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vlc/modules/visualization/visual/effects.c

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/*****************************************************************************
* effects.c : Effects for the visualization system
*****************************************************************************
* Copyright (C) 2002-2009 VLC authors and VideoLAN
*
* Authors: Clément Stenac <zorglub@via.ecp.fr>
* Adrien Maglo <magsoft@videolan.org>
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation; either version 2.1 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston MA 02110-1301, USA.
*****************************************************************************/
/*****************************************************************************
* Preamble
*****************************************************************************/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include <vlc_common.h>
#include <vlc_picture.h>
#include <vlc_block.h>
#include "visual.h"
#include <math.h>
#include "fft.h"
#include "window.h"
#define PEAK_SPEED 1
#define BAR_DECREASE_SPEED 5
#define GRAD_ANGLE_MIN 0.2
#define GRAD_ANGLE_MAX 0.5
#define GRAD_INCR 0.01
#define LOG_OFFSET 0.1
/*****************************************************************************
* dummy_Run
*****************************************************************************/
static int dummy_Run( visual_effect_t * p_effect, vlc_object_t *p_aout,
const block_t * p_buffer , picture_t * p_picture)
{
VLC_UNUSED(p_effect); VLC_UNUSED(p_aout); VLC_UNUSED(p_buffer);
VLC_UNUSED(p_picture);
return 0;
}
static void dummy_Free( void *data )
{
VLC_UNUSED(data);
}
/*****************************************************************************
* spectrum_Run: spectrum analyser
*****************************************************************************/
typedef struct spectrum_data
{
int *peaks;
int *prev_heights;
unsigned i_prev_nb_samples;
int16_t *p_prev_s16_buff;
window_param wind_param;
} spectrum_data;
static int spectrum_Run(visual_effect_t * p_effect, vlc_object_t *p_aout,
const block_t * p_buffer , picture_t * p_picture)
{
spectrum_data *p_data = p_effect->p_data;
float p_output[FFT_BUFFER_SIZE]; /* Raw FFT Result */
int *height; /* Bar heights */
int *peaks; /* Peaks */
int *prev_heights; /* Previous bar heights */
int i_80_bands; /* number of bands : 80 if true else 20 */
int i_nb_bands; /* number of bands : 80 or 20 */
int i_band_width; /* width of bands */
int i_start; /* first band horizontal position */
int i_peak; /* Should we draw peaks ? */
/* Horizontal scale for 20-band equalizer */
const int xscale1[]={0,1,2,3,4,5,6,7,8,11,15,20,27,
36,47,62,82,107,141,184,255};
/* Horizontal scale for 80-band equalizer */
const int xscale2[] =
{0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,
19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,
35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,
52,53,54,55,56,57,58,59,61,63,67,72,77,82,87,93,99,105,
110,115,121,130,141,152,163,174,185,200,255};
const int *xscale;
fft_state *p_state; /* internal FFT data */
DEFINE_WIND_CONTEXT( wind_ctx ); /* internal window data */
int i , j , y , k;
