char *mm_typecode_to_str(MM_typecode matcode)
{
char buffer[MM_MAX_LINE_LENGTH];
char *types[4];
int error =0;
int i;
/* check for MTX type */
if (mm_is_matrix(matcode))
types[0] = MM_MTX_STR;
else
error=1;
/* check for CRD or ARR matrix */
if (mm_is_sparserow(matcode))
types[1] = MM_SPARSEROW_STR;
else
if (mm_is_coordinate(matcode))
types[1] = MM_COORDINATE_STR;
else
if (mm_is_dense(matcode))
types[1] = MM_DENSE_STR;
else
return NULL;
/* check for element data type */
if (mm_is_real(matcode))
types[2] = MM_REAL_STR;
else
if (mm_is_complex(matcode))
types[2] = MM_COMPLEX_STR;
else
if (mm_is_pattern(matcode))
types[2] = MM_PATTERN_STR;
else
if (mm_is_integer(matcode))
types[2] = MM_INT_STR;
else
return NULL;
/* check for symmetry type */
if (mm_is_general(matcode))
types[3] = MM_GENERAL_STR;
else
if (mm_is_symmetric(matcode))
types[3] = MM_SYMM_STR;
else
if (mm_is_hermitian(matcode))
types[3] = MM_HERM_STR;
else
if (mm_is_skew(matcode))
types[3] = MM_SKEW_STR;
else
return NULL;
sprintf(buffer,"%s %s %s %s", types[0], types[1], types[2], types[3]);
return strdup(buffer);
}
int mm_is_valid ( MM_typecode matcode )
/******************************************************************************/
/*
Purpose:
MM_IS_VALID checks whether the MM header information is valid.
Modified:
31 October 2008
Parameters:
Input, MM_typecode MATCODE, the header information.
Output, int MM_IS_VALID, is TRUE if the matrix code is valid.
*/
{
if ( !mm_is_matrix ( matcode ) )
{
return 0;
}
if ( mm_is_dense ( matcode ) && mm_is_pattern ( matcode ) )
{
return 0;
}
if ( mm_is_real ( matcode ) && mm_is_hermitian ( matcode ) )
{
return 0;
}
if ( mm_is_pattern ( matcode ) &&
( mm_is_hermitian ( matcode ) || mm_is_skew ( matcode ) ) )
{
return 0;
}
return 1;
}
int mm_is_valid(MM_typecode matcode)
{
if (!mm_is_matrix(matcode)) return 0;
if (mm_is_dense(matcode) && mm_is_pattern(matcode)) return 0;
if (mm_is_real(matcode) && mm_is_hermitian(matcode)) return 0;
if (mm_is_pattern(matcode) && (mm_is_hermitian(matcode) ||
mm_is_skew(matcode))) return 0;
return 1;
}
void mm_typecode_to_str(MM_typecode matcode, char * buffer)
{
char type0[20];
char type1[20];
char type2[20];
char type3[20];
int error =0;
/* check for MTX type */
if (mm_is_matrix(matcode))
strcpy(type0, MM_MTX_STR);
else
error=1;
/* check for CRD or ARR matrix */
if (mm_is_sparse(matcode))
strcpy(type1, MM_SPARSE_STR);
else
if (mm_is_dense(matcode))
strcpy(type1, MM_DENSE_STR);
else
return;
/* check for element data type */
if (mm_is_real(matcode))
strcpy(type2, MM_REAL_STR);
else
if (mm_is_complex(matcode))
strcpy(type2, MM_COMPLEX_STR);
else
if (mm_is_pattern(matcode))
strcpy(type2, MM_PATTERN_STR);
else
if (mm_is_integer(matcode))
strcpy(type2, MM_INT_STR);
else
return;
/* check for symmetry type */
if (mm_is_general(matcode))
strcpy(type3, MM_GENERAL_STR);
else
