source: NonGTP/OpenEXR/include/Imath/ImathShear.h @ 855

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33///////////////////////////////////////////////////////////////////////////
34
35
36
37#ifndef INCLUDED_IMATHSHEAR_H
38#define INCLUDED_IMATHSHEAR_H
39
40//----------------------------------------------------
41//
42//      Shear6 class template.
43//
44//----------------------------------------------------
45
46#include <ImathExc.h>
47#include <ImathLimits.h>
48#include <ImathMath.h>
49#include <ImathVec.h>
50
51#include <iostream>
52
53
54namespace Imath {
55
56
57
58
59template <class T> class Shear6
60{
61  public:
62
63    //-------------------
64    // Access to elements
65    //-------------------
66
67    T                   xy, xz, yz, yx, zx, zy;
68
69    T &                 operator [] (int i);
70    const T &           operator [] (int i) const;
71
72
73    //-------------
74    // Constructors
75    //-------------
76
77    Shear6 ();                     // (0 0 0 0 0 0)
78    Shear6 (T XY, T XZ, T YZ);     // (XY XZ YZ 0 0 0)
79    Shear6 (const Vec3<T> &v);     // (v.x v.y v.z 0 0 0)
80    template <class S>             // (v.x v.y v.z 0 0 0)
81        Shear6 (const Vec3<S> &v);
82    Shear6 (T XY, T XZ, T YZ,      // (XY XZ YZ YX ZX ZY)
83            T YX, T ZX, T ZY); 
84
85
86    //---------------------------------
87    // Copy constructors and assignment
88    //---------------------------------
89
90    Shear6 (const Shear6 &h);
91    template <class S> Shear6 (const Shear6<S> &h);
92
93    const Shear6 &      operator = (const Shear6 &h);
94    template <class S>
95        const Shear6 &  operator = (const Vec3<S> &v);
96
97
98    //----------------------
99    // Compatibility with Sb
100    //----------------------
101
102    template <class S>
103    void                setValue (S XY, S XZ, S YZ, S YX, S ZX, S ZY);
104
105    template <class S>
106    void                setValue (const Shear6<S> &h);
107
108    template <class S>
109    void                getValue (S &XY, S &XZ, S &YZ,
110                                  S &YX, S &ZX, S &ZY) const;
111
112    template <class S>
113    void                getValue (Shear6<S> &h) const;
114
115    T *                 getValue();
116    const T *           getValue() const;
117
118
119    //---------
120    // Equality
121    //---------
122
123    template <class S>
124    bool                operator == (const Shear6<S> &h) const;
125
126    template <class S>
127    bool                operator != (const Shear6<S> &h) const;
128
129    //-----------------------------------------------------------------------
130    // Compare two shears and test if they are "approximately equal":
131    //
132    // equalWithAbsError (h, e)
133    //
134    //      Returns true if the coefficients of this and h are the same with
135    //      an absolute error of no more than e, i.e., for all i
136    //
137    //      abs (this[i] - h[i]) <= e
138    //
139    // equalWithRelError (h, e)
140    //
141    //      Returns true if the coefficients of this and h are the same with
142    //      a relative error of no more than e, i.e., for all i
143    //
144    //      abs (this[i] - h[i]) <= e * abs (this[i])
145    //-----------------------------------------------------------------------
146
147    bool                equalWithAbsError (const Shear6<T> &h, T e) const;
148    bool                equalWithRelError (const Shear6<T> &h, T e) const;
149
150
151    //------------------------
152    // Component-wise addition
153    //------------------------
154
155    const Shear6 &      operator += (const Shear6 &h);
156    Shear6              operator + (const Shear6 &h) const;
157
158