int i_line;
uint16_t p_dest[FFT_BUFFER_SIZE]; /* Adapted FFT result */
int16_t p_buffer1[FFT_BUFFER_SIZE]; /* Buffer on which we perform
the FFT (first channel) */
float *p_buffl = /* Original buffer */
(float*)p_buffer->p_buffer;
int16_t *p_buffs; /* int16_t converted buffer */
int16_t *p_s16_buff; /* int16_t converted buffer */
if (!p_buffer->i_nb_samples) {
msg_Err(p_aout, "no samples yet");
return -1;
}
/* Create p_data if needed */
if( !p_data )
{
p_effect->p_data = p_data = malloc( sizeof( spectrum_data ) );
if( !p_data )
return -1;
p_data->peaks = calloc( 80, sizeof(int) );
p_data->prev_heights = calloc( 80, sizeof(int) );
p_data->i_prev_nb_samples = 0;
p_data->p_prev_s16_buff = NULL;
window_get_param( p_aout, &p_data->wind_param );
}
peaks = (int *)p_data->peaks;
prev_heights = (int *)p_data->prev_heights;
/* Allocate the buffer only if the number of samples change */
if( p_buffer->i_nb_samples != p_data->i_prev_nb_samples )
{
free( p_data->p_prev_s16_buff );
p_data->p_prev_s16_buff = vlc_alloc( p_buffer->i_nb_samples *
p_effect->i_nb_chans,
sizeof(int16_t));
p_data->i_prev_nb_samples = p_buffer->i_nb_samples;
if( !p_data->p_prev_s16_buff )
return -1;
}
p_buffs = p_s16_buff = p_data->p_prev_s16_buff;
i_80_bands = var_InheritInteger( p_aout, "visual-80-bands" );
i_peak = var_InheritInteger( p_aout, "visual-peaks" );
if( i_80_bands != 0)
{
xscale = xscale2;
i_nb_bands = 80;
}
else
{
xscale = xscale1;
i_nb_bands = 20;
}
height = vlc_alloc( i_nb_bands, sizeof(int) );
if( !height )
{
return -1;
}
/* Convert the buffer to int16_t */
/* Pasted from float32tos16.c */
for (i = p_buffer->i_nb_samples * p_effect->i_nb_chans; i--; )
{
union { float f; int32_t i; } u;
u.f = *p_buffl + 384.0;
if(u.i > 0x43c07fff ) * p_buffs = 32767;
else if ( u.i < 0x43bf8000 ) *p_buffs = -32768;
else *p_buffs = u.i - 0x43c00000;
p_buffl++ ; p_buffs++ ;
}
p_state = visual_fft_init();
if( !p_state)
{
free( height );
msg_Err(p_aout,"unable to initialize FFT transform");
return -1;
}
if( !window_init( FFT_BUFFER_SIZE, &p_data->wind_param, &wind_ctx ) )
{
fft_close( p_state );
free( height );
msg_Err(p_aout,"unable to initialize FFT window");
return -1;
}
p_buffs = p_s16_buff;
for ( i = 0 ; i < FFT_BUFFER_SIZE ; i++)
{
p_output[i] = 0;
p_buffer1[i] = *p_buffs;
p_buffs += p_effect->i_nb_chans;
if( p_buffs >= &p_s16_buff[p_buffer->i_nb_samples * p_effect->i_nb_chans] )
p_buffs = p_s16_buff;
}
window_scale_in_place( p_buffer1, &wind_ctx );
fft_perform( p_buffer1, p_output, p_state);
for( i = 0; i< FFT_BUFFER_SIZE ; i++ )
{
/* Scale the output between 0 and UINT16MAX */
p_dest[i] = p_output[i] * UINT16_MAX / FFT_SCALING_VALUE;
}
/* Compute the horizontal position of the first band */
i_band_width = floor( p_effect->i_width / i_nb_bands);
i_start = ( p_effect->i_width - i_band_width * i_nb_bands ) / 2;
for ( i = 0 ; i < i_nb_bands ;i++)
{
/* We search the maximum on one scale */
for( j = xscale[i], y = 0; j< xscale[ i + 1 ]; j++ )
{
if ( p_dest[j] > y )
y = p_dest[j];
}
/* Calculate the height of the bar
This log_offset makes it possible to display low values */
if( y != 0 )
{
height[i] = log( y + LOG_OFFSET ) * 30;
if( height[i] > 380 )
height[i] = 380;
}
else
height[ i ] = 0;
/* Draw the bar now */
