/*
 * file: hot/hot.c
 *
 * $Id: hot.c,v 1.38 2004/10/12 21:48:38 mitch Exp $
 */

/*
 * hot.c - Scan an image for pixels with RGB values that will give
 *	"unsafe" values of chrominance signal or composite signal
 *	amplitude when encoded into an NTSC or PAL colour signal.
 *	(This happens for certain high-intensity high-saturation colours
 *	that are rare in real scenes, but can easily be present
 *	in synthetic images.)
 *
 * 	Such pixels can be flagged so the user may then choose other
 *	colours.  Or, the offending pixels can be made "safe"
 *	in a manner that preserves hue.
 *
 *	There are two reasonable ways to make a pixel "safe":
 *	We can reduce its intensity (luminance) while leaving
 *	hue and saturation the same.  Or, we can reduce saturation
 *	while leaving hue and luminance the same.  A #define selects
 *	which strategy to use.
 *
 * Note to the user: You must add your own read_pixel() and write_pixel()
 *	routines.  You may have to modify pix_decode() and pix_encode().
 *	MAXPIX, WID, and HGT are likely to need modification.
 */

/*
 * Originally written as "ikNTSC.c" by Alan Wm Paeth,
 *	University of Waterloo, August, 1985
 * Updated by Dave Martindale, Imax Systems Corp., December 1990
 */

/*
 * Compile time options:
 *
 *
 * CHROMA_LIM is the limit (in IRE units) of the overall
 *	chrominance amplitude; it should be 50 or perhaps
 *	very slightly higher.
 *
 * COMPOS_LIM is the maximum amplitude (in IRE units) allowed for
 *	the composite signal.  A value of 100 is the maximum
 *	monochrome white, and is always safe.  120 is the absolute
 *	limit for NTSC broadcasting, since the transmitter's carrier
 *	goes to zero with 120 IRE input signal.  Generally, 110
 *	is a good compromise - it allows somewhat brighter colours
 *	than 100, while staying safely away from the hard limit.
 */

/*
 * run-time options:
 *
 * Define either NTSC or PAL as 1 to select the colour system.
 * Define the other one as zero, or leave it undefined.
 *
 * Define FLAG_HOT as 1 if you want "hot" pixels set to black
 *	to identify them.  Otherwise they will be made safe.
 *
 * Define REDUCE_SAT as 1 if you want hot pixels to be repaired by
 *	reducing their saturation.  By default, luminance is reduced.
 *
 */

#include "config.h"

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include <gtk/gtk.h>

#include <libgimp/gimp.h>
#include <libgimp/gimpui.h>

#include "libgimp/stdplugins-intl.h"

typedef struct
{
  gint32 image;
  gint32 drawable;
  gint32 mode;
  gint32 action;
  gint32 new_layerp;
} piArgs;

typedef enum
{
  ACT_LREDUX,
  ACT_SREDUX,
  ACT_FLAG
} hotAction;

typedef enum
{
  MODE_NTSC,
  MODE_PAL
} hotModes;

#define	CHROMA_LIM      50.0		/* chroma amplitude limit */
#define	COMPOS_LIM      110.0		/* max IRE amplitude */

/*
 * RGB to YIQ encoding matrix.
 */

struct
{
  gdouble pedestal;
  gdouble gamma;
  gdouble code[3][3];
} mode[2] = {
  {
    7.5,
    2.2,
    {
      { 0.2989,  0.5866,  0.1144 },
      { 0.5959, -0.2741, -0.3218 },
      { 0.2113, -0.5227,  0.3113 }
    }
  },
  {
    0.0,
    2.8,
    {
      { 0.2989,  0.5866,  0.1144 },
      { -0.1473, -0.2891,  0.4364 },
      { 0.6149, -0.5145, -0.1004 }
    }
  }
};


