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/* Copyright (c) 2004 Tim Blechmann.
* For information on usage and redistribution, and for a DISCLAIMER OF ALL
* WARRANTIES, see the file, "gpl.txt" in this distribution.
*
* 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 2
* of the License, or (at your option) any later version.
*
* See file LICENSE for further informations on licensing terms.
*
* 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
* Based on PureData by Miller Puckette and others.
*
* coded while listening to: Julien Ottavi: Nervure Magnetique
* */
#include "m_pd.h"
#include "m_simd.h"
/* ----------------------------- volctl ----------------------------- */
static t_class *volctl_class;
typedef struct _volctl
{
t_object x_obj;
t_float x_f;
t_float x_h; //interpolation time
t_float x_value; //current factor
t_float x_target; //target factor
int x_ticksleft; //dsp ticks to go
t_float x_samples_per_ms; //ms per sample
t_float x_slope; //slope
t_float * x_slopes; //slopes for simd
t_float x_slope_step;
int x_line;
int x_blocksize;
t_float x_1overblocksize;
} t_volctl;
void *volctl_new(t_symbol *s, int argc, t_atom *argv)
{
if (argc > 3) post("volctl~: extra arguments ignored");
t_volctl *x = (t_volctl *)pd_new(volctl_class);
inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_float, gensym("f1"));
inlet_settip(x->x_obj.ob_inlet,gensym("factor"));
x->x_value = atom_getfloatarg(0, argc, argv);
t_inlet * time = floatinlet_new(&x->x_obj, &x->x_h);
inlet_settip(time,gensym("interpolation_time"));
x->x_h = atom_getfloatarg(1, argc, argv);
x->x_samples_per_ms = 44100.f / 1000.f; // assume default samplerate
x->x_blocksize = 64;
x->x_1overblocksize = 1.f/64.f;
outlet_new(&x->x_obj, &s_signal);
x->x_f = 0;
x->x_slopes = getalignedbytes(4*sizeof(t_float));
return (x);
}
static void volctl_free(t_volctl *x)
{
freealignedbytes(x->x_slopes, 4*sizeof(t_float));
}
static t_int *volctl_perform(t_int *w)
{
t_volctl * x = (t_volctl *)(w[1]);
t_float *in = (t_float *)(w[2]);
t_float *out = (t_float *)(w[3]);
int n = (int)(w[4]);
if (x->x_ticksleft)
{
t_float f = x->x_value;
t_float x_slope = x->x_slope;
x->x_ticksleft--;
while (n--)
{
f+=x_slope;
*out++ = *in++ * f;
}
x->x_value = f;
}
else
{
t_float f = x->x_target;
while (n--) *out++ = *in++ * f;
}
return (w+5);
}
static t_int *volctl_perf8(t_int *w)
{
t_volctl * x = (t_volctl *)(w[1]);
t_float *in = (t_float *)(w[2]);
t_float *out = (t_float *)(w[3]);
int n = (int)(w[4]);
if (x->x_ticksleft)
{
t_float f = x->x_value;
t_float x_slope = x->x_slope;
x->x_ticksleft--;
n = n>>3;
while (n--)
{
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
}
x->x_value = f;
}
else
{
t_float f = x->x_target;
if (f)
for (; n; n -= 8, in += 8, out += 8)
{
t_float f0 = in[0], f1 = in[1], f2 = in[2], f3 = in[3];
t_float f4 = in[4], f5 = in[5], f6 = in[6], f7 = in[7];
out[0] = f0 * f; out[1] = f1 * f; out[2] = f2 * f; out[3] = f3 * f;
out[4] = f4 * f; out[5] = f5 * f; out[6] = f6 * f; out[7] = f7 * f;
}
else
for (; n; n -= 8, in += 8, out += 8)
{
out[0] = 0; out[1] = 0; out[2] = 0; out[3] = 0;
out[4] = 0; out[5] = 0; out[6] = 0; out[7] = 0;
}
}
return (w+5);
}
static t_int *volctl_perf_simd(t_int *w)
{
t_volctl * x = (t_volctl *)(w[1]);
t_float *in = (t_float *)(w[2]);
t_float *out = (t_float *)(w[3]);
int n = (int)(w[4]);
if (x->x_ticksleft)
{
#if defined(__GNUC__) && (defined(_X86_) || defined(__i386__) || defined(__i586__) || defined(__i686__))
asm(
".set T_FLOAT,4 \n"
"movss (%3),%%xmm0 \n" /* value */
