Commit 400622e8 authored by Martin Briza's avatar Martin Briza Committed by Jean-Baptiste Kempf

Fix sepia video filter in PackedYUV

SSE function used in PackedYUV plane was bad, removed
copying data using Memcpy8BMMX was slower than vlc_memset -> changed
Sepia8ySSE4_1 changed to Sepia8ySSE2, due to some changes I made to speed it up and clean
Minor changes in indentation and comments
Signed-off-by: default avatarJean-Baptiste Kempf <jb@videolan.org>
parent 47c1409f
......@@ -47,8 +47,7 @@ static void RVSepia( picture_t *, picture_t *, int );
static void PlanarI420Sepia( picture_t *, picture_t *, int);
static void PackedYUVSepia( picture_t *, picture_t *, int);
static picture_t *Filter( filter_t *, picture_t * );
inline void Sepia8ySSE41( uint8_t *, const uint8_t *, volatile uint8_t * );
inline void Memcpy8BMMX( uint8_t *, const uint8_t * );
inline void Sepia8ySSE2( uint8_t *, const uint8_t *, int );
static const char *const ppsz_filter_options[] = {
"intensity", NULL
};
......@@ -68,7 +67,7 @@ vlc_module_begin ()
set_category( CAT_VIDEO )
set_subcategory( SUBCAT_VIDEO_VFILTER )
set_capability( "video filter2", 0 )
add_integer_with_range( CFG_PREFIX "intensity", 100, 0, 255,
add_integer_with_range( CFG_PREFIX "intensity", 120, 0, 255,
SEPIA_INTENSITY_TEXT, SEPIA_INTENSITY_LONGTEXT,
false )
set_callbacks( Create, Destroy )
......@@ -215,22 +214,15 @@ static void PlanarI420Sepia( picture_t *p_pic, picture_t *p_outpic,
const uint8_t filling_const_8u = 128 - i_intensity / 6;
const uint8_t filling_const_8v = 128 + i_intensity / 14;
#if defined(CAN_COMPILE_SSE4_1) && 1
if (vlc_CPU() & CPU_CAPABILITY_SSE4_1)
#if defined(CAN_COMPILE_SSE2)
if (vlc_CPU() & CPU_CAPABILITY_SSE2)
{
/*prepare array of values to copy with mmx, compute only once
to improve speed */
volatile uint8_t intensity_array[8] = { i_intensity, i_intensity,
i_intensity, i_intensity, i_intensity, i_intensity,
i_intensity, i_intensity };
const uint8_t filling_array_8u[8] =
{ filling_const_8u, filling_const_8u, filling_const_8u,
filling_const_8u, filling_const_8u, filling_const_8u,
filling_const_8u, filling_const_8u };
const uint8_t filling_array_8v[8] =
{ filling_const_8v, filling_const_8v, filling_const_8v,
filling_const_8v, filling_const_8v, filling_const_8v,
filling_const_8v, filling_const_8v };
/* prepared value for faster broadcasting in xmm register */
int i_intensity_spread = 0x10001 * (uint8_t) i_intensity;
__asm__ volatile(
"pxor %%xmm7, %%xmm7\n"
::);
/* iterate for every two visible line in the frame */
for (int y = 0; y < p_pic->p[Y_PLANE].i_visible_lines - 1; y += 2)
......@@ -244,35 +236,36 @@ static void PlanarI420Sepia( picture_t *p_pic, picture_t *p_outpic,
(y / 2) * p_outpic->p[V_PLANE].i_pitch;
int x = 0;
/* iterate for every visible line in the frame (eight values at once) */
for (; x < p_pic->p[Y_PLANE].i_visible_pitch - 15; x += 16)
for ( ; x < p_pic->p[Y_PLANE].i_visible_pitch - 15; x += 16 )
{