if (mm_is_symmetric(matcode))
strcpy(type3, MM_SYMM_STR);
else
if (mm_is_hermitian(matcode))
strcpy(type3, MM_HERM_STR);
else
if (mm_is_skew(matcode))
strcpy(type3, MM_SKEW_STR);
else
return;
sprintf(buffer,"%s %s %s %s", type0, type1, type2, type3);
return;
}
/* mm_real supports real symmetric/general sparse/dense matrix */
static bool
is_type_supported (const MM_typecode typecode)
{
// invalid type
if (!mm_is_valid (typecode)) return false;
// pattern is not supported
if (mm_is_pattern (typecode)) return false;
// integer and complex matrix are not supported
if (mm_is_integer (typecode) || mm_is_complex (typecode)) return false;
// skew and hermitian are not supported
if (mm_is_skew (typecode) || mm_is_hermitian (typecode)) return false;
return true;
}
bool loadMmProperties(int *rowsCount,
int *columnsCount,
int *nonZerosCount,
bool *isStoredSparse,
int* matrixStorage,
int* matrixType,
FILE *file)
{
MM_typecode matcode;
// supports only valid matrices
if ((mm_read_banner(file, &matcode) != 0)
|| (!mm_is_matrix(matcode))
|| (!mm_is_valid(matcode)))
return false;
if ( mm_read_mtx_crd_size(file, rowsCount, columnsCount, nonZerosCount) != 0 )
return false;
// is it stored sparse?
if (mm_is_sparse(matcode))
*isStoredSparse = true;
else
*isStoredSparse = false;
if (mm_is_integer(matcode))
*matrixStorage = MATRIX_STORAGE_INTEGER;
else if (mm_is_real(matcode))
*matrixStorage = MATRIX_STORAGE_REAL;
else if (mm_is_complex(matcode))
*matrixStorage = MATRIX_STORAGE_COMPLEX;
else if (mm_is_pattern(matcode))
*matrixStorage = MATRIX_STORAGE_PATTERN;
if (mm_is_general(matcode))
*matrixType = MATRIX_TYPE_GENERAL;
else if (mm_is_symmetric(matcode))
*matrixType = MATRIX_TYPE_SYMMETRIC;
else if (mm_is_skew(matcode))
*matrixType = MATRIX_TYPE_SKEW;
else if (mm_is_hermitian(matcode))
*matrixType = MATRIX_TYPE_HERMITIAN;
return true;
}
bool LoadMatrixMarketFile(const std::string& file_path,
SparseMatrix<T>& A,
unsigned int& height,
unsigned int& width,
unsigned int& nnz)
{
std::ifstream infile(file_path);
if (!infile)
return false;
char mm_typecode[4];
// read the matrix market banner (header)
if (0 != mm_read_banner(infile, mm_typecode))
return false;
if (!mm_is_valid(mm_typecode))
return false;
// this reader supports these matrix types:
//
// sparse, real/integer/pattern, general/symm/skew
//
if (!mm_is_sparse(mm_typecode))
{
std::cerr << "Only sparse MatrixMarket files are supported." << std::endl;
return false;
}
if (!mm_is_real(mm_typecode) && !mm_is_integer(mm_typecode) && !mm_is_pattern(mm_typecode))
{
std::cerr << "Only real, integer, and pattern MatrixMarket formats are supported." << std::endl;
return false;
}
if (!mm_is_general(mm_typecode) && !mm_is_symmetric(mm_typecode) && !mm_is_skew(mm_typecode))
{
std::cerr << "Only general, symmetric, and skew-symmetric MatrixMarket formats are supported."
