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Reference Guide
TODBCStatement.cxx
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1 // @(#)root/odbc:$Id$
2 // Author: Sergey Linev 6/02/2006
3 
4 /*************************************************************************
5  * Copyright (C) 1995-2006, Rene Brun and Fons Rademakers. *
6  * All rights reserved. *
7  * *
8  * For the licensing terms see $ROOTSYS/LICENSE. *
9  * For the list of contributors see $ROOTSYS/README/CREDITS. *
10  *************************************************************************/
11 
12 
13 //________________________________________________________________________
14 //
15 // SQL statement class for ODBC
16 //
17 // See TSQLStatement class documentation for more details
18 //
19 //________________________________________________________________________
20 
21 
22 #include "TODBCStatement.h"
23 #include "TODBCServer.h"
24 #include "TDataType.h"
25 #include "Riostream.h"
26 
27 #include <sqlext.h>
28 #include <stdlib.h>
29 
30 #define kSqlTime 123781
31 #define kSqlDate 123782
32 #define kSqlTimestamp 123783
33 #define kSqlBinary 123784
34 
35 
37 
38 ////////////////////////////////////////////////////////////////////////////////
39 ///constructor
40 
41 TODBCStatement::TODBCStatement(SQLHSTMT stmt, Int_t rowarrsize, Bool_t errout) :
42  TSQLStatement(errout)
43 {
44  fHstmt = stmt;
45  fBufferPreferredSize = rowarrsize;
46 
47  fBuffer = 0;
48  fStatusBuffer = 0;
49  fNumBuffers = 0;
50  fBufferLength = 0;
51  fBufferCounter = 0;
52 
53  fWorkingMode = 0;
54 
55  fNumParsProcessed = 0;
56  fNumRowsFetched = 0;
57 
58  SQLSMALLINT paramsCount = 0;
59  SQLRETURN retcode = SQLNumParams(fHstmt, &paramsCount);
60  if (ExtractErrors(retcode,"Constructor"))
61  paramsCount = 0;
62 
63  if (paramsCount>0) {
64 
65  fWorkingMode = 1; // we are now using buffers for parameters
66  fNumParsProcessed = 0;
67 
68  SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAM_BIND_TYPE, SQL_PARAM_BIND_BY_COLUMN, 0);
69 
70  SQLUINTEGER setsize = fBufferPreferredSize;
71  retcode = SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAMSET_SIZE, (SQLPOINTER) (long) setsize, 0);
72  ExtractErrors(retcode,"Constructor");
73 
74  SQLUINTEGER getsize = 0;
75 
76  retcode = SQLGetStmtAttr(fHstmt, SQL_ATTR_PARAMSET_SIZE, &getsize, 0, 0);
77  ExtractErrors(retcode,"Constructor");
78 
79  Int_t bufferlen = fBufferPreferredSize;
80 
81  // MySQL is not yet support array of parameters
82  if (getsize<=1) bufferlen=1; else
83  if (getsize!=setsize) {
84  SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAMSET_SIZE, (SQLPOINTER) 1, 0);
85  bufferlen = 1;
86  }
87 
88  SetNumBuffers(paramsCount, bufferlen);
89 
90  SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAM_STATUS_PTR, fStatusBuffer, 0);
91  SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAMS_PROCESSED_PTR, &fNumParsProcessed, 0);
92 
93  // indicates that we are starting
94  fBufferCounter = -1;
95  }
96 
97  fNumRowsFetched = 0;
98  fLastResultRow = 0;
99 }
100 
101 ////////////////////////////////////////////////////////////////////////////////