/* Compute yellow channel values with asm function */
Sepia8ySSE41(
Sepia8ySSE2(
&p_outpic->p[Y_PLANE].p_pixels[i_dy_line1_start + x],
&p_pic->p[Y_PLANE].p_pixels[i_dy_line1_start + x],
intensity_array );
Sepia8ySSE41(
i_intensity_spread );
Sepia8ySSE2(
&p_outpic->p[Y_PLANE].p_pixels[i_dy_line2_start + x],
&p_pic->p[Y_PLANE].p_pixels[i_dy_line2_start + x],
intensity_array );
Sepia8ySSE41(
i_intensity_spread );
Sepia8ySSE2(
&p_outpic->p[Y_PLANE].p_pixels[i_dy_line1_start + x + 8],
&p_pic->p[Y_PLANE].p_pixels[i_dy_line1_start + x + 8],
intensity_array );
Sepia8ySSE41(
i_intensity_spread );
Sepia8ySSE2(
&p_outpic->p[Y_PLANE].p_pixels[i_dy_line2_start + x + 8],
&p_pic->p[Y_PLANE].p_pixels[i_dy_line2_start + x + 8],
intensity_array );
/* Copy precomputed values to destination image memory location */
Memcpy8BMMX(
i_intensity_spread );
/* Copy precomputed values to destination memory location */
vlc_memset(
&p_outpic->p[U_PLANE].p_pixels[i_du_line_start + (x / 2)],
filling_array_8u );
Memcpy8BMMX(&p_outpic->p[V_PLANE].p_pixels[i_dv_line_start + (x / 2)],
filling_array_8v );
filling_const_8u, 8 );
vlc_memset(
&p_outpic->p[V_PLANE].p_pixels[i_dv_line_start + (x / 2)],
filling_const_8v, 8 );
}
/* Completing the job, the cycle above takes really big chunks, so
this makes sure the job will be done completely */
for (; x < p_pic->p[Y_PLANE].i_visible_pitch - 1; x += 2)
for ( ; x < p_pic->p[Y_PLANE].i_visible_pitch - 1; x += 2 )
{
// y = y - y/4 {to prevent overflow} + intensity / 4
p_outpic->p[Y_PLANE].p_pixels[i_dy_line1_start + x] =
......@@ -299,7 +292,8 @@ static void PlanarI420Sepia( picture_t *p_pic, picture_t *p_outpic,
filling_const_8v;
}
}
} else
}
else
#endif
{
/* iterate for every two visible line in the frame */
......@@ -369,68 +363,7 @@ static void PackedYUVSepia( picture_t *p_pic, picture_t *p_outpic,
p_in_end = p_in + p_pic->p[0].i_visible_lines
* p_pic->p[0].i_pitch;
p_out = p_outpic->p[0].p_pixels;
#if defined(CAN_COMPILE_SSE4_1)
if (vlc_CPU() & CPU_CAPABILITY_SSE4_1)
{
/*prepare array of values to copy with mmx, compute only once
to improve speed */
volatile uint8_t intensity_array[8] = { i_intensity, i_intensity,
i_intensity, i_intensity, i_intensity, i_intensity,
i_intensity,
i_intensity
};
const uint8_t filling_array_8u[8] =
{ filling_const_8u, filling_const_8u,
filling_const_8u, filling_const_8u, filling_const_8u,
filling_const_8u,
filling_const_8u, filling_const_8u
};
const uint8_t filling_array_8v[8] =
{ filling_const_8v, filling_const_8v,
filling_const_8v, filling_const_8v, filling_const_8v,
filling_const_8v,
filling_const_8v, filling_const_8v
};
/* iterate for every two visible line in the frame */
while (p_in < p_in_end)
{
p_line_end = p_in + p_pic->p[0].i_visible_pitch;
while (p_in < p_line_end)
{
Sepia8ySSE41(&p_out[i_yindex], &p_in[i_yindex],
intensity_array);
Sepia8ySSE41(&p_out[i_yindex + 8], &p_in[i_yindex + 8],
intensity_array);
Sepia8ySSE41(&p_out[i_yindex + 16], &p_in[i_yindex + 16],