#define SCALE	8192            /* scale factor: do floats with int math */
#define MAXPIX	 255            /* white value */

static gint	tab[3][3][MAXPIX+1]; /* multiply lookup table */
static gdouble	chroma_lim;          /* chroma limit */
static gdouble	compos_lim;          /* composite amplitude limit */
static glong	ichroma_lim2;        /* chroma limit squared (scaled integer) */
static gint	icompos_lim;         /* composite amplitude limit (scaled integer) */

static void query        (void);
static void run          (const gchar      *name,
			  gint              nparam,
			  const GimpParam  *param,
			  gint             *nretvals,
			  GimpParam       **retvals);

static gint pluginCore   (piArgs   *argp);
static gint pluginCoreIA (piArgs   *argp);
static gboolean hotp     (guint8  r,
			  guint8  g,
			  guint8  b);
static void build_tab    (gint    m);

/*
 * gc: apply the gamma correction specified for this video standard.
 * inv_gc: inverse function of gc.
 *
 * These are generally just a call to pow(), but be careful!
 * Future standards may use more complex functions.
 * (e.g. SMPTE 240M's "electro-optic transfer characteristic").
 */
#define gc(x,m) pow(x, 1.0 / mode[m].gamma)
#define inv_gc(x,m) pow(x, mode[m].gamma)

/*
 * pix_decode: decode an integer pixel value into a floating-point
 *	intensity in the range [0, 1].
 *
 * pix_encode: encode a floating-point intensity into an integer
 *	pixel value.
 *
 * The code given here assumes simple linear encoding; you must change
 * these routines if you use a different pixel encoding technique.
 */
#define pix_decode(v)  ((double)v / (double)MAXPIX)
#define pix_encode(v)  ((int)(v * (double)MAXPIX + 0.5))

GimpPlugInInfo PLUG_IN_INFO =
{
  NULL,  /* init_proc  */
  NULL,  /* quit_proc  */
  query, /* query_proc */
  run,   /* run_proc   */
};

MAIN ()

static void
query (void)
{
  static GimpParamDef args[] =
  {
    { GIMP_PDB_INT32, "run_mode", "Interactive, non-interactive" },
    { GIMP_PDB_IMAGE, "image", "The Image" },
    { GIMP_PDB_DRAWABLE, "drawable", "The Drawable" },
    { GIMP_PDB_INT32, "mode", "Mode -- NTSC/PAL" },
    { GIMP_PDB_INT32, "action", "The action to perform" },
    { GIMP_PDB_INT32, "new_layerp", "Create a new layer iff True" }
  };

  gimp_install_procedure ("plug_in_hot",
			  "Look for hot NTSC or PAL pixels ",
			  "hot scans an image for pixels that will give unsave "
			  "values of chrominance or composite signale "
			  "amplitude when encoded into an NTSC or PAL signal.  "
			  "Three actions can be performed on these ``hot'' "
			  "pixels. (0) reduce luminance, (1) reduce "
			  "saturation, or (2) Blacken.",
			  "Eric L. Hernes, Alan Wm Paeth",
			  "Eric L. Hernes",
			  "1997",
			  N_("_Hot..."),
			  "RGB",
			  GIMP_PLUGIN,
			  G_N_ELEMENTS (args), 0,
			  args, NULL);

  gimp_plugin_menu_register ("plug_in_hot", "<Image>/Filters/Colors");
}

static void
run (const gchar      *name,
     gint              nparam,
     const GimpParam  *param,
     gint             *nretvals,
     GimpParam       **retvals)
{
  static GimpParam rvals[1];
  piArgs    args;

  *nretvals = 1;
  *retvals  = rvals;

  INIT_I18N ();

  memset (&args, (int) 0, sizeof (args));
  args.mode = -1;

  gimp_get_data ("plug_in_hot", &args);

  args.image    = param[1].data.d_image;
  args.drawable = param[2].data.d_drawable;

  rvals[0].type          = GIMP_PDB_STATUS;
  rvals[0].data.d_status = GIMP_PDB_SUCCESS;

  switch (param[0].data.d_int32)
    {
    case GIMP_RUN_INTERACTIVE:
      /* XXX: add code here for interactive running */
      if (args.mode == -1)
	{
	  args.mode       = MODE_NTSC;
	  args.action     = ACT_LREDUX;
	  args.new_layerp = 1;
	}