if( height[i] > peaks[i] )
{
peaks[i] = height[i];
}
else if( peaks[i] > 0 )
{
peaks[i] -= PEAK_SPEED;
if( peaks[i] < height[i] )
{
peaks[i] = height[i];
}
if( peaks[i] < 0 )
{
peaks[i] = 0;
}
}
/* Decrease the bars if needed */
if( height[i] <= prev_heights[i] - BAR_DECREASE_SPEED )
{
height[i] = prev_heights[i];
height[i] -= BAR_DECREASE_SPEED;
}
prev_heights[i] = height[i];
if( peaks[i] > 0 && i_peak )
{
if( peaks[i] >= p_effect->i_height )
peaks[i] = p_effect->i_height - 2;
i_line = peaks[i];
for( j = 0; j < i_band_width - 1; j++ )
{
for( k = 0; k < 3; k ++ )
{
/* Draw the peak */
*(p_picture->p[0].p_pixels +
( p_effect->i_height - i_line -1 -k ) *
p_picture->p[0].i_pitch +
( i_start + i_band_width*i + j ) )
= 0xff;
*(p_picture->p[1].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[1].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) )
= 0x00;
if( i_line + k - 0x0f > 0 )
{
if ( i_line + k - 0x0f < 0xff )
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) )
= ( i_line + k ) - 0x0f;
else
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) )
= 0xff;
}
else
{
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) )
= 0x10 ;
}
}
}
}
if(height[i] > p_effect->i_height)
height[i] = floor(p_effect->i_height );
for( i_line = 0; i_line < height[i]; i_line++ )
{
for( j = 0 ; j < i_band_width - 1; j++)
{
*(p_picture->p[0].p_pixels +
(p_effect->i_height - i_line - 1) *
p_picture->p[0].i_pitch +
( i_start + i_band_width*i + j ) ) = 0xff;
*(p_picture->p[1].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[1].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) ) = 0x00;
if( i_line - 0x0f > 0 )
{
if( i_line - 0x0f < 0xff )
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) ) =
i_line - 0x0f;
else
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) ) =
0xff;
}
else
{
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_start + i_band_width * i + j ) /2 ) ) =
0x10;
}
}
}
}
window_close( &wind_ctx );
fft_close( p_state );
free( height );
return 0;
}
static void spectrum_Free( void *data )
{
spectrum_data *p_data = data;
if( p_data != NULL )
{
free( p_data->peaks );
free( p_data->prev_heights );
free( p_data->p_prev_s16_buff );
free( p_data );
}
}
/*****************************************************************************
* spectrometer_Run: derivative spectrum analysis
*****************************************************************************/
typedef struct
{
int *peaks;
unsigned i_prev_nb_samples;
int16_t *p_prev_s16_buff;
window_param wind_param;
} spectrometer_data;
static int spectrometer_Run(visual_effect_t * p_effect, vlc_object_t *p_aout,
const block_t * p_buffer , picture_t * p_picture)
{
#define Y(R,G,B) ((uint8_t)( (R * .299) + (G * .587) + (B * .114) ))
#define U(R,G,B) ((uint8_t)( (R * -.169) + (G * -.332) + (B * .500) + 128 ))
#define V(R,G,B) ((uint8_t)( (R * .500) + (G * -.419) + (B * -.0813) + 128 ))
float p_output[FFT_BUFFER_SIZE]; /* Raw FFT Result */
int *height; /* Bar heights */
int *peaks; /* Peaks */
int i_80_bands; /* number of bands : 80 if true else 20 */
int i_nb_bands; /* number of bands : 80 or 20 */
int i_band_width; /* width of bands */
int i_separ; /* Should we let blanks ? */
int i_amp; /* Vertical amplification */
