src/hb-subset-instancer-solver.cc - third_party/harfbuzz - Git at Google

 /*
  * Copyright © 2023  Behdad Esfahbod
  *
  *  This is part of HarfBuzz, a text shaping library.
  *
  * Permission is hereby granted, without written agreement and without
  * license or royalty fees, to use, copy, modify, and distribute this
  * software and its documentation for any purpose, provided that the
  * above copyright notice and the following two paragraphs appear in
  * all copies of this software.
  *
  * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
  * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
  * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
  * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
  * DAMAGE.
  *
  * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
  * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
  * FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
  * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
  * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
  */

 #include "hb-subset-instancer-solver.hh"

 /* This file is a straight port of the following:
  *
  * https://github.com/fonttools/fonttools/blob/f73220816264fc383b8a75f2146e8d69e455d398/Lib/fontTools/varLib/instancer/solver.py
  *
  * Where that file returns None for a triple, we return Triple{}.
  * This should be safe.
  */

 constexpr static float EPSILON = 1.f / (1 << 14);
 constexpr static float MAX_F2DOT14 = float (0x7FFF) / (1 << 14);

 static inline Triple _reverse_negate(const Triple &v)
 { return {-v.maximum, -v.middle, -v.minimum}; }


 static inline float supportScalar (float coord, const Triple &tent)
 {
   /* Copied from VarRegionAxis::evaluate() */
   float start = tent.minimum, peak = tent.middle, end = tent.maximum;

   if (unlikely (start > peak || peak > end))
     return 1.;
   if (unlikely (start < 0 && end > 0 && peak != 0))
     return 1.;

   if (peak == 0 || coord == peak)
     return 1.;

   if (coord <= start || end <= coord)
     return 0.;

   /* Interpolate */
   if (coord < peak)
     return (coord - start) / (peak - start);
   else
     return  (end - coord) / (end - peak);
 }

 static inline result_t
 _solve (Triple tent, Triple axisLimit, bool negative = false)
 {
   float axisMin = axisLimit.minimum;
   float axisDef = axisLimit.middle;
   float axisMax = axisLimit.maximum;
   float lower = tent.minimum;
   float peak  = tent.middle;
   float upper = tent.maximum;

   // Mirror the problem such that axisDef <= peak
   if (axisDef > peak)
   {
     result_t vec = _solve (_reverse_negate (tent),
 			   _reverse_negate (axisLimit),
 			   !negative);

     for (auto &p : vec)
       p = hb_pair (p.first, _reverse_negate (p.second));

     return vec;
   }
   // axisDef <= peak

   /* case 1: The whole deltaset falls outside the new limit; we can drop it
    *
    *                                          peak
    *  1.........................................o..........
    *                                           / \
    *                                          /   \
    *                                         /     \
    *                                        /       \
    *  0---|-----------|----------|-------- o         o----1
    *    axisMin     axisDef    axisMax   lower     upper
    */
   if (axisMax <= lower && axisMax < peak)
       return result_t{};  // No overlap

   /* case 2: Only the peak and outermost bound fall outside the new limit;
    * we keep the deltaset, update peak and outermost bound and scale deltas
    * by the scalar value for the restricted axis at the new limit, and solve
    * recursively.
    *
    *                                  |peak
    *  1...............................|.o..........
    *                                  |/ \
    *                                  /   \
    *                                 /|    \
    *                                / |     \
    *  0--------------------------- o  |      o----1
    *                           lower  |      upper
    *                                  |
    *                                axisMax
    *
    * Convert to:
    *
    *  1............................................
    *                                  |
    *                                  o peak
    *                                 /|
    *                                /x|
    *  0--------------------------- o  o upper ----1
    *                           lower  |
    *                                  |
    *                                axisMax
    */
   if (axisMax < peak)
   {
     float mult = supportScalar (axisMax, tent);
     tent = Triple{lower, axisMax, axisMax};

     result_t vec = _solve (tent, axisLimit);

     for (auto &p : vec)
       p = hb_pair (p.first * mult, p.second);

     return vec;
   }

   // lower <= axisDef <= peak <= axisMax

   float gain = supportScalar (axisDef, tent);
   result_t out {hb_pair (gain, Triple{})};

   // First, the positive side

   // outGain is the scalar of axisMax at the tent.
   float outGain = supportScalar (axisMax, tent);

