
* if (2.Sca <= Sa)
* Dca.(Sa - (1 - Dca/Da).(2.Sca - Sa))
* otherwise if Dca.4 <= Da
* Dca.(Sa + (2.Sca - Sa).((16.Dca/Da - 12).Dca/Da + 3)
* otherwise
* (Dca.Sa + (SQRT (Dca/Da).Da - Dca).(2.Sca - Sa))
*/
static inline uint64_t
blend_soft_light (uint64_t dca_org,
uint64_t da_org,
uint64_t sca_org,
uint64_t sa_org)
{
double dca = dca_org * (1.0 / MASK);
double da = da_org * (1.0 / MASK);
double sca = sca_org * (1.0 / MASK);
double sa = sa_org * (1.0 / MASK);
double rca;
if (2 * sca < sa)
{
if (da == 0)
rca = dca * sa;
else
rca = dca * sa - dca * (da - dca) * (sa - 2 * sca) / da;
}
else if (da == 0)
{
rca = 0;
}
else if (4 * dca <= da)
{
rca = dca * sa +
(2 * sca - sa) * dca * ((16 * dca / da - 12) * dca / da + 3);
}
else
{
rca = dca * sa + (sqrt (dca * da) - dca) * (2 * sca - sa);
}
return rca * MASK + 0.5;
}
PDF_SEPARABLE_BLEND_MODE (soft_light)
/*
* Difference
* B(Dca, Da, Sca, Sa) = abs (Dca.Sa - Sca.Da)
*/
static inline uint64_t
blend_difference (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
uint64_t dcasa = dca * sa;
uint64_t scada = sca * da;
if (scada < dcasa)
return DIV_ONE_UN16 (dcasa - scada);
else
return DIV_ONE_UN16 (scada - dcasa);
}
PDF_SEPARABLE_BLEND_MODE (difference)
/*
* Exclusion
* B(Dca, Da, Sca, Sa) = (Sca.Da + Dca.Sa - 2.Sca.Dca)
*/
/* This can be made faster by writing it directly and not using
* PDF_SEPARABLE_BLEND_MODE, but that's a performance optimization */
static inline uint64_t
blend_exclusion (uint64_t dca, uint64_t da, uint64_t sca, uint64_t sa)
{
return DIV_ONE_UN16 (sca * da + dca * sa - 2 * dca * sca);
}
PDF_SEPARABLE_BLEND_MODE (exclusion)
#undef PDF_SEPARABLE_BLEND_MODE
/*
* PDF nonseperable blend modes are implemented using the following functions
* to operate in Hsl space, with Cmax, Cmid, Cmin referring to the max, mid
* and min value of the red, green and blue components.
*
* LUM (C) = 0.3 × Cred + 0.59 × Cgreen + 0.11 × Cblue
*
* clip_color (C):
* l = LUM (C)
* min = Cmin
* max = Cmax
* if n < 0.0
* C = l + ( ( ( C l ) × l ) ( l min ) )
* if x > 1.0
* C = l + ( ( ( C l ) × ( 1 l ) ) ( max l ) )
* return C
*
* set_lum (C, l):
* d = l LUM (C)
* C += d
* return clip_color (C)
*
* SAT (C) = CH_MAX (C) - CH_MIN (C)
*
* set_sat (C, s):
* if Cmax > Cmin
* Cmid = ( ( ( Cmid Cmin ) × s ) ( Cmax Cmin ) )
* Cmax = s
* else
* Cmid = Cmax = 0.0
* Cmin = 0.0
* return C
*/
/* For premultiplied colors, we need to know what happens when C is
* multiplied by a real number. LUM and SAT are linear:
*
* LUM (r × C) = r × LUM (C) SAT (r * C) = r * SAT (C)
*
* If we extend clip_color with an extra argument a and change
*
* if x >= 1.0
*
* into
*
* if x >= a
*
* then clip_color is also linear:
*
* r * clip_color (C, a) = clip_color (r_c, ra);
*
* for positive r.
*
* Similarly, we can extend set_lum with an extra argument that is just passed
* on to clip_color:
*
* r * set_lum ( C, l, a)
*
* = r × clip_color ( C + l - LUM (C), a)
*
* = clip_color ( r * C + r × l - r * LUM (C), r * a)
*
* = set_lum ( r * C, r * l, r * a)
*
* Finally, set_sat:
*
* r * set_sat (C, s) = set_sat (x * C, r * s)
*
* The above holds for all non-zero x, because the x'es in the fraction for
* C_mid cancel out. Specifically, it holds for x = r:
*
* r * set_sat (C, s) = set_sat (r_c, rs)
*
*/
/* So, for the non-separable PDF blend modes, we have (using s, d for
* non-premultiplied colors, and S, D for premultiplied:
*
* Color:
*
* a_s * a_d * B(s, d)
* = a_s * a_d * set_lum (S/a_s, LUM (D/a_d), 1)
* = set_lum (S * a_d, a_s * LUM (D), a_s * a_d)
*
*
* Luminosity:
*
* a_s * a_d * B(s, d)
* = a_s * a_d * set_lum (D/a_d, LUM(S/a_s), 1)
* = set_lum (a_s * D, a_d * LUM(S), a_s * a_d)
*
*
* Saturation:
*
* a_s * a_d * B(s, d)
* = a_s * a_d * set_lum (set_sat (D/a_d, SAT (S/a_s)), LUM (D/a_d), 1)
* = set_lum (a_s * a_d * set_sat (D/a_d, SAT (S/a_s)),
* a_s * LUM (D), a_s * a_d)
* = set_lum (set_sat (a_s * D, a_d * SAT (S), a_s * LUM (D), a_s * a_d))
*
* Hue:
*
* a_s * a_d * B(s, d)
* = a_s * a_d * set_lum (set_sat (S/a_s, SAT (D/a_d)), LUM (D/a_d), 1)
* = set_lum (set_sat (a_d * S, a_s * SAT (D)), a_s * LUM (D), a_s * a_d)
*
*/
