fix indentation

linalg.c

@@ -15,75 +15,75 @@
 
 workspace_t *workspace_alloc(int n)
 {
-  workspace_t *result = (workspace_t*)malloc(sizeof(workspace_t));
-  result->n = n;
-  result->work_nonsymmv = gsl_eigen_nonsymmv_alloc(n);
-  result->work_symmv = gsl_eigen_symmv_alloc(n);
-  result->work_sv = gsl_vector_alloc(n);
-  result->eval_complex = gsl_vector_complex_alloc(n);
-  result->evec_complex = gsl_matrix_complex_alloc(n, n);
-  result->eval_real = gsl_vector_alloc(n);
-  result->evec_real = gsl_matrix_alloc(n, n);
-  result->permutation = gsl_permutation_alloc(n);
+	workspace_t *result = (workspace_t*)malloc(sizeof(workspace_t));
+	result->n = n;
+	result->work_nonsymmv = gsl_eigen_nonsymmv_alloc(n);
+	result->work_symmv = gsl_eigen_symmv_alloc(n);
+	result->work_sv = gsl_vector_alloc(n);
+	result->eval_complex = gsl_vector_complex_alloc(n);
+	result->evec_complex = gsl_matrix_complex_alloc(n, n);
+	result->eval_real = gsl_vector_alloc(n);
+	result->evec_real = gsl_matrix_alloc(n, n);
+	result->permutation = gsl_permutation_alloc(n);
 
-  result->tmp_mat = malloc(MAX_TEMP_MATRICES*sizeof(gsl_matrix*));
-  for(int i = 0; i < MAX_TEMP_MATRICES; i++)
-	  result->tmp_mat[i] = gsl_matrix_alloc(3, 3);
-  result->tmp_mat_used = 0;
-  result->tmp_vec = malloc(MAX_TEMP_MATRICES*sizeof(gsl_vector*));
-  for(int i = 0; i < MAX_TEMP_MATRICES; i++)
-	  result->tmp_vec[i] = gsl_vector_alloc(3);
-  result->tmp_vec_used = 0;
-  return result;
+	result->tmp_mat = malloc(MAX_TEMP_MATRICES*sizeof(gsl_matrix*));
+	for(int i = 0; i < MAX_TEMP_MATRICES; i++)
+		result->tmp_mat[i] = gsl_matrix_alloc(3, 3);
+	result->tmp_mat_used = 0;
+	result->tmp_vec = malloc(MAX_TEMP_MATRICES*sizeof(gsl_vector*));
+	for(int i = 0; i < MAX_TEMP_MATRICES; i++)
+		result->tmp_vec[i] = gsl_vector_alloc(3);
+	result->tmp_vec_used = 0;
+	return result;
 }
 
 void workspace_free(workspace_t *workspace)
 {
-  gsl_eigen_nonsymmv_free(workspace->work_nonsymmv);
-  gsl_eigen_symmv_free(workspace->work_symmv);
-  gsl_vector_free(workspace->work_sv);
-  gsl_vector_complex_free(workspace->eval_complex);
-  gsl_matrix_complex_free(workspace->evec_complex);
-  gsl_vector_free(workspace->eval_real);
-  gsl_matrix_free(workspace->evec_real);
-  gsl_permutation_free(workspace->permutation);
+	gsl_eigen_nonsymmv_free(workspace->work_nonsymmv);
+	gsl_eigen_symmv_free(workspace->work_symmv);
+	gsl_vector_free(workspace->work_sv);
+	gsl_vector_complex_free(workspace->eval_complex);
+	gsl_matrix_complex_free(workspace->evec_complex);
+	gsl_vector_free(workspace->eval_real);
+	gsl_matrix_free(workspace->evec_real);
+	gsl_permutation_free(workspace->permutation);
 
-  for(int i = 0; i < MAX_TEMP_MATRICES; i++)
-	  gsl_matrix_free(workspace->tmp_mat[i]);
-  free(workspace->tmp_mat);
-  for(int i = 0; i < MAX_TEMP_VECTORS; i++)
-	  gsl_vector_free(workspace->tmp_vec[i]);
-  free(workspace->tmp_vec);
+	for(int i = 0; i < MAX_TEMP_MATRICES; i++)
+		gsl_matrix_free(workspace->tmp_mat[i]);
+	free(workspace->tmp_mat);
+	for(int i = 0; i < MAX_TEMP_VECTORS; i++)
+		gsl_vector_free(workspace->tmp_vec[i]);
+	free(workspace->tmp_vec);
 }
 
 /************************************************** basic operations ********************************************************/
 
 void invert(gsl_matrix *in, gsl_matrix *out, workspace_t *ws)
 {
-  int s;
-  gsl_matrix *tmp = getTempMatrix(ws);
+	int s;
+	gsl_matrix *tmp = getTempMatrix(ws);
 
