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SimplifyProduct.h
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1 #ifndef PhysicsTools_Utilities_SimplifyProduct_h
2 #define PhysicsTools_Utilities_SimplifyProduct_h
3 
8 
10 
11 namespace funct {
12 
13  // a * ( b * c ) = ( a * b ) * c
14  PROD_RULE(TYPT3, A, PROD_S(B, C),
15  PROD(PROD(A, B), C), (_1 * _2._1) * _2._2);
16 
17  // 0 * a = 0
18  PROD_RULE(TYPT1, NUM(0), A, NUM(0), num<0>());
19 
20  // 0 * n = 0
21  PROD_RULE(TYPN1, NUM(0), NUM(n), NUM(0), num<0>());
22 
23  // 0 * ( a * b ) => 0
24  PROD_RULE(TYPT2, NUM(0), PROD_S(A, B), NUM(0), num<0>());
25 
26  // 1 * a = a
27  PROD_RULE(TYPT1, NUM(1), A, A, _2);
28 
29  // avoid template ambiguities
30  // 1 * n = n
31  PROD_RULE(TYPN1, NUM(1), NUM(n), NUM(n), _2);
32 
33  // 1 * (n/m) = (n/m)
34  PROD_RULE(TYPN2, NUM(1), FRACT_S(n, m), FRACT_S(n, m), _2);
35 
36  // 1 * 1 = 1
37  PROD_RULE(TYP0, NUM(1), NUM(1), NUM(1), num<1>());
38 
39  // ( - 1 ) * a = - a
40  PROD_RULE(TYPT1, NUM(-1), A, MINUS_S(A), -_2);
41 
42  // ( - 1 ) * n = -n
43  PROD_RULE(TYPN1, NUM(-1), NUM(n), NUM(-n), num<-n>());
44 
45  // 1 * ( a * b ) => ( a * b )
46  PROD_RULE(TYPT2, NUM(1), PROD_S(A, B), PROD_S(A, B), _2);
47 
48  // a * ( -b ) = - ( a * b )
49  PROD_RULE(TYPT2, A, MINUS_S(B), MINUS(PROD(A, B)), -(_1 * _2._));
50 
51  // n * ( -a ) = - ( n * a )
52  PROD_RULE(TYPN1T1, NUM(n), MINUS_S(A), MINUS(PROD(NUM(n), A)), -(_1 * _2._ ));
53 
54  // ( a * b ) * ( -c )= - ( ( a * b ) * c )
55  PROD_RULE(TYPT3, PROD_S(A, B), MINUS_S(C), MINUS(PROD(PROD(A, B), C)), -(_1 * _2._));
56 
57  // 1 * ( -a ) = -a
58  PROD_RULE(TYPT1, NUM(1), MINUS_S(A), MINUS(A), _2);
59 
60  // ( - a ) * ( - b ) = a * b
61  PROD_RULE(TYPT2, MINUS_S(A), MINUS_S(B), PROD(A, B), _1._ * _2._);
62 
63  // ( -a ) * b = -( a * b )
64  PROD_RULE(TYPT2, MINUS_S(A), B, MINUS(PROD(A, B)), -(_1._ * _2));
65 
66  // a * ( b / c ) = ( a * b ) / c
67  PROD_RULE(TYPT3, A, RATIO_S(B, C), RATIO(PROD(A, B), C), (_1 * _2._1)/_2._2);
68 
69  // n * ( a / b ) = ( n * a ) / b
71  RATIO(PROD(NUM(n), A), B), (_1 * _2._1)/_2._2);
72 
73  // 1 * ( a / b ) = a / b
74  PROD_RULE(TYPT2, NUM(1), RATIO_S(A, B), RATIO(A, B), _2);
75 
76  // 0 * ( a / b ) = 0
77  PROD_RULE(TYPT2, NUM(0), RATIO_S(A, B), NUM(0), num<0>());
78 
79  // a * n = n * a
80  PROD_RULE(TYPN1T1, A, NUM(n), PROD(NUM(n), A), _2 * _1);
81 
82  // ( a * b ) n = ( n * a ) * b
83  PROD_RULE(TYPN1T2, PROD_S(A, B), NUM(n), PROD(PROD(NUM(n), A), B),
84  (_2 * _1._1) * _1._2);
85 
86  // ( a * b ) * ( c * d ) => ( ( a * b ) * c ) * d
87  PROD_RULE(TYPT4, PROD_S(A, B), PROD_S(C, D),
88  PROD(PROD(PROD(A, B), C), D),
89  (_1 * _2._1) * _2._2);
90 
91  // n/m * ( a / k ) = n/(m+k) * a
93  PROD(FRACT(n, m + k), A), (fract<n, m + k>() * _2._1));
94 
95  // ( a / b ) * n = ( n a ) / b
97  RATIO(PROD(NUM(n), A), B), (_2 * _1._1) / _1._2);
98 
99  // ( a / b ) * c = ( a * c ) / b
100  PROD_RULE(TYPT3, RATIO_S(A, B), C,
101  RATIO(PROD(A, C), B), (_1._1 * _2) / _1._2);
102 
103  // 0 * 1 = 0 ( avoid template ambiguity )
104  PROD_RULE(TYP0, NUM(0), NUM(1), NUM(0), num<0>());
105 
106  // ( a / b ) * ( c / d )= a * c / ( b * d )
108  RATIO(PROD(A, C), PROD(B, D)),
109  (_1._1 * _2._1)/(_1._2 * _2._2));
110 
111  // a^b * a^c => a^( b + c )
114  typedef POWER( A, B ) arg1;
115  typedef POWER( A, C ) arg2;
116  typedef PROD_S( arg1, arg2 ) type;
117  COMBINE( arg1, arg2, type( _1, _2 ) );
118  };
119 
120  TEMPL( T3 )
121  struct SimplifyPowerProduct< A, B, C, false > {
122  typedef POWER( A, B ) arg1;
123  typedef POWER( A, C ) arg2;
124  typedef POWER( A, SUM( B, C ) ) type;
125  inline static type combine( const arg1 & _1, const arg2 & _2 )
126  { return pow( DecomposePower< A, B >::getBase( _1 ),