#define CH_MIN(c) (c[0] < c[1] ? (c[0] < c[2] ? c[0] : c[2]) : (c[1] < c[2] ? c[1] : c[2]))
#define CH_MAX(c) (c[0] > c[1] ? (c[0] > c[2] ? c[0] : c[2]) : (c[1] > c[2] ? c[1] : c[2]))
#define LUM(c) ((c[0] * 30 + c[1] * 59 + c[2] * 11) / 100)
#define SAT(c) (CH_MAX (c) - CH_MIN (c))
#define PDF_NON_SEPARABLE_BLEND_MODE(name) \
static void \
combine_ ## name ## _u (pixman_implementation_t *imp, \
pixman_op_t op, \
uint64_t *dest, \
const uint64_t *src, \
const uint64_t *mask, \
int width) \
{ \
int i; \
for (i = 0; i < width; ++i) \
{ \
uint64_t s = combine_mask (src, mask, i); \
uint64_t d = *(dest + i); \
uint16_t sa = ALPHA_16 (s); \
uint16_t isa = ~sa; \
uint16_t da = ALPHA_16 (d); \
uint16_t ida = ~da; \
uint64_t result; \
uint64_t sc[3], dc[3], c[3]; \
\
result = d; \
UN16x4_MUL_UN16_ADD_UN16x4_MUL_UN16 (result, isa, s, ida); \
dc[0] = RED_16 (d); \
sc[0] = RED_16 (s); \
dc[1] = GREEN_16 (d); \
sc[1] = GREEN_16 (s); \
dc[2] = BLUE_16 (d); \
sc[2] = BLUE_16 (s); \
blend_ ## name (c, dc, da, sc, sa); \
\
*(dest + i) = result + \
(DIV_ONE_UN16 (sa * (uint64_t)da) << A_SHIFT) + \
(DIV_ONE_UN16 (c[0]) << R_SHIFT) + \
(DIV_ONE_UN16 (c[1]) << G_SHIFT) + \
(DIV_ONE_UN16 (c[2])); \
} \
}
static void
set_lum (uint64_t dest[3], uint64_t src[3], uint64_t sa, uint64_t lum)
{
double a, l, min, max;
double tmp[3];
a = sa * (1.0 / MASK);
l = lum * (1.0 / MASK);
tmp[0] = src[0] * (1.0 / MASK);
tmp[1] = src[1] * (1.0 / MASK);
tmp[2] = src[2] * (1.0 / MASK);
l = l - LUM (tmp);
tmp[0] += l;
tmp[1] += l;
tmp[2] += l;
/* clip_color */
l = LUM (tmp);
min = CH_MIN (tmp);
max = CH_MAX (tmp);
if (min < 0)
{
if (l - min == 0.0)
{
tmp[0] = 0;
tmp[1] = 0;
tmp[2] = 0;
}
else
{
tmp[0] = l + (tmp[0] - l) * l / (l - min);
tmp[1] = l + (tmp[1] - l) * l / (l - min);
tmp[2] = l + (tmp[2] - l) * l / (l - min);
}
}
if (max > a)
{
if (max - l == 0.0)
{
tmp[0] = a;
tmp[1] = a;
tmp[2] = a;
}
else
{
tmp[0] = l + (tmp[0] - l) * (a - l) / (max - l);
tmp[1] = l + (tmp[1] - l) * (a - l) / (max - l);
tmp[2] = l + (tmp[2] - l) * (a - l) / (max - l);
}
}
dest[0] = tmp[0] * MASK + 0.5;
dest[1] = tmp[1] * MASK + 0.5;
dest[2] = tmp[2] * MASK + 0.5;
}
static void
set_sat (uint64_t dest[3], uint64_t src[3], uint64_t sat)
{
int id[3];
uint64_t min, max;
if (src[0] > src[1])
{
if (src[0] > src[2])
{
id[0] = 0;
if (src[1] > src[2])
{
id[1] = 1;
id[2] = 2;
}
else
{
id[1] = 2;
id[2] = 1;
}
}
else
{
id[0] = 2;
id[1] = 0;
id[2] = 1;
}
}
else
{
if (src[0] > src[2])
{
id[0] = 1;
id[1] = 0;
id[2] = 2;
}
else
{
id[2] = 0;
if (src[1] > src[2])
{
id[0] = 1;
id[1] = 2;
}
else
{
id[0] = 2;
id[1] = 1;
}
}
}
max = dest[id[0]];
min = dest[id[2]];
if (max > min)
{
dest[id[1]] = (dest[id[1]] - min) * sat / (max - min);
dest[id[0]] = sat;
dest[id[2]] = 0;
}
else
{
dest[0] = dest[1] = dest[2] = 0;
}
}
/*
* Hue:
* B(Cb, Cs) = set_lum (set_sat (Cs, SAT (Cb)), LUM (Cb))
*/
static inline void
blend_hsl_hue (uint64_t c[3],
uint64_t dc[3],
uint64_t da,
uint64_t sc[3],
uint64_t sa)
{
c[0] = sc[0] * da;
c[1] = sc[1] * da;
c[2] = sc[2] * da;
set_sat (c, c, SAT (dc) * sa);
set_lum (c, c, sa * da, LUM (dc) * sa);
}
PDF_NON_SEPARABLE_BLEND_MODE (hsl_hue)
/*
* Saturation:
* B(Cb, Cs) = set_lum (set_sat (Cb, SAT (Cs)), LUM (Cb))
*/
static inline void
blend_hsl_saturation (uint64_t c[3],
uint64_t dc[3],
uint64_t da,
uint64_t sc[3],
uint64_t sa)
{
c[0] = dc[0] * sa;
c[1] = dc[1] * sa;
c[2] = dc[2] * sa;
set_sat (c, c, SAT (sc) * da);
set_lum (c, c, sa * da, LUM (dc) * sa);
}
PDF_NON_SEPARABLE_BLEND_MODE (hsl_saturation)
/*
* Color:
* B(Cb, Cs) = set_lum (Cs, LUM (Cb))
*/
static inline void
blend_hsl_color (uint64_t c[3],
uint64_t dc[3],
uint64_t da,
uint64_t sc[3],
uint64_t sa)
{
c[0] = sc[0] * da;
c[1] = sc[1] * da;
c[2] = sc[2] * da;
set_lum (c, c, sa * da, LUM (dc) * sa);
}
PDF_NON_SEPARABLE_BLEND_MODE (hsl_color)
/*
* Luminosity:
* B(Cb, Cs) = set_lum (Cb, LUM (Cs))
*/
static inline void
blend_hsl_luminosity (uint64_t c[3],
uint64_t dc[3],
uint64_t da,
uint64_t sc[3],
uint64_t sa)
{
c[0] = dc[0] * sa;
c[1] = dc[1] * sa;
c[2] = dc[2] * sa;
set_lum (c, c, sa * da, LUM (sc) * da);
}
PDF_NON_SEPARABLE_BLEND_MODE (hsl_luminosity)