<< std::endl;
return false;
}
// read the number of rows, cols, nonzeros
if (0 != mm_read_mtx_crd_size(infile, height, width, nnz))
{
std::cerr << "could not read matrix coordinate information" << std::endl;
height = width = nnz = 0;
return false;
}
// read the data according to the type
bool is_real = mm_is_real(mm_typecode);
bool is_int = mm_is_integer(mm_typecode);
bool is_symmetric = mm_is_symmetric(mm_typecode);
bool is_skew = mm_is_skew(mm_typecode);
std::string line;
unsigned int reserve_size = nnz;
if (is_symmetric || is_skew)
reserve_size *= 2;
A.Clear();
A.Reserve(height, width, reserve_size);
// load num random entries of A
A.BeginLoad();
unsigned int row, col, count;
if (is_real)
{
double val;
for (count=0; count != nnz; ++count)
{
infile >> row; assert(row >= 1);
infile >> col; assert(col >= 1);
infile >> val;
// convert to 0-based indexing
row -= 1;
col -= 1;
A.Load(row, col, val);
if (row != col)
{
if (is_symmetric)
A.Load(col, row, val);
else if (is_skew)
A.Load(col, row, -val);
}
}
}
else if (is_int)
char *mm_typecode_to_str(MM_typecode matcode)
{
char buffer[MM_MAX_LINE_LENGTH];
const char *types[4];
char *mm_strdup(const char *);
int error =0;
/* check for MTX type */
if (mm_is_matrix(matcode))
types[0] = MM_MTX_STR;
else {
types[0] = NULL;
error=1;
}
/* check for CRD or ARR matrix */
if (mm_is_sparse(matcode))
types[1] = MM_SPARSE_STR;
else
if (mm_is_dense(matcode))
types[1] = MM_DENSE_STR;
else
return NULL;
/* check for element data type */
if (mm_is_real(matcode))
types[2] = MM_REAL_STR;
else
if (mm_is_complex(matcode))
types[2] = MM_COMPLEX_STR;
else
if (mm_is_pattern(matcode))
types[2] = MM_PATTERN_STR;
else
if (mm_is_integer(matcode))
types[2] = MM_INT_STR;
else
return NULL;
/* check for symmetry type */
if (mm_is_general(matcode))
types[3] = MM_GENERAL_STR;
else
if (mm_is_symmetric(matcode))
types[3] = MM_SYMM_STR;
else
if (mm_is_hermitian(matcode))
types[3] = MM_HERM_STR;
else
if (mm_is_skew(matcode))
types[3] = MM_SKEW_STR;
else
return NULL;
if( error == 1 )
sprintf(buffer,"Object to write is not a matrix; this is unsupported by the current mmio code.");
else
sprintf(buffer,"%s %s %s %s", types[0], types[1], types[2], types[3]);
return mm_strdup(buffer);
}
char *mm_typecode_to_str ( MM_typecode matcode )
/******************************************************************************/
/*
Purpose:
MM_TYPECODE_TO_STR converts the internal typecode to an MM header string.
Modified:
31 October 2008
*/
{
char buffer[MM_MAX_LINE_LENGTH];
char *types[4];
char *mm_strdup(const char *);
//int error =0;
/*
check for MTX type
*/
if (mm_is_matrix(matcode))
types[0] = MM_MTX_STR;
// else
// error=1;
/*
check for CRD or ARR matrix
*/
if (mm_is_sparse(matcode))
types[1] = MM_SPARSE_STR;
else
if (mm_is_dense(matcode))
types[1] = MM_DENSE_STR;
else
return NULL;
/*
check for element data type
*/
if (mm_is_real(matcode))
types[2] = MM_REAL_STR;
else
if (mm_is_complex(matcode))
types[2] = MM_COMPLEX_STR;
else
if (mm_is_pattern(matcode))
types[2] = MM_PATTERN_STR;
else
if (mm_is_integer(matcode))
types[2] = MM_INT_STR;
else
return NULL;
/*
check for symmetry type
*/
if (mm_is_general(matcode))
types[3] = MM_GENERAL_STR;
else
if (mm_is_symmetric(matcode))
