diag::Writer &
PrintTable::verbose_print(
diag::Writer & dout) const
{
calculate_column_widths();
dout << m_title << diag::dendl;
for (Table::const_iterator row_it = m_header.begin(); row_it != m_header.end(); ++row_it) {
dout << "";
printRow(dout.getStream(), *row_it);
dout << diag::dendl;
}
if (m_header.size() > 0) {
dout << "";
printHeaderBar(dout.getStream());
dout << diag::dendl;
}
for (Table::const_iterator row_it = m_table.begin(); row_it != m_table.end(); ++row_it) {
dout << "";
printRow(dout.getStream(), *row_it);
dout << diag::dendl;
}
return dout;
}
diag::Writer &
PrintTable::verbose_print(
diag::Writer & dout) const
{
// const ColumnWidthVector &column_width = calculate_column_widths();
// for (Table::const_iterator row_it = m_header.begin(); row_it != m_header.end(); ++row_it) {
// printRow(os, *row_it);
// os << '\n';
// }
// if (m_header.size() > 0)
// printHeaderBar(os);
// for (Table::const_iterator row_it = m_table.begin(); row_it != m_table.end(); ++row_it) {
// int i = 0;
// for (Row::const_iterator cell_it = (*row_it).begin(); cell_it != (*row_it).end(); ++cell_it, ++i)
// if ((*cell_it).m_flags & Cell::SPAN)
// dout << (*cell_it).m_string;
// else
// dout << std::setw(column_width[i]) << (*cell_it).m_string;
// dout << dendl;
// }
calculate_column_widths();
dout << m_title << std::endl;
for (Table::const_iterator row_it = m_header.begin(); row_it != m_header.end(); ++row_it) {
dout << "";
printRow(dout.getStream(), *row_it);
dout << diag::dendl;
}
if (m_header.size() > 0) {
dout << "";
printHeaderBar(dout.getStream());
dout << diag::dendl;
}
for (Table::const_iterator row_it = m_table.begin(); row_it != m_table.end(); ++row_it) {
dout << "";
printRow(dout.getStream(), *row_it);
dout << diag::dendl;
}
return dout;
}
/* function prints a 2-dimensional, square array to console */
void print2DArray(double **array, int length){
int i;
for(i = 0; i < length; ++i){
printf("row%d\t",i);
printRow(array[i], length);
}
}
static void msBedPrintTable(struct bed *bedList, struct hash *erHash,
char *itemName, char *expName, float minScore, float maxScore,
float stepSize, int base,
void(*printHeader)(struct bed *bedList, struct hash *erHash, char *item),
void(*printRow)(struct bed *bedList,struct hash *erHash, int expIndex, char *expName, float maxScore, enum expColorType colorScheme),
void(*printKey)(float minVal, float maxVal, float size, int base, struct rgbColor(*getColor)(float val, float max, enum expColorType colorScheme), enum expColorType colorScheme),
struct rgbColor(*getColor)(float val, float max, enum expColorType colorScheme),
enum expColorType colorScheme)
/* prints out a table from the data present in the bedList */
{
int i,featureCount=0;
if(bedList == NULL)
errAbort("hgc::msBedPrintTable() - bedList is NULL");
featureCount = slCount(bedList);
/* time to write out some html, first the table and header */
if(printKey != NULL)
printKey(minScore, maxScore, stepSize, base, getColor, colorScheme);
printf("<p>\n");
printf("<basefont size=-1>\n");
printf("<table bgcolor=\"#000000\" border=\"0\" cellspacing=\"0\" cellpadding=\"1\"><tr><td>");