#undef SAT
#undef LUM
#undef CH_MAX
#undef CH_MIN
#undef PDF_NON_SEPARABLE_BLEND_MODE
/* All of the disjoint/conjoint composing functions
*
* The four entries in the first column indicate what source contributions
* come from each of the four areas of the picture -- areas covered by neither
* A nor B, areas covered only by A, areas covered only by B and finally
* areas covered by both A and B.
*
* Disjoint Conjoint
* Fa Fb Fa Fb
* (0,0,0,0) 0 0 0 0
* (0,A,0,A) 1 0 1 0
* (0,0,B,B) 0 1 0 1
* (0,A,B,A) 1 min((1-a)/b,1) 1 max(1-a/b,0)
* (0,A,B,B) min((1-b)/a,1) 1 max(1-b/a,0) 1
* (0,0,0,A) max(1-(1-b)/a,0) 0 min(1,b/a) 0
* (0,0,0,B) 0 max(1-(1-a)/b,0) 0 min(a/b,1)
* (0,A,0,0) min(1,(1-b)/a) 0 max(1-b/a,0) 0
* (0,0,B,0) 0 min(1,(1-a)/b) 0 max(1-a/b,0)
* (0,0,B,A) max(1-(1-b)/a,0) min(1,(1-a)/b) min(1,b/a) max(1-a/b,0)
* (0,A,0,B) min(1,(1-b)/a) max(1-(1-a)/b,0) max(1-b/a,0) min(1,a/b)
* (0,A,B,0) min(1,(1-b)/a) min(1,(1-a)/b) max(1-b/a,0) max(1-a/b,0)
*
* See http://marc.info/?l=xfree-render&m=99792000027857&w=2 for more
* information about these operators.
*/
#define COMBINE_A_OUT 1
#define COMBINE_A_IN 2
#define COMBINE_B_OUT 4
#define COMBINE_B_IN 8
#define COMBINE_CLEAR 0
#define COMBINE_A (COMBINE_A_OUT | COMBINE_A_IN)
#define COMBINE_B (COMBINE_B_OUT | COMBINE_B_IN)
#define COMBINE_A_OVER (COMBINE_A_OUT | COMBINE_B_OUT | COMBINE_A_IN)
#define COMBINE_B_OVER (COMBINE_A_OUT | COMBINE_B_OUT | COMBINE_B_IN)
#define COMBINE_A_ATOP (COMBINE_B_OUT | COMBINE_A_IN)
#define COMBINE_B_ATOP (COMBINE_A_OUT | COMBINE_B_IN)
#define COMBINE_XOR (COMBINE_A_OUT | COMBINE_B_OUT)
/* portion covered by a but not b */
static uint16_t
combine_disjoint_out_part (uint16_t a, uint16_t b)
{
/* min (1, (1-b) / a) */
b = ~b; /* 1 - b */
if (b >= a) /* 1 - b >= a -> (1-b)/a >= 1 */
return MASK; /* 1 */
return DIV_UN16 (b, a); /* (1-b) / a */
}
/* portion covered by both a and b */
static uint16_t
combine_disjoint_in_part (uint16_t a, uint16_t b)
{
/* max (1-(1-b)/a,0) */
/* = - min ((1-b)/a - 1, 0) */
/* = 1 - min (1, (1-b)/a) */
b = ~b; /* 1 - b */
if (b >= a) /* 1 - b >= a -> (1-b)/a >= 1 */
return 0; /* 1 - 1 */
return ~DIV_UN16(b, a); /* 1 - (1-b) / a */
}
/* portion covered by a but not b */
static uint16_t
combine_conjoint_out_part (uint16_t a, uint16_t b)
{
/* max (1-b/a,0) */
/* = 1-min(b/a,1) */
/* min (1, (1-b) / a) */
if (b >= a) /* b >= a -> b/a >= 1 */
return 0x00; /* 0 */
return ~DIV_UN16(b, a); /* 1 - b/a */
}
/* portion covered by both a and b */
static uint16_t
combine_conjoint_in_part (uint16_t a, uint16_t b)
{
/* min (1,b/a) */
if (b >= a) /* b >= a -> b/a >= 1 */
return MASK; /* 1 */
return DIV_UN16 (b, a); /* b/a */
}
#define GET_COMP(v, i) ((uint32_t) (uint16_t) ((v) >> i))
#define ADD(x, y, i, t) \
((t) = GET_COMP (x, i) + GET_COMP (y, i), \
(uint64_t) ((uint16_t) ((t) | (0 - ((t) >> G_SHIFT)))) << (i))
#define GENERIC(x, y, i, ax, ay, t, u, v) \
((t) = (MUL_UN16 (GET_COMP (y, i), ay, (u)) + \
MUL_UN16 (GET_COMP (x, i), ax, (v))), \
(uint64_t) ((uint16_t) ((t) | \
(0 - ((t) >> G_SHIFT)))) << (i))
static void
combine_disjoint_general_u (uint64_t * dest,
const uint64_t *src,
const uint64_t *mask,
int width,
uint16_t combine)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t m, n, o, p;
uint32_t Fa, Fb, t, u, v;
uint16_t sa = s >> A_SHIFT;
uint16_t da = d >> A_SHIFT;
switch (combine & COMBINE_A)
{
default:
Fa = 0;
break;
case COMBINE_A_OUT:
Fa = combine_disjoint_out_part (sa, da);
break;
case COMBINE_A_IN:
Fa = combine_disjoint_in_part (sa, da);
break;
case COMBINE_A:
Fa = MASK;
break;
}
switch (combine & COMBINE_B)
{
default:
Fb = 0;
break;
case COMBINE_B_OUT:
Fb = combine_disjoint_out_part (da, sa);
break;
case COMBINE_B_IN:
Fb = combine_disjoint_in_part (da, sa);
break;
case COMBINE_B:
Fb = MASK;
break;
}
m = GENERIC (s, d, 0, Fa, Fb, t, u, v);
n = GENERIC (s, d, G_SHIFT, Fa, Fb, t, u, v);
o = GENERIC (s, d, R_SHIFT, Fa, Fb, t, u, v);
p = GENERIC (s, d, A_SHIFT, Fa, Fb, t, u, v);
s = m | n | o | p;
*(dest + i) = s;
}
}
static void
combine_disjoint_over_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint32_t a = s >> A_SHIFT;
