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1 //
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2 // Copyright (c) 2000-2010
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3 // Joerg Walter, Mathias Koch, David Bellot
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4 //
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5 // Distributed under the Boost Software License, Version 1.0. (See
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6 // accompanying file LICENSE_1_0.txt or copy at
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7 // http://www.boost.org/LICENSE_1_0.txt)
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8 //
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9 // The authors gratefully acknowledge the support of
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10 // GeNeSys mbH & Co. KG in producing this work.
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11 //
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12
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13 #ifndef _BOOST_UBLAS_IO_
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14 #define _BOOST_UBLAS_IO_
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15
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16 // Only forward definition required to define stream operations
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17 #include <iosfwd>
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18 #include <sstream>
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19 #include <boost/numeric/ublas/matrix_expression.hpp>
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20
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21
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22 namespace boost { namespace numeric { namespace ublas {
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23
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24 /** \brief output stream operator for vector expressions
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25 *
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26 * Any vector expressions can be written to a standard output stream
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27 * as defined in the C++ standard library. For example:
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28 * \code
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29 * vector<float> v1(3),v2(3);
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30 * for(size_t i=0; i<3; i++)
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31 * {
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32 * v1(i) = i+0.2;
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33 * v2(i) = i+0.3;
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34 * }
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35 * cout << v1+v2 << endl;
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36 * \endcode
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37 * will display the some of the 2 vectors like this:
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38 * \code
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39 * [3](0.5,2.5,4.5)
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40 * \endcode
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41 *
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42 * \param os is a standard basic output stream
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43 * \param v is a vector expression
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44 * \return a reference to the resulting output stream
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45 */
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46 template<class E, class T, class VE>
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47 // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it.
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48 std::basic_ostream<E, T> &operator << (std::basic_ostream<E, T> &os,
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49 const vector_expression<VE> &v) {
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50 typedef typename VE::size_type size_type;
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51 size_type size = v ().size ();
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52 std::basic_ostringstream<E, T, std::allocator<E> > s;
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53 s.flags (os.flags ());
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54 s.imbue (os.getloc ());
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55 s.precision (os.precision ());
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56 s << '[' << size << "](";
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57 if (size > 0)
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58 s << v () (0);
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59 for (size_type i = 1; i < size; ++ i)
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60 s << ',' << v () (i);
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61 s << ')';
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62 return os << s.str ().c_str ();
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63 }
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64
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65 /** \brief input stream operator for vectors
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66 *
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67 * This is used to feed in vectors with data stored as an ASCII representation
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68 * from a standard input stream.
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69 *
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70 * From a file or any valid stream, the format is:
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71 * \c [<vector size>](<data1>,<data2>,...<dataN>) like for example:
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72 * \code
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73 * [5](1,2.1,3.2,3.14,0.2)
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74 * \endcode
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75 *
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76 * You can use it like this
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77 * \code
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78 * my_input_stream >> my_vector;
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79 * \endcode
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80 *
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81 * You can only put data into a valid \c vector<> not a \c vector_expression
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82 *
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83 * \param is is a standard basic input stream
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84 * \param v is a vector
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85 * \return a reference to the resulting input stream
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86 */
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87 template<class E, class T, class VT, class VA>
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88 // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it.
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89 std::basic_istream<E, T> &operator >> (std::basic_istream<E, T> &is,
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90 vector<VT, VA> &v) {
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91 typedef typename vector<VT, VA>::size_type size_type;
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92 E ch;
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93 size_type size;
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94 if (is >> ch && ch != '[') {
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95 is.putback (ch);
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96 is.setstate (std::ios_base::failbit);
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97 } else if (is >> size >> ch && ch != ']') {
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98 is.putback (ch);
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99 is.setstate (std::ios_base::failbit);
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100 } else if (! is.fail ()) {
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101 vector<VT, VA> s (size);
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102 if (is >> ch && ch != '(') {
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103 is.putback (ch);
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104 is.setstate (std::ios_base::failbit);
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105 } else if (! is.fail ()) {
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106 for (size_type i = 0; i < size; i ++) {
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107 if (is >> s (i) >> ch && ch != ',') {
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108 is.putback (ch);
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109 if (i < size - 1)
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110 is.setstate (std::ios_base::failbit);
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111 break;
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112 }
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113 }
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114 if (is >> ch && ch != ')') {
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115 is.putback (ch);
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116 is.setstate (std::ios_base::failbit);
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117 }
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118 }
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119 if (! is.fail ())
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120 v.swap (s);
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121 }
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122 return is;
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123 }
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124
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125 /** \brief output stream operator for matrix expressions
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126 *
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127 * it outpus the content of a \f$(M \times N)\f$ matrix to a standard output
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128 * stream using the following format:
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129 * \c[<rows>,<columns>]((<m00>,<m01>,...,<m0N>),...,(<mM0>,<mM1>,...,<mMN>))
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130 *
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131 * For example:
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132 * \code
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133 * matrix<float> m(3,3) = scalar_matrix<float>(3,3,1.0) - diagonal_matrix<float>(3,3,1.0);
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134 * cout << m << endl;
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135 * \encode
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136 * will display
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137 * \code
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138 * [3,3]((0,1,1),(1,0,1),(1,1,0))
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139 * \endcode
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140 * This output is made for storing and retrieving matrices in a simple way but you can
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141 * easily recognize the following:
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142 * \f[ \left( \begin{array}{ccc} 1 & 1 & 1\\ 1 & 1 & 1\\ 1 & 1 & 1 \end{array} \right) - \left( \begin{array}{ccc} 1 & 0 & 0\\ 0 & 1 & 0\\ 0 & 0 & 1 \end{array} \right) = \left( \begin{array}{ccc} 0 & 1 & 1\\ 1 & 0 & 1\\ 1 & 1 & 0 \end{array} \right) \f]
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143 *
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144 * \param os is a standard basic output stream
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145 * \param m is a matrix expression
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146 * \return a reference to the resulting output stream
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147 */
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148 template<class E, class T, class ME>
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149 // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it.
