我要问的是这个问题的概括。具体来说,我想在旧版C和Fortran库周围制作C 特征包装器,该包装使用2D数据结构:
[ x[0,0] ... x[0,w-1] ]
[ u[0,0] ... u[0,w-1] ]
[ ... ]
[ x[c-1,0] ... x[c-1,w-1] ]
[ u[c-1,0] ... u[c-1,w-1] ]
每个条目x[i,j]和u[i,j]本身分别是大小(nx1(和(mx1(的列向量。这导致了一些复杂(容易出错的(指针算术以及一些非常不可读的代码。
因此,我想编写一个特征类,其唯一目的是使该矩阵的提取条目尽可能容易。在C 14中,看起来像data_getter.h:
#ifndef DATA_GETTER_HEADER
#define DATA_GETTER_HEADER
#include "Eigen/Dense"
template<typename T, int n, int m, int c, int w>
class DataGetter {
public:
/** Return a reference to the data as a matrix */
static auto asMatrix(T *raw_ptr) {
auto out = Eigen::Map<Eigen::Matrix<T, (n + m) * c, w>>(raw_ptr);
static_assert(decltype(out)::RowsAtCompileTime == (n + m) * c);
static_assert(decltype(out)::ColsAtCompileTime == w);
return out;
}
/** Return a reference to the submatrix
* [ x[i,0], ..., x[i,w-1]]
* [ u[i,0], ..., u[i,w-1]] */
static auto W(T *raw_ptr, int i) {
auto out = asMatrix(raw_ptr).template middleRows<n + m>((n + m) * i);
static_assert(decltype(out)::RowsAtCompileTime == (n + m));
static_assert(decltype(out)::ColsAtCompileTime == w);
return out;
}
/** Return a reference to the submatrix [ x[i,0], ..., x[i,w-1]] */
static auto X(T *raw_ptr, int i) {
auto out = W(raw_ptr, i).template topRows<n>();
static_assert(decltype(out)::RowsAtCompileTime == n);
static_assert(decltype(out)::ColsAtCompileTime == w);
return out;
}
/** Return a reference to x[i,j] */
static auto X(T *raw_ptr, int i, int j) {
auto out = X(raw_ptr, i).col(j);
static_assert(decltype(out)::RowsAtCompileTime == n);
static_assert(decltype(out)::ColsAtCompileTime == 1);
return out;
}
/** Return a reference to the submatrix [ u[i,0], ..., u[i,w-1]] */
static auto U(T *raw_ptr, int i) {
auto out = W(raw_ptr, i).template bottomRows<m>();
static_assert(decltype(out)::RowsAtCompileTime == m);
static_assert(decltype(out)::ColsAtCompileTime == w);
return out;
}
/** Return a reference to u[i,j] */
static auto U(T *raw_ptr, int i, int j) {
auto out = U(raw_ptr, i).col(j);
static_assert(decltype(out)::RowsAtCompileTime == m);
static_assert(decltype(out)::ColsAtCompileTime == 1);
return out;
}
/** Return a reference to the submatrix
* [ x[0,i], ..., x[c-1,i]]
* [ u[0,i], ..., u[c-1,i]] */
static auto C(T *raw_ptr, int i) {
auto out = Eigen::Map<Eigen::Matrix<T, n + m, c>>(
asMatrix(raw_ptr).col(i).template topRows<(n + m) * c>().data());
static_assert(decltype(out)::RowsAtCompileTime == (n + m));
static_assert(decltype(out)::ColsAtCompileTime == c);
return out;
}
/** Return a reference to the submatrix [ x[0,i], ..., x[c-1,i]] */
static auto Xc(T *raw_ptr, int i) {
auto out = C(raw_ptr, i).template topRows<n>();
static_assert(decltype(out)::RowsAtCompileTime == n);
static_assert(decltype(out)::ColsAtCompileTime == c);
return out;
}
/** Return a reference to the submatrix [ u[0,i], ..., u[c-1,i]] */
static auto Uc(T *raw_ptr, int i) {
auto out = C(raw_ptr, i).template bottomRows<m>();
static_assert(decltype(out)::RowsAtCompileTime == m);
static_assert(decltype(out)::ColsAtCompileTime == c);
return out;
}
};
#endif /* DATA_GETTER_HEADER */