if (s != 0x00)
{
uint64_t d = *(dest + i);
a = combine_disjoint_out_part (d >> A_SHIFT, a);
UN16x4_MUL_UN16_ADD_UN16x4 (d, a, s);
*(dest + i) = d;
}
}
}
static void
combine_disjoint_in_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_A_IN);
}
static void
combine_disjoint_in_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_B_IN);
}
static void
combine_disjoint_out_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_A_OUT);
}
static void
combine_disjoint_out_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_B_OUT);
}
static void
combine_disjoint_atop_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_A_ATOP);
}
static void
combine_disjoint_atop_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_B_ATOP);
}
static void
combine_disjoint_xor_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_u (dest, src, mask, width, COMBINE_XOR);
}
static void
combine_conjoint_general_u (uint64_t * dest,
const uint64_t *src,
const uint64_t *mask,
int width,
uint16_t combine)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = combine_mask (src, mask, i);
uint64_t d = *(dest + i);
uint64_t m, n, o, p;
uint32_t Fa, Fb, t, u, v;
uint16_t sa = s >> A_SHIFT;
uint16_t da = d >> A_SHIFT;
switch (combine & COMBINE_A)
{
default:
Fa = 0;
break;
case COMBINE_A_OUT:
Fa = combine_conjoint_out_part (sa, da);
break;
case COMBINE_A_IN:
Fa = combine_conjoint_in_part (sa, da);
break;
case COMBINE_A:
Fa = MASK;
break;
}
switch (combine & COMBINE_B)
{
default:
Fb = 0;
break;
case COMBINE_B_OUT:
Fb = combine_conjoint_out_part (da, sa);
break;
case COMBINE_B_IN:
Fb = combine_conjoint_in_part (da, sa);
break;
case COMBINE_B:
Fb = MASK;
break;
}
m = GENERIC (s, d, 0, Fa, Fb, t, u, v);
n = GENERIC (s, d, G_SHIFT, Fa, Fb, t, u, v);
o = GENERIC (s, d, R_SHIFT, Fa, Fb, t, u, v);
p = GENERIC (s, d, A_SHIFT, Fa, Fb, t, u, v);
s = m | n | o | p;
*(dest + i) = s;
}
}
static void
combine_conjoint_over_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_A_OVER);
}
static void
combine_conjoint_over_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_B_OVER);
}
static void
combine_conjoint_in_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_A_IN);
}
static void
combine_conjoint_in_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_B_IN);
}
static void
combine_conjoint_out_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_A_OUT);
}
static void
combine_conjoint_out_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_B_OUT);
}
static void
combine_conjoint_atop_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_A_ATOP);
}
static void
combine_conjoint_atop_reverse_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_B_ATOP);
}
static void
combine_conjoint_xor_u (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_u (dest, src, mask, width, COMBINE_XOR);
}
/************************************************************************/
/*********************** Per Channel functions **************************/
/************************************************************************/
static void
combine_clear_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
memset (dest, 0, width * sizeof(uint64_t));
}
static void
combine_src_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
combine_mask_value_ca (&s, &m);
*(dest + i) = s;
}
}
static void
combine_over_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t a;
combine_mask_ca (&s, &m);
a = ~m;
if (a)
{
uint64_t d = *(dest + i);
UN16x4_MUL_UN16x4_ADD_UN16x4 (d, a, s);
s = d;
}
*(dest + i) = s;
}
}
static void
combine_over_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint64_t a = ~d >> A_SHIFT;
if (a)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
UN16x4_MUL_UN16x4 (s, m);
UN16x4_MUL_UN16_ADD_UN16x4 (s, a, d);
*(dest + i) = s;
}
}
}
static void
combine_in_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint32_t a = d >> A_SHIFT;
uint64_t s = 0;
if (a)
{
uint64_t m = *(mask + i);
s = *(src + i);
combine_mask_value_ca (&s, &m);
if (a != MASK)
UN16x4_MUL_UN16 (s, a);
}
*(dest + i) = s;
}
}
static void
combine_in_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t a;