printf("<table bgcolor=\"#fffee8\" border=\"0\" cellspacing=\"0\" cellpadding=\"1\">");
printHeader(bedList, erHash, itemName);
for(i=0; i<bedList->expCount; i++)
{
printRow(bedList, erHash, i, expName, maxScore, colorScheme);
}
printf("</table>");
printf("</td></tr></table>");
printf("</basefont>");
}
/**
* \brief Binary search of a sorted array
* \param b Array
* \param searchKey Search key
* \param low low index
* \param high high index
* \return found index or -1 if the search element hasn't been found
*/
size_t binarySearch(const int b[], const int searchKey, size_t low, size_t high)
{
// loop until low index is greater than high index
while (low <= high)
{
// determine middle element of subarray being searched
const size_t middle = (low + high) / 2;
// display subarray used in this loop iteration
printRow(b, low, middle, high);
// if searchKey matched middle element, return middle
if (searchKey == b[middle])
{
return middle;
}
if (searchKey < b[middle]) // if searchKey is less than middle element, set new high
{
high = middle - 1; // search low end of array
}
else // if searchKey is greater than middle element, set low
{
low = middle + 1; // search high end of array
}
}
return -1; // searchKey not found
}
void CRowSolution<T>::printSolutions(FILE *file, bool markNextUsed) const
{
if (!solutionSize() || !numSolutions())
return;
MUTEX_LOCK(out_mutex);
char buffer[2048];
if (numSolutions() >= sizeof(buffer) / 2) {
if (markNextUsed) {
SPRINTF(buffer, "Using solution # %zd out of %zd\n", solutionIndex(), numSolutions());
outString(buffer, file);
}
}
else {
if (markNextUsed) {
const size_t len2 = sizeof(buffer) << 1;
const size_t len = solutionIndex() * 2;
const size_t nLoops = len / len2;
size_t idx = 0;
for (size_t j = 0; j < nLoops; j++) {
idx = setSolutionFlags(buffer, sizeof(buffer), idx);
buffer[sizeof(buffer)-1] = '\0';
outString(buffer, file);
}
const size_t lastLen = 2 * (numSolutions() - idx);
setSolutionFlags(buffer, lastLen, idx);
buffer[len % len2 + 1] = '*';
strcpy_s(buffer + lastLen, sizeof(buffer)-lastLen, "\n");
outString(buffer, file);
}
printRow(file);
PERMUT_ELEMENT_TYPE *pPerm = solutionPerm() ? solutionPerm()->GetData() : NULL;
if (pPerm)
printRow(file, pPerm);
const VECTOR_ELEMENT_TYPE *pSolution = firstSolution();
for (unsigned int i = 0; i < solutionSize(); i++)
printRow(file, pPerm, pSolution + i);
}
MUTEX_UNLOCK(out_mutex);
}
std::ostream &
PrintTable::print(
std::ostream & os) const
{
if (m_flags & COMMA_SEPARATED_VALUES)
csvPrint(os);
else {
if (m_flags & PRINT_TRANSPOSED)
transpose_table();
calculate_column_widths();
if (!m_title.empty()) {
int prespaces = 0;
if(m_title.length() < m_tableWidth)
prespaces = (m_tableWidth - m_title.length())/2;;
os << m_commentPrefix;
os << std::left << std::setw(prespaces) << "" << m_title << '\n';
}
for (Table::const_iterator row_it = m_header.begin(); row_it != m_header.end(); ++row_it) {
os << m_commentPrefix;
printRow(os, *row_it);
os << '\n';
}
if (m_header.size() > 0) {
os << m_commentPrefix;
printHeaderBar(os);
os << '\n';
}
for (Table::const_iterator row_it = m_table.begin(); row_it != m_table.end(); ++row_it) {
os << std::left << std::setw(m_commentPrefix.size()) << "";
