path: root/src/vline~~.c

/* For information on usage and redistribution, and for a DISCLAIMER OF ALL
* WARRANTIES, see the file, "LICENSE.txt," in this distribution.

iem_dp written by IOhannes m zmoelnig, Thomas Musil, Copyright (c) IEM KUG Graz Austria 1999 - 2007 */
/* double precision library */

#include "m_pd.h"
#include "iemlib.h"
#include "iem_dp.h"


/* -------------------------- vline~~ ------------------------------ */
/* based on miller's vline~ which is part of pd */

static t_class *vline_tilde_tilde_class;

typedef struct _vseg_tt
{
  double  s_targettime;
  double  s_starttime;
  double  s_target;
  struct  _vseg_tt *s_next;
} t_vseg_tt;

typedef struct _vline_tilde_tilde
{
  t_object   x_obj;
  double     x_value;
  double     x_inc;
  double     x_referencetime;
  double     x_samppermsec;
  double     x_msecpersamp;
  double     x_targettime;
  double     x_target;
  t_float    x_inlet2_fine_target;
  t_float    x_inlet3_coarse_ramp_duration;
  t_float    x_inlet4_fine_ramp_duration;
  t_float    x_inlet5_coarse_delay;
  t_float    x_inlet6_fine_delay;
  t_vseg_tt  *x_list;
} t_vline_tilde_tilde;

static t_int *vline_tilde_tilde_perform(t_int *w)
{
  t_vline_tilde_tilde *x = (t_vline_tilde_tilde *)(w[1]);
  t_float *out_float_cast = (t_float *)(w[2]);
  t_float *out_residual = (t_float *)(w[3]);
  t_float f_val;
  int n = (int)(w[4]), i;
  double d_val = x->x_value;
  double inc = x->x_inc;
  double msecpersamp = x->x_msecpersamp;
  double samppermsec = x->x_samppermsec;
  double timenow = clock_gettimesince(x->x_referencetime) - (double)n * msecpersamp;
  t_vseg_tt *seg_list = x->x_list;
  
  for(i = 0; i < n; i++)
  {
    double timenext = timenow + msecpersamp;
checknext_tt:
    if(seg_list)
    {
      /* has starttime elapsed?  If so update value and increment */
      if(seg_list->s_starttime < timenext)
      {
        if(x->x_targettime <= timenext)
          d_val = x->x_target, inc = 0;
        /* if zero-length segment bash output value */
        if(seg_list->s_targettime <= seg_list->s_starttime)
        {
          d_val = seg_list->s_target;
          inc = 0;
        }
        else
        {
          double incpermsec = (seg_list->s_target - d_val)/(seg_list->s_targettime - seg_list->s_starttime);
		  
          d_val += incpermsec * (timenext - seg_list->s_starttime);
          inc = incpermsec * msecpersamp;
        }
        x->x_inc = inc;
        x->x_target = seg_list->s_target;
        x->x_targettime = seg_list->s_targettime;
        x->x_list = seg_list->s_next;
        t_freebytes(seg_list, sizeof(*seg_list));
        seg_list = x->x_list;
        goto checknext_tt;
      }
    }
    if(x->x_targettime <= timenext)
    {
      d_val = x->x_target;
      inc = x->x_inc = 0;
      x->x_targettime = 1e20;
    }
    f_val = iem_dp_cast_to_float(d_val);
    *out_residual++ = iem_dp_calc_residual(d_val, f_val);
    *out_float_cast++ = f_val;
    d_val += inc;
    timenow = timenext;
  }
  x->x_value = d_val;
  return (w+5);
}

static void vline_tilde_tilde_stop(t_vline_tilde_tilde *x)
{
  t_vseg_tt *s1, *s2;
  
  for (s1 = x->x_list; s1; s1 = s2)
    s2 = s1->s_next, t_freebytes(s1, sizeof(*s1));
  x->x_list = 0;
  x->x_inc = 0;
  x->x_inlet2_fine_target = x->x_inlet3_coarse_ramp_duration = 0;
  x->x_inlet4_fine_ramp_duration = x->x_inlet5_coarse_delay = x->x_inlet6_fine_delay = 0;
  x->x_target = x->x_value;
  x->x_targettime = 1e20;
}

static void vline_tilde_tilde_float(t_vline_tilde_tilde *x, t_float inlet1_coarse_target) /* coarse target value */
{
  double timenow = clock_gettimesince(x->x_referencetime);
  double inlet12_target = iem_dp_calc_sum(inlet1_coarse_target, x->x_inlet2_fine_target);
  double inlet34_ramp_duration = iem_dp_calc_sum(x->x_inlet3_coarse_ramp_duration, x->x_inlet4_fine_ramp_duration);
  double inlet56_delay = iem_dp_calc_sum(x->x_inlet5_coarse_delay, x->x_inlet6_fine_delay);
  double starttime = timenow + inlet56_delay;
  t_vseg_tt *s1, *s2, *deletefrom = 0, *snew;
  
  if(inlet34_ramp_duration < 0)
    inlet34_ramp_duration = 0;
  