combine_mask_alpha_ca (&s, &m);
a = m;
if (a != ~0)
{
uint64_t d = 0;
if (a)
{
d = *(dest + i);
UN16x4_MUL_UN16x4 (d, a);
}
*(dest + i) = d;
}
}
}
static void
combine_out_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint32_t a = ~d >> A_SHIFT;
uint64_t s = 0;
if (a)
{
uint64_t m = *(mask + i);
s = *(src + i);
combine_mask_value_ca (&s, &m);
if (a != MASK)
UN16x4_MUL_UN16 (s, a);
}
*(dest + i) = s;
}
}
static void
combine_out_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t a;
combine_mask_alpha_ca (&s, &m);
a = ~m;
if (a != ~0)
{
uint64_t d = 0;
if (a)
{
d = *(dest + i);
UN16x4_MUL_UN16x4 (d, a);
}
*(dest + i) = d;
}
}
}
static void
combine_atop_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t ad;
uint32_t as = d >> A_SHIFT;
combine_mask_ca (&s, &m);
ad = ~m;
UN16x4_MUL_UN16x4_ADD_UN16x4_MUL_UN16 (d, ad, s, as);
*(dest + i) = d;
}
}
static void
combine_atop_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t ad;
uint32_t as = ~d >> A_SHIFT;
combine_mask_ca (&s, &m);
ad = m;
UN16x4_MUL_UN16x4_ADD_UN16x4_MUL_UN16 (d, ad, s, as);
*(dest + i) = d;
}
}
static void
combine_xor_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t d = *(dest + i);
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t ad;
uint32_t as = ~d >> A_SHIFT;
combine_mask_ca (&s, &m);
ad = ~m;
UN16x4_MUL_UN16x4_ADD_UN16x4_MUL_UN16 (d, ad, s, as);
*(dest + i) = d;
}
}
static void
combine_add_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s = *(src + i);
uint64_t m = *(mask + i);
uint64_t d = *(dest + i);
combine_mask_value_ca (&s, &m);
UN16x4_ADD_UN16x4 (d, s);
*(dest + i) = d;
}
}
static void
combine_saturate_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s, d;
uint32_t sa, sr, sg, sb, da;
uint32_t t, u, v;
uint64_t m, n, o, p;
d = *(dest + i);
s = *(src + i);
m = *(mask + i);
combine_mask_ca (&s, &m);
sa = (m >> A_SHIFT);
sr = (m >> R_SHIFT) & MASK;
sg = (m >> G_SHIFT) & MASK;
sb = m & MASK;
da = ~d >> A_SHIFT;
if (sb <= da)
m = ADD (s, d, 0, t);
else
m = GENERIC (s, d, 0, (da << G_SHIFT) / sb, MASK, t, u, v);
if (sg <= da)
n = ADD (s, d, G_SHIFT, t);
else
n = GENERIC (s, d, G_SHIFT, (da << G_SHIFT) / sg, MASK, t, u, v);
if (sr <= da)
o = ADD (s, d, R_SHIFT, t);
else
o = GENERIC (s, d, R_SHIFT, (da << G_SHIFT) / sr, MASK, t, u, v);
if (sa <= da)
p = ADD (s, d, A_SHIFT, t);
else
p = GENERIC (s, d, A_SHIFT, (da << G_SHIFT) / sa, MASK, t, u, v);
*(dest + i) = m | n | o | p;
}
}
static void
combine_disjoint_general_ca (uint64_t * dest,
const uint64_t *src,
const uint64_t *mask,
int width,
uint16_t combine)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s, d;
uint64_t m, n, o, p;
uint64_t Fa, Fb;
uint32_t t, u, v;
uint64_t sa;
uint16_t da;
s = *(src + i);
m = *(mask + i);
d = *(dest + i);
da = d >> A_SHIFT;
combine_mask_ca (&s, &m);
sa = m;
switch (combine & COMBINE_A)
{
default:
Fa = 0;
break;
case COMBINE_A_OUT:
m = (uint64_t)combine_disjoint_out_part ((uint16_t) (sa >> 0), da);
n = (uint64_t)combine_disjoint_out_part ((uint16_t) (sa >> G_SHIFT), da) << G_SHIFT;
o = (uint64_t)combine_disjoint_out_part ((uint16_t) (sa >> R_SHIFT), da) << R_SHIFT;
p = (uint64_t)combine_disjoint_out_part ((uint16_t) (sa >> A_SHIFT), da) << A_SHIFT;
Fa = m | n | o | p;
break;
case COMBINE_A_IN:
m = (uint64_t)combine_disjoint_in_part ((uint16_t) (sa >> 0), da);
n = (uint64_t)combine_disjoint_in_part ((uint16_t) (sa >> G_SHIFT), da) << G_SHIFT;
o = (uint64_t)combine_disjoint_in_part ((uint16_t) (sa >> R_SHIFT), da) << R_SHIFT;
p = (uint64_t)combine_disjoint_in_part ((uint16_t) (sa >> A_SHIFT), da) << A_SHIFT;
Fa = m | n | o | p;
break;
case COMBINE_A:
Fa = ~0;
break;
}
switch (combine & COMBINE_B)
{
default:
Fb = 0;
break;
case COMBINE_B_OUT:
m = (uint64_t)combine_disjoint_out_part (da, (uint16_t) (sa >> 0));
n = (uint64_t)combine_disjoint_out_part (da, (uint16_t) (sa >> G_SHIFT)) << G_SHIFT;
o = (uint64_t)combine_disjoint_out_part (da, (uint16_t) (sa >> R_SHIFT)) << R_SHIFT;
p = (uint64_t)combine_disjoint_out_part (da, (uint16_t) (sa >> A_SHIFT)) << A_SHIFT;
Fb = m | n | o | p;
break;
case COMBINE_B_IN:
m = (uint64_t)combine_disjoint_in_part (da, (uint16_t) (sa >> 0));
n = (uint64_t)combine_disjoint_in_part (da, (uint16_t) (sa >> G_SHIFT)) << G_SHIFT;
o = (uint64_t)combine_disjoint_in_part (da, (uint16_t) (sa >> R_SHIFT)) << R_SHIFT;
p = (uint64_t)combine_disjoint_in_part (da, (uint16_t) (sa >> A_SHIFT)) << A_SHIFT;
Fb = m | n | o | p;
break;
case COMBINE_B:
Fb = ~0;
break;
}
m = GENERIC (s, d, 0, GET_COMP (Fa, 0), GET_COMP (Fb, 0), t, u, v);
n = GENERIC (s, d, G_SHIFT, GET_COMP (Fa, G_SHIFT), GET_COMP (Fb, G_SHIFT), t, u, v);
o = GENERIC (s, d, R_SHIFT, GET_COMP (Fa, R_SHIFT), GET_COMP (Fb, R_SHIFT), t, u, v);
p = GENERIC (s, d, A_SHIFT, GET_COMP (Fa, A_SHIFT), GET_COMP (Fb, A_SHIFT), t, u, v);
s = m | n | o | p;
*(dest + i) = s;
}
}
static void
combine_disjoint_over_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_A_OVER);
}
static void
combine_disjoint_in_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_A_IN);
}
static void
combine_disjoint_in_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_B_IN);
}
static void
combine_disjoint_out_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_A_OUT);
}
static void
combine_disjoint_out_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_B_OUT);
}
static void
combine_disjoint_atop_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_A_ATOP);
}
static void
combine_disjoint_atop_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_B_ATOP);
}
static void
combine_disjoint_xor_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_disjoint_general_ca (dest, src, mask, width, COMBINE_XOR);
}
static void
combine_conjoint_general_ca (uint64_t * dest,
const uint64_t *src,
const uint64_t *mask,
int width,
uint16_t combine)
{
int i;
for (i = 0; i < width; ++i)
{
uint64_t s, d;
uint64_t m, n, o, p;
uint64_t Fa, Fb;
uint32_t t, u, v;
uint64_t sa;
uint16_t da;
s = *(src + i);
m = *(mask + i);
d = *(dest + i);
da = d >> A_SHIFT;
combine_mask_ca (&s, &m);
sa = m;
switch (combine & COMBINE_A)
{
default:
Fa = 0;
break;
case COMBINE_A_OUT:
m = (uint64_t)combine_conjoint_out_part ((uint16_t) (sa >> 0), da);
n = (uint64_t)combine_conjoint_out_part ((uint16_t) (sa >> G_SHIFT), da) << G_SHIFT;
o = (uint64_t)combine_conjoint_out_part ((uint16_t) (sa >> R_SHIFT), da) << R_SHIFT;
p = (uint64_t)combine_conjoint_out_part ((uint16_t) (sa >> A_SHIFT), da) << A_SHIFT;
Fa = m | n | o | p;
break;
case COMBINE_A_IN:
m = (uint64_t)combine_conjoint_in_part ((uint16_t) (sa >> 0), da);
n = (uint64_t)combine_conjoint_in_part ((uint16_t) (sa >> G_SHIFT), da) << G_SHIFT;
o = (uint64_t)combine_conjoint_in_part ((uint16_t) (sa >> R_SHIFT), da) << R_SHIFT;
p = (uint64_t)combine_conjoint_in_part ((uint16_t) (sa >> A_SHIFT), da) << A_SHIFT;
Fa = m | n | o | p;
break;
case COMBINE_A:
Fa = ~0;
break;
}
switch (combine & COMBINE_B)
{
default:
Fb = 0;
break;
case COMBINE_B_OUT:
m = (uint64_t)combine_conjoint_out_part (da, (uint16_t) (sa >> 0));
n = (uint64_t)combine_conjoint_out_part (da, (uint16_t) (sa >> G_SHIFT)) << G_SHIFT;
o = (uint64_t)combine_conjoint_out_part (da, (uint16_t) (sa >> R_SHIFT)) << R_SHIFT;
p = (uint64_t)combine_conjoint_out_part (da, (uint16_t) (sa >> A_SHIFT)) << A_SHIFT;
Fb = m | n | o | p;
break;
case COMBINE_B_IN:
m = (uint64_t)combine_conjoint_in_part (da, (uint16_t) (sa >> 0));
n = (uint64_t)combine_conjoint_in_part (da, (uint16_t) (sa >> G_SHIFT)) << G_SHIFT;
o = (uint64_t)combine_conjoint_in_part (da, (uint16_t) (sa >> R_SHIFT)) << R_SHIFT;
p = (uint64_t)combine_conjoint_in_part (da, (uint16_t) (sa >> A_SHIFT)) << A_SHIFT;
Fb = m | n | o | p;
break;
case COMBINE_B:
Fb = ~0;
break;
}
m = GENERIC (s, d, 0, GET_COMP (Fa, 0), GET_COMP (Fb, 0), t, u, v);
n = GENERIC (s, d, G_SHIFT, GET_COMP (Fa, G_SHIFT), GET_COMP (Fb, G_SHIFT), t, u, v);
o = GENERIC (s, d, R_SHIFT, GET_COMP (Fa, R_SHIFT), GET_COMP (Fb, R_SHIFT), t, u, v);
p = GENERIC (s, d, A_SHIFT, GET_COMP (Fa, A_SHIFT), GET_COMP (Fb, A_SHIFT), t, u, v);
s = m | n | o | p;
*(dest + i) = s;
}
}
static void
combine_conjoint_over_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_A_OVER);
}
static void
combine_conjoint_over_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_B_OVER);