printRow(os, *row_it);
os << '\n';
}
}
return os;
}
void CsvExporter::beginTable(TableCellIterator *iterator)
{
// See RFC 4180 for format specification
// Write header row
QStringList cols;
for(int i=0;i<iterator->columns();++i) {
cols << iterator->header(i).name();
}
printRow(cols);
// Write data rows
while(iterator->nextRow()) {
cols.clear();
while(iterator->nextColumn())
cols << iterator->value().toString();
printRow(cols);
}
}
void stage1( char* X_name, int r, int c ) //r is row index, c is column index
{
matrix *mainMatrix;
mainMatrix = readInFile(X_name);
//find the value in r,c
int value;
value = findingValue(c, r, mainMatrix);
printf("%d\n", value); //prints the value
printRow(mainMatrix, r);
printCol(mainMatrix, c);
return;
}
void SplitTwo::printRow(EvenOdd row) const {
switch (row) {
case EvenOdd::EVEN: {
cout << charForAnimal(this->animals[0][0]);
cout << charForAnimal(this->animals[0][1]);
break;}
case EvenOdd::ODD: {
cout << charForAnimal(this->animals[1][0]);
cout << charForAnimal(this->animals[1][1]);
break;}
default: {
printRow(this->row);
break;}}}
void printSudoku(int **board){
int r;
char strboard[19*38+1];
char *majorborder = repeatStr("+===", 9);
char *minorborder = repeatStr("+---", 9);
for(r=0; r<9; r++){
if (r%3==0){
printf ("%s+\n",majorborder);
}else{
printf ("%s+\n",minorborder);
}
printf ("%s",printRow(board[r], 9));
}
printf ("%s+\n",majorborder);
}
static void
doPage(FILE * const ifP,
struct cmdlineInfo const cmdline) {
bit * bitrow;
int rows, cols, format, row;
unsigned int blankRows;
bool rowIsBlank;
pbm_readpbminit(ifP, &cols, &rows, &format);
bitrow = pbm_allocrow(cols);
allocateBuffers(cols);
putinit(cmdline);
blankRows = 0;
prevRowBufferIndex = 0;
memset(prevRowBuffer, 0, rowBufferSize);
for (row = 0; row < rows; ++row) {
pbm_readpbmrow(ifP, bitrow, cols, format);
convertRow(bitrow, cols, cmdline.pack, cmdline.delta,
&rowIsBlank);
if (rowIsBlank)
++blankRows;
else {
printBlankRows(blankRows);
blankRows = 0;
printRow();
}
}
printBlankRows(blankRows);
blankRows = 0;
putrest(!cmdline.noreset);
freeBuffers();
pbm_freerow(bitrow);
}
int binearSearch(const int arr[], int key, int low, int high) {
int middle;
while (low <= high) {
middle = (low + high) / 2;
printRow(arr, low, middle, high);
if (key == arr[middle]) {
return middle;
}
else if (key < arr[middle]) {
high = middle - 1;
}
else {
low = middle + 1;
}
}
return -1;//searched key not found!
}
static void printMap(unsigned char *map)
{
printf("%s\n", _("1st row"));
printRow(keyEsc, keyPause, map);
printf("%s\n", _("2nd row"));
printRow(keyE0, keyMinus, map);
printf("%s\n", _("3rd row"));
printRow(keyTab, keyNine, map);
printf("%s\n", _("4th row"));
printRow(keyCapsLock, keyPlus, map);
printf("%s\n", _("5th row"));
printRow(keyLShift, keyThree, map);
printf("%s\n", _("6th row"));
printRow(keyLCtrl, keyEnter, map);
printf("\n");
}
void scan_callback(int32_t err, hb_scanner_t scanner,
hb_result_t results[], size_t num_results, void *extra) {
if (num_results) {
const char *table_name;
size_t table_name_len;
hb_result_get_table(results[0], &table_name, &table_name_len);