102 ///destructor
103 
105 {
106  Close();
107 }
108 
109 ////////////////////////////////////////////////////////////////////////////////
110 /// Close statement
111 
113 {
114  FreeBuffers();
115 
116  SQLFreeHandle(SQL_HANDLE_STMT, fHstmt);
117 
118  fHstmt=0;
119 }
120 
121 ////////////////////////////////////////////////////////////////////////////////
122 /// process statement
123 
125 {
126  ClearError();
127 
128  SQLRETURN retcode = SQL_SUCCESS;
129 
130  if (IsParSettMode()) {
131 
132  // check if we start filling buffers, but not complete it
133  if (fBufferCounter>=0) {
134  // if buffer used not fully, set smaller size of buffer arrays
136  SQLUINTEGER setsize = fBufferCounter+1;
137  SQLSetStmtAttr(fHstmt, SQL_ATTR_PARAMSET_SIZE, (SQLPOINTER) (long) setsize, 0);
138  }
139  retcode = SQLExecute(fHstmt);
140  }
141 
142  // after Process we finish working with parameters data,
143  // if necessary, user can try to access resultset of statement
144  fWorkingMode = 0;
145  FreeBuffers();
146  fBufferCounter = -1;
147  } else {
148 
149  // just execute statement,
150  // later one can try to access results of statement
151  retcode = SQLExecute(fHstmt);
152  }
153 
154  return !ExtractErrors(retcode, "Process");
155 }
156 
157 ////////////////////////////////////////////////////////////////////////////////
158 ///get number of affected rows
159 
161 {
162  ClearError();
163 
164  SQLLEN rowCount;
165  SQLRETURN retcode = SQL_SUCCESS;
166 
167  retcode = SQLRowCount(fHstmt, &rowCount);
168 
169  if (ExtractErrors(retcode, "GetNumAffectedRows")) return -1;
170 
171  return rowCount;
172 }
173 
174 ////////////////////////////////////////////////////////////////////////////////
175 /// Store result of statement processing.
176 /// Results set, produced by processing of statement, can be stored, and accessed by
177 /// TODBCStamenet methoods like NextResultRow(), GetInt(), GetLong() and so on.
178 
180 {
181  ClearError();
182 
183  if (IsParSettMode()) {
184  SetError(-1,"Call Process() method before","StoreResult");
185  return kFALSE;
186  }
187 
188  FreeBuffers();
189 
190  SQLSMALLINT columnCount = 0;
191 
192  SQLRETURN retcode = SQLNumResultCols(fHstmt, &columnCount);
193  if (ExtractErrors(retcode, "StoreResult")) return kFALSE;
194 
195  if (columnCount==0) return kFALSE;
196 
197  SetNumBuffers(columnCount, fBufferPreferredSize);
198 
199  SQLULEN arrsize = fBufferLength;
200 
201  SQLSetStmtAttr(fHstmt, SQL_ATTR_ROW_BIND_TYPE, SQL_BIND_BY_COLUMN, 0);
202  SQLSetStmtAttr(fHstmt, SQL_ATTR_ROW_ARRAY_SIZE, (SQLPOINTER) arrsize, 0);
203  SQLSetStmtAttr(fHstmt, SQL_ATTR_ROW_STATUS_PTR, fStatusBuffer, 0);
204  SQLSetStmtAttr(fHstmt, SQL_ATTR_ROWS_FETCHED_PTR, &fNumRowsFetched, 0);
205 
206  for (int n=0;n<fNumBuffers;n++) {
207  SQLCHAR columnName[1024];
208  SQLSMALLINT nameLength;
209  SQLSMALLINT dataType;
210  SQLULEN columnSize;
211  SQLSMALLINT decimalDigits;
212  SQLSMALLINT nullable;
213 
214  retcode = SQLDescribeCol(fHstmt, n+1, columnName, 1024,
215  &nameLength, &dataType,
216  &columnSize, &decimalDigits, &nullable);
217 
218  BindColumn(n, dataType, columnSize);