-  gsl_matrix_memcpy(tmp, in);
-  gsl_linalg_LU_decomp(tmp, ws->permutation, &s);
-  gsl_linalg_LU_invert(tmp, ws->permutation, out);
+	gsl_matrix_memcpy(tmp, in);
+	gsl_linalg_LU_decomp(tmp, ws->permutation, &s);
+	gsl_linalg_LU_invert(tmp, ws->permutation, out);
 
-  releaseTempMatrices(ws, 1);
+	releaseTempMatrices(ws, 1);
 }
 
 void conjugate(gsl_matrix *in, gsl_matrix *conjugator, gsl_matrix *out, workspace_t *ws)
 {
-  gsl_matrix *tmp = getTempMatrix(ws);
+	gsl_matrix *tmp = getTempMatrix(ws);
 
-  invert(conjugator, out, ws);   // use out to temporarily store inverse conjugator
-  gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, in, out, 0.0, tmp);  // in * conjugator^{-1}
-  gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, conjugator, tmp, 0.0, out);
+	invert(conjugator, out, ws);   // use out to temporarily store inverse conjugator
+	gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, in, out, 0.0, tmp);  // in * conjugator^{-1}
+	gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, conjugator, tmp, 0.0, out);
 
-  releaseTempMatrices(ws, 1);
+	releaseTempMatrices(ws, 1);
 }
 
 void multiply(gsl_matrix *a, gsl_matrix *b, gsl_matrix *out)
 {
-  gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, a, b, 0.0, out);
+	gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, a, b, 0.0, out);
 }
 
 void multiply_right(gsl_matrix *a, gsl_matrix *b, workspace_t *ws)
@@ -105,7 +105,7 @@ void multiply_left(gsl_matrix *a, gsl_matrix *b, workspace_t *ws)
 void multiply_many(workspace_t *ws, gsl_matrix *out, int n, ...)
 {
 	va_list args;
-    va_start(args, n);
+	va_start(args, n);
 
 	gsl_matrix_set_identity(out);
 
@@ -114,7 +114,7 @@ void multiply_many(workspace_t *ws, gsl_matrix *out, int n, ...)
 		multiply_right(out, cur, ws);
 	}
 
-    va_end(args);
+	va_end(args);
 }
 
 void cartan_calc(gsl_matrix *g, double *mu, workspace_t *ws)
@@ -132,69 +132,69 @@ void cartan_calc(gsl_matrix *g, double *mu, workspace_t *ws)
 
 void initialize(gsl_matrix *g, double *data, int x, int y)
 {
-  gsl_matrix_view view = gsl_matrix_view_array(data, x, y);
-  gsl_matrix_memcpy(g, &view.matrix);
+	gsl_matrix_view view = gsl_matrix_view_array(data, x, y);
+	gsl_matrix_memcpy(g, &view.matrix);
 }
 
 void rotation_matrix(gsl_matrix *g, double *vector)
 {
-  double normalized[3];
-  double norm = sqrt(vector[0]*vector[0] + vector[1]*vector[1] + vector[2]*vector[2]);
-  for(int i = 0; i < 3; i++)
-    normalized[i] = vector[i] / norm;
-  gsl_matrix_set_identity(g);
-  gsl_matrix_set(g, 0, 0, cos(norm));
-  gsl_matrix_set(g, 0, 1, -sin(norm) * normalized[2]);
-  gsl_matrix_set(g, 0, 2, +sin(norm) * normalized[1]);
-  gsl_matrix_set(g, 1, 0, +sin(norm) * normalized[2]);
-  gsl_matrix_set(g, 1, 1, cos(norm));
-  gsl_matrix_set(g, 1, 2, -sin(norm) * normalized[0]);
-  gsl_matrix_set(g, 2, 0, -sin(norm) * normalized[1]);
-  gsl_matrix_set(g, 2, 1, +sin(norm) * normalized[0]);
-  gsl_matrix_set(g, 2, 2, cos(norm));
-  for(int i = 0; i < 3; i++)
-    for(int j = 0; j < 3; j++)
-      g->data[i * g->tda + j] += (1 - cos(norm)) * normalized[i] * normalized[j];
+	double normalized[3];
+	double norm = sqrt(vector[0]*vector[0] + vector[1]*vector[1] + vector[2]*vector[2]);
+	for(int i = 0; i < 3; i++)
+		normalized[i] = vector[i] / norm;
+	gsl_matrix_set_identity(g);
+	gsl_matrix_set(g, 0, 0, cos(norm));
+	gsl_matrix_set(g, 0, 1, -sin(norm) * normalized[2]);
+	gsl_matrix_set(g, 0, 2, +sin(norm) * normalized[1]);
+	gsl_matrix_set(g, 1, 0, +sin(norm) * normalized[2]);
+	gsl_matrix_set(g, 1, 1, cos(norm));
+	gsl_matrix_set(g, 1, 2, -sin(norm) * normalized[0]);
+	gsl_matrix_set(g, 2, 0, -sin(norm) * normalized[1]);
+	gsl_matrix_set(g, 2, 1, +sin(norm) * normalized[0]);
+	gsl_matrix_set(g, 2, 2, cos(norm));
+	for(int i = 0; i < 3; i++)
+		for(int j = 0; j < 3; j++)
+			g->data[i * g->tda + j] += (1 - cos(norm)) * normalized[i] * normalized[j];
 }
 