int i_peak; /* Should we draw peaks ? */
int i_original; /* original spectrum graphic routine */
int i_rad; /* radius of circle of base of bands */
int i_sections; /* sections of spectranalysis */
int i_extra_width; /* extra width on peak */
int i_peak_height; /* height of peak */
int c; /* sentinel container of total spectral sections */
double band_sep_angle; /* angled separation between beginning of each band */
double section_sep_angle;/* " " ' " ' " " spectrum section */
int max_band_length; /* try not to go out of screen */
int i_show_base; /* Should we draw base of circle ? */
int i_show_bands; /* Should we draw bands ? */
//int i_invert_bands; /* do the bands point inward ? */
double a; /* for various misc angle situations in radians */
int x,y,xx,yy; /* various misc x/y */
char color1; /* V slide on a YUV color cube */
//char color2; /* U slide.. ? color2 fade color ? */
/* Horizontal scale for 20-band equalizer */
const int xscale1[]={0,1,2,3,4,5,6,7,8,11,15,20,27,
36,47,62,82,107,141,184,255};
/* Horizontal scale for 80-band equalizer */
const int xscale2[] =
{0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,
19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,
35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,
52,53,54,55,56,57,58,59,61,63,67,72,77,82,87,93,99,105,
110,115,121,130,141,152,163,174,185,200,255};
const int *xscale;
const double y_scale = 3.60673760222; /* (log 256) */
fft_state *p_state; /* internal FFT data */
DEFINE_WIND_CONTEXT( wind_ctx ); /* internal window data */
int i , j , k;
int i_line = 0;
uint16_t p_dest[FFT_BUFFER_SIZE]; /* Adapted FFT result */
int16_t p_buffer1[FFT_BUFFER_SIZE]; /* Buffer on which we perform
the FFT (first channel) */
float *p_buffl = /* Original buffer */
(float*)p_buffer->p_buffer;
int16_t *p_buffs; /* int16_t converted buffer */
int16_t *p_s16_buff; /* int16_t converted buffer */
if (!p_buffer->i_nb_samples) {
msg_Err(p_aout, "no samples yet");
return -1;
}
/* Create the data struct if needed */
spectrometer_data *p_data = p_effect->p_data;
if( !p_data )
{
p_data = malloc( sizeof(spectrometer_data) );
if( !p_data )
return -1;
p_data->peaks = calloc( 80, sizeof(int) );
if( !p_data->peaks )
{
free( p_data );
return -1;
}
p_data->i_prev_nb_samples = 0;
p_data->p_prev_s16_buff = NULL;
window_get_param( p_aout, &p_data->wind_param );
p_effect->p_data = (void*)p_data;
}
peaks = p_data->peaks;
/* Allocate the buffer only if the number of samples change */
if( p_buffer->i_nb_samples != p_data->i_prev_nb_samples )
{
free( p_data->p_prev_s16_buff );
p_data->p_prev_s16_buff = vlc_alloc( p_buffer->i_nb_samples *
p_effect->i_nb_chans,
sizeof(int16_t));
p_data->i_prev_nb_samples = p_buffer->i_nb_samples;
if( !p_data->p_prev_s16_buff )
return -1;
}
p_buffs = p_s16_buff = p_data->p_prev_s16_buff;
i_original = var_InheritInteger( p_aout, "spect-show-original" );
i_80_bands = var_InheritInteger( p_aout, "spect-80-bands" );
i_separ = var_InheritInteger( p_aout, "spect-separ" );
i_amp = var_InheritInteger( p_aout, "spect-amp" );
i_peak = var_InheritInteger( p_aout, "spect-show-peaks" );
i_show_base = var_InheritInteger( p_aout, "spect-show-base" );
i_show_bands = var_InheritInteger( p_aout, "spect-show-bands" );