159    //---------------------------
160    // Component-wise subtraction
161    //---------------------------
162
163    const Shear6 &      operator -= (const Shear6 &h);
164    Shear6              operator - (const Shear6 &h) const;
165
166
167    //------------------------------------
168    // Component-wise multiplication by -1
169    //------------------------------------
170
171    Shear6              operator - () const;
172    const Shear6 &      negate ();
173
174
175    //------------------------------
176    // Component-wise multiplication
177    //------------------------------
178
179    const Shear6 &      operator *= (const Shear6 &h);
180    const Shear6 &      operator *= (T a);
181    Shear6              operator * (const Shear6 &h) const;
182    Shear6              operator * (T a) const;
183
184
185    //------------------------
186    // Component-wise division
187    //------------------------
188
189    const Shear6 &      operator /= (const Shear6 &h);
190    const Shear6 &      operator /= (T a);
191    Shear6              operator / (const Shear6 &h) const;
192    Shear6              operator / (T a) const;
193
194
195    //----------------------------------------------------------
196    // Number of dimensions, i.e. number of elements in a Shear6
197    //----------------------------------------------------------
198
199    static unsigned int dimensions() {return 6;}
200
201
202    //-------------------------------------------------
203    // Limitations of type T (see also class limits<T>)
204    //-------------------------------------------------
205
206    static T            baseTypeMin()           {return limits<T>::min();}
207    static T            baseTypeMax()           {return limits<T>::max();}
208    static T            baseTypeSmallest()      {return limits<T>::smallest();}
209    static T            baseTypeEpsilon()       {return limits<T>::epsilon();}
210
211
212    //--------------------------------------------------------------
213    // Base type -- in templates, which accept a parameter, V, which
214    // could be either a Vec2<T> or a Shear6<T>, you can refer to T as
215    // V::BaseType
216    //--------------------------------------------------------------
217
218    typedef T           BaseType;
219};
220
221
222//--------------
223// Stream output
224//--------------
225
226template <class T>
227std::ostream &  operator << (std::ostream &s, const Shear6<T> &h);
228
229
230//----------------------------------------------------
231// Reverse multiplication: scalar * Shear6<T>
232//----------------------------------------------------
233
234template <class S, class T> Shear6<T>   operator * (S a, const Shear6<T> &h);
235
236
237//-------------------------
238// Typedefs for convenience
239//-------------------------
240
241typedef Vec3   <float>  Shear3f;
242typedef Vec3   <double> Shear3d;
243typedef Shear6 <float>  Shear6f;
244typedef Shear6 <double> Shear6d;
245
246
247
248
249//-----------------------
250// Implementation of Shear6
251//-----------------------
252
253template <class T>
254inline T &
255Shear6<T>::operator [] (int i)
256{
257    return (&xy)[i];
258}
259
260template <class T>
261inline const T &
262Shear6<T>::operator [] (int i) const
263{
264    return (&xy)[i];
265}
266
267template <class T>
268inline
269Shear6<T>::Shear6 ()
270{
271    xy = xz = yz = yx = zx = zy = 0;
272}
273
274template <class T>
275inline
276Shear6<T>::Shear6 (T XY, T XZ, T YZ)
277{
278    xy = XY;
279    xz = XZ;
280    yz = YZ;
281    yx = 0;
282    zx = 0;
283    zy = 0;
284}
285
286template <class T>
287inline
288Shear6<T>::Shear6 (const Vec3<T> &v)
289{
290    xy = v.x;
291    xz = v.y;
292    yz = v.z;
293    yx = 0;