 double trace(gsl_matrix *g)
 {
-  return gsl_matrix_get(g, 0, 0) + gsl_matrix_get(g, 1, 1) + gsl_matrix_get(g, 2, 2);
+	return gsl_matrix_get(g, 0, 0) + gsl_matrix_get(g, 1, 1) + gsl_matrix_get(g, 2, 2);
 }
 
 double determinant(gsl_matrix *g, workspace_t *ws)
 {
-  int s;
-  double result;
-  gsl_matrix *tmp = getTempMatrix(ws);
+	int s;
+	double result;
+	gsl_matrix *tmp = getTempMatrix(ws);
 
-  gsl_matrix_memcpy(tmp, g);
-  gsl_linalg_LU_decomp(tmp, ws->permutation, &s);
-  result = gsl_linalg_LU_det(tmp, s);
+	gsl_matrix_memcpy(tmp, g);
+	gsl_linalg_LU_decomp(tmp, ws->permutation, &s);
+	result = gsl_linalg_LU_det(tmp, s);
 
-  releaseTempMatrices(ws, 1);
-  return result;
+	releaseTempMatrices(ws, 1);
+	return result;
 }
 
 int jordan_calc(gsl_matrix *g, double *mu, workspace_t *ws)
 {
-  gsl_eigen_nonsymmv_params(1, ws->work_nonsymmv);
-  gsl_eigen_nonsymmv(g, ws->eval_complex, ws->evec_complex, ws->work_nonsymmv);
-  gsl_eigen_nonsymmv_sort(ws->eval_complex, ws->evec_complex, GSL_EIGEN_SORT_ABS_DESC);
+	gsl_eigen_nonsymmv_params(1, ws->work_nonsymmv);
+	gsl_eigen_nonsymmv(g, ws->eval_complex, ws->evec_complex, ws->work_nonsymmv);
+	gsl_eigen_nonsymmv_sort(ws->eval_complex, ws->evec_complex, GSL_EIGEN_SORT_ABS_DESC);
 
-  int real = 1;
-  for(int i = 0; i < 4; i++)
-    if(FCMP(GSL_IMAG(gsl_vector_complex_get(ws->eval_complex, i)), 0) != 0)
-      real = 0;
+	int real = 1;
+	for(int i = 0; i < 4; i++)
+		if(FCMP(GSL_IMAG(gsl_vector_complex_get(ws->eval_complex, i)), 0) != 0)
+			real = 0;
 
-  if(!real)
-	  return 0; // non-real eigenvalues!
+	if(!real)
+		return 0; // non-real eigenvalues!
 
-  for(int i = 0; i < ws->n - 1; i++) {
-    mu[i] = log(GSL_REAL(gsl_vector_complex_get(ws->eval_complex, i)) / GSL_REAL(gsl_vector_complex_get(ws->eval_complex, i+1)));
-  }
+	for(int i = 0; i < ws->n - 1; i++) {
+		mu[i] = log(GSL_REAL(gsl_vector_complex_get(ws->eval_complex, i)) / GSL_REAL(gsl_vector_complex_get(ws->eval_complex, i+1)));
+	}
 
-  return 1;
+	return 1;
 }
 
 int eigenvectors(gsl_matrix *g, gsl_matrix *evec_real, workspace_t *ws)
@@ -218,8 +218,8 @@ int eigenvectors(gsl_matrix *g, gsl_matrix *evec_real, workspace_t *ws)
 		goto eigenvectors_out;
 
 	for(int i = 0; i < ws->n; i++)
-	  for(int j = 0; j < ws->n; j++)
-		  gsl_matrix_set(evec_real, i, j, GSL_REAL(gsl_matrix_complex_get(ws->evec_complex, i, j)));
+		for(int j = 0; j < ws->n; j++)
+			gsl_matrix_set(evec_real, i, j, GSL_REAL(gsl_matrix_complex_get(ws->evec_complex, i, j)));
 
 	success = 1;