third_party/lcms/src/cmsmtrx.c - pdfium - Git at Google

 //---------------------------------------------------------------------------------
 //
 //  Little Color Management System
 //  Copyright (c) 1998-2020 Marti Maria Saguer
 //
 // Permission is hereby granted, free of charge, to any person obtaining
 // a copy of this software and associated documentation files (the "Software"),
 // to deal in the Software without restriction, including without limitation
 // the rights to use, copy, modify, merge, publish, distribute, sublicense,
 // and/or sell copies of the Software, and to permit persons to whom the Software
 // is furnished to do so, subject to the following conditions:
 //
 // The above copyright notice and this permission notice shall be included in
 // all copies or substantial portions of the Software.
 //
 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
 // THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 // NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
 // LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
 // OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 // WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 //
 //---------------------------------------------------------------------------------
 //

 #include "lcms2_internal.h"


 #define DSWAP(x, y)     {cmsFloat64Number tmp = (x); (x)=(y); (y)=tmp;}


 // Initiate a vector
 void CMSEXPORT _cmsVEC3init(cmsVEC3* r, cmsFloat64Number x, cmsFloat64Number y, cmsFloat64Number z)
 {
     r -> n[VX] = x;
     r -> n[VY] = y;
     r -> n[VZ] = z;
 }

 // Vector subtraction
 void CMSEXPORT _cmsVEC3minus(cmsVEC3* r, const cmsVEC3* a, const cmsVEC3* b)
 {
   r -> n[VX] = a -> n[VX] - b -> n[VX];
   r -> n[VY] = a -> n[VY] - b -> n[VY];
   r -> n[VZ] = a -> n[VZ] - b -> n[VZ];
 }

 // Vector cross product
 void CMSEXPORT _cmsVEC3cross(cmsVEC3* r, const cmsVEC3* u, const cmsVEC3* v)
 {
     r ->n[VX] = u->n[VY] * v->n[VZ] - v->n[VY] * u->n[VZ];
     r ->n[VY] = u->n[VZ] * v->n[VX] - v->n[VZ] * u->n[VX];
     r ->n[VZ] = u->n[VX] * v->n[VY] - v->n[VX] * u->n[VY];
 }

 // Vector dot product
 cmsFloat64Number CMSEXPORT _cmsVEC3dot(const cmsVEC3* u, const cmsVEC3* v)
 {
     return u->n[VX] * v->n[VX] + u->n[VY] * v->n[VY] + u->n[VZ] * v->n[VZ];
 }

 // Euclidean length
 cmsFloat64Number CMSEXPORT _cmsVEC3length(const cmsVEC3* a)
 {
     return sqrt(a ->n[VX] * a ->n[VX] +
                 a ->n[VY] * a ->n[VY] +
                 a ->n[VZ] * a ->n[VZ]);
 }

 // Euclidean distance
 cmsFloat64Number CMSEXPORT _cmsVEC3distance(const cmsVEC3* a, const cmsVEC3* b)
 {
     cmsFloat64Number d1 = a ->n[VX] - b ->n[VX];
     cmsFloat64Number d2 = a ->n[VY] - b ->n[VY];
     cmsFloat64Number d3 = a ->n[VZ] - b ->n[VZ];

     return sqrt(d1*d1 + d2*d2 + d3*d3);
 }


 // 3x3 Identity
 void CMSEXPORT _cmsMAT3identity(cmsMAT3* a)
 {
     _cmsVEC3init(&a-> v[0], 1.0, 0.0, 0.0);
     _cmsVEC3init(&a-> v[1], 0.0, 1.0, 0.0);
     _cmsVEC3init(&a-> v[2], 0.0, 0.0, 1.0);
 }

 static
 cmsBool CloseEnough(cmsFloat64Number a, cmsFloat64Number b)
 {
     return fabs(b - a) < (1.0 / 65535.0);
 }


 cmsBool CMSEXPORT _cmsMAT3isIdentity(const cmsMAT3* a)
 {
     cmsMAT3 Identity;
     int i, j;