      if (pluginCoreIA(&args) == -1)
	{
	  rvals[0].data.d_status = GIMP_PDB_EXECUTION_ERROR;
	}
      gimp_set_data ("plug_in_hot", &args, sizeof (args));

    break;

    case GIMP_RUN_NONINTERACTIVE:
      /* XXX: add code here for non-interactive running */
      if (nparam != 6)
	{
	  rvals[0].data.d_status = GIMP_PDB_CALLING_ERROR;
	  break;
	}
      args.mode       = param[3].data.d_int32;
      args.action     = param[4].data.d_int32;
      args.new_layerp = param[5].data.d_int32;

      if (pluginCore(&args) == -1)
	{
	  rvals[0].data.d_status = GIMP_PDB_EXECUTION_ERROR;
	  break;
	}
    break;

    case GIMP_RUN_WITH_LAST_VALS:
      /* XXX: add code here for last-values running */
      if (pluginCore (&args) == -1)
	{
	  rvals[0].data.d_status = GIMP_PDB_EXECUTION_ERROR;
	}
    break;
  }
}

static gint
pluginCore (piArgs *argp)
{
  GimpDrawable *drw, *ndrw=NULL;
  GimpPixelRgn srcPr, dstPr;
  gint retval = 0;
  gint nl=0;
  gint y, x, i;
  gint Y, I, Q;
  guint width, height, bpp;
  gint sel_x1, sel_x2, sel_y1, sel_y2;
  gint prog_interval;
  guchar *src, *s, *dst, *d;
  guchar r, prev_r=0, new_r=0;
  guchar g, prev_g=0, new_g=0;
  guchar b, prev_b=0, new_b=0;
  gdouble fy, fc, t, scale;
  gdouble pr, pg, pb;
  gdouble py;

  drw = gimp_drawable_get (argp->drawable);

  width = drw->width;
  height = drw->height;
  bpp = drw->bpp;
  if (argp->new_layerp)
    {
      gchar name[40];
      gchar *mode_names[] =
      {
	"ntsc",
	"pal",
      };
      gchar *action_names[] =
      {
	"lum redux",
	"sat redux",
	"flag",
      };

      g_snprintf (name, sizeof (name), "hot mask (%s, %s)",
		  mode_names[argp->mode],
		  action_names[argp->action]);

      nl = gimp_layer_new (argp->image, name, width, height,
			   GIMP_RGBA_IMAGE, (gdouble)100, GIMP_NORMAL_MODE);
      ndrw = gimp_drawable_get (nl);
      gimp_drawable_fill (nl, GIMP_TRANSPARENT_FILL);
      gimp_image_add_layer (argp->image, nl, 0);
    }

  gimp_drawable_mask_bounds (drw->drawable_id,
			     &sel_x1, &sel_y1, &sel_x2, &sel_y2);

  width = sel_x2 - sel_x1;
  height = sel_y2 - sel_y1;

  src = g_new (guchar, width * height * bpp);
  dst = g_new (guchar, width * height * 4);
  gimp_pixel_rgn_init (&srcPr, drw, sel_x1, sel_y1, width, height,
                       FALSE, FALSE);

  if (argp->new_layerp)
    {
      gimp_pixel_rgn_init (&dstPr, ndrw, sel_x1, sel_y1, width, height,
                           FALSE, FALSE);
    }
  else
    {
      gimp_pixel_rgn_init (&dstPr, drw, sel_x1, sel_y1, width, height,
                           TRUE, TRUE);
    }

  gimp_pixel_rgn_get_rect (&srcPr, src, sel_x1, sel_y1, width, height);

  s = src;
  d = dst;

  build_tab (argp->mode);

  gimp_progress_init (_("Hot..."));
  prog_interval = height / 10;

  for (y = sel_y1; y < sel_y2; y++)
    {
      if (y % prog_interval == 0)
	gimp_progress_update ((double) y / (double) (sel_y2 - sel_y1));