   /* Case 3a: Gain is more than outGain. The tent down-slope crosses
    * the axis into negative. We have to split it into multiples.
    *
    *                      | peak  |
    *  1...................|.o.....|..............
    *                      |/x\_   |
    *  gain................+....+_.|..............
    *                     /|    |y\|
    *  ................../.|....|..+_......outGain
    *                   /  |    |  | \
    *  0---|-----------o   |    |  |  o----------1
    *    axisMin    lower  |    |  |   upper
    *                      |    |  |
    *                axisDef    |  axisMax
    *                           |
    *                      crossing
    */
   if (gain > outGain)
   {
     // Crossing point on the axis.
     float crossing = peak + (1 - gain) * (upper - peak);

     Triple loc{axisDef, peak, crossing};
     float scalar = 1.f;

     // The part before the crossing point.
     out.push (hb_pair (scalar - gain, loc));

     /* The part after the crossing point may use one or two tents,
      * depending on whether upper is before axisMax or not, in one
      * case we need to keep it down to eternity.
      *
      * Case 3a1, similar to case 1neg; just one tent needed, as in
      * the drawing above.
      */
     if (upper >= axisMax)
     {
       Triple loc {crossing, axisMax, axisMax};
       float scalar = outGain;

       out.push (hb_pair (scalar - gain, loc));
     }

     /* Case 3a2: Similar to case 2neg; two tents needed, to keep
      * down to eternity.
      *
      *                      | peak             |
      *  1...................|.o................|...
      *                      |/ \_              |
      *  gain................+....+_............|...
      *                     /|    | \xxxxxxxxxxy|
      *                    / |    |  \_xxxxxyyyy|
      *                   /  |    |    \xxyyyyyy|
      *  0---|-----------o   |    |     o-------|--1
      *    axisMin    lower  |    |      upper  |
      *                      |    |             |
      *                axisDef    |             axisMax
      *                           |
      *                      crossing
      */
     else
     {
       // A tent's peak cannot fall on axis default. Nudge it.
       if (upper == axisDef)
 	upper += EPSILON;

       // Downslope.
       Triple loc1 {crossing, upper, axisMax};
       float scalar1 = 0.f;

       // Eternity justify.
       Triple loc2 {upper, axisMax, axisMax};
       float scalar2 = 0.f;

       out.push (hb_pair (scalar1 - gain, loc1));
       out.push (hb_pair (scalar2 - gain, loc2));
     }
   }

   else
   {
     // Special-case if peak is at axisMax.
     if (axisMax == peak)
 	upper = peak;

     /* Case 3:
      * we keep deltas as is and only scale the axis upper to achieve
      * the desired new tent if feasible.
      *
      *                        peak
      *  1.....................o....................
      *                       / \_|
      *  ..................../....+_.........outGain
      *                     /     | \
      *  gain..............+......|..+_.............
      *                   /|      |  | \
      *  0---|-----------o |      |  |  o----------1
      *    axisMin    lower|      |  |   upper
      *                    |      |  newUpper
      *              axisDef      axisMax
      */
     float newUpper = peak + (1 - gain) * (upper - peak);
     assert (axisMax <= newUpper);  // Because outGain >= gain
     if (newUpper <= axisDef + (axisMax - axisDef) * 2)
     {
       upper = newUpper;
       if (!negative && axisDef + (axisMax - axisDef) * MAX_F2DOT14 < upper)
       {
 	// we clamp +2.0 to the max F2Dot14 (~1.99994) for convenience
 	upper = axisDef + (axisMax - axisDef) * MAX_F2DOT14;
 	assert (peak < upper);
       }

       Triple loc {hb_max (axisDef, lower), peak, upper};
       float scalar = 1.f;

       out.push (hb_pair (scalar - gain, loc));
     }

     /* Case 4: New limit doesn't fit; we need to chop into two tents,
      * because the shape of a triangle with part of one side cut off
      * cannot be represented as a triangle itself.
      *
      *            |   peak |
      *  1.........|......o.|....................
      *  ..........|...../x\|.............outGain
      *            |    |xxy|\_
      *            |   /xxxy|  \_
      *            |  |xxxxy|    \_
      *            |  /xxxxy|      \_
      *  0---|-----|-oxxxxxx|        o----------1
      *    axisMin | lower  |        upper
      *            |        |
      *          axisDef  axisMax
      */
     else
     {
       Triple loc1 {hb_max (axisDef, lower), peak, axisMax};
       float scalar1 = 1.f;