i_rad = var_InheritInteger( p_aout, "spect-radius" );
i_sections = var_InheritInteger( p_aout, "spect-sections" );
i_extra_width = var_InheritInteger( p_aout, "spect-peak-width" );
i_peak_height = var_InheritInteger( p_aout, "spect-peak-height" );
color1 = var_InheritInteger( p_aout, "spect-color" );
if( i_80_bands != 0)
{
xscale = xscale2;
i_nb_bands = 80;
}
else
{
xscale = xscale1;
i_nb_bands = 20;
}
height = vlc_alloc( i_nb_bands, sizeof(int) );
if( !height)
return -1;
/* Convert the buffer to int16_t */
/* Pasted from float32tos16.c */
for (i = p_buffer->i_nb_samples * p_effect->i_nb_chans; i--; )
{
union { float f; int32_t i; } u;
u.f = *p_buffl + 384.0;
if(u.i > 0x43c07fff ) * p_buffs = 32767;
else if ( u.i < 0x43bf8000 ) *p_buffs = -32768;
else *p_buffs = u.i - 0x43c00000;
p_buffl++ ; p_buffs++ ;
}
p_state = visual_fft_init();
if( !p_state)
{
msg_Err(p_aout,"unable to initialize FFT transform");
free( height );
return -1;
}
if( !window_init( FFT_BUFFER_SIZE, &p_data->wind_param, &wind_ctx ) )
{
fft_close( p_state );
free( height );
msg_Err(p_aout,"unable to initialize FFT window");
return -1;
}
p_buffs = p_s16_buff;
for ( i = 0 ; i < FFT_BUFFER_SIZE; i++)
{
p_output[i] = 0;
p_buffer1[i] = *p_buffs;
p_buffs += p_effect->i_nb_chans;
if( p_buffs >= &p_s16_buff[p_buffer->i_nb_samples * p_effect->i_nb_chans] )
p_buffs = p_s16_buff;
}
window_scale_in_place( p_buffer1, &wind_ctx );
fft_perform( p_buffer1, p_output, p_state);
for(i = 0; i < FFT_BUFFER_SIZE; i++)
{
int sqrti = sqrt(p_output[i]);
p_dest[i] = sqrti >> 8;
}
i_nb_bands *= i_sections;
for ( i = 0 ; i< i_nb_bands/i_sections ;i++)
{
/* We search the maximum on one scale */
for( j = xscale[i] , y=0 ; j< xscale[ i + 1 ] ; j++ )
{
if ( p_dest[j] > y )
y = p_dest[j];
}
/* Calculate the height of the bar */
y >>=7;/* remove some noise */
if( y != 0)
{
int logy = log(y);
height[i] = logy * y_scale;
if(height[i] > 150)
height[i] = 150;
}
else
{
height[i] = 0 ;
}
/* Draw the bar now */
i_band_width = floor( p_effect->i_width / (i_nb_bands/i_sections)) ;
if( i_amp * height[i] > peaks[i])
{
peaks[i] = i_amp * height[i];
}
else if (peaks[i] > 0 )
{
peaks[i] -= PEAK_SPEED;
if( peaks[i] < i_amp * height[i] )
{
peaks[i] = i_amp * height[i];
}
if( peaks[i] < 0 )
{
peaks[i] = 0;
}
}
if( i_original != 0 )
{
if( peaks[i] > 0 && i_peak )
{
if( peaks[i] >= p_effect->i_height )
peaks[i] = p_effect->i_height - 2;
i_line = peaks[i];
for( j = 0 ; j< i_band_width - i_separ; j++)
{
for( k = 0 ; k< 3 ; k ++)
{
//* Draw the peak
*(p_picture->p[0].p_pixels +
(p_effect->i_height - i_line -1 -k ) *
p_picture->p[0].i_pitch + (i_band_width*i +j) )
= 0xff;
*(p_picture->p[1].p_pixels +
( ( p_effect->i_height - i_line ) / 2 -1 -k/2 ) *
p_picture->p[1].i_pitch +
( ( i_band_width * i + j ) /2 ) )
= 0x00;
if( 0x04 * (i_line + k ) - 0x0f > 0 )
{
if ( 0x04 * (i_line + k ) -0x0f < 0xff)
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) )
= ( 0x04 * ( i_line + k ) ) -0x0f ;
else
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) )
= 0xff;
}
else
{
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1 -k/2 ) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) )
= 0x10 ;
}
}
}
}
if(height[i] * i_amp > p_effect->i_height)
height[i] = floor(p_effect->i_height / i_amp );