types[3] = MM_SYMM_STR;
else
if (mm_is_hermitian(matcode))
types[3] = MM_HERM_STR;
else
if (mm_is_skew(matcode))
types[3] = MM_SKEW_STR;
else
return NULL;
sprintf(buffer,"%s %s %s %s", types[0], types[1], types[2], types[3]);
return mm_strdup(buffer);
}
int main() {
/* Host/device data structures */
cl_platform_id platform;
cl_device_id device;
cl_context context;
cl_command_queue queue;
cl_int err, i;
/* Program/kernel data structures */
cl_program program;
FILE *program_handle;
char *program_buffer, *program_log;
size_t program_size, log_size;
cl_kernel kernel;
size_t global_size, local_size;
/* Data and buffers */
int num_rows, num_cols, num_values;
int *rows, *cols;
float *values, *b_vec;
float result[2];
double value_double;
cl_mem rows_buffer, cols_buffer, values_buffer,
b_buffer, result_buffer;
/* Read sparse file */
FILE *mm_handle;
MM_typecode code;
/* Read matrix file */
if ((mm_handle = fopen(MM_FILE, "r")) == NULL) {
perror("Couldn't open the MatrixMarket file");
exit(1);
}
mm_read_banner(mm_handle, &code);
mm_read_mtx_crd_size(mm_handle, &num_rows, &num_cols, &num_values);
/* Check for symmetry and allocate memory */
if(mm_is_symmetric(code) || mm_is_skew(code) || mm_is_hermitian(code)) {
num_values += num_values - num_rows;
}
rows = (int*) malloc(num_values * sizeof(int));
cols = (int*) malloc(num_values * sizeof(int));
values = (float*) malloc(num_values * sizeof(float));
b_vec = (float*) malloc(num_rows * sizeof(float));
/* Read matrix data and close file */
i=0;
while(i<num_values) {
fscanf(mm_handle, "%d %d %lg\n", &rows[i], &cols[i], &value_double);
values[i] = (float)value_double;
cols[i]--;
rows[i]--;
if((rows[i] != cols[i]) && (mm_is_symmetric(code) || mm_is_skew(code) || mm_is_hermitian(code))) {
i++;
rows[i] = cols[i-1];
cols[i] = rows[i-1];
values[i] = values[i-1];
}
i++;
}
sort(num_values, rows, cols, values);
fclose(mm_handle);
/* Initialize the b vector */
srand(time(0));
for(i=0; i<num_rows; i++) {
b_vec[i] = (float)(rand() - RAND_MAX/2);
}
/* Identify a platform */
err = clGetPlatformIDs(1, &platform, NULL);
if(err < 0) {
perror("Couldn't identify a platform");
exit(1);
}
/* Access a device */
err = clGetDeviceIDs(platform, CL_DEVICE_TYPE_GPU, 1, &device, NULL);
if(err < 0) {
perror("Couldn't access any devices");
exit(1);
}
/* Create a context */
context = clCreateContext(NULL, 1, &device, NULL, NULL, &err);
if(err < 0) {
perror("Couldn't create a context");
exit(1);
}
/* Read program file and place content into buffer */
program_handle = fopen(PROGRAM_FILE, "r");
if(program_handle == NULL) {
perror("Couldn't find the program file");
exit(1);
}
fseek(program_handle, 0, SEEK_END);
program_size = ftell(program_handle);
rewind(program_handle);
program_buffer = (char*)calloc(program_size+1, sizeof(char));
fread(program_buffer, sizeof(char), program_size, program_handle);
fclose(program_handle);
/* Create program from file */
program = clCreateProgramWithSource(context, 1,
(const char**)&program_buffer, &program_size, &err);
if(err < 0) {
perror("Couldn't create the program");
exit(1);
}
free(program_buffer);
/* Build program */
err = clBuildProgram(program, 0, NULL, NULL, NULL, NULL);
if(err < 0) {
/* Find size of log and print to std output */
