Android NDK对{extern";C";函数}的未定义引用?
我尝试开发一个Android应用程序。我已经成功地使用NDK实现了一个相当小的C++函数。但现在我想使用一个相当大的C++库,我在谷歌文档中找到了。 当我现在尝试使用ndk构建工具构建它时,我在cygwin控制台中遇到以下错误:Android NDK对{extern";C";函数}的未定义引用?,android,c++,android-ndk,Android,C++,Android Ndk,我尝试开发一个Android应用程序。我已经成功地使用NDK实现了一个相当小的C++函数。但现在我想使用一个相当大的C++库,我在谷歌文档中找到了。 当我现在尝试使用ndk构建工具构建它时,我在cygwin控制台中遇到以下错误: Compile++ thumb : ndkfoo <= subspace.cpp Compile++ thumb : ndkfoo <= classifier.cpp Compile++ thumb : ndkfoo <= eigen.cpp C
Compile++ thumb : ndkfoo <= subspace.cpp
Compile++ thumb : ndkfoo <= classifier.cpp
Compile++ thumb : ndkfoo <= eigen.cpp
Compile++ thumb : ndkfoo <= image.cpp
Compile++ thumb : ndkfoo <= imageio.cpp
Compile++ thumb : ndkfoo <= local.cpp
Compile++ thumb : ndkfoo <= matrix.cpp
Compile++ thumb : ndkfoo <= sample.cpp
SharedLibrary : libndkfoo.so
./obj/local/armeabi/objs/ndkfoo/eigen.o: In function `LibSubspace::geneigen(doub
le*, double*, int, double*, int, bool)':
U:\workspace\test/jni/eigen.cpp:91: undefined reference to `ilaenv_'
U:\workspace\test/jni/eigen.cpp:96: undefined reference to `dsygv_'
U:\workspace\test/jni/eigen.cpp:128: undefined reference to `dggev_'
./obj/local/armeabi/objs/ndkfoo/eigen.o: In function `LibSubspace::eigen(double*
, double*, double*, int, bool)':
U:\workspace\test/jni/eigen.cpp:55: undefined reference to `ilaenv_'
U:\workspace\test/jni/eigen.cpp:58: undefined reference to `dsyev_'
collect2: ld returned 1 exit status
make: *** [obj/local/armeabi/libndkfoo.so] Error 1
Compile++thumb:ndkfooGoogle告诉我这些函数来自Fortran-to-C编译器的运行时。因此,您需要链接一个名为libf2c
的库,或者查找源代码并使其成为NDK项目的一部分。后一种方法听起来更有希望——我认为不存在现成的NDK构建。这些是链接器错误,而不是编译器错误。您需要为linker命令指定相关的库。我必须在Android.mk中这样做吗?我认为ndk构建工具会自动进行链接:(嗯,无论从哪一个地方得到这四个函数,这些都必须在链接时可用。但是,您可以检查实际的链接器调用,看看是否一切都符合您的预期,如果您打算从库中来,也可以重复检查函数声明。我认为您的“大型C++库”。依赖于其他实现这4个缺失函数的库。你必须找到丢失的库,并编译并链接到你的代码。好的,听起来我应该先检查一下这个C++项目是否运行。我试着用VisualStudio编译它,看看它是否工作,如果不是,我会尝试LI2FC,无论如何都会告诉你:)谢谢。
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <float.h>
#include <assert.h>
#include <string.h>
#include "eigen.h"
extern "C" int ilaenv_(int *ispec, const char *name__, const char *opts,
int *n1, int *n2, int *n3, int *n4, int name_len, int opts_len);
extern "C" int dsyev_(const char *jobz, const char *uplo, int *n, double *a,
int *lda, double *w, double *work, int *lwork,
int *info);
extern "C" int dsygv_(int *itype, const char *jobz, const char *uplo, int *
n, double *a, int *lda, double *b, int *ldb,
double *w, double *work, int *lwork, int *info);
extern "C" int dggev_(const char *jobvl, const char *jobvr, int *n, double *
a, int *lda, double *b, int *ldb, double *alphar,
double *alphai, double *beta, double *vl, int *ldvl,
double *vr, int *ldvr, double *work, int *lwork,
int *info);
namespace LibSubspace {
int eigen(double* A, double* V, double* E, int n, bool verbose) {
int info;
int ispec = 1;
int lwork;
lwork = (ilaenv_(&ispec,"DSYEV","U",&n,&n,&n,&n,5,1)+2)*n;
double *work = (double *)malloc(lwork*sizeof(double));
memcpy(V,A,n*n*sizeof(double));
dsyev_("V","U",&n,V,&n,E,work,&lwork,&info);
free(work);
//check the return value
if(info!=0) {
if(verbose) {
printf("Error computing eigenvectors: ");
if(info>0) {
printf("Algorithm failed to converge\n");
} else if(info<0) {
printf("Illegal argument\n");
} else {
printf("Unknown error\n");
}
}
return 0;
}
return 1;
}
int geneigen(double *A, double *B, int n, double *W, int algorithm,
bool verbose) {
//getting the optimal lwork
int ispec = 1;
int lwork;
int info;
switch(algorithm) {
case EIGEN_CHOL:
{
//computing eigenvectors
lwork = (ilaenv_(&ispec,"DSYGV","U",&n,&n,&n,&n,5,1)+2)*n;
double *work = (double *)malloc(lwork*sizeof(double));
int problemType = 1;
char job = 'V';
char uplo = 'U';
dsygv_(&problemType,&job,&uplo,&n,A,&n,B,&n,W,work,&lwork,&info);
free(work);
//check the return value
if(info!=0) {
if(verbose) {
printf("Error computing eigenvectors: ");
if(info>n) {
printf("Matrix B is not positive definite\n");
} else if(info<=n) {
printf("The problem failed to converge\n");
} else if(info<0) {
printf("Illegal argument\n");
} else {
printf("Unknown error\n");
}
}
return 0;
}
}
break;
case EIGEN_QZ:
{
//more general algorithm
double *alphar = (double *)malloc(n*sizeof(double));
double *alphai = (double *)malloc(n*sizeof(double));
double *beta = (double *)malloc(n*sizeof(double));
double *VR = (double *)malloc(n*n*sizeof(double));
lwork = 8*n;
double *work = (double *)malloc(lwork*sizeof(double));
dggev_("N","V",&n,A,&n,B,&n,alphar,alphai,beta,
NULL,&n,VR,&n,work,&lwork,&info);
//eigenvalues
for(long i=0;i<n;i++) {
if(beta[i]!=0) {
W[i] = alphar[i]/beta[i];
} else W[i] = 0;
}
//eigenvectors
for(long i=0;i<n;i++) {
for(long j=0;j<n;j++) {
A[i*n+j] = VR[i*n+j];
}
}
free(alphar);
free(alphai);
free(beta);
free(VR);
free(work);
if(info!=0) {
printf("Error computing eigenvectors: ");
if(info<0) {
printf("Illegal argument\n");
} else if(info<=n) {
printf("QZ iteration failed\n");
} else {
printf("Unknown error\n");
}
return 0;
}
}
break;
}
return 1;
}
} //namespace