HBASE_LOG_INFO("Received scan_next callback for table=\'%.*s\', row count=%d.",
table_name_len, table_name, num_results);
for (int i = 0; i < num_results; ++i) {
printRow(results[i]);
hb_result_destroy(results[i]);
}
hb_scanner_next(scanner, scan_callback, NULL);
} else {
hb_scanner_destroy(scanner, NULL, NULL);
pthread_mutex_lock(&scan_mutex);
scan_done = true;
pthread_cond_signal(&scan_cv);
pthread_mutex_unlock(&scan_mutex);
}
}
bool Printer::print(TableManager &tm)
{
/* if there is nothing to print, return */
if (conf.getColumns().size() == 0) {
return true;
}
this->tableManager = &tm;
/* print table header */
if (!conf.getQuiet()) {
printHeader();
}
const Cursor *cursor;
TableManagerCursor *tmc = tm.createCursor();
if (tmc == NULL) {
/* no tables, no rows */
return true;
}
uint64_t numPrinted = 0;
while (tmc->next()) {
cursor = tmc->getCurrentCursor();
printRow(cursor);
numPrinted++;
}
delete(tmc);
if (!conf.getQuiet()) {
printFooter(numPrinted);
}
return true;
}
static void
get_callback(int32_t err, hb_client_t client,
hb_get_t get, hb_result_t result, void *extra) {
bytebuffer rowKey = (bytebuffer)extra;
if (err == 0) {
const char *table_name;
size_t table_name_len;
hb_result_get_table(result, &table_name, &table_name_len);
HBASE_LOG_INFO("Received get callback for table=\'%.*s\'.",
table_name_len, table_name);
printRow(result);
const hb_cell_t *mycell;
bytebuffer qualifier = bytebuffer_strcpy("column-a");
HBASE_LOG_INFO("Looking up cell for family=\'%s\', qualifier=\'%.*s\'.",
FAMILIES[0], qualifier->length, qualifier->buffer);
if (hb_result_get_cell(result, FAMILIES[0], 1, qualifier->buffer,
qualifier->length, &mycell) == 0) {
HBASE_LOG_INFO("Cell found, value=\'%.*s\', timestamp=%lld.",
mycell->value_len, mycell->value, mycell->ts);
} else {
HBASE_LOG_ERROR("Cell not found.");
}
bytebuffer_free(qualifier);
hb_result_destroy(result);
} else {
HBASE_LOG_ERROR("Get failed with error code: %d.", err);
}
bytebuffer_free(rowKey);
hb_get_destroy(get);
pthread_mutex_lock(&get_mutex);
get_done = true;
pthread_cond_signal(&get_cv);
pthread_mutex_unlock(&get_mutex);
}
char *UniformData::ValueString(){
ostringstream os;
if (outputString){
free(outputString);
}
if (isValueSet){
if ((datasize[0] == datasize[1]) && (datasize[0] == 1)){ //Single Value
switch(datatype){
case 0:
os << name << "(" << program << ", " << location << ") = " << ((int*) data)[0];
break;
case 1:
os << name << "(" << program << ", " << location << ") = " << ((unsigned int*) data)[0];
break;
case 2:
os << name << "(" << program << ", " << location << ") = " << ((float*) data)[0];
break;
case 3:
os << name << "(" << program << ", " << location << ") = " << ((bool*) data)[0];
break;
default:
os << name << "(" << program << ", " << location << ") = " << std::hex << ((unsigned int*) data)[0];
break;
}
}
else if (datasize[0] == 1){ //Array
switch(datatype){
case 0:
os << name << "(" << program << ", " << location << ") = ";
printRow(&os, 0);
break;
case 1:
os << name << "(" << program << ", " << location << ") = ";
printRow(&os, 0);
break;
case 2:
os << name << "(" << program << ", " << location << ") = ";
printRow(&os, 0);
break;
case 3:
os << name << "(" << program << ", " << location << ") = ";
printRow(&os, 0);
break;
default:
os << name << "(" << program << ", " << location << ") = ";
printRow(&os, 0);
break;
}
}
else if (datasize[0] != 0){ //Matrix
//int blanklength = 7 + name.length() + getLength(program) + getLength(location);
os << name << "(" << program << ", " << location << ") = (about to be implemented)";
}
else{
os << name << "(" << program << ", " << location << ") = (not implemented yet / unknown)";
}
}
else{
os << name << "(" << program << ", " << location << ") = (null)";
}
outputString = strdup(os.str().c_str());
return outputString;
}
void printGrid(const Grid *const grid, bool use_colour, const char *phase) {
if (phase != nullptr) {
std::cout << "After " << phase << "...\n";
}
std::cout << " ";
for (unsigned i = 0; i < 9; ++i) {
std::cout << i << " ";
}
std::cout << "\n";
printLine(grid, 0, /*big_grid*/ true, /*thick*/ true, /*top*/ true,
/*bottom*/ false, use_colour);
std::cout << "\n";
for (unsigned row = 0; row < 9; ++row) {
const bool in_small_grid = row >= 3 && row <= 5;
unsigned small_row = (row - 3) * 3;
printRow(*grid->rows[row], row, 0, /*big_grid*/ true, use_colour);
if (in_small_grid) {
printRow(*grid->rows[small_row], small_row, 0, /*big_grid*/ false,
use_colour);
}
std::cout << "\n";
printRow(*grid->rows[row], row, 1, /*big_grid*/ true, use_colour);
if (in_small_grid) {
printRow(*grid->rows[small_row + 1], small_row + 1, 0, /*big_grid*/ false,
use_colour);
}
std::cout << "\n";
printRow(*grid->rows[row], row, 2, /*big_grid*/ true, use_colour);
if (in_small_grid) {
printRow(*grid->rows[small_row + 2], small_row + 2, 0, /*big_grid*/ false,
use_colour);
}
std::cout << "\n";
if (row != 8) {
printLine(grid, row, /*big_grid*/ true, row == 2 || row == 5,
/*top*/ false,
/*bottom*/ false, use_colour);
if (row == 2) {
// The line just before the small grid starts
printLine(grid, 0, /*big_grid*/ false, true, /*top*/ true,
/*bottom*/ false, use_colour);
} else if (in_small_grid) {
printLine(grid, small_row + 2, /*big_grid*/ false, /*thick*/ true,
/*top*/ false,
/*bottom*/ row == 5, use_colour);
}
std::cout << "\n";
}
}
printLine(grid, 8, /*big_grid*/ true, /*thick*/ true, /*top*/ false,
/*bottom*/ true, use_colour);
std::cout << "\n";
}
void main(){
int i;
for(i = 1; i <= 9; i++){
printRow(i);
}
}
// Print the whole matrix.
void printMatrix( ROW_t *pMat, int nRows )
{
for( int r = 0; r < nRows; ++r )
printRow( pMat[r] ); // Print each row.
}
/** prints given linear constraint information in PPM format to file stream */
static
SCIP_RETCODE printLinearCons(
SCIP* scip, /**< SCIP data structure */
FILE* file, /**< output file (or NULL for standard output) */
SCIP_READERDATA* readerdata, /**< information for reader */
SCIP_VAR** vars, /**< array of variables */
SCIP_Real* vals, /**< array of coefficients values (or NULL if all coefficient values are 1) */
int nvars, /**< number of variables */
int ncompletevars, /**< number of variables in whole problem */
SCIP_Bool transformed, /**< transformed constraint? */
SCIP_Real* maxcoef, /**< maximal coefficient */
SCIP_Bool printbool /**< print row or calculate maximum coefficient */
)
{