     _cmsMAT3identity(&Identity);

     for (i=0; i < 3; i++)
         for (j=0; j < 3; j++)
             if (!CloseEnough(a ->v[i].n[j], Identity.v[i].n[j])) return FALSE;

     return TRUE;
 }


 // Multiply two matrices
 void CMSEXPORT _cmsMAT3per(cmsMAT3* r, const cmsMAT3* a, const cmsMAT3* b)
 {
 #define ROWCOL(i, j) \
     a->v[i].n[0]*b->v[0].n[j] + a->v[i].n[1]*b->v[1].n[j] + a->v[i].n[2]*b->v[2].n[j]

     _cmsVEC3init(&r-> v[0], ROWCOL(0,0), ROWCOL(0,1), ROWCOL(0,2));
     _cmsVEC3init(&r-> v[1], ROWCOL(1,0), ROWCOL(1,1), ROWCOL(1,2));
     _cmsVEC3init(&r-> v[2], ROWCOL(2,0), ROWCOL(2,1), ROWCOL(2,2));

 #undef ROWCOL //(i, j)
 }


 // Inverse of a matrix b = a^(-1)
 cmsBool  CMSEXPORT _cmsMAT3inverse(const cmsMAT3* a, cmsMAT3* b)
 {
    cmsFloat64Number det, c0, c1, c2;

    c0 =  a -> v[1].n[1]*a -> v[2].n[2] - a -> v[1].n[2]*a -> v[2].n[1];
    c1 = -a -> v[1].n[0]*a -> v[2].n[2] + a -> v[1].n[2]*a -> v[2].n[0];
    c2 =  a -> v[1].n[0]*a -> v[2].n[1] - a -> v[1].n[1]*a -> v[2].n[0];

    det = a -> v[0].n[0]*c0 + a -> v[0].n[1]*c1 + a -> v[0].n[2]*c2;

    if (fabs(det) < MATRIX_DET_TOLERANCE) return FALSE;  // singular matrix; can't invert

    b -> v[0].n[0] = c0/det;
    b -> v[0].n[1] = (a -> v[0].n[2]*a -> v[2].n[1] - a -> v[0].n[1]*a -> v[2].n[2])/det;
    b -> v[0].n[2] = (a -> v[0].n[1]*a -> v[1].n[2] - a -> v[0].n[2]*a -> v[1].n[1])/det;
    b -> v[1].n[0] = c1/det;
    b -> v[1].n[1] = (a -> v[0].n[0]*a -> v[2].n[2] - a -> v[0].n[2]*a -> v[2].n[0])/det;
    b -> v[1].n[2] = (a -> v[0].n[2]*a -> v[1].n[0] - a -> v[0].n[0]*a -> v[1].n[2])/det;
    b -> v[2].n[0] = c2/det;
    b -> v[2].n[1] = (a -> v[0].n[1]*a -> v[2].n[0] - a -> v[0].n[0]*a -> v[2].n[1])/det;
    b -> v[2].n[2] = (a -> v[0].n[0]*a -> v[1].n[1] - a -> v[0].n[1]*a -> v[1].n[0])/det;

    return TRUE;
 }


 // Solve a system in the form Ax = b
 cmsBool  CMSEXPORT _cmsMAT3solve(cmsVEC3* x, cmsMAT3* a, cmsVEC3* b)
 {
     cmsMAT3 m, a_1;

     memmove(&m, a, sizeof(cmsMAT3));