/*  if (PD_BIGORSMALL(inlet12_target))
    inlet12_target = 0;  */
  
  /* negative delay input means stop and jump immediately to new value */
  if (inlet56_delay < 0)
  {
    x->x_value = inlet12_target;
    vline_tilde_tilde_stop(x);
    return;
  }
  snew = (t_vseg_tt *)t_getbytes(sizeof(*snew));
  /* check if we supplant the first item in the list.  We supplant
  an item by having an earlier starttime, or an equal starttime unless
  the equal one was instantaneous and the new one isn't (in which case
  we'll do a jump-and-slide starting at that time.) */
  if (!x->x_list || x->x_list->s_starttime > starttime ||
    (x->x_list->s_starttime == starttime &&
    (x->x_list->s_targettime > x->x_list->s_starttime || inlet34_ramp_duration <= 0)))
  {
    deletefrom = x->x_list;
    x->x_list = snew;
  }
  else
  {
    for (s1 = x->x_list; s2 = s1->s_next; s1 = s2)
    {
      if (s2->s_starttime > starttime ||
        (s2->s_starttime == starttime &&
        (s2->s_targettime > s2->s_starttime || inlet34_ramp_duration <= 0)))
      {
        deletefrom = s2;
        s1->s_next = snew;
        goto vl_didit_tt;
      }
    }
    s1->s_next = snew;
    deletefrom = 0;
vl_didit_tt: ;
  }
  while (deletefrom)
  {
    s1 = deletefrom->s_next;
    t_freebytes(deletefrom, sizeof(*deletefrom));
    deletefrom = s1;
  }
  snew->s_next = 0;
  snew->s_target = inlet12_target;
  snew->s_starttime = starttime;
  snew->s_targettime = starttime + inlet34_ramp_duration;
  x->x_inlet3_coarse_ramp_duration = x->x_inlet4_fine_ramp_duration = 0;
  x->x_inlet5_coarse_delay = x->x_inlet6_fine_delay = 0;
}

static void vline_tilde_tilde_dsp(t_vline_tilde_tilde *x, t_signal **sp)
{
  dsp_add(vline_tilde_tilde_perform, 4, x, sp[0]->s_vec, sp[1]->s_vec, sp[0]->s_n);
  x->x_samppermsec = ((double)(sp[0]->s_sr)) / 1000.0;
  x->x_msecpersamp = ((double)1000.0) / sp[0]->s_sr;
}

static void *vline_tilde_tilde_new(t_floatarg init_val)
{
  t_vline_tilde_tilde *x = (t_vline_tilde_tilde *)pd_new(vline_tilde_tilde_class);
  
  outlet_new(&x->x_obj, gensym("signal"));
  outlet_new(&x->x_obj, gensym("signal"));
  floatinlet_new(&x->x_obj, &x->x_inlet2_fine_target);
  floatinlet_new(&x->x_obj, &x->x_inlet3_coarse_ramp_duration);
  floatinlet_new(&x->x_obj, &x->x_inlet4_fine_ramp_duration);
  floatinlet_new(&x->x_obj, &x->x_inlet5_coarse_delay);
  floatinlet_new(&x->x_obj, &x->x_inlet6_fine_delay);
  x->x_inlet2_fine_target = x->x_inlet3_coarse_ramp_duration = 0;
  x->x_inlet4_fine_ramp_duration = x->x_inlet5_coarse_delay = x->x_inlet6_fine_delay = 0;
  x->x_value = x->x_inc = 0;
  x->x_referencetime = clock_getlogicaltime();
  x->x_list = 0;
  x->x_samppermsec = 0;
  x->x_targettime = 1e20;
  return (x);
}

void vline_tilde_tilde_setup(void)
{
  vline_tilde_tilde_class = class_new(gensym("vline~~"), (t_newmethod)vline_tilde_tilde_new,
    (t_method)vline_tilde_tilde_stop, sizeof(t_vline_tilde_tilde), 0, 0);
  class_addfloat(vline_tilde_tilde_class, (t_method)vline_tilde_tilde_float);
  class_addmethod(vline_tilde_tilde_class, (t_method)vline_tilde_tilde_dsp, gensym("dsp"), 0);
  class_addmethod(vline_tilde_tilde_class, (t_method)vline_tilde_tilde_stop, gensym("stop"), 0);
}