int v;
SCIP_VAR** activevars;
SCIP_Real* activevals;
int nactivevars;
SCIP_Real activeconstant = 0.0;
assert( scip != NULL );
assert( vars != NULL );
assert( nvars > 0 );
assert( readerdata != NULL );
/* duplicate variable and value array */
nactivevars = nvars;
SCIP_CALL( SCIPduplicateBufferArray(scip, &activevars, vars, nactivevars ) );
if( vals != NULL )
{
SCIP_CALL( SCIPduplicateBufferArray(scip, &activevals, vals, nactivevars ) );
}
else
{
SCIP_CALL( SCIPallocBufferArray(scip, &activevals, nactivevars) );
for( v = 0; v < nactivevars; ++v )
activevals[v] = 1.0;
}
/* retransform given variables to active variables */
SCIP_CALL( getActiveVariables(scip, activevars, activevals, &nactivevars, &activeconstant, transformed) );
if(!readerdata->rgb_relativ)
{
if(!printbool)
for(v = 0; v < nactivevars; ++v)
{
if( REALABS(activevals[v]) > *maxcoef)
*maxcoef = REALABS(activevals[v]);
}
else
{
assert (*maxcoef > 0);
/* print constraint */
printRow(scip, file, readerdata, activevars, activevals, nactivevars, ncompletevars, *maxcoef);
}
}
else
{
/* print constraint */
printRow(scip, file, readerdata, activevars, activevals, nactivevars, ncompletevars, *maxcoef);
}
/* free buffer arrays */
SCIPfreeBufferArray(scip, &activevars);
SCIPfreeBufferArray(scip, &activevals);
return SCIP_OKAY;
}
void printH(int n,int m){
for(int i=0;i<n;i++)
printRow(m);
}
int main(int argc, char* argv[]){
/*
* Main variables
*/
int shmfd;
char *token;
//void *shared_void;
// shared segment capable of storing MAX_ROWS elements
ssize_t shared_seg_size = (sizeof(sem_t)) + (MAX_ROWS * sizeof(host_row_t));
// Struct defination
struct addrinfo hints;
struct addrinfo *addr_list;
//printf("sizeof sem_t %lu\n",sizeof(sem_t));
//Umask
umask(0);
//Define shm Name
SHARED_MEM_NAME(sharedMemName);
//fprintf(stderr,"Shared Mem Name: <%s>\n",sharedMemName);
// Create shared Memory object
if((shmfd = shm_open(sharedMemName,O_CREAT | O_RDWR | O_EXCL, SHARED_MEM_PERMISSIONS)) >= 0){
//fprintf(stderr, "sharedMemName opened with O_EXCL: %s\n", strerror(errno));
// Ftruncate space in shmfd
ftruncate(shmfd,shared_seg_size);
//fprintf(stderr, "ftruncate: %s", strerror(errno));
//mmap space (create space)
shared_void = mmap(NULL, shared_seg_size, PROT_WRITE | PROT_READ, MAP_SHARED, shmfd, 0);
//fprintf(stderr, "mmap: %s\n", strerror(errno));
// Memset entire mmap space (host) to NULL if shm object doesn't exsist
memset(shared_void,0,sizeof(shared_void));
//fprintf(stderr, "memset host: %s\n", strerror(errno));
// sem_t for entire DataBase
globalSem = (sem_t *) shared_void;
sem_init(globalSem, SHARE_BETWEEN_PROCESSES,NUM_RESOURCES);
//fprintf(stderr, "globalSem init: %s\n", strerror(errno));
// Go to Structs area in memory
host = (host_row_t *) (shared_void + sizeof(sem_t));
// Initialize semaphores
for(i=0; i<=MAX_ROWS ;i++){
sem_init(&host[i].host_lock, SHARE_BETWEEN_PROCESSES,NUM_RESOURCES);
//fprintf(stderr, "sem_init[%d]: %s\n",i, strerror(errno));
}
}else{
//fprintf(stderr,"shm object exsists\n");
shmfd = shm_open(sharedMemName,O_RDWR, SHARED_MEM_PERMISSIONS);
//fprintf(stderr, "sharedMemName opened no O_EXCL: %s", strerror(errno));
//mmap space (get space)