     if (!_cmsMAT3inverse(&m, &a_1)) return FALSE;  // Singular matrix

     _cmsMAT3eval(x, &a_1, b);
     return TRUE;
 }

 // Evaluate a vector across a matrix
 void CMSEXPORT _cmsMAT3eval(cmsVEC3* r, const cmsMAT3* a, const cmsVEC3* v)
 {
     r->n[VX] = a->v[0].n[VX]*v->n[VX] + a->v[0].n[VY]*v->n[VY] + a->v[0].n[VZ]*v->n[VZ];
     r->n[VY] = a->v[1].n[VX]*v->n[VX] + a->v[1].n[VY]*v->n[VY] + a->v[1].n[VZ]*v->n[VZ];
     r->n[VZ] = a->v[2].n[VX]*v->n[VX] + a->v[2].n[VY]*v->n[VY] + a->v[2].n[VZ]*v->n[VZ];
 }
	//---------------------------------------------------------------------------------
	//
	// Little Color Management System
	// Copyright (c) 1998-2020 Marti Maria Saguer
	//
	// Permission is hereby granted, free of charge, to any person obtaining
	// a copy of this software and associated documentation files (the "Software"),
	// to deal in the Software without restriction, including without limitation
	// the rights to use, copy, modify, merge, publish, distribute, sublicense,
	// and/or sell copies of the Software, and to permit persons to whom the Software
	// is furnished to do so, subject to the following conditions:
	//
	// The above copyright notice and this permission notice shall be included in
	// all copies or substantial portions of the Software.
	//
	// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
	// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
	// THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
	// NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
	// LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
	// OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
	// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
	//
	//---------------------------------------------------------------------------------
	//

	#include "lcms2_internal.h"


	#define DSWAP(x, y) {cmsFloat64Number tmp = (x); (x)=(y); (y)=tmp;}


	// Initiate a vector
	void CMSEXPORT _cmsVEC3init(cmsVEC3* r, cmsFloat64Number x, cmsFloat64Number y, cmsFloat64Number z)
	{
	r -> n[VX] = x;
	r -> n[VY] = y;
	r -> n[VZ] = z;
	}

	// Vector subtraction
	void CMSEXPORT _cmsVEC3minus(cmsVEC3* r, const cmsVEC3* a, const cmsVEC3* b)
	{
	r -> n[VX] = a -> n[VX] - b -> n[VX];
	r -> n[VY] = a -> n[VY] - b -> n[VY];
	r -> n[VZ] = a -> n[VZ] - b -> n[VZ];
	}

	// Vector cross product
	void CMSEXPORT _cmsVEC3cross(cmsVEC3* r, const cmsVEC3* u, const cmsVEC3* v)
	{
	r ->n[VX] = u->n[VY] * v->n[VZ] - v->n[VY] * u->n[VZ];
	r ->n[VY] = u->n[VZ] * v->n[VX] - v->n[VZ] * u->n[VX];
	r ->n[VZ] = u->n[VX] * v->n[VY] - v->n[VX] * u->n[VY];
	}

	// Vector dot product
	cmsFloat64Number CMSEXPORT _cmsVEC3dot(const cmsVEC3* u, const cmsVEC3* v)
	{
	return u->n[VX] * v->n[VX] + u->n[VY] * v->n[VY] + u->n[VZ] * v->n[VZ];
	}

	// Euclidean length
	cmsFloat64Number CMSEXPORT _cmsVEC3length(const cmsVEC3* a)
	{
	return sqrt(a ->n[VX] * a ->n[VX] +
	a ->n[VY] * a ->n[VY] +
	a ->n[VZ] * a ->n[VZ]);
	}

	// Euclidean distance
	cmsFloat64Number CMSEXPORT _cmsVEC3distance(const cmsVEC3* a, const cmsVEC3* b)
	{
	cmsFloat64Number d1 = a ->n[VX] - b ->n[VX];
	cmsFloat64Number d2 = a ->n[VY] - b ->n[VY];
	cmsFloat64Number d3 = a ->n[VZ] - b ->n[VZ];

	return sqrt(d1d1 + d2d2 + d3*d3);
	}



	// 3x3 Identity
	void CMSEXPORT _cmsMAT3identity(cmsMAT3* a)
	{
	_cmsVEC3init(&a-> v[0], 1.0, 0.0, 0.0);
	_cmsVEC3init(&a-> v[1], 0.0, 1.0, 0.0);
	_cmsVEC3init(&a-> v[2], 0.0, 0.0, 1.0);
	}

	static
	cmsBool CloseEnough(cmsFloat64Number a, cmsFloat64Number b)
	{
	return fabs(b - a) < (1.0 / 65535.0);
	}


	cmsBool CMSEXPORT _cmsMAT3isIdentity(const cmsMAT3* a)
	{
	cmsMAT3 Identity;
	int i, j;