294    zx = 0;
295    zy = 0;
296}
297
298template <class T>
299template <class S>
300inline
301Shear6<T>::Shear6 (const Vec3<S> &v)
302{
303    xy = T (v.x);
304    xz = T (v.y);
305    yz = T (v.z);
306    yx = 0;
307    zx = 0;
308    zy = 0;
309}
310
311template <class T>
312inline
313Shear6<T>::Shear6 (T XY, T XZ, T YZ, T YX, T ZX, T ZY)
314{
315    xy = XY;
316    xz = XZ;
317    yz = YZ;
318    yx = YX;
319    zx = ZX;
320    zy = ZY;
321}
322
323template <class T>
324inline
325Shear6<T>::Shear6 (const Shear6 &h)
326{
327    xy = h.xy;
328    xz = h.xz;
329    yz = h.yz;
330    yx = h.yx;
331    zx = h.zx;
332    zy = h.zy;
333}
334
335template <class T>
336template <class S>
337inline
338Shear6<T>::Shear6 (const Shear6<S> &h)
339{
340    xy = T (h.xy);
341    xz = T (h.xz);
342    yz = T (h.yz);
343    yx = T (h.yx);
344    zx = T (h.zx);
345    zy = T (h.zy);
346}
347
348template <class T>
349inline const Shear6<T> &
350Shear6<T>::operator = (const Shear6 &h)
351{
352    xy = h.xy;
353    xz = h.xz;
354    yz = h.yz;
355    yx = h.yx;
356    zx = h.zx;
357    zy = h.zy;
358    return *this;
359}
360
361template <class T>
362template <class S>
363inline const Shear6<T> &
364Shear6<T>::operator = (const Vec3<S> &v)
365{
366    xy = T (v.x);
367    xz = T (v.y);
368    yz = T (v.z);
369    yx = 0;
370    zx = 0;
371    zy = 0;
372    return *this;
373}
374
375template <class T>
376template <class S>
377inline void
378Shear6<T>::setValue (S XY, S XZ, S YZ, S YX, S ZX, S ZY)
379{
380    xy = T (XY);
381    xz = T (XZ);
382    yz = T (YZ);
383    yx = T (YX);
384    zx = T (ZX);
385    zy = T (ZY);
386}
387
388template <class T>
389template <class S>
390inline void
391Shear6<T>::setValue (const Shear6<S> &h)
392{
393    xy = T (h.xy);
394    xz = T (h.xz);
395    yz = T (h.yz);
396    yx = T (h.yx);
397    zx = T (h.zx);
398    zy = T (h.zy);
399}
400
401template <class T>
402template <class S>
403inline void
404Shear6<T>::getValue (S &XY, S &XZ, S &YZ, S &YX, S &ZX, S &ZY) const
405{
406    XY = S (xy);
407    XZ = S (xz);
408    YZ = S (yz);
409    YX = S (yx);
410    ZX = S (zx);
411    ZY = S (zy);
412}
413
414template <class T>
415template <class S>
416inline void
417Shear6<T>::getValue (Shear6<S> &h) const
418{
419    h.xy = S (xy);
420    h.xz = S (xz);
421    h.yz = S (yz);
422    h.yx = S (yx);
423    h.zx = S (zx);
424    h.zy = S (zy);
425}
426
427template <class T>
428inline T *
429Shear6<T>::getValue()
430{
431    return (T *) &xy;
432}
433
434template <class T>
435inline const T *
436Shear6<T>::getValue() const
437{
438    return (const T *) &xy;
439}
440
441template <class T>
442template <class S>
443inline bool
444Shear6<T>::operator == (const Shear6<S> &h) const
445{
446    return xy == h.xy  &&  xz == h.xz  &&  yz == h.yz  && 
447           yx == h.yx  &&  zx == h.zx  &&  zy == h.zy;
448}
449
450template <class T>
451template <class S>
452inline bool
453Shear6<T>::operator != (const Shear6<S> &h) const
454{
455    return xy != h.xy  ||  xz != h.xz  ||  yz != h.yz  ||
456           yx != h.yx  ||  zx != h.zx  ||  zy != h.zy;
457}
458
459template <class T>
460bool
461Shear6<T>::equalWithAbsError (const Shear6<T> &h, T e) const
462{
463    for (int i = 0; i < 6; i++)
464        if (!Imath::equalWithAbsError ((*this)[i], h[i], e))
465            return false;
466
467    return true;
468}
469
470template <class T>
471bool
472Shear6<T>::equalWithRelError (const Shear6<T> &h, T e) const
473{
474    for (int i = 0; i < 6; i++)
475        if (!Imath::equalWithRelError ((*this)[i], h[i], e))
476            return false;
477
478    return true;
479}
480
481
482template <class T>
483inline const Shear6<T> &
484Shear6<T>::operator += (const Shear6 &h)