      for (x = sel_x1; x < sel_x2; x++)
	{
	  if (hotp (r = *(s + 0), g = *(s + 1), b = *(s + 2)))
	    {
	      if (argp->action == ACT_FLAG)
		{
		  for (i = 0; i < 3; i++)
		    *d++ = 0;
		  s += 3;
		  if (bpp == 4)
		    *d++ = *s++;
		  else if (argp->new_layerp)
		    *d++ = 255;
		}
	      else
		{
		  /*
		   * Optimization: cache the last-computed hot pixel.
		   */
		  if (r == prev_r && g == prev_g && b == prev_b)
		    {
		      *d++ = new_r;
		      *d++ = new_g;
		      *d++ = new_b;
		      s += 3;
		      if (bpp == 4)
			*d++ = *s++;
		      else if (argp->new_layerp)
			*d++ = 255;
		    }
		  else
		    {
		      Y = tab[0][0][r] + tab[0][1][g] + tab[0][2][b];
		      I = tab[1][0][r] + tab[1][1][g] + tab[1][2][b];
		      Q = tab[2][0][r] + tab[2][1][g] + tab[2][2][b];

		      prev_r = r;
		      prev_g = g;
		      prev_b = b;
		      /*
		       * Get Y and chroma amplitudes in floating point.
		       *
		       * If your C library doesn't have hypot(), just use
		       * hypot(a,b) = sqrt(a*a, b*b);
		       *
		       * Then extract linear (un-gamma-corrected)
		       * floating-point pixel RGB values.
		       */
		      fy = (double)Y / (double)SCALE;
		      fc = hypot ((double) I / (double) SCALE,
				  (double) Q / (double) SCALE);

		      pr = (double) pix_decode (r);
		      pg = (double) pix_decode (g);
		      pb = (double) pix_decode (b);

		      /*
		       * Reducing overall pixel intensity by scaling R,
		       * G, and B reduces Y, I, and Q by the same factor.
		       * This changes luminance but not saturation, since
		       * saturation is determined by the chroma/luminance
		       * ratio.
		       *
		       * On the other hand, by linearly interpolating
		       * between the original pixel value and a grey
		       * pixel with the same luminance (R=G=B=Y), we
		       * change saturation without affecting luminance.
		       */
		      if (argp->action == ACT_LREDUX)
			{
			  /*
			   * Calculate a scale factor that will bring the pixel
			   * within both chroma and composite limits, if we scale
			   * luminance and chroma simultaneously.
			   *
			   * The calculated chrominance reduction applies
			   * to the gamma-corrected RGB values that are
			   * the input to the RGB-to-YIQ operation.
			   * Multiplying the original un-gamma-corrected
			   * pixel values by the scaling factor raised to
			   * the "gamma" power is equivalent, and avoids
			   * calling gc() and inv_gc() three times each.  */
			  scale = chroma_lim / fc;
			  t = compos_lim / (fy + fc);
			  if (t < scale)
			    scale = t;
			  scale = pow (scale, mode[argp->mode].gamma);

			  r = (guint8) pix_encode (scale * pr);
			  g = (guint8) pix_encode (scale * pg);
			  b = (guint8) pix_encode (scale * pb);
			}
		      else
			{ /* ACT_SREDUX hopefully */
			  /*
			   * Calculate a scale factor that will bring the
			   * pixel within both chroma and composite
			   * limits, if we scale chroma while leaving
			   * luminance unchanged.
			   *
			   * We have to interpolate gamma-corrected RGB
			   * values, so we must convert from linear to
			   * gamma-corrected before interpolation and then
			   * back to linear afterwards.
			   */
			  scale = chroma_lim / fc;
			  t = (compos_lim - fy) / fc;
			  if (t < scale)
			    scale = t;