       Triple loc2 {peak, axisMax, axisMax};
       float scalar2 = outGain;

       out.push (hb_pair (scalar1 - gain, loc1));
       // Don't add a dirac delta!
       if (peak < axisMax)
 	out.push (hb_pair (scalar2 - gain, loc2));
     }
   }

   /* Now, the negative side
    *
    * Case 1neg: Lower extends beyond axisMin: we chop. Simple.
    *
    *                     |   |peak
    *  1..................|...|.o.................
    *                     |   |/ \
    *  gain...............|...+...\...............
    *                     |x_/|    \
    *                     |/  |     \
    *                   _/|   |      \
    *  0---------------o  |   |       o----------1
    *              lower  |   |       upper
    *                     |   |
    *               axisMin   axisDef
    */
   if (lower <= axisMin)
   {
     Triple loc {axisMin, axisMin, axisDef};
     float scalar = supportScalar (axisMin, tent);

     out.push (hb_pair (scalar - gain, loc));
   }

   /* Case 2neg: Lower is betwen axisMin and axisDef: we add two
    * tents to keep it down all the way to eternity.
    *
    *      |               |peak
    *  1...|...............|.o.................
    *      |               |/ \
    *  gain|...............+...\...............
    *      |yxxxxxxxxxxxxx/|    \
    *      |yyyyyyxxxxxxx/ |     \
    *      |yyyyyyyyyyyx/  |      \
    *  0---|-----------o   |       o----------1
    *    axisMin    lower  |       upper
    *                      |
    *                    axisDef
    */
   else
   {
     // A tent's peak cannot fall on axis default. Nudge it.
     if (lower == axisDef)
       lower -= EPSILON;

     // Downslope.
     Triple loc1 {axisMin, lower, axisDef};
     float scalar1 = 0.f;

     // Eternity justify.
     Triple loc2 {axisMin, axisMin, lower};
     float scalar2 = 0.f;

     out.push (hb_pair (scalar1 - gain, loc1));
     out.push (hb_pair (scalar2 - gain, loc2));
   }

   return out;
 }

 static inline TripleDistances _reverse_triple_distances (const TripleDistances &v)
 { return TripleDistances (v.positive, v.negative); }

 float renormalizeValue (float v, const Triple &triple,
                         const TripleDistances &triple_distances, bool extrapolate)
 {
   float lower = triple.minimum, def = triple.middle, upper = triple.maximum;
   assert (lower <= def && def <= upper);

   if (!extrapolate)
       v = hb_max (hb_min (v, upper), lower);

   if (v == def)
     return 0.f;

   if (def < 0.f)
     return -renormalizeValue (-v, _reverse_negate (triple),
                               _reverse_triple_distances (triple_distances), extrapolate);

   /* default >= 0 and v != default */
   if (v > def)
     return (v - def) / (upper - def);

   /* v < def */
   if (lower >= 0.f)
     return (v - def) / (def - lower);

   /* lower < 0 and v < default */
   float total_distance = triple_distances.negative * (-lower) + triple_distances.positive * def;

   float v_distance;
   if (v >= 0.f)
     v_distance = (def - v) * triple_distances.positive;
   else
     v_distance = (-v) * triple_distances.negative + triple_distances.positive * def;

   return (-v_distance) /total_distance;
 }

 result_t
 rebase_tent (Triple tent, Triple axisLimit, TripleDistances axis_triple_distances)
 {
   assert (-1.f <= axisLimit.minimum && axisLimit.minimum <= axisLimit.middle && axisLimit.middle <= axisLimit.maximum && axisLimit.maximum <= +1.f);
   assert (-2.f <= tent.minimum && tent.minimum <= tent.middle && tent.middle <= tent.maximum && tent.maximum <= +2.f);
   assert (tent.middle != 0.f);

   result_t sols = _solve (tent, axisLimit);

   auto n = [&axisLimit, &axis_triple_distances] (float v) { return renormalizeValue (v, axisLimit, axis_triple_distances); };

   result_t out;
   for (auto &p : sols)
   {
     if (!p.first) continue;
     if (p.second == Triple{})
     {
       out.push (p);
       continue;
     }
     Triple t = p.second;
     out.push (hb_pair (p.first,
 		       Triple{n (t.minimum), n (t.middle), n (t.maximum)}));
   }