for(i_line = 0 ; i_line < i_amp * height[i]; i_line ++ )
{
for( j = 0 ; j< i_band_width - i_separ ; j++)
{
*(p_picture->p[0].p_pixels +
(p_effect->i_height - i_line -1) *
p_picture->p[0].i_pitch + (i_band_width*i +j) ) = 0xff;
*(p_picture->p[1].p_pixels +
( ( p_effect->i_height - i_line ) / 2 -1) *
p_picture->p[1].i_pitch +
( ( i_band_width * i + j ) /2 ) ) = 0x00;
if( 0x04 * i_line - 0x0f > 0 )
{
if( 0x04 * i_line - 0x0f < 0xff )
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) ) =
( 0x04 * i_line) -0x0f ;
else
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) ) =
0xff;
}
else
{
*(p_picture->p[2].p_pixels +
( ( p_effect->i_height - i_line ) / 2 - 1) *
p_picture->p[2].i_pitch +
( ( i_band_width * i + j ) /2 ) ) =
0x10 ;
}
}
}
}
}
band_sep_angle = 360.0 / i_nb_bands;
section_sep_angle = 360.0 / i_sections;
if( i_peak_height < 1 )
i_peak_height = 1;
max_band_length = p_effect->i_height / 2 - ( i_rad + i_peak_height + 1 );
i_band_width = floor( 360 / i_nb_bands - i_separ );
if( i_band_width < 1 )
i_band_width = 1;
for( c = 0 ; c < i_sections ; c++ )
for( i = 0 ; i < (i_nb_bands / i_sections) ; i++ )
{
/* DO A PEAK */
if( peaks[i] > 0 && i_peak )
{
if( peaks[i] >= p_effect->i_height )
peaks[i] = p_effect->i_height - 2;
i_line = peaks[i];
/* circular line pattern(so color blend is more visible) */
for( j = 0 ; j < i_peak_height ; j++ )
{
//x = p_picture->p[0].i_pitch / 2;
x = p_effect->i_width / 2;
y = p_effect->i_height / 2;
xx = x;
yy = y;
for( k = 0 ; k < (i_band_width + i_extra_width) ; k++ )
{
x = xx;
y = yy;
a = ( (i+1) * band_sep_angle + section_sep_angle * (c+1) + k )
* 3.141592 / 180.0;
x += (double)( cos(a) * (double)( i_line + j + i_rad ) );
y += (double)( -sin(a) * (double)( i_line + j + i_rad ) );
*(p_picture->p[0].p_pixels + x + y * p_picture->p[0].i_pitch
) = 255;/* Y(R,G,B); */
x /= 2;
y /= 2;
*(p_picture->p[1].p_pixels + x + y * p_picture->p[1].i_pitch
) = 0;/* U(R,G,B); */
if( 0x04 * (i_line + k ) - 0x0f > 0 )
{
if ( 0x04 * (i_line + k ) -0x0f < 0xff)
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = ( 0x04 * ( i_line + k ) ) -(color1-1);/* -V(R,G,B); */
else
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = 255;/* V(R,G,B); */
}
else
{
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = color1;/* V(R,G,B); */
}
}
}
}
if( (height[i] * i_amp) > p_effect->i_height )
height[i] = floor( p_effect->i_height / i_amp );
/* DO BASE OF BAND (mostly makes a circle) */
if( i_show_base != 0 )
{
//x = p_picture->p[0].i_pitch / 2;
x = p_effect->i_width / 2;
y = p_effect->i_height / 2;
a = ( (i+1) * band_sep_angle + section_sep_angle * (c+1) )
* 3.141592 / 180.0;
x += (double)( cos(a) * (double)i_rad );/* newb-forceful casting */
y += (double)( -sin(a) * (double)i_rad );
*(p_picture->p[0].p_pixels + x + y * p_picture->p[0].i_pitch
) = 255;/* Y(R,G,B); */
x /= 2;
y /= 2;
*(p_picture->p[1].p_pixels + x + y * p_picture->p[1].i_pitch
) = 0;/* U(R,G,B); */
if( 0x04 * i_line - 0x0f > 0 )
{
if( 0x04 * i_line -0x0f < 0xff)
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = ( 0x04 * i_line) -(color1-1);/* -V(R,G,B); */
else
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = 255;/* V(R,G,B); */
}
else
{