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150 std::basic_ostream<E, T> &operator << (std::basic_ostream<E, T> &os,
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151 const matrix_expression<ME> &m) {
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152 typedef typename ME::size_type size_type;
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153 size_type size1 = m ().size1 ();
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154 size_type size2 = m ().size2 ();
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155 std::basic_ostringstream<E, T, std::allocator<E> > s;
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156 s.flags (os.flags ());
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157 s.imbue (os.getloc ());
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158 s.precision (os.precision ());
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159 s << '[' << size1 << ',' << size2 << "](";
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160 if (size1 > 0) {
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161 s << '(' ;
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162 if (size2 > 0)
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163 s << m () (0, 0);
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164 for (size_type j = 1; j < size2; ++ j)
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165 s << ',' << m () (0, j);
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166 s << ')';
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167 }
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168 for (size_type i = 1; i < size1; ++ i) {
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169 s << ",(" ;
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170 if (size2 > 0)
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171 s << m () (i, 0);
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172 for (size_type j = 1; j < size2; ++ j)
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173 s << ',' << m () (i, j);
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174 s << ')';
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175 }
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176 s << ')';
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177 return os << s.str ().c_str ();
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178 }
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179
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180 /** \brief input stream operator for matrices
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181 *
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182 * This is used to feed in matrices with data stored as an ASCII representation
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183 * from a standard input stream.
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184 *
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185 * From a file or any valid standard stream, the format is:
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186 * \c[<rows>,<columns>]((<m00>,<m01>,...,<m0N>),...,(<mM0>,<mM1>,...,<mMN>))
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187 *
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188 * You can use it like this
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189 * \code
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190 * my_input_stream >> my_matrix;
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191 * \endcode
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192 *
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193 * You can only put data into a valid \c matrix<> not a \c matrix_expression
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194 *
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195 * \param is is a standard basic input stream
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196 * \param m is a matrix
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197 * \return a reference to the resulting input stream
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198 */
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199 template<class E, class T, class MT, class MF, class MA>
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200 // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it.
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201 std::basic_istream<E, T> &operator >> (std::basic_istream<E, T> &is,
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202 matrix<MT, MF, MA> &m) {
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203 typedef typename matrix<MT, MF, MA>::size_type size_type;
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204 E ch;
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205 size_type size1, size2;
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206 if (is >> ch && ch != '[') {
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207 is.putback (ch);
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208 is.setstate (std::ios_base::failbit);
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209 } else if (is >> size1 >> ch && ch != ',') {
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210 is.putback (ch);
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211 is.setstate (std::ios_base::failbit);
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212 } else if (is >> size2 >> ch && ch != ']') {
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213 is.putback (ch);
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214 is.setstate (std::ios_base::failbit);
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215 } else if (! is.fail ()) {
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216 matrix<MT, MF, MA> s (size1, size2);
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217 if (is >> ch && ch != '(') {
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218 is.putback (ch);
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219 is.setstate (std::ios_base::failbit);
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220 } else if (! is.fail ()) {
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221 for (size_type i = 0; i < size1; i ++) {
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222 if (is >> ch && ch != '(') {
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223 is.putback (ch);
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224 is.setstate (std::ios_base::failbit);
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225 break;
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226 }
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227 for (size_type j = 0; j < size2; j ++) {
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228 if (is >> s (i, j) >> ch && ch != ',') {
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229 is.putback (ch);
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230 if (j < size2 - 1) {
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231 is.setstate (std::ios_base::failbit);
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232 break;
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233 }
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234 }
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235 }
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236 if (is >> ch && ch != ')') {
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237 is.putback (ch);
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238 is.setstate (std::ios_base::failbit);
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239 break;
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240 }
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241 if (is >> ch && ch != ',') {
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242 is.putback (ch);
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243 if (i < size1 - 1) {
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244 is.setstate (std::ios_base::failbit);
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245 break;
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246 }
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247 }
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248 }
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249 if (is >> ch && ch != ')') {
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250 is.putback (ch);
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251 is.setstate (std::ios_base::failbit);
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252 }
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253 }
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254 if (! is.fail ())
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255 m.swap (s);
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256 }
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257 return is;
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258 }
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259
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260 /** \brief special input stream operator for symmetric matrices
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261 *
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262 * This is used to feed in symmetric matrices with data stored as an ASCII
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263 * representation from a standard input stream.