128  DecomposePower< A, C >::getExp( _2 ) ) ); }
129  };
130 
131  TEMPL( T3 ) struct Product< POWER_S( A, B ),POWER_S( A, C ) > :
132  public SimplifyPowerProduct< A, B, C > { };
133 
134  TEMPL( T2 ) struct Product< POWER_S( A, B ),POWER_S( A, B ) > :
135  public SimplifyPowerProduct< A, B, B > { };
136 
137  TEMPL( T2 ) struct Product< A, POWER_S( A, B ) > :
138  public SimplifyPowerProduct< A, NUM( 1 ), B > { };
139 
140  TEMPL( N1T1 ) struct Product< A, POWER_S( A, NUM( n ) ) > :
141  public SimplifyPowerProduct< A, NUM( 1 ), NUM( n ) > { };
142 
143  TEMPL( T2 ) struct Product< POWER_S( A, B ), A > :
144  public SimplifyPowerProduct< A, B, NUM( 1 ) > { };
145 
146  TEMPL( N1T1 ) struct Product< POWER_S( A, NUM( n ) ), A > :
147  public SimplifyPowerProduct< A, NUM( n ), NUM( 1 ) > { };
148 
149  TEMPL( T1 ) struct Product< A, A > :
150  public SimplifyPowerProduct< A, NUM( 1 ), NUM( 1 ) > { };
151 
152  TEMPL( T2 ) struct Product< PROD_S( A, B ), PROD_S( A, B ) > :
153  public SimplifyPowerProduct< PROD( A, B ), NUM( 1 ), NUM( 1 ) > { };
154 
155  TEMPL( T1 ) struct Product< MINUS_S( A ), MINUS_S( A ) > :
156  public SimplifyPowerProduct< MINUS_S( A ), NUM( 1 ), NUM( 1 ) > { };
157 
158 
159  // n * n = n ^ 2
160  PROD_RULE(TYPN1, NUM(n), NUM(n), NUM(n*n), num<n*n>());
161 
162  // a/ b * ( c * d ) = ( a * c * d ) / b
163  PROD_RULE(TYPT4, RATIO_S(A, B), PROD_S(C, D),
164  RATIO(PROD(PROD(A, C), D), B),
165  ((_1._1 * _2._1) * _2._2) / _1._2);
166 
167  // simplify f * g * h regardless of the order
168  template <typename Prod, bool simplify = Prod::value> struct AuxProduct {
169  typedef PROD(typename Prod::AB, typename Prod::C) type;
170  COMBINE(typename Prod::AB, typename Prod::C, _1 * _2);
171  };
172 
173  template<typename Prod> struct AuxProduct<Prod, false> {
174  typedef PROD_S(typename Prod::AB, typename Prod::C) type;
175  COMBINE(typename Prod::AB, typename Prod::C, type(_1, _2));
176  };
177 
178  template<typename F, typename G, typename H>
179  struct Product<PROD_S(F, G), H> {
180  struct prod0 {
181  typedef F A; typedef G B; typedef H C;
182  typedef PROD_S(A, B) AB;
183  inline static const A& a(const F& f, const G& g, const H& h) { return f; }
184  inline static const B& b(const F& f, const G& g, const H& h) { return g; }
185  inline static const C& c(const F& f, const G& g, const H& h) { return h; }
186  enum { value = false };
187  };
188  struct prod1 {
189  typedef F A; typedef H B; typedef G C;
190  typedef PROD_S(A, B) base;
191  typedef PROD(A, B) AB;
192  inline static const A& a(const F& f, const G& g, const H& h) { return f; }
193  inline static const B& b(const F& f, const G& g, const H& h) { return h; }
194  inline static const C& c(const F& f, const G& g, const H& h) { return g; }
195  enum { value = ::boost::type_traits::ice_not<
197  };
198  struct prod2 {
199  typedef G A; typedef H B; typedef F C;
200  typedef PROD_S(A, B) base;
201  typedef PROD(A, B) AB;
202  inline static const A& a(const F& f, const G& g, const H& h) { return g; }
203  inline static const B& b(const F& f, const G& g, const H& h) { return h; }
204  inline static const C& c(const F& f, const G& g, const H& h) { return f; }
205  enum { value = ::boost::type_traits::ice_not<
207  };
208 
209  typedef typename
210  ::boost::mpl::if_ <prod1, prod1,
213  typedef typename AuxProduct<prod>::type type;
214  inline static type combine(const ProductStruct<F, G>& fg, const H& h) {
215  const F& f = fg._1;
216  const G& g = fg._2;
217  const typename prod::A & a = prod::a(f, g, h);
218  const typename prod::B & b = prod::b(f, g, h);
219  const typename prod::C & c = prod::c(f, g, h);
220  return AuxProduct<prod>::combine(a * b, c);
221  }
222  };
223 
224 }
225 
227 
228 #endif
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