intensity_array);
Sepia8ySSE41(&p_out[i_yindex + 24], &p_in[i_yindex + 24],
intensity_array);
Memcpy8BMMX(&p_out[i_uindex], filling_array_8u);
Memcpy8BMMX(&p_out[i_vindex], filling_array_8v);
p_in += 32;
p_out += 32;
}
while (p_in < p_line_end)
{
p_out[i_yindex] =
p_in[i_yindex] - (p_in[i_yindex] >> 2) +
(i_intensity >> 2);
p_out[i_yindex + 2] =
p_in[i_yindex + 2] - (p_in[i_yindex + 2] >> 2) +
(i_intensity >> 2);
p_out[i_uindex] = filling_const_8u;
p_out[i_vindex] = filling_const_8v;
p_in += 4;
p_out += 4;
}
p_in += p_pic->p[0].i_pitch - p_pic->p[0].i_visible_pitch;
p_out += p_outpic->p[0].i_pitch
- p_outpic->p[0].i_visible_pitch;
}
} else
#endif
{
while( p_in < p_in_end )
{
......@@ -526,20 +459,24 @@ static void RVSepia( picture_t *p_pic, picture_t *p_outpic, int i_intensity )
}
/*****************************************************************************
* Sepia8ySSE41
* Sepia8ySSE2
*****************************************************************************
* This function applies sepia effect to eight bytes of yellow using SSE4.1
* instructions. It copies those 8 bytes to 128b register and fills the gaps
* with zeroes and following operations are made with word-operating instructs.
*****************************************************************************/
inline void Sepia8ySSE41(uint8_t * dst, const uint8_t * src,
volatile uint8_t * i_intensity)
inline void Sepia8ySSE2(uint8_t * dst, const uint8_t * src,
int i_intensity_spread)
{
#if defined(CAN_COMPILE_SSE4_1) && 1
#if defined(CAN_COMPILE_SSE2)
__asm__ volatile (
"pmovzxbw (%1), %%xmm1\n" // y = y - y / 4 + i_intensity / 4
"pmovzxbw (%1), %%xmm2\n" // store bytes as words with 0s in between
"pmovzxbw (%2), %%xmm3\n"
// y = y - y / 4 + i_intensity / 4
"movq (%1), %%xmm1\n"
"punpcklbw %%xmm7, %%xmm1\n"
"movq (%1), %%xmm2\n" // store bytes as words with 0s in between
"punpcklbw %%xmm7, %%xmm2\n"
"movd %2, %%xmm3\n"
"pshufd $0, %%xmm3, %%xmm3\n"
"psrlw $2, %%xmm2\n" // rotate right 2
"psubusb %%xmm1, %%xmm2\n" // subtract
"psrlw $2, %%xmm3\n"
......@@ -547,24 +484,7 @@ inline void Sepia8ySSE41(uint8_t * dst, const uint8_t * src,
"packuswb %%xmm2, %%xmm1\n" // pack back to bytes
"movq %%xmm1, (%0) \n" // load to dest
:
:"r" (dst), "r"(src), "r"(i_intensity)
:"memory");
#endif
}
/*****************************************************************************
* Memcpy8BMMX: Copies 8 bytes of memory in two instructions
*****************************************************************************
* Not quite clean, but it should be fast.
*****************************************************************************/
inline void Memcpy8BMMX(uint8_t * dst, const uint8_t * src)
{
#if defined(CAN_COMPILE_MMX) && 1
__asm__ volatile (
"movq (%1), %%xmm0\n"
"movq %%xmm0, (%0)\n"
:
:"r" (dst), "r"(src)
:"r" (dst), "r"(src), "r"(i_intensity_spread)
:"memory");
#endif
}
......
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