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = color1;/* V(R,G,B); */
}
}
/* DO A BAND */
if( i_show_bands != 0 )
for( j = 0 ; j < i_band_width ; j++ )
{
x = p_effect->i_width / 2;
y = p_effect->i_height / 2;
xx = x;
yy = y;
a = ( (i+1) * band_sep_angle + section_sep_angle * (c+1) + j )
* 3.141592/180.0;
for( k = (i_rad+1) ; k < max_band_length ; k++ )
{
if( (k-i_rad) > height[i] )
break;/* uhh.. */
x = xx;
y = yy;
x += (double)( cos(a) * (double)k );/* newbed! */
y += (double)( -sin(a) * (double)k );
*(p_picture->p[0].p_pixels + x + y * p_picture->p[0].i_pitch
) = 255;
x /= 2;
y /= 2;
*(p_picture->p[1].p_pixels + x + y * p_picture->p[1].i_pitch
) = 0;
if( 0x04 * i_line - 0x0f > 0 )
{
if ( 0x04 * i_line -0x0f < 0xff)
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = ( 0x04 * i_line) -(color1-1);
else
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = 255;
}
else
{
*(p_picture->p[2].p_pixels + x + y * p_picture->p[2].i_pitch
) = color1;
}
}
}
}
window_close( &wind_ctx );
fft_close( p_state );
free( height );
return 0;
}
static void spectrometer_Free( void *data )
{
spectrometer_data *p_data = data;
if( p_data != NULL )
{
free( p_data->peaks );
free( p_data->p_prev_s16_buff );
free( p_data );
}
}
/*****************************************************************************
* scope_Run: scope effect
*****************************************************************************/
static int scope_Run(visual_effect_t * p_effect, vlc_object_t *p_aout,
const block_t * p_buffer , picture_t * p_picture)
{
VLC_UNUSED(p_aout);
int i_index;
float *p_sample ;
uint8_t *ppp_area[2][3];
for( i_index = 0 ; i_index < 2 ; i_index++ )
{
for( int j = 0 ; j < 3 ; j++ )
{
ppp_area[i_index][j] =
p_picture->p[j].p_pixels + (i_index * 2 + 1) * p_picture->p[j].i_lines
/ 4 * p_picture->p[j].i_pitch;
}
}
for( i_index = 0, p_sample = (float *)p_buffer->p_buffer;
i_index < __MIN( p_effect->i_width, (int)p_buffer->i_nb_samples );
i_index++ )
{
int8_t i_value;
/* Left channel */
i_value = p_sample[p_effect->i_idx_left] * 127;
*(ppp_area[0][0]
+ p_picture->p[0].i_pitch * i_index / p_effect->i_width
+ p_picture->p[0].i_lines * i_value / 512
* p_picture->p[0].i_pitch) = 0xbf;
*(ppp_area[0][1]
+ p_picture->p[1].i_pitch * i_index / p_effect->i_width
+ p_picture->p[1].i_lines * i_value / 512
* p_picture->p[1].i_pitch) = 0xff;
/* Right channel */
i_value = p_sample[p_effect->i_idx_right] * 127;
*(ppp_area[1][0]
+ p_picture->p[0].i_pitch * i_index / p_effect->i_width
+ p_picture->p[0].i_lines * i_value / 512
* p_picture->p[0].i_pitch) = 0x9f;
*(ppp_area[1][2]
+ p_picture->p[2].i_pitch * i_index / p_effect->i_width
+ p_picture->p[2].i_lines * i_value / 512
* p_picture->p[2].i_pitch) = 0xdd;
p_sample += p_effect->i_nb_chans;
}
return 0;
}
/*****************************************************************************
* vuMeter_Run: vu meter effect
*****************************************************************************/
static int vuMeter_Run(visual_effect_t * p_effect, vlc_object_t *p_aout,
const block_t * p_buffer , picture_t * p_picture)
{
VLC_UNUSED(p_aout);
float i_value_l = 0;
float i_value_r = 0;
/* Compute the peak values */
for ( unsigned i = 0 ; i < p_buffer->i_nb_samples; i++ )
{