			  pr = gc (pr, argp->mode);
			  pg = gc (pg, argp->mode);
			  pb = gc (pb, argp->mode);
			  py = pr * mode[argp->mode].code[0][0] + pg *
			    mode[argp->mode].code[0][1] + pb *
			    mode[argp->mode].code[0][2];
			  r = pix_encode (inv_gc (py + scale * (pr - py),
						  argp->mode));
			  g = pix_encode (inv_gc (py + scale * (pg - py),
						  argp->mode));
			  b = pix_encode (inv_gc (py + scale * (pb - py),
						  argp->mode));
			}
		      *d++ = new_r = r;
		      *d++ = new_g = g;
		      *d++ = new_b = b;
		      s += 3;
		      if (bpp == 4)
			*d++ = *s++;
		      else if (argp->new_layerp)
			*d++ = 255;
		    }
		}
	    }
	  else
	    {
	      if (!argp->new_layerp)
		{
		  for (i = 0; i < bpp; i++)
		    *d++ = *s++;
		}
	      else
		{
		  s += bpp;
		  d += 4;
		}
	    }
	}
    }
  gimp_pixel_rgn_set_rect (&dstPr, dst, sel_x1, sel_y1, width, height);

  g_free (src);
  g_free (dst);

  if (argp->new_layerp)
    {
      gimp_drawable_flush (ndrw);
      gimp_drawable_update (nl, sel_x1, sel_y1, width, height);
    }
  else
    {
      gimp_drawable_flush (drw);
      gimp_drawable_merge_shadow (drw->drawable_id, TRUE);
      gimp_drawable_update (drw->drawable_id, sel_x1, sel_y1, width, height);
    }

  gimp_displays_flush ();

  return retval;
}

static gint
pluginCoreIA (piArgs *argp)
{
  GtkWidget *dlg;
  GtkWidget *hbox;
  GtkWidget *vbox;
  GtkWidget *toggle;
  GtkWidget *frame;
  gboolean   run;

  gimp_ui_init ("hot", FALSE);

  dlg = gimp_dialog_new (_("Hot"), "hot",
                         NULL, 0,
			 gimp_standard_help_func, "plug-in-hot",

			 GTK_STOCK_CANCEL, GTK_RESPONSE_CANCEL,
			 GTK_STOCK_OK,     GTK_RESPONSE_OK,

			 NULL);

  hbox = gtk_hbox_new (FALSE, 12);
  gtk_container_set_border_width (GTK_CONTAINER (hbox), 12);
  gtk_box_pack_start (GTK_BOX (GTK_DIALOG (dlg)->vbox), hbox, TRUE, TRUE, 0);
  gtk_widget_show (hbox);

  vbox = gtk_vbox_new (FALSE, 12);
  gtk_box_pack_start (GTK_BOX (hbox), vbox, TRUE, TRUE, 0);
  gtk_widget_show (vbox);

  frame = gimp_int_radio_group_new (TRUE, _("Mode"),
				    G_CALLBACK (gimp_radio_button_update),
				    &argp->mode, argp->mode,

				    "N_TSC", MODE_NTSC, NULL,
				    "_PAL",  MODE_PAL,  NULL,

				    NULL);

  gtk_box_pack_start (GTK_BOX (vbox), frame, FALSE, FALSE, 0);
  gtk_widget_show (frame);

  toggle = gtk_check_button_new_with_mnemonic (_("Create _New layer"));
  gtk_toggle_button_set_active (GTK_TOGGLE_BUTTON (toggle), argp->new_layerp);
  gtk_box_pack_start (GTK_BOX (vbox), toggle, FALSE, FALSE, 0);
  gtk_widget_show (toggle);

  g_signal_connect (toggle, "toggled",
                    G_CALLBACK (gimp_toggle_button_update),
                    &argp->new_layerp);

  frame = gimp_int_radio_group_new (TRUE, _("Action"),
                                    G_CALLBACK (gimp_radio_button_update),
                                    &argp->action, argp->action,

                                    _("Reduce _Luminance"),  ACT_LREDUX, NULL,
                                    _("Reduce _Saturation"), ACT_SREDUX, NULL,
                                    _("_Blacken"),           ACT_FLAG,   NULL,