}
static void
combine_conjoint_in_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_A_IN);
}
static void
combine_conjoint_in_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_B_IN);
}
static void
combine_conjoint_out_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_A_OUT);
}
static void
combine_conjoint_out_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_B_OUT);
}
static void
combine_conjoint_atop_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_A_ATOP);
}
static void
combine_conjoint_atop_reverse_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_B_ATOP);
}
static void
combine_conjoint_xor_ca (pixman_implementation_t *imp,
pixman_op_t op,
uint64_t * dest,
const uint64_t * src,
const uint64_t * mask,
int width)
{
combine_conjoint_general_ca (dest, src, mask, width, COMBINE_XOR);
}
void
_pixman_setup_combiner_functions_64 (pixman_implementation_t *imp)
{
/* Unified alpha */
imp->combine_64[PIXMAN_OP_CLEAR] = combine_clear;
imp->combine_64[PIXMAN_OP_SRC] = combine_src_u;
imp->combine_64[PIXMAN_OP_DST] = combine_dst;
imp->combine_64[PIXMAN_OP_OVER] = combine_over_u;
imp->combine_64[PIXMAN_OP_OVER_REVERSE] = combine_over_reverse_u;
imp->combine_64[PIXMAN_OP_IN] = combine_in_u;
imp->combine_64[PIXMAN_OP_IN_REVERSE] = combine_in_reverse_u;
imp->combine_64[PIXMAN_OP_OUT] = combine_out_u;
imp->combine_64[PIXMAN_OP_OUT_REVERSE] = combine_out_reverse_u;
imp->combine_64[PIXMAN_OP_ATOP] = combine_atop_u;
imp->combine_64[PIXMAN_OP_ATOP_REVERSE] = combine_atop_reverse_u;
imp->combine_64[PIXMAN_OP_XOR] = combine_xor_u;
imp->combine_64[PIXMAN_OP_ADD] = combine_add_u;
imp->combine_64[PIXMAN_OP_SATURATE] = combine_saturate_u;
/* Disjoint, unified */
imp->combine_64[PIXMAN_OP_DISJOINT_CLEAR] = combine_clear;
imp->combine_64[PIXMAN_OP_DISJOINT_SRC] = combine_src_u;
imp->combine_64[PIXMAN_OP_DISJOINT_DST] = combine_dst;
imp->combine_64[PIXMAN_OP_DISJOINT_OVER] = combine_disjoint_over_u;
imp->combine_64[PIXMAN_OP_DISJOINT_OVER_REVERSE] = combine_saturate_u;
imp->combine_64[PIXMAN_OP_DISJOINT_IN] = combine_disjoint_in_u;
imp->combine_64[PIXMAN_OP_DISJOINT_IN_REVERSE] = combine_disjoint_in_reverse_u;
imp->combine_64[PIXMAN_OP_DISJOINT_OUT] = combine_disjoint_out_u;
imp->combine_64[PIXMAN_OP_DISJOINT_OUT_REVERSE] = combine_disjoint_out_reverse_u;
imp->combine_64[PIXMAN_OP_DISJOINT_ATOP] = combine_disjoint_atop_u;
imp->combine_64[PIXMAN_OP_DISJOINT_ATOP_REVERSE] = combine_disjoint_atop_reverse_u;
imp->combine_64[PIXMAN_OP_DISJOINT_XOR] = combine_disjoint_xor_u;
/* Conjoint, unified */
imp->combine_64[PIXMAN_OP_CONJOINT_CLEAR] = combine_clear;
imp->combine_64[PIXMAN_OP_CONJOINT_SRC] = combine_src_u;
imp->combine_64[PIXMAN_OP_CONJOINT_DST] = combine_dst;
imp->combine_64[PIXMAN_OP_CONJOINT_OVER] = combine_conjoint_over_u;
imp->combine_64[PIXMAN_OP_CONJOINT_OVER_REVERSE] = combine_conjoint_over_reverse_u;
imp->combine_64[PIXMAN_OP_CONJOINT_IN] = combine_conjoint_in_u;
imp->combine_64[PIXMAN_OP_CONJOINT_IN_REVERSE] = combine_conjoint_in_reverse_u;
imp->combine_64[PIXMAN_OP_CONJOINT_OUT] = combine_conjoint_out_u;
imp->combine_64[PIXMAN_OP_CONJOINT_OUT_REVERSE] = combine_conjoint_out_reverse_u;
imp->combine_64[PIXMAN_OP_CONJOINT_ATOP] = combine_conjoint_atop_u;
imp->combine_64[PIXMAN_OP_CONJOINT_ATOP_REVERSE] = combine_conjoint_atop_reverse_u;
imp->combine_64[PIXMAN_OP_CONJOINT_XOR] = combine_conjoint_xor_u;
imp->combine_64[PIXMAN_OP_MULTIPLY] = combine_multiply_u;
imp->combine_64[PIXMAN_OP_SCREEN] = combine_screen_u;
imp->combine_64[PIXMAN_OP_OVERLAY] = combine_overlay_u;
imp->combine_64[PIXMAN_OP_DARKEN] = combine_darken_u;
imp->combine_64[PIXMAN_OP_LIGHTEN] = combine_lighten_u;
imp->combine_64[PIXMAN_OP_COLOR_DODGE] = combine_color_dodge_u;
imp->combine_64[PIXMAN_OP_COLOR_BURN] = combine_color_burn_u;
imp->combine_64[PIXMAN_OP_HARD_LIGHT] = combine_hard_light_u;
imp->combine_64[PIXMAN_OP_SOFT_LIGHT] = combine_soft_light_u;
imp->combine_64[PIXMAN_OP_DIFFERENCE] = combine_difference_u;
imp->combine_64[PIXMAN_OP_EXCLUSION] = combine_exclusion_u;
imp->combine_64[PIXMAN_OP_HSL_HUE] = combine_hsl_hue_u;