   return out;
 }
	/*
	* Copyright © 2023 Behdad Esfahbod
	*
	* This is part of HarfBuzz, a text shaping library.
	*
	* Permission is hereby granted, without written agreement and without
	* license or royalty fees, to use, copy, modify, and distribute this
	* software and its documentation for any purpose, provided that the
	* above copyright notice and the following two paragraphs appear in
	* all copies of this software.
	*
	* IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
	* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
	* ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
	* IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
	* DAMAGE.
	*
	* THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
	* BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
	* FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS
	* ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
	* PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
	*/

	#include "hb-subset-instancer-solver.hh"

	/* This file is a straight port of the following:
	*
	* https://github.com/fonttools/fonttools/blob/f73220816264fc383b8a75f2146e8d69e455d398/Lib/fontTools/varLib/instancer/solver.py
	*
	* Where that file returns None for a triple, we return Triple{}.
	* This should be safe.
	*/

	constexpr static float EPSILON = 1.f / (1 << 14);
	constexpr static float MAX_F2DOT14 = float (0x7FFF) / (1 << 14);

	static inline Triple _reverse_negate(const Triple &v)
	{ return {-v.maximum, -v.middle, -v.minimum}; }


	static inline float supportScalar (float coord, const Triple &tent)
	{
	/* Copied from VarRegionAxis::evaluate() */
	float start = tent.minimum, peak = tent.middle, end = tent.maximum;

	if (unlikely (start > peak \|\| peak > end))
	return 1.;
	if (unlikely (start < 0 && end > 0 && peak != 0))
	return 1.;

	if (peak == 0 \|\| coord == peak)
	return 1.;

	if (coord <= start \|\| end <= coord)
	return 0.;

	/* Interpolate */
	if (coord < peak)
	return (coord - start) / (peak - start);
	else
	return (end - coord) / (end - peak);
	}

	static inline result_t
	_solve (Triple tent, Triple axisLimit, bool negative = false)
	{
	float axisMin = axisLimit.minimum;
	float axisDef = axisLimit.middle;
	float axisMax = axisLimit.maximum;
	float lower = tent.minimum;
	float peak = tent.middle;
	float upper = tent.maximum;

	// Mirror the problem such that axisDef <= peak
	if (axisDef > peak)
	{
	result_t vec = _solve (_reverse_negate (tent),
	_reverse_negate (axisLimit),
	!negative);

	for (auto &p : vec)
	p = hb_pair (p.first, _reverse_negate (p.second));

	return vec;
	}
	// axisDef <= peak

	/* case 1: The whole deltaset falls outside the new limit; we can drop it
	*
	* peak
	* 1.........................................o..........
	* / \
	* / \
	* / \
	* / \
	* 0---\|-----------\|----------\|-------- o o----1
	* axisMin axisDef axisMax lower upper
	*/
	if (axisMax <= lower && axisMax < peak)
	return result_t{}; // No overlap

	/* case 2: Only the peak and outermost bound fall outside the new limit;
	* we keep the deltaset, update peak and outermost bound and scale deltas
	* by the scalar value for the restricted axis at the new limit, and solve
	* recursively.
	*
	* \|peak
	* 1...............................\|.o..........
	* \|/ \
	* / \
	* /\| \
	* / \| \
	* 0--------------------------- o \| o----1
	* lower \| upper
	* \|
	* axisMax
	*
	* Convert to:
	*
	* 1............................................
	* \|
	* o peak
	* /\|
	* /x\|
	* 0--------------------------- o o upper ----1
	* lower \|
	* \|
	* axisMax
	*/
	if (axisMax < peak)
	{
	float mult = supportScalar (axisMax, tent);
	tent = Triple{lower, axisMax, axisMax};

	result_t vec = _solve (tent, axisLimit);

	for (auto &p : vec)
	p = hb_pair (p.first * mult, p.second);

	return vec;
	}

	// lower <= axisDef <= peak <= axisMax

	float gain = supportScalar (axisDef, tent);
	result_t out {hb_pair (gain, Triple{})};

	// First, the positive side

	// outGain is the scalar of axisMax at the tent.
	float outGain = supportScalar (axisMax, tent);