const float *p_sample = (float *)p_buffer->p_buffer;
float ch;
ch = p_sample[p_effect->i_idx_left] * 256;
if (ch > i_value_l)
i_value_l = ch;
ch = p_sample[p_effect->i_idx_right] * 256;
if (ch > i_value_r)
i_value_r = ch;
p_sample += p_effect->i_nb_chans;
}
i_value_l = fabsf(i_value_l);
i_value_r = fabsf(i_value_r);
/* Stay under maximum value admitted */
if ( i_value_l > 200 * M_PI_2 )
i_value_l = 200 * M_PI_2;
if ( i_value_r > 200 * M_PI_2 )
i_value_r = 200 * M_PI_2;
float *i_value;
if( !p_effect->p_data )
{
/* Allocate memory to save hand positions */
p_effect->p_data = vlc_alloc( 2, sizeof(float) );
i_value = p_effect->p_data;
i_value[0] = i_value_l;
i_value[1] = i_value_r;
}
else
{
/* Make the hands go down slowly if the current values are slower
than the previous */
i_value = p_effect->p_data;
if ( i_value_l > i_value[0] - 6 )
i_value[0] = i_value_l;
else
i_value[0] = i_value[0] - 6;
if ( i_value_r > i_value[1] - 6 )
i_value[1] = i_value_r;
else
i_value[1] = i_value[1] - 6;
}
int x, y;
float teta;
float teta_grad;
int start_x = p_effect->i_width / 2 - 120; /* i_width.min = 532 (visual.c) */
for ( int j = 0; j < 2; j++ )
{
/* Draw the two scales */
int k = 0;
teta_grad = GRAD_ANGLE_MIN;
for ( teta = -M_PI_4; teta <= M_PI_4; teta = teta + 0.003 )
{
for ( unsigned i = 140; i <= 150; i++ )
{
y = i * cos(teta) + 20;
x = i * sin(teta) + start_x + 240 * j;
/* Compute the last color for the gradation */
if (teta >= teta_grad + GRAD_INCR && teta_grad <= GRAD_ANGLE_MAX)
{
teta_grad = teta_grad + GRAD_INCR;
k = k + 5;
}
*(p_picture->p[0].p_pixels +
(p_picture->p[0].i_lines - y - 1 ) * p_picture->p[0].i_pitch
+ x ) = 0x45;
*(p_picture->p[1].p_pixels +
(p_picture->p[1].i_lines - y / 2 - 1 ) * p_picture->p[1].i_pitch
+ x / 2 ) = 0x0;
*(p_picture->p[2].p_pixels +
(p_picture->p[2].i_lines - y / 2 - 1 ) * p_picture->p[2].i_pitch
+ x / 2 ) = 0x4D + k;
}
}
/* Draw the two hands */
teta = (float)i_value[j] / 200 - M_PI_4;
for ( int i = 0; i <= 150; i++ )
{
y = i * cos(teta) + 20;
x = i * sin(teta) + start_x + 240 * j;
*(p_picture->p[0].p_pixels +
(p_picture->p[0].i_lines - y - 1 ) * p_picture->p[0].i_pitch
+ x ) = 0xAD;
*(p_picture->p[1].p_pixels +
(p_picture->p[1].i_lines - y / 2 - 1 ) * p_picture->p[1].i_pitch
+ x / 2 ) = 0xFC;
*(p_picture->p[2].p_pixels +
(p_picture->p[2].i_lines - y / 2 - 1 ) * p_picture->p[2].i_pitch
+ x / 2 ) = 0xAC;
}
/* Draw the hand bases */
for ( teta = -M_PI_2; teta <= M_PI_2 + 0.01; teta = teta + 0.003 )
{
for ( int i = 0; i < 10; i++ )
{
y = i * cos(teta) + 20;
x = i * sin(teta) + start_x + 240 * j;
*(p_picture->p[0].p_pixels +
(p_picture->p[0].i_lines - y - 1 ) * p_picture->p[0].i_pitch
+ x ) = 0xFF;
*(p_picture->p[1].p_pixels +
(p_picture->p[1].i_lines - y / 2 - 1 ) * p_picture->p[1].i_pitch
+ x / 2 ) = 0x80;
*(p_picture->p[2].p_pixels +
(p_picture->p[2].i_lines - y / 2 - 1 ) * p_picture->p[2].i_pitch
+ x / 2 ) = 0x80;
}
}
}
return 0;
}
/* Table of effects */
const struct visual_cb_t effectv[] = {
{ "scope", scope_Run, dummy_Free },
{ "vuMeter", vuMeter_Run, dummy_Free },
{ "spectrum", spectrum_Run, spectrum_Free },
{ "spectrometer", spectrometer_Run, spectrometer_Free },
{ "dummy", dummy_Run, dummy_Free },
};
const unsigned effectc = sizeof (effectv) / sizeof (effectv[0]);