	_cmsMAT3identity(&Identity);

	for (i=0; i < 3; i++)
	for (j=0; j < 3; j++)
	if (!CloseEnough(a ->v[i].n[j], Identity.v[i].n[j])) return FALSE;

	return TRUE;
	}


	// Multiply two matrices
	void CMSEXPORT _cmsMAT3per(cmsMAT3* r, const cmsMAT3* a, const cmsMAT3* b)
	{
	#define ROWCOL(i, j) \
	a->v[i].n[0]b->v[0].n[j] + a->v[i].n[1]b->v[1].n[j] + a->v[i].n[2]*b->v[2].n[j]

	_cmsVEC3init(&r-> v[0], ROWCOL(0,0), ROWCOL(0,1), ROWCOL(0,2));
	_cmsVEC3init(&r-> v[1], ROWCOL(1,0), ROWCOL(1,1), ROWCOL(1,2));
	_cmsVEC3init(&r-> v[2], ROWCOL(2,0), ROWCOL(2,1), ROWCOL(2,2));

	#undef ROWCOL //(i, j)
	}



	// Inverse of a matrix b = a^(-1)
	cmsBool CMSEXPORT _cmsMAT3inverse(const cmsMAT3* a, cmsMAT3* b)
	{
	cmsFloat64Number det, c0, c1, c2;

	c0 = a -> v[1].n[1]a -> v[2].n[2] - a -> v[1].n[2]a -> v[2].n[1];
	c1 = -a -> v[1].n[0]a -> v[2].n[2] + a -> v[1].n[2]a -> v[2].n[0];
	c2 = a -> v[1].n[0]a -> v[2].n[1] - a -> v[1].n[1]a -> v[2].n[0];

	det = a -> v[0].n[0]c0 + a -> v[0].n[1]c1 + a -> v[0].n[2]*c2;

	if (fabs(det) < MATRIX_DET_TOLERANCE) return FALSE; // singular matrix; can't invert

	b -> v[0].n[0] = c0/det;
	b -> v[0].n[1] = (a -> v[0].n[2]a -> v[2].n[1] - a -> v[0].n[1]a -> v[2].n[2])/det;
	b -> v[0].n[2] = (a -> v[0].n[1]a -> v[1].n[2] - a -> v[0].n[2]a -> v[1].n[1])/det;
	b -> v[1].n[0] = c1/det;
	b -> v[1].n[1] = (a -> v[0].n[0]a -> v[2].n[2] - a -> v[0].n[2]a -> v[2].n[0])/det;
	b -> v[1].n[2] = (a -> v[0].n[2]a -> v[1].n[0] - a -> v[0].n[0]a -> v[1].n[2])/det;
	b -> v[2].n[0] = c2/det;
	b -> v[2].n[1] = (a -> v[0].n[1]a -> v[2].n[0] - a -> v[0].n[0]a -> v[2].n[1])/det;
	b -> v[2].n[2] = (a -> v[0].n[0]a -> v[1].n[1] - a -> v[0].n[1]a -> v[1].n[0])/det;

	return TRUE;
	}


	// Solve a system in the form Ax = b
	cmsBool CMSEXPORT _cmsMAT3solve(cmsVEC3* x, cmsMAT3* a, cmsVEC3* b)
	{
	cmsMAT3 m, a_1;

	memmove(&m, a, sizeof(cmsMAT3));

	if (!_cmsMAT3inverse(&m, &a_1)) return FALSE; // Singular matrix

	_cmsMAT3eval(x, &a_1, b);
	return TRUE;
	}

	// Evaluate a vector across a matrix
	void CMSEXPORT _cmsMAT3eval(cmsVEC3* r, const cmsMAT3* a, const cmsVEC3* v)
	{
	r->n[VX] = a->v[0].n[VX]v->n[VX] + a->v[0].n[VY]v->n[VY] + a->v[0].n[VZ]*v->n[VZ];
	r->n[VY] = a->v[1].n[VX]v->n[VX] + a->v[1].n[VY]v->n[VY] + a->v[1].n[VZ]*v->n[VZ];
	r->n[VZ] = a->v[2].n[VX]v->n[VX] + a->v[2].n[VY]v->n[VY] + a->v[2].n[VZ]*v->n[VZ];
	}