	/* Case 3a: Gain is more than outGain. The tent down-slope crosses
	* the axis into negative. We have to split it into multiples.
	*
	* \| peak \|
	* 1...................\|.o.....\|..............
	* \|/x\_ \|
	* gain................+....+_.\|..............
	* /\| \|y\\|
	* ................../.\|....\|..+_......outGain
	* / \| \| \| \
	* 0---\|-----------o \| \| \| o----------1
	* axisMin lower \| \| \| upper
	* \| \| \|
	* axisDef \| axisMax
	* \|
	* crossing
	*/
	if (gain > outGain)
	{
	// Crossing point on the axis.
	float crossing = peak + (1 - gain) * (upper - peak);

	Triple loc{axisDef, peak, crossing};
	float scalar = 1.f;

	// The part before the crossing point.
	out.push (hb_pair (scalar - gain, loc));

	/* The part after the crossing point may use one or two tents,
	* depending on whether upper is before axisMax or not, in one
	* case we need to keep it down to eternity.
	*
	* Case 3a1, similar to case 1neg; just one tent needed, as in
	* the drawing above.
	*/
	if (upper >= axisMax)
	{
	Triple loc {crossing, axisMax, axisMax};
	float scalar = outGain;

	out.push (hb_pair (scalar - gain, loc));
	}

	/* Case 3a2: Similar to case 2neg; two tents needed, to keep
	* down to eternity.
	*
	* \| peak \|
	* 1...................\|.o................\|...
	* \|/ \_ \|
	* gain................+....+_............\|...
	* /\| \| \xxxxxxxxxxy\|
	* / \| \| \_xxxxxyyyy\|
	* / \| \| \xxyyyyyy\|
	* 0---\|-----------o \| \| o-------\|--1
	* axisMin lower \| \| upper \|
	* \| \| \|
	* axisDef \| axisMax
	* \|
	* crossing
	*/
	else
	{
	// A tent's peak cannot fall on axis default. Nudge it.
	if (upper == axisDef)
	upper += EPSILON;

	// Downslope.
	Triple loc1 {crossing, upper, axisMax};
	float scalar1 = 0.f;

	// Eternity justify.
	Triple loc2 {upper, axisMax, axisMax};
	float scalar2 = 0.f;

	out.push (hb_pair (scalar1 - gain, loc1));
	out.push (hb_pair (scalar2 - gain, loc2));
	}
	}

	else
	{
	// Special-case if peak is at axisMax.
	if (axisMax == peak)
	upper = peak;

	/* Case 3:
	* we keep deltas as is and only scale the axis upper to achieve
	* the desired new tent if feasible.
	*
	* peak
	* 1.....................o....................
	* / \_\|
	* ..................../....+_.........outGain
	* / \| \
	* gain..............+......\|..+_.............
	* /\| \| \| \
	* 0---\|-----------o \| \| \| o----------1
	* axisMin lower\| \| \| upper
	* \| \| newUpper
	* axisDef axisMax
	*/
	float newUpper = peak + (1 - gain) * (upper - peak);
	assert (axisMax <= newUpper); // Because outGain >= gain
	if (newUpper <= axisDef + (axisMax - axisDef) * 2)
	{
	upper = newUpper;
	if (!negative && axisDef + (axisMax - axisDef) * MAX_F2DOT14 < upper)
	{
	// we clamp +2.0 to the max F2Dot14 (~1.99994) for convenience
	upper = axisDef + (axisMax - axisDef) * MAX_F2DOT14;
	assert (peak < upper);
	}

	Triple loc {hb_max (axisDef, lower), peak, upper};
	float scalar = 1.f;

	out.push (hb_pair (scalar - gain, loc));
	}

	/* Case 4: New limit doesn't fit; we need to chop into two tents,
	* because the shape of a triangle with part of one side cut off
	* cannot be represented as a triangle itself.
	*
	* \| peak \|
	* 1.........\|......o.\|....................
	* ..........\|...../x\\|.............outGain
	* \| \|xxy\|\_
	* \| /xxxy\| \_
	* \| \|xxxxy\| \_
	* \| /xxxxy\| \_
	* 0---\|-----\|-oxxxxxx\| o----------1
	* axisMin \| lower \| upper
	* \| \|
	* axisDef axisMax
	*/
	else
	{
	Triple loc1 {hb_max (axisDef, lower), peak, axisMax};
	float scalar1 = 1.f;

