2 // Copyright (c) 2014 Samsung Electronics Co., Ltd.
4 // Licensed under the Flora License, Version 1.0 (the License);
5 // you may not use this file except in compliance with the License.
6 // You may obtain a copy of the License at
8 // http://floralicense.org/license/
10 // Unless required by applicable law or agreed to in writing, software
11 // distributed under the License is distributed on an AS IS BASIS,
12 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 // See the License for the specific language governing permissions and
14 // limitations under the License.
18 #include <dali/public-api/math/matrix3.h>
24 #include <dali/public-api/math/math-utils.h>
44 const size_t NUM_BYTES_IN_ROW = 3*sizeof(float);
45 const size_t NUM_BYTES_IN_MATRIX = 9*sizeof(float);
51 const Matrix3 Matrix3::IDENTITY(1.0f, 0.0f, 0.0f,
58 memset(m, 0, NUM_BYTES_IN_MATRIX);
64 Matrix3::Matrix3(const Matrix3& m)
66 memcpy( mElements, m.mElements, NUM_BYTES_IN_MATRIX );
69 Matrix3::Matrix3(const Matrix& matrix)
71 const float* m4 = matrix.AsFloat();
72 memcpy(&mElements[S00], m4, NUM_BYTES_IN_ROW);
73 memcpy(&mElements[S10], m4+4, NUM_BYTES_IN_ROW);
74 memcpy(&mElements[S20], m4+8, NUM_BYTES_IN_ROW);
77 Matrix3::Matrix3(float s00, float s01, float s02, float s10, float s11, float s12, float s20, float s21, float s22)
91 void Matrix3::SetIdentity()
93 memset(mElements, 0, NUM_BYTES_IN_MATRIX);
99 Matrix3& Matrix3::operator=( const Matrix3& matrix )
101 // no point copying if self assigning
102 if( this != &matrix )
104 memcpy( AsFloat(), matrix.AsFloat(), NUM_BYTES_IN_MATRIX );
109 Matrix3& Matrix3::operator=( const Matrix& matrix )
111 const float* m4 = matrix.AsFloat();
112 memcpy(&mElements[S00], m4, NUM_BYTES_IN_ROW);
113 memcpy(&mElements[S10], m4+4, NUM_BYTES_IN_ROW);
114 memcpy(&mElements[S20], m4+8, NUM_BYTES_IN_ROW);
118 bool Matrix3::Invert()
120 bool succeeded = false;
123 cof[S00] = (mElements[S11] * mElements[S22] - mElements[S12] * mElements[S21]);
124 cof[S01] = (mElements[S02] * mElements[S21] - mElements[S01] * mElements[S22]);
125 cof[S02] = (mElements[S01] * mElements[S12] - mElements[S02] * mElements[S11]);
127 cof[S10] = (mElements[S12] * mElements[S20] - mElements[S10] * mElements[S22]);
128 cof[S11] = (mElements[S00] * mElements[S22] - mElements[S02] * mElements[S20]);
129 cof[S12] = (mElements[S02] * mElements[S10] - mElements[S00] * mElements[S12]);
131 cof[S20] = (mElements[S10] * mElements[S21] - mElements[S11] * mElements[S20]);
132 cof[S21] = (mElements[S01] * mElements[S20] - mElements[S00] * mElements[S21]);
133 cof[S22] = (mElements[S00] * mElements[S11] - mElements[S01] * mElements[S10]);
135 float det = mElements[S00] * cof[S00] + mElements[S01] * cof[S10] + mElements[S02] * cof[S20];
137 // In the case where the determinant is exactly zero, the matrix is non-invertible
138 if( ! EqualsZero( det ) )
141 for (int i = 0; i < 9; i++)
143 mElements[i] = cof[i] * det;
150 bool Matrix3::Transpose()
153 tmp = mElements[S01]; mElements[S01] = mElements[S10]; mElements[S10]=tmp;
154 tmp = mElements[S02]; mElements[S02] = mElements[S20]; mElements[S20]=tmp;
155 tmp = mElements[S21]; mElements[S21] = mElements[S12]; mElements[S12]=tmp;
159 bool Matrix3::ScaledInverseTranspose()
161 bool succeeded = false;
164 cof[S00] = (mElements[S11] * mElements[S22] - mElements[S12] * mElements[S21]);
165 cof[S01] = (mElements[S02] * mElements[S21] - mElements[S01] * mElements[S22]);