219 
220  if (nameLength>0) {
221  fBuffer[n].fBnamebuffer = new char[nameLength+1];
222  strlcpy(fBuffer[n].fBnamebuffer, (const char*) columnName, nameLength+1);
223  }
224  }
225 
226  fNumRowsFetched = 0;
227  fLastResultRow = 0;
228 
229  fWorkingMode = 2;
230 
231  return kTRUE;
232 }
233 
234 ////////////////////////////////////////////////////////////////////////////////
235 ///return number of fields
236 
238 {
239  return IsResultSet() ? fNumBuffers : -1;
240 }
241 
242 ////////////////////////////////////////////////////////////////////////////////
243 ///return field name
244 
246 {
247  ClearError();
248 
249  if (!IsResultSet() || (nfield<0) || (nfield>=fNumBuffers)) return 0;
250 
251  return fBuffer[nfield].fBnamebuffer;
252 }
253 
254 
255 ////////////////////////////////////////////////////////////////////////////////
256 ///next result row
257 
259 {
260  ClearError();
261 
262  if (!IsResultSet()) return kFALSE;
263 
264  if ((fNumRowsFetched==0) ||
265  (1.*fBufferCounter >= 1.*(fNumRowsFetched-1))) {
266 
267  fBufferCounter = 0;
268  fNumRowsFetched = 0;
269 
270  SQLRETURN retcode = SQLFetchScroll(fHstmt, SQL_FETCH_NEXT, 0);
271  if (retcode==SQL_NO_DATA) fNumRowsFetched=0; else
272  ExtractErrors(retcode,"NextResultRow");
273 
274  // this is workaround of Oracle Linux ODBC driver
275  // it does not returns number of fetched lines, therefore one should
276  // calculate it from current row number
277  if (!IsError() && (retcode!=SQL_NO_DATA) && (fNumRowsFetched==0)) {
278  SQLULEN rownumber = 0;
279  SQLRETURN retcode2 = SQLGetStmtAttr(fHstmt, SQL_ATTR_ROW_NUMBER, &rownumber, 0, 0);
280  ExtractErrors(retcode2, "NextResultRow");
281 
282  if (!IsError()) {
283  fNumRowsFetched = rownumber - fLastResultRow;
284  fLastResultRow = rownumber;
285  }
286  }
287 
289  SetError(-1, "Missmatch between buffer length and fetched rows number", "NextResultRow");
290 
291  if (IsError() || (fNumRowsFetched==0)) {
292  fWorkingMode = 0;
293  FreeBuffers();
294  }
295 
296  } else
297  fBufferCounter++;
298 
299  return IsResultSet();
300 }
301 
302 ////////////////////////////////////////////////////////////////////////////////
303 /// Extract errors, produced by last ODBC function call
304 
305 Bool_t TODBCStatement::ExtractErrors(SQLRETURN retcode, const char* method)
306 {
307  if ((retcode== SQL_SUCCESS) || (retcode == SQL_SUCCESS_WITH_INFO)) return kFALSE;
308 
309  SQLINTEGER i = 0;
310  SQLINTEGER native;
311  SQLCHAR state[ 7 ];
312  SQLCHAR text[256];
313  SQLSMALLINT len;
314  SQLRETURN ret;
315  do {
316  ret = SQLGetDiagRec(SQL_HANDLE_STMT, fHstmt, ++i, state, &native, text,
317  sizeof(text), &len );
318  if (ret == SQL_SUCCESS) SetError(native, (const char*) text, method);
319 // Error(method, "%s:%ld:%ld:%s\n", state, i, native, text);
320  }
321  while( ret == SQL_SUCCESS );
322  return kTRUE;
323 }
324 
325 ////////////////////////////////////////////////////////////////////////////////
326 ///run next iteration
327 
329 {
330  ClearError();
331 
332  if (!IsParSettMode() || (fBuffer==0) || (fBufferLength<=0)) return kFALSE;
333 