485{
486    xy += h.xy;
487    xz += h.xz;
488    yz += h.yz;
489    yx += h.yx;
490    zx += h.zx;
491    zy += h.zy;
492    return *this;
493}
494
495template <class T>
496inline Shear6<T>
497Shear6<T>::operator + (const Shear6 &h) const
498{
499    return Shear6 (xy + h.xy, xz + h.xz, yz + h.yz,
500                   yx + h.yx, zx + h.zx, zy + h.zy);
501}
502
503template <class T>
504inline const Shear6<T> &
505Shear6<T>::operator -= (const Shear6 &h)
506{
507    xy -= h.xy;
508    xz -= h.xz;
509    yz -= h.yz;
510    yx -= h.yx;
511    zx -= h.zx;
512    zy -= h.zy;
513    return *this;
514}
515
516template <class T>
517inline Shear6<T>
518Shear6<T>::operator - (const Shear6 &h) const
519{
520    return Shear6 (xy - h.xy, xz - h.xz, yz - h.yz,
521                   yx - h.yx, zx - h.zx, zy - h.zy);
522}
523
524template <class T>
525inline Shear6<T>
526Shear6<T>::operator - () const
527{
528    return Shear6 (-xy, -xz, -yz, -yx, -zx, -zy);
529}
530
531template <class T>
532inline const Shear6<T> &
533Shear6<T>::negate ()
534{
535    xy = -xy;
536    xz = -xz;
537    yz = -yz;
538    yx = -yx;
539    zx = -zx;
540    zy = -zy;
541    return *this;
542}
543
544template <class T>
545inline const Shear6<T> &
546Shear6<T>::operator *= (const Shear6 &h)
547{
548    xy *= h.xy;
549    xz *= h.xz;
550    yz *= h.yz;
551    yx *= h.yx;
552    zx *= h.zx;
553    zy *= h.zy;
554    return *this;
555}
556
557template <class T>
558inline const Shear6<T> &
559Shear6<T>::operator *= (T a)
560{
561    xy *= a;
562    xz *= a;
563    yz *= a;
564    yx *= a;
565    zx *= a;
566    zy *= a;
567    return *this;
568}
569
570template <class T>
571inline Shear6<T>
572Shear6<T>::operator * (const Shear6 &h) const
573{
574    return Shear6 (xy * h.xy, xz * h.xz, yz * h.yz,
575                   yx * h.yx, zx * h.zx, zy * h.zy);
576}
577
578template <class T>
579inline Shear6<T>
580Shear6<T>::operator * (T a) const
581{
582    return Shear6 (xy * a, xz * a, yz * a,
583                   yx * a, zx * a, zy * a);
584}
585
586template <class T>
587inline const Shear6<T> &
588Shear6<T>::operator /= (const Shear6 &h)
589{
590    xy /= h.xy;
591    xz /= h.xz;
592    yz /= h.yz;
593    yx /= h.yx;
594    zx /= h.zx;
595    zy /= h.zy;
596    return *this;
597}
598
599template <class T>
600inline const Shear6<T> &
601Shear6<T>::operator /= (T a)
602{
603    xy /= a;
604    xz /= a;
605    yz /= a;
606    yx /= a;
607    zx /= a;
608    zy /= a;
609    return *this;
610}
611
612template <class T>
613inline Shear6<T>
614Shear6<T>::operator / (const Shear6 &h) const
615{
616    return Shear6 (xy / h.xy, xz / h.xz, yz / h.yz,
617                   yx / h.yx, zx / h.zx, zy / h.zy);
618}
619
620template <class T>
621inline Shear6<T>
622Shear6<T>::operator / (T a) const
623{
624    return Shear6 (xy / a, xz / a, yz / a,
625                   yx / a, zx / a, zy / a);
626}
627
628
629//-----------------------------
630// Stream output implementation
631//-----------------------------
632
633template <class T>
634std::ostream &
635operator << (std::ostream &s, const Shear6<T> &h)
636{
637    return s << '('
638             << h.xy << ' ' << h.xz << ' ' << h.yz
639             << h.yx << ' ' << h.zx << ' ' << h.zy
640             << ')';
641}
642
643
644//-----------------------------------------
645// Implementation of reverse multiplication
646//-----------------------------------------
647
648template <class S, class T>
649inline Shear6<T>
650operator * (S a, const Shear6<T> &h)
651{
652    return Shear6<T> (a * h.xy, a * h.xz, a * h.yz,
653                      a * h.yx, a * h.zx, a * h.zy);
654}
655
656
657} // namespace Imath
658
659#endif
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