shared_void = (host_row_t*)mmap(NULL, shared_seg_size, PROT_WRITE | PROT_READ, MAP_SHARED, shmfd, 0);
//fprintf(stderr, "mmap: %s", strerror(errno));
// sem_t for entire DataBase
globalSem = (sem_t *) shared_void;
// Go to Structs area in memory
host = (host_row_t *) (shared_void + sizeof(sem_t));
}
while(1){
printf("%s",PROMPT);
fgets(input,NAME_SIZE,stdin);
//perror("fgets");
//fprintf(stderr,"User Command <%s>\n",input);
// Strip newline charector from fgets
for(i = 0; i<= strlen(input); i++){
if(strcmp(&input[i], "\n") == 0){
input[i] = '\0';
}
}
if(strncmp(CMD_SELECT,input,(ssize_t)6) == 0){
strtok(input," ");
token = strtok(NULL, " ");
//fprintf(stderr,"In select\n");
//fprintf(stderr,"token: %s \n",token);
if(token == NULL){
//fprintf(stderr,"All rows being printed\n");
printAll(host);
}else{
//fprintf(stderr,"***** Finding & printing selected row(token) ******\n");
i = search(token, host, 0);
if(i >= 0){
printRow(host, i);
}else{
fprintf(stdout,"There is no row named %s in database\n",token);
}
}
}else if(strcmp(CMD_EXIT,input) == 0){
printf("exit called\n");
break;
}else if(strncmp(CMD_INSERT,input,(ssize_t)6) == 0){
//fprintf(stderr,"Insert Command <%s>\n",input);
strtok(input," ");
token = strtok(NULL, " ");
if( token == NULL){
printf("You must provide a hostname!\n");
}else{
//Memset hints
memset(&hints, 0, sizeof(struct addrinfo));
// memset addr_list
memset(&addr_list, 0, sizeof(struct addrinfo));
// Uset getInfo function to return relevant addresses
getInfo(token,hints,addr_list,host);
// Use insert function to insert the new row data
if((z = insert(token, ipstr4, ipstr6, host, globalSem)) != -1){
//fprintf(stderr,"insert done\n");
memset(&ipstr6,0,sizeof(ipstr6));
memset(&ipstr4,0,sizeof(ipstr4));
printRow(host, z);
} else{
//fprintf(stderr,"\ninsert function returned %d\n",z);
}
}
}else if(strncmp(input,"clear",(ssize_t)5) == 0){
printf("\e[1;1H\e[2J");
}else if(strncmp(input,CMD_UPDATE,(ssize_t)6) == 0){
char *UniformData::UniformString(){
ostringstream os;
if (outputString){
free(outputString);
}
os << name << "(" << program << ", " << location << ") type: " << std::hex << datatype_enum << " : " << datatypeName(datatype);
if (isValueSet){
if ((datasize[0] == datasize[1]) && (datasize[0] == 1)){ //Single Value
switch(datatype){
case CINT:
os << " = " << ((int*) data)[0];
break;
case CUINT:
os << " = " << ((unsigned int*) data)[0];
break;
case CFLOAT:
os << " = " << ((float*) data)[0];
break;
case CBOOL:
os << " = " << ((bool*) data)[0];
break;
default:
os << " = " << std::hex << ((unsigned int*) data)[0];
break;
}
}
else if (datasize[0] == 1){ //Array
os << " = ";
printRow(&os, 0);
}
else if (datasize[0] != 0){ //Matrix
os << " = ";
int blanklength = os.str().length();
char *blank = (char*) malloc (sizeof(char) * (blanklength + 1));
for (int i = 0; i < blanklength; i++){
blank[i] = ' ';
}
blank[blanklength] = 0;
printRow(&os, 0);
for (int i = 1; i < datasize[0]; i++)
{
os << '\n' << blank;
printRow(&os, i);
}
}
else{
os << " = (not implemented yet / unknown)";
}
}
else{
os << " = (null / not set)";
}
outputString = strdup(os.str().c_str());
return outputString;
}