334  if (fBufferCounter>=fBufferLength-1) {
335  SQLRETURN retcode = SQLExecute(fHstmt);
336  if (ExtractErrors(retcode,"NextIteration")) return kFALSE;
337  fBufferCounter = 0;
338  } else
339  fBufferCounter++;
340 
341  // probably, we do not need it, but anyway
342  fStatusBuffer[fBufferCounter] = SQL_ROW_SUCCESS;
343 
344  return kTRUE;
345 }
346 
347 ////////////////////////////////////////////////////////////////////////////////
348 ///return number of parameters
349 
351 {
352  return IsParSettMode() ? fNumBuffers : 0;
353 }
354 
355 ////////////////////////////////////////////////////////////////////////////////
356 ///set number of buffers
357 
359 {
360  FreeBuffers();
361 
362  fNumBuffers = isize;
363  fBufferLength = ilen;
364  fBufferCounter = 0;
365 
367  for (Int_t n=0;n<fNumBuffers;n++) {
368  fBuffer[n].fBroottype = 0;
369  fBuffer[n].fBsqltype = 0;
370  fBuffer[n].fBsqlctype = 0;
371  fBuffer[n].fBbuffer = 0;
372  fBuffer[n].fBelementsize = 0;
373  fBuffer[n].fBlenarray = 0;
374  fBuffer[n].fBstrbuffer = 0;
375  fBuffer[n].fBnamebuffer = 0;
376  }
377 
378  fStatusBuffer = new SQLUSMALLINT[fBufferLength];
379 }
380 
381 ////////////////////////////////////////////////////////////////////////////////
382 /// Free allocated buffers
383 
385 {
386  if (fBuffer==0) return;
387  for (Int_t n=0;n<fNumBuffers;n++) {
388  if (fBuffer[n].fBbuffer!=0)
389  free(fBuffer[n].fBbuffer);
390  delete[] fBuffer[n].fBlenarray;
391  delete[] fBuffer[n].fBstrbuffer;
392  delete[] fBuffer[n].fBnamebuffer;
393  }
394 
395  delete[] fStatusBuffer;
396  delete[] fBuffer;
397  fBuffer = 0;
398  fNumBuffers = 0;
399  fBufferLength = 0;
400  fStatusBuffer = 0;
401 }
402 
403 ////////////////////////////////////////////////////////////////////////////////
404 /// Bind result column to buffer. Allocate buffer of appropriate type
405 
406 Bool_t TODBCStatement::BindColumn(Int_t ncol, SQLSMALLINT sqltype, SQLUINTEGER size)
407 {
408  ClearError();
409 
410  if ((ncol<0) || (ncol>=fNumBuffers)) {
411  SetError(-1,"Internal error. Column number invalid","BindColumn");
412  return kFALSE;
413  }
414 
415  if (fBuffer[ncol].fBsqltype!=0) {
416  SetError(-1,"Internal error. Bind for column already done","BindColumn");
417  return kFALSE;
418  }
419 
420  SQLSMALLINT sqlctype = 0;
421  switch (sqltype) {
422  case SQL_CHAR:
423  case SQL_VARCHAR: sqlctype = SQL_C_CHAR; break;
424  case SQL_BINARY:
425  case SQL_LONGVARBINARY:
426  case SQL_VARBINARY: sqlctype = SQL_C_BINARY; break;
427  case SQL_LONGVARCHAR: Info("BindColumn","BIG VARCHAR not supported yet"); return kFALSE; break;
428 
429  case SQL_DECIMAL: sqlctype = SQL_C_DOUBLE; break;
430  case SQL_NUMERIC: sqlctype = SQL_C_DOUBLE; break;
431  case SQL_SMALLINT: sqlctype = SQL_C_SLONG; break;
432  case SQL_INTEGER: sqlctype = SQL_C_SLONG; break;
433  case SQL_FLOAT: sqlctype = SQL_C_FLOAT; break;
434  case SQL_REAL:
435  case SQL_DOUBLE: sqlctype = SQL_C_DOUBLE; break;
436  case SQL_TINYINT: sqlctype = SQL_C_STINYINT; break;
437  case SQL_BIGINT: sqlctype = SQL_C_SBIGINT; break;
438  case SQL_TYPE_DATE: sqlctype = SQL_C_TYPE_DATE; break;