imp->combine_64[PIXMAN_OP_HSL_SATURATION] = combine_hsl_saturation_u;
imp->combine_64[PIXMAN_OP_HSL_COLOR] = combine_hsl_color_u;
imp->combine_64[PIXMAN_OP_HSL_LUMINOSITY] = combine_hsl_luminosity_u;
/* Component alpha combiners */
imp->combine_64_ca[PIXMAN_OP_CLEAR] = combine_clear_ca;
imp->combine_64_ca[PIXMAN_OP_SRC] = combine_src_ca;
/* dest */
imp->combine_64_ca[PIXMAN_OP_OVER] = combine_over_ca;
imp->combine_64_ca[PIXMAN_OP_OVER_REVERSE] = combine_over_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_IN] = combine_in_ca;
imp->combine_64_ca[PIXMAN_OP_IN_REVERSE] = combine_in_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_OUT] = combine_out_ca;
imp->combine_64_ca[PIXMAN_OP_OUT_REVERSE] = combine_out_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_ATOP] = combine_atop_ca;
imp->combine_64_ca[PIXMAN_OP_ATOP_REVERSE] = combine_atop_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_XOR] = combine_xor_ca;
imp->combine_64_ca[PIXMAN_OP_ADD] = combine_add_ca;
imp->combine_64_ca[PIXMAN_OP_SATURATE] = combine_saturate_ca;
/* Disjoint CA */
imp->combine_64_ca[PIXMAN_OP_DISJOINT_CLEAR] = combine_clear_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_SRC] = combine_src_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_DST] = combine_dst;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_OVER] = combine_disjoint_over_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_OVER_REVERSE] = combine_saturate_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_IN] = combine_disjoint_in_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_IN_REVERSE] = combine_disjoint_in_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_OUT] = combine_disjoint_out_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_OUT_REVERSE] = combine_disjoint_out_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_ATOP] = combine_disjoint_atop_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_ATOP_REVERSE] = combine_disjoint_atop_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_DISJOINT_XOR] = combine_disjoint_xor_ca;
/* Conjoint CA */
imp->combine_64_ca[PIXMAN_OP_CONJOINT_CLEAR] = combine_clear_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_SRC] = combine_src_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_DST] = combine_dst;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_OVER] = combine_conjoint_over_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_OVER_REVERSE] = combine_conjoint_over_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_IN] = combine_conjoint_in_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_IN_REVERSE] = combine_conjoint_in_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_OUT] = combine_conjoint_out_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_OUT_REVERSE] = combine_conjoint_out_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_ATOP] = combine_conjoint_atop_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_ATOP_REVERSE] = combine_conjoint_atop_reverse_ca;
imp->combine_64_ca[PIXMAN_OP_CONJOINT_XOR] = combine_conjoint_xor_ca;
imp->combine_64_ca[PIXMAN_OP_MULTIPLY] = combine_multiply_ca;
imp->combine_64_ca[PIXMAN_OP_SCREEN] = combine_screen_ca;
imp->combine_64_ca[PIXMAN_OP_OVERLAY] = combine_overlay_ca;
imp->combine_64_ca[PIXMAN_OP_DARKEN] = combine_darken_ca;
imp->combine_64_ca[PIXMAN_OP_LIGHTEN] = combine_lighten_ca;
imp->combine_64_ca[PIXMAN_OP_COLOR_DODGE] = combine_color_dodge_ca;
imp->combine_64_ca[PIXMAN_OP_COLOR_BURN] = combine_color_burn_ca;
imp->combine_64_ca[PIXMAN_OP_HARD_LIGHT] = combine_hard_light_ca;
imp->combine_64_ca[PIXMAN_OP_SOFT_LIGHT] = combine_soft_light_ca;
imp->combine_64_ca[PIXMAN_OP_DIFFERENCE] = combine_difference_ca;
imp->combine_64_ca[PIXMAN_OP_EXCLUSION] = combine_exclusion_ca;
/* It is not clear that these make sense, so make them noops for now */
imp->combine_64_ca[PIXMAN_OP_HSL_HUE] = combine_dst;
imp->combine_64_ca[PIXMAN_OP_HSL_SATURATION] = combine_dst;
imp->combine_64_ca[PIXMAN_OP_HSL_COLOR] = combine_dst;
imp->combine_64_ca[PIXMAN_OP_HSL_LUMINOSITY] = combine_dst;
}
Reference in New Issue View Git Blame Copy Permalink