这是一个测试程序,展示了其工作原理:
#include <iostream>
#include <vector>
#include "Eigen/Dense"
#include "data_getter.h"
using namespace std;
using namespace Eigen;
template<typename T>
void printSize(MatrixBase<T> &mat) {
cout << T::RowsAtCompileTime << " x " << T::ColsAtCompileTime;
}
int main() {
using T = double;
const int n = 2;
const int m = 3;
const int c = 2;
const int w = 5;
const int size = w * (c * (n + m));
std::vector<T> vec;
for (int i = 0; i < size; ++i)
vec.push_back(i);
/* Define the interface that we will use a lot */
using Data = DataGetter<T, n, m, c, w>;
/* Now let's map that pointer to some submatrices */
Ref<Matrix<T, (n + m) * c, w>> allData = Data::asMatrix(vec.data());
Ref<Matrix<T, n, w>> x1 = Data::X(vec.data(), 1);
Ref<Matrix<T, n, c>> xc2 = Data::Xc(vec.data(), 2);
Ref<Matrix<T, n + m, c>> xuc2 = Data::C(vec.data(), 2);
Ref<Matrix<T, n, 1>> x12 = Data::X(vec.data(), 1, 2);
cout << "Data::asMatrix( T* ): ";
printSize(allData);
cout << endl << endl << allData << endl << endl;
cout << "Data::X( T*, 1 ) : ";
printSize(x1);
cout << endl << endl << x1 << endl << endl;
cout << "Data::Xc( T*, 2 ) : ";
printSize(xc2);
cout << endl << endl << xc2 << endl << endl;
cout << "Data::C( T*, 2 ) : ";
printSize(xuc2);
cout << endl << endl << xuc2 << endl << endl;
cout << "Data::X( T*, 1, 2 ) : ";
printSize(x12);
cout << endl << endl << x12 << endl << endl;
/* Now changes to x12 should be reflected in the other variables */
x12.setZero();
cout << "-----" << endl << endl << "x12.setZero() " << endl << endl << "-----" << endl;
cout << "allData" << endl << endl << allData << endl << endl;
cout << "x1" << endl << endl << x1 << endl << endl;
cout << "xc2" << endl << endl << xc2 << endl << endl;
cout << "xuc2" << endl << endl << xuc2 << endl << endl;
cout << "x12" << endl << endl << x12 << endl << endl;
return 0;
}
具体来说,它会产生以下输出(如预期(:
Data::asMatrix( T* ): 10 x 5
0 10 20 30 40
1 11 21 31 41
2 12 22 32 42
3 13 23 33 43
4 14 24 34 44
5 15 25 35 45
6 16 26 36 46
7 17 27 37 47
8 18 28 38 48
9 19 29 39 49
Data::X( T*, 1 ) : 2 x 5
5 15 25 35 45
6 16 26 36 46
Data::Xc( T*, 2 ) : 2 x 2
20 25
21 26
Data::C( T*, 2 ) : 5 x 2
20 25
21 26
22 27
23 28
24 29
Data::X( T*, 1, 2 ) : 2 x 1
25
26
-----
x12.setZero()
-----
allData
0 10 20 30 40
1 11 21 31 41
2 12 22 32 42
3 13 23 33 43
4 14 24 34 44
5 15 0 35 45
6 16 0 36 46
7 17 27 37 47
8 18 28 38 48
9 19 29 39 49
x1
5 15 0 35 45
6 16 0 36 46
xc2
20 0
21 0
xuc2
20 0
21 0
22 27
23 28
24 29
x12
0
0
问题是,关于尺寸的编译时间检查似乎无法正常工作。在data_getter.h中,您可能会注意到我在尺寸上放了一堆static_assert s。这似乎有点过分杀伤力,但我想确保表达式确实正在执行编译时间操作,以便我们可以在尺寸上获得检查。如果它们是动态表达式,那么大小将是-1。
但是,尽管所有static_assert S通过,但似乎并没有对参考文献进行任何编译时间检查。例如,如果我们更改测试程序中的以下行
Ref<Matrix<T, (n + m) * c, w>> allData = Data::asMatrix(vec.data());
进入
Ref<Matrix<T, (n + m) * c + 1, w>> allData = Data::asMatrix(vec.data());
代码编译,但会产生运行时崩溃。这似乎表明Ref正在丢弃尺寸。那么我应该如何定义这些变量呢?
可能会想到的一个想法是将这些返回值也定义为auto。但是,特征文档会劝阻这一点,因为如果我们最终在循环中使用输出,则可能会一遍又一遍地评估该表达式。这就是我使用Ref s的原因。另外,由于我们在编译时知道它的大小似乎是个好主意...
那么,这是参考中的错误吗?我应该使用哪种类型用于我所有访问者方法都吐出的变量?
如果您在评论中错过了它... @Ggael说eigen Ref s在编译时不要检查尺寸。