	Triple loc2 {peak, axisMax, axisMax};
	float scalar2 = outGain;

	out.push (hb_pair (scalar1 - gain, loc1));
	// Don't add a dirac delta!
	if (peak < axisMax)
	out.push (hb_pair (scalar2 - gain, loc2));
	}
	}

	/* Now, the negative side
	*
	* Case 1neg: Lower extends beyond axisMin: we chop. Simple.
	*
	* \| \|peak
	* 1..................\|...\|.o.................
	* \| \|/ \
	* gain...............\|...+...\...............
	* \|x_/\| \
	* \|/ \| \
	* _/\| \| \
	* 0---------------o \| \| o----------1
	* lower \| \| upper
	* \| \|
	* axisMin axisDef
	*/
	if (lower <= axisMin)
	{
	Triple loc {axisMin, axisMin, axisDef};
	float scalar = supportScalar (axisMin, tent);

	out.push (hb_pair (scalar - gain, loc));
	}

	/* Case 2neg: Lower is betwen axisMin and axisDef: we add two
	* tents to keep it down all the way to eternity.
	*
	* \| \|peak
	* 1...\|...............\|.o.................
	* \| \|/ \
	* gain\|...............+...\...............
	* \|yxxxxxxxxxxxxx/\| \
	* \|yyyyyyxxxxxxx/ \| \
	* \|yyyyyyyyyyyx/ \| \
	* 0---\|-----------o \| o----------1
	* axisMin lower \| upper
	* \|
	* axisDef
	*/
	else
	{
	// A tent's peak cannot fall on axis default. Nudge it.
	if (lower == axisDef)
	lower -= EPSILON;

	// Downslope.
	Triple loc1 {axisMin, lower, axisDef};
	float scalar1 = 0.f;

	// Eternity justify.
	Triple loc2 {axisMin, axisMin, lower};
	float scalar2 = 0.f;

	out.push (hb_pair (scalar1 - gain, loc1));
	out.push (hb_pair (scalar2 - gain, loc2));
	}

	return out;
	}

	static inline TripleDistances _reverse_triple_distances (const TripleDistances &v)
	{ return TripleDistances (v.positive, v.negative); }

	float renormalizeValue (float v, const Triple &triple,
	const TripleDistances &triple_distances, bool extrapolate)
	{
	float lower = triple.minimum, def = triple.middle, upper = triple.maximum;
	assert (lower <= def && def <= upper);

	if (!extrapolate)
	v = hb_max (hb_min (v, upper), lower);

	if (v == def)
	return 0.f;

	if (def < 0.f)
	return -renormalizeValue (-v, _reverse_negate (triple),
	_reverse_triple_distances (triple_distances), extrapolate);

	/* default >= 0 and v != default */
	if (v > def)
	return (v - def) / (upper - def);

	/* v < def */
	if (lower >= 0.f)
	return (v - def) / (def - lower);

	/* lower < 0 and v < default */
	float total_distance = triple_distances.negative * (-lower) + triple_distances.positive * def;

	float v_distance;
	if (v >= 0.f)
	v_distance = (def - v) * triple_distances.positive;
	else
	v_distance = (-v) * triple_distances.negative + triple_distances.positive * def;

	return (-v_distance) /total_distance;
	}

	result_t
	rebase_tent (Triple tent, Triple axisLimit, TripleDistances axis_triple_distances)
	{
	assert (-1.f <= axisLimit.minimum && axisLimit.minimum <= axisLimit.middle && axisLimit.middle <= axisLimit.maximum && axisLimit.maximum <= +1.f);
	assert (-2.f <= tent.minimum && tent.minimum <= tent.middle && tent.middle <= tent.maximum && tent.maximum <= +2.f);
	assert (tent.middle != 0.f);

	result_t sols = _solve (tent, axisLimit);

	auto n = [&axisLimit, &axis_triple_distances] (float v) { return renormalizeValue (v, axisLimit, axis_triple_distances); };

	result_t out;
	for (auto &p : sols)
	{
	if (!p.first) continue;
	if (p.second == Triple{})
	{
	out.push (p);
	continue;
	}
	Triple t = p.second;
	out.push (hb_pair (p.first,
	Triple{n (t.minimum), n (t.middle), n (t.maximum)}));
	}

	return out;
	}