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264 *
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265 * You can simply write your matrices in a file or any valid stream and read them again
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266 * at a later time with this function. The format is the following:
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267 * \code [<rows>,<columns>]((<m00>,<m01>,...,<m0N>),...,(<mM0>,<mM1>,...,<mMN>)) \endcode
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268 *
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269 * You can use it like this
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270 * \code
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271 * my_input_stream >> my_symmetric_matrix;
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272 * \endcode
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273 *
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274 * You can only put data into a valid \c symmetric_matrix<>, not in a \c matrix_expression
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275 * This function also checks that input data form a valid symmetric matrix
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276 *
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277 * \param is is a standard basic input stream
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278 * \param m is a \c symmetric_matrix
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279 * \return a reference to the resulting input stream
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280 */
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281 template<class E, class T, class MT, class MF1, class MF2, class MA>
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282 // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it.
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283 std::basic_istream<E, T> &operator >> (std::basic_istream<E, T> &is,
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284 symmetric_matrix<MT, MF1, MF2, MA> &m) {
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285 typedef typename symmetric_matrix<MT, MF1, MF2, MA>::size_type size_type;
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286 E ch;
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287 size_type size1, size2;
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288 MT value;
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289 if (is >> ch && ch != '[') {
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290 is.putback (ch);
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291 is.setstate (std::ios_base::failbit);
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292 } else if (is >> size1 >> ch && ch != ',') {
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293 is.putback (ch);
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294 is.setstate (std::ios_base::failbit);
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295 } else if (is >> size2 >> ch && (size2 != size1 || ch != ']')) { // symmetric matrix must be square
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296 is.putback (ch);
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297 is.setstate (std::ios_base::failbit);
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298 } else if (! is.fail ()) {
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299 symmetric_matrix<MT, MF1, MF2, MA> s (size1, size2);
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300 if (is >> ch && ch != '(') {
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301 is.putback (ch);
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302 is.setstate (std::ios_base::failbit);
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303 } else if (! is.fail ()) {
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304 for (size_type i = 0; i < size1; i ++) {
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Chris@16
|
305 if (is >> ch && ch != '(') {
|
|
Chris@16
|
306 is.putback (ch);
|
|
Chris@16
|
307 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
308 break;
|
|
Chris@16
|
309 }
|
|
Chris@16
|
310 for (size_type j = 0; j < size2; j ++) {
|
|
Chris@16
|
311 if (is >> value >> ch && ch != ',') {
|
|
Chris@16
|
312 is.putback (ch);
|
|
Chris@16
|
313 if (j < size2 - 1) {
|
|
Chris@16
|
314 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
315 break;
|
|
Chris@16
|
316 }
|
|
Chris@16
|
317 }
|
|
Chris@16
|
318 if (i <= j) {
|
|
Chris@16
|
319 // this is the first time we read this element - set the value
|
|
Chris@16
|
320 s(i,j) = value;
|
|
Chris@16
|
321 }
|
|
Chris@16
|
322 else if ( s(i,j) != value ) {
|
|
Chris@16
|
323 // matrix is not symmetric
|
|
Chris@16
|
324 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
325 break;
|
|
Chris@16
|
326 }
|
|
Chris@16
|
327 }
|
|
Chris@16
|
328 if (is >> ch && ch != ')') {
|
|
Chris@16
|
329 is.putback (ch);
|
|
Chris@16
|
330 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
331 break;
|
|
Chris@16
|
332 }
|
|
Chris@16
|
333 if (is >> ch && ch != ',') {
|
|
Chris@16
|
334 is.putback (ch);
|
|
Chris@16
|
335 if (i < size1 - 1) {
|
|
Chris@16
|
336 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
337 break;
|
|
Chris@16
|
338 }
|
|
Chris@16
|
339 }
|
|
Chris@16
|
340 }
|
|
Chris@16
|
341 if (is >> ch && ch != ')') {
|
|
Chris@16
|
342 is.putback (ch);
|
|
Chris@16
|
343 is.setstate (std::ios_base::failbit);
|
|
Chris@16
|
344 }
|
|
Chris@16
|
345 }
|
|
Chris@16
|
346 if (! is.fail ())
|
|
Chris@16
|
347 m.swap (s);
|
|
Chris@16
|
348 }
|
|
Chris@16
|
349 return is;
|
|
Chris@16
|
350 }
|
|
Chris@16
|
351
|
|
Chris@16
|
352
|
|
Chris@16
|
353 }}}
|
|
Chris@16
|
354
|
|
Chris@16
|
355 #endif
|