                                    NULL);

  gtk_box_pack_start (GTK_BOX (hbox), frame, FALSE, FALSE, 0);
  gtk_widget_show (frame);

  gtk_widget_show (dlg);

  run = (gimp_dialog_run (GIMP_DIALOG (dlg)) == GTK_RESPONSE_OK);

  gtk_widget_destroy (dlg);

  if (run)
    return pluginCore (argp);
  else
    return -1;
}

/*
 * build_tab: Build multiply lookup table.
 *
 * For each possible pixel value, decode value into floating-point
 * intensity.  Then do gamma correction required by the video
 * standard.  Scale the result by our fixed-point scale factor.
 * Then calculate 9 lookup table entries for this pixel value.
 *
 * We also calculate floating-point and scaled integer versions
 * of our limits here.  This prevents evaluating expressions every pixel
 * when the compiler is too stupid to evaluate constant-valued
 * floating-point expressions at compile time.
 *
 * For convenience, the limits are #defined using IRE units.
 * We must convert them here into the units in which YIQ
 * are measured.  The conversion from IRE to internal units
 * depends on the pedestal level in use, since as Y goes from
 * 0 to 1, the signal goes from the pedestal level to 100 IRE.
 * Chroma is always scaled to remain consistent with Y.
 */
static void
build_tab (int m)
{
  double f;
  int pv;

  for (pv = 0; pv <= MAXPIX; pv++)
    {
      f = (double)SCALE * (double)gc((double)pix_decode(pv),m);
      tab[0][0][pv] = (int)(f * mode[m].code[0][0] + 0.5);
      tab[0][1][pv] = (int)(f * mode[m].code[0][1] + 0.5);
      tab[0][2][pv] = (int)(f * mode[m].code[0][2] + 0.5);
      tab[1][0][pv] = (int)(f * mode[m].code[1][0] + 0.5);
      tab[1][1][pv] = (int)(f * mode[m].code[1][1] + 0.5);
      tab[1][2][pv] = (int)(f * mode[m].code[1][2] + 0.5);
      tab[2][0][pv] = (int)(f * mode[m].code[2][0] + 0.5);
      tab[2][1][pv] = (int)(f * mode[m].code[2][1] + 0.5);
      tab[2][2][pv] = (int)(f * mode[m].code[2][2] + 0.5);
    }

  chroma_lim = (double)CHROMA_LIM / (100.0 - mode[m].pedestal);
  compos_lim = ((double)COMPOS_LIM - mode[m].pedestal) /
    (100.0 - mode[m].pedestal);

  ichroma_lim2 = (int)(chroma_lim * SCALE + 0.5);
  ichroma_lim2 *= ichroma_lim2;
  icompos_lim = (int)(compos_lim * SCALE + 0.5);
}

static gboolean
hotp (guint8 r,
      guint8 g,
      guint8 b)
{
  int	y, i, q;
  long	y2, c2;

  /*
   * Pixel decoding, gamma correction, and matrix multiplication
   * all done by lookup table.
   *
   * "i" and "q" are the two chrominance components;
   * they are I and Q for NTSC.
   * For PAL, "i" is U (scaled B-Y) and "q" is V (scaled R-Y).
   * Since we only care about the length of the chroma vector,
   * not its angle, we don't care which is which.
   */
  y = tab[0][0][r] + tab[0][1][g] + tab[0][2][b];
  i = tab[1][0][r] + tab[1][1][g] + tab[1][2][b];
  q = tab[2][0][r] + tab[2][1][g] + tab[2][2][b];

  /*
   * Check to see if the chrominance vector is too long or the
   * composite waveform amplitude is too large.
   *
   * Chrominance is too large if
   *
   *	sqrt(i^2, q^2)  >  chroma_lim.
   *
   * The composite signal amplitude is too large if
   *
   *	y + sqrt(i^2, q^2)  >  compos_lim.
   *
   * We avoid doing the sqrt by checking
   *
   *	i^2 + q^2  >  chroma_lim^2
   * and
   *	y + sqrt(i^2 + q^2)  >  compos_lim
   *	sqrt(i^2 + q^2)  >  compos_lim - y
   *	i^2 + q^2  >  (compos_lim - y)^2
   *
   */

  c2 = (long)i * i + (long)q * q;
  y2 = (long)icompos_lim - y;
  y2 *= y2;

  if (c2 <= ichroma_lim2 && c2 <= y2)
    {	/* no problems */
      return FALSE;
    }

  return TRUE;
}