clGetProgramBuildInfo(program, device, CL_PROGRAM_BUILD_LOG,
0, NULL, &log_size);
program_log = (char*) calloc(log_size+1, sizeof(char));
clGetProgramBuildInfo(program, device, CL_PROGRAM_BUILD_LOG,
log_size+1, program_log, NULL);
printf("%s\n", program_log);
free(program_log);
exit(1);
}
/* Create a kernel */
kernel = clCreateKernel(program, KERNEL_FUNC, &err);
if(err < 0) {
printf("Couldn't create a kernel: %d", err);
exit(1);
};
/* Create buffers to hold the text characters and count */
rows_buffer = clCreateBuffer(context,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
num_values*sizeof(int), rows, &err);
if(err < 0) {
perror("Couldn't create a buffer");
exit(1);
};
cols_buffer = clCreateBuffer(context,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
num_values*sizeof(int), cols, NULL);
values_buffer = clCreateBuffer(context,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
num_values*sizeof(float), values, NULL);
b_buffer = clCreateBuffer(context,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
num_values*sizeof(float), b_vec, NULL);
result_buffer = clCreateBuffer(context, CL_MEM_WRITE_ONLY,
2*sizeof(float), NULL, NULL);
/* Create kernel argument */
err = clSetKernelArg(kernel, 0, sizeof(num_rows), &num_rows);
err |= clSetKernelArg(kernel, 1, sizeof(num_values), &num_values);
err |= clSetKernelArg(kernel, 2, num_rows * sizeof(float), NULL);
err |= clSetKernelArg(kernel, 3, num_rows * sizeof(float), NULL);
err |= clSetKernelArg(kernel, 4, num_rows * sizeof(float), NULL);
err |= clSetKernelArg(kernel, 5, num_rows * sizeof(float), NULL);
err |= clSetKernelArg(kernel, 6, sizeof(cl_mem), &rows_buffer);
err |= clSetKernelArg(kernel, 7, sizeof(cl_mem), &cols_buffer);
err |= clSetKernelArg(kernel, 8, sizeof(cl_mem), &values_buffer);
err |= clSetKernelArg(kernel, 9, sizeof(cl_mem), &b_buffer);
err |= clSetKernelArg(kernel, 10, sizeof(cl_mem), &result_buffer);
if(err < 0) {
printf("Couldn't set a kernel argument");
exit(1);
};
/* Create a command queue */
queue = clCreateCommandQueue(context, device, 0, &err);
if(err < 0) {
perror("Couldn't create a command queue");
exit(1);
};
/* Enqueue kernel */
global_size = num_rows;
local_size = num_rows;
err = clEnqueueNDRangeKernel(queue, kernel, 1, NULL, &global_size,
&local_size, 0, NULL, NULL);
if(err < 0) {
perror("Couldn't enqueue the kernel");
printf("Error: %d\n", err);
exit(1);
}
/* Read the results */
err = clEnqueueReadBuffer(queue, result_buffer, CL_TRUE, 0,
2*sizeof(float), result, 0, NULL, NULL);
if(err < 0) {
perror("Couldn't read the buffer");
exit(1);
}
/* Print the result */
printf("After %d iterations, the residual length is %f.\n",
(int)result[0], result[1]);
/* Deallocate resources */
free(b_vec);
free(rows);
free(cols);
free(values);
clReleaseMemObject(b_buffer);
clReleaseMemObject(rows_buffer);
clReleaseMemObject(cols_buffer);
clReleaseMemObject(values_buffer);
clReleaseMemObject(result_buffer);
clReleaseKernel(kernel);
clReleaseCommandQueue(queue);
clReleaseProgram(program);
clReleaseContext(context);
return 0;
}
static PetscErrorCode loadmtx(const char* filename, Mat *M, PetscBool *pattern) {
PetscErrorCode ierr;
FILE *f;
MM_typecode type;
int m,n,nz,i,j,k;