439  case SQL_TYPE_TIME: sqlctype = SQL_C_TYPE_TIME; break;
440  case SQL_TYPE_TIMESTAMP: sqlctype = SQL_C_TYPE_TIMESTAMP; break;
441  default: {
442  SetError(-1, Form("SQL type %d not supported",sqltype), "BindColumn");
443  return kFALSE;
444  }
445  }
446 
447  int elemsize = 0;
448 
449  switch (sqlctype) {
450  case SQL_C_ULONG: elemsize = sizeof(SQLUINTEGER); break;
451  case SQL_C_SLONG: elemsize = sizeof(SQLINTEGER); break;
452  case SQL_C_UBIGINT: elemsize = sizeof(ULong64_t); break; // should be SQLUBIGINT, but it is 64-bit structure on some platforms
453  case SQL_C_SBIGINT: elemsize = sizeof(Long64_t); break; // should be SQLBIGINT, but it is 64-bit structure on some platforms
454  case SQL_C_USHORT: elemsize = sizeof(SQLUSMALLINT); break;
455  case SQL_C_SSHORT: elemsize = sizeof(SQLSMALLINT); break;
456  case SQL_C_UTINYINT: elemsize = sizeof(SQLCHAR); break;
457  case SQL_C_STINYINT: elemsize = sizeof(SQLSCHAR); break;
458  case SQL_C_FLOAT: elemsize = sizeof(SQLREAL); break;
459  case SQL_C_DOUBLE: elemsize = sizeof(SQLDOUBLE); break;
460  case SQL_C_CHAR: elemsize = size; break;
461  case SQL_C_BINARY: elemsize = size; break;
462  case SQL_C_TYPE_DATE: elemsize = sizeof(DATE_STRUCT); break;
463  case SQL_C_TYPE_TIME: elemsize = sizeof(TIME_STRUCT); break;
464  case SQL_C_TYPE_TIMESTAMP: elemsize = sizeof(TIMESTAMP_STRUCT); break;
465 
466  default: {
467  SetError(-1, Form("SQL C Type %d is not supported",sqlctype), "BindColumn");
468  return kFALSE;
469  }
470  }
471 
472  fBuffer[ncol].fBroottype = 0;
473  fBuffer[ncol].fBsqltype = sqltype;
474  fBuffer[ncol].fBsqlctype = sqlctype;
475  fBuffer[ncol].fBbuffer = malloc(elemsize * fBufferLength);
476  fBuffer[ncol].fBelementsize = elemsize;
477  fBuffer[ncol].fBlenarray = new SQLLEN[fBufferLength];
478 
479  SQLRETURN retcode =
480  SQLBindCol(fHstmt, ncol+1, sqlctype, fBuffer[ncol].fBbuffer,
481  elemsize,
482  fBuffer[ncol].fBlenarray);
483 
484  return !ExtractErrors(retcode, "BindColumn");
485 }
486 
487 ////////////////////////////////////////////////////////////////////////////////
488 /// Bind query parameter with buffer. Creates buffer of appropriate type
489 
491 {
492  ClearError();
493 
494  if ((npar<0) || (npar>=fNumBuffers)) return kFALSE;
495 
496  if (fBuffer[npar].fBroottype!=0) {
497  SetError(-1,Form("ParameterType for par %d already specified", npar),"BindParam");
498  return kFALSE;
499  }
500 
501  SQLSMALLINT sqltype = 0, sqlctype = 0;
502  int elemsize = 0;
503 
504  switch (roottype) {
505  case kUInt_t: sqltype = SQL_INTEGER; sqlctype = SQL_C_ULONG; elemsize = sizeof(SQLUINTEGER); break;
506  case kInt_t: sqltype = SQL_INTEGER; sqlctype = SQL_C_SLONG; elemsize = sizeof(SQLINTEGER); break;
507  case kULong_t: sqltype = SQL_INTEGER; sqlctype = SQL_C_ULONG; elemsize = sizeof(SQLUINTEGER); break;
508  case kLong_t: sqltype = SQL_INTEGER; sqlctype = SQL_C_SLONG; elemsize = sizeof(SQLINTEGER); break;
509 
510  // here SQLUBIGINT/SQLBIGINT types should be used,
511  // but on 32-bit platforms it is structures, which makes its usage inconvinient
512  case kULong64_t: sqltype = SQL_BIGINT; sqlctype = SQL