166 cof[S02] = (mElements[S01] * mElements[S12] - mElements[S02] * mElements[S11]);
168 cof[S10] = (mElements[S12] * mElements[S20] - mElements[S10] * mElements[S22]);
169 cof[S11] = (mElements[S00] * mElements[S22] - mElements[S02] * mElements[S20]);
170 cof[S12] = (mElements[S02] * mElements[S10] - mElements[S00] * mElements[S12]);
172 cof[S20] = (mElements[S10] * mElements[S21] - mElements[S11] * mElements[S20]);
173 cof[S21] = (mElements[S01] * mElements[S20] - mElements[S00] * mElements[S21]);
174 cof[S22] = (mElements[S00] * mElements[S11] - mElements[S01] * mElements[S10]);
176 float det = mElements[S00] * cof[S00] + mElements[S01] * cof[S10] + mElements[S02] * cof[S20];
178 // In the case where the determinant is exactly zero, the matrix is non-invertible
179 if( ! EqualsZero( det ) )
181 // Use average rather than determinant to remove rounding to zero errors in further multiplication
183 for(size_t i=0;i<9;i++)
187 float scale = 9.0f/sum; // Inverse of the average values
190 // Ensure the signs of the inverse are correct
194 mElements[S00] = cof[S00] * scale;
195 mElements[S01] = cof[S10] * scale;
196 mElements[S02] = cof[S20] * scale;
198 mElements[S10] = cof[S01] * scale;
199 mElements[S11] = cof[S11] * scale;
200 mElements[S12] = cof[S21] * scale;
202 mElements[S20] = cof[S02] * scale;
203 mElements[S21] = cof[S12] * scale;
204 mElements[S22] = cof[S22] * scale;
211 void Matrix3::Scale(float scale)
213 mElements[S00] *= scale;
214 mElements[S01] *= scale;
215 mElements[S02] *= scale;
216 mElements[S10] *= scale;
217 mElements[S11] *= scale;
218 mElements[S12] *= scale;
219 mElements[S20] *= scale;
220 mElements[S21] *= scale;
221 mElements[S22] *= scale;
224 float Matrix3::Magnitude() const
227 for(size_t i=0;i<9;i++)
229 avg+=fabsf(mElements[i]);
235 void Matrix3::Multiply( Matrix3& result, const Matrix3& lhs, const Matrix3& rhs )
237 float* temp = result.AsFloat();
238 const float* rhsPtr = rhs.AsFloat();
239 const float* lhsPtr = lhs.AsFloat();
241 for( int i=0; i < 3; i++ )
247 float value0 = lhsPtr[loc];
248 float value1 = lhsPtr[loc1];
249 float value2 = lhsPtr[loc2];
250 temp[loc] = (value0 * rhsPtr[0]) +
251 (value1 * rhsPtr[3]) +
252 (value2 * rhsPtr[6]);
254 temp[loc1] = (value0 * rhsPtr[1]) +
255 (value1 * rhsPtr[4]) +
256 (value2 * rhsPtr[7]);
258 temp[loc2] = (value0 * rhsPtr[2]) +
259 (value1 * rhsPtr[5]) +
260 (value2 * rhsPtr[8]);
264 bool Matrix3::operator==(const Matrix3 & rhs) const
267 Equals( mElements[0], rhs.mElements[0]) &&
268 Equals( mElements[1], rhs.mElements[1]) &&
269 Equals( mElements[2], rhs.mElements[2]) &&
270 Equals( mElements[3], rhs.mElements[3]) &&
271 Equals( mElements[4], rhs.mElements[4]) &&
272 Equals( mElements[5], rhs.mElements[5]) &&
273 Equals( mElements[6], rhs.mElements[6]) &&
274 Equals( mElements[7], rhs.mElements[7]) &&
275 Equals( mElements[8], rhs.mElements[8]));
278 bool Matrix3::operator!=(const Matrix3& rhs) const
280 return !(*this == rhs);
283 std::ostream& operator<< (std::ostream& o, const Matrix3& matrix)
285 return o << "[ [" << matrix.mElements[0] << ", " << matrix.mElements[1] << ", " << matrix.mElements[2] << "], "
286 << "[" << matrix.mElements[3] << ", " << matrix.mElements[4] << ", " << matrix.mElements[5] << "], "
287 << "[" << matrix.mElements[6] << ", " << matrix.mElements[7] << ", " << matrix.mElements[8] << "] ]";