PetscInt low,high,lowj,highj,*d_nz,*o_nz;
double re,im;
PetscScalar s;
long pos;
PetscFunctionBegin;
f = fopen(filename,"r");
if (!f) SETERRQ2(PETSC_COMM_SELF,1,"fopen '%s': %s",filename,strerror(errno));
/* first read to set matrix kind and size */
ierr = mm_read_banner(f,&type);CHKERRQ(ierr);
if (!mm_is_valid(type) || !mm_is_sparse(type) ||
!(mm_is_real(type) || mm_is_complex(type) || mm_is_pattern(type) || mm_is_integer(type)))
SETERRQ1(PETSC_COMM_SELF,1,"Matrix format '%s' not supported",mm_typecode_to_str(type));
#if !defined(PETSC_USE_COMPLEX)
if (mm_is_complex(type)) SETERRQ(PETSC_COMM_SELF,1,"Complex matrix not supported in real configuration");
#endif
if (pattern) *pattern = mm_is_pattern(type) ? PETSC_TRUE : PETSC_FALSE;
ierr = mm_read_mtx_crd_size(f,&m,&n,&nz);CHKERRQ(ierr);
pos = ftell(f);
ierr = MatCreate(PETSC_COMM_WORLD,M);CHKERRQ(ierr);
ierr = MatSetSizes(*M,PETSC_DECIDE,PETSC_DECIDE,(PetscInt)m,(PetscInt)n);CHKERRQ(ierr);
ierr = MatSetFromOptions(*M);CHKERRQ(ierr);
ierr = MatSetUp(*M);CHKERRQ(ierr);
ierr = MatGetOwnershipRange(*M,&low,&high);CHKERRQ(ierr);
ierr = MatGetOwnershipRangeColumn(*M,&lowj,&highj);CHKERRQ(ierr);
ierr = PetscMalloc(sizeof(PetscInt)*(high-low),&d_nz);CHKERRQ(ierr);
ierr = PetscMalloc(sizeof(PetscInt)*(high-low),&o_nz);CHKERRQ(ierr);
for (i=0; i<high-low;i++) {
d_nz[i] = (i+low>=lowj && i+low<highj) ? 1 : 0;
o_nz[i] = (i+low>=lowj && i+low<highj) ? 0 : 1;
}
for (k=0;k<nz;k++) {
ierr = mm_read_mtx_crd_entry(f,&i,&j,&re,&im,type);CHKERRQ(ierr);
i--; j--;
if (i!=j) {
if (i>=low && i<high) {
if (j>=lowj && j<highj)
d_nz[i-low]++;
else
o_nz[i-low]++;
}
if (j>=low && j<high && !mm_is_general(type)) {
if (i>=low && i<high)
d_nz[j-low]++;
else
o_nz[j-low]++;
}
}
}
ierr = preallocation(*M,d_nz,o_nz);CHKERRQ(ierr);
ierr = PetscFree(d_nz);CHKERRQ(ierr);
ierr = PetscFree(o_nz);CHKERRQ(ierr);
/* second read to load the values */
ierr = fseek(f, pos, SEEK_SET);
if (ierr) SETERRQ1(PETSC_COMM_SELF,1,"fseek: %s",strerror(errno));
re = 1.0;
im = 0.0;
/* Set the diagonal to zero */
for (i=low; i<PetscMin(high,n); i++) {
ierr = MatSetValue(*M,i,i,0.0,INSERT_VALUES);CHKERRQ(ierr);
}
for (k=0;k<nz;k++) {
ierr = mm_read_mtx_crd_entry(f,&i,&j,&re,&im,type);
i--; j--;
if (i>=low && i<high) {
s = re + IMAGINARY * im;
ierr = MatSetValue(*M,i,j,s,INSERT_VALUES);CHKERRQ(ierr);
}
if (j>=low && j<high && i != j && !mm_is_general(type)) {
if (mm_is_symmetric(type)) s = re + IMAGINARY * im;
else if (mm_is_hermitian(type)) s = re - IMAGINARY * im;
else if (mm_is_skew(type)) s = -re - IMAGINARY * im;
else {
SETERRQ1(PETSC_COMM_SELF,1,"Matrix format '%s' not supported",mm_typecode_to_str(type));
}
ierr = MatSetValue(*M,j,i,s,INSERT_VALUES);CHKERRQ(ierr);
}
}
ierr = MatAssemblyBegin(*M,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr);
ierr = MatAssemblyEnd(*M,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr);
if (mm_is_symmetric(type)) {
ierr = MatSetOption(*M,MAT_SYMMETRIC,PETSC_TRUE);CHKERRQ(ierr);
}
if ((mm_is_symmetric(type) && mm_is_real(type)) || mm_is_hermitian(type)) {
ierr = MatSetOption(*M,MAT_HERMITIAN,PETSC_TRUE);CHKERRQ(ierr);
}
ierr = fclose(f);
if (ierr) SETERRQ1(PETSC_COMM_SELF,1,"fclose: %s",strerror(errno));
PetscFunctionReturn(0);
}