"shufps $0, %%xmm0, %%xmm0 \n"
"movaps (%4), %%xmm1 \n" /* x_slopes */
"addps %%xmm0, %%xmm1 \n"
"movss (%5), %%xmm0 \n"
"shufps $0, %%xmm0, %%xmm0 \n" /* x_slope_step */
"shrl $4, %2 \n" /* n>>4 */
"1: \n"
"movaps (%0), %%xmm2 \n"
"mulps %%xmm1, %%xmm2 \n"
"movaps %%xmm2, (%1) \n"
"addps %%xmm0, %%xmm1 \n"
"movaps 4*T_FLOAT(%0), %%xmm2 \n"
"mulps %%xmm1, %%xmm2 \n"
"movaps %%xmm2, 4*T_FLOAT(%1) \n"
"addps %%xmm0, %%xmm1 \n"
"movaps 8*T_FLOAT(%0), %%xmm2 \n"
"mulps %%xmm1, %%xmm2 \n"
"movaps %%xmm2, 8*T_FLOAT(%1) \n"
"addps %%xmm0, %%xmm1 \n"
"movaps 12*T_FLOAT(%0), %%xmm2 \n"
"mulps %%xmm1, %%xmm2 \n"
"movaps %%xmm2, 12*T_FLOAT(%1) \n"
"addps %%xmm0, %%xmm1 \n" /* one instr. obsolete */
"addl $16*T_FLOAT, %0 \n"
"addl $16*T_FLOAT, %1 \n"
"loop 1b \n"
:
:"r"(in), "r"(out), "c"(n), "r"(&(t_float)(x->x_value)),
"r"((t_float*)x->x_slopes), "r"(&(t_float)(x->x_slope_step))
:"%xmm0", "%xmm1", "%xmm2");
#elif defined(NT) && defined(_MSC_VER)
__asm {
mov ecx,n
mov ebx,in
mov edx,out
movss xmm0,xmmword prt [x->x_value]
shufps xmm0,xmm0,0
movaps xmm1,xmmword prt [x->x_slopes]
addps xmm1,xmm0
movss xmm0,xmmword prt [x->x_slope_step]
shufps xmm0,xmm0,0
shr ecx,4
loopa:
movaps xmm2,xmmword ptr[ebx]
mulps xmm2,xmm1
movaps xmmword prt[edx],xmm2
addps xmm1,xmm0
movaps xmm2,xmmword ptr[ebx+4*TYPE t_float]
mulps xmm2,xmm1
movaps xmmword prt[edx+4*TYPE t_float],xmm2
addps xmm1,xmm0
movaps xmm2,xmmword ptr[ebx+8*TYPE t_float]
mulps xmm2,xmm1
movaps xmmword prt[edx+8*TYPE t_float],xmm2
addps xmm1,xmm0
movaps xmm2,xmmword ptr[ebx+12*TYPE t_float]
mulps xmm2,xmm1
movaps xmmword prt[edx+12*TYPE t_float],xmm2
addps xmm1,xmm0
add ebx,16*TYPE t_float
add edx,16*TYPE t_float
loop loopa
}
#else /* not yet implemented ... */
t_float f = x->x_value;
t_float x_slope = x->x_slope;
n = n>>3;
while (n--)
{
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
*out++ = *in++ * f;
f+=x_slope;
}
#endif
x->x_ticksleft--;
x->x_value += n*(x->x_slope);
}
else
{
if (x->x_target == 0.f)
zerovec_simd(out, n);
else
if (x->x_target == 1.f)
{
if (in != out)
copyvec_simd(out, in, n);
}
else
{
t_int args[6]={0,
(t_int)in,
(t_int)&x->x_target,
(t_int)out,
n,
0};
scalartimes_perf_simd(args);
}
}
return (w+5);
}
static void volctl_set(t_volctl *x, t_float f)
{
t_float slope;
int i;
int samplesleft = x->x_h * x->x_samples_per_ms;
samplesleft += x->x_blocksize - ( samplesleft & (x->x_blocksize - 1));
x->x_ticksleft = (int) (t_float)samplesleft * x->x_1overblocksize;
slope = (f - x->x_value) / samplesleft;
x->x_slope = slope;
for (i = 0; i != 4; ++i)
{
x->x_slopes[i] = i*slope;
}
x->x_slope_step = 4*slope;
x->x_target = f;
}
static void volctl_dsp(t_volctl *x, t_signal **sp)
{
const int n = sp[0]->s_n;
if (n&7)
dsp_add(volctl_perform, 4, x, sp[0]->s_vec, sp[1]->s_vec, n);
else
{
if(SIMD_CHECK2(n,sp[0]->s_vec,sp[1]->s_vec))
dsp_add(volctl_perf_simd, 4, x, sp[0]->s_vec, sp[1]->s_vec, n);
else
dsp_add(volctl_perf8, 4, x, sp[0]->s_vec, sp[1]->s_vec, n);
}
x->x_blocksize = n;
x->x_1overblocksize = 1./n;
x->x_samples_per_ms = sp[0]->s_sr / 1000.f;
}
void volctl_tilde_setup(void)
{
volctl_class = class_new(gensym("volctl~"), (t_newmethod)volctl_new,
(t_method)volctl_free, sizeof(t_volctl), 0, A_GIMME, 0);
CLASS_MAINSIGNALIN(volctl_class, t_volctl, x_f);
class_addmethod(volctl_class, (t_method)volctl_dsp, gensym("dsp"), 0);
class_addmethod(volctl_class, (t_method)volctl_set, gensym("f1"),A_FLOAT,0);
class_settip(volctl_class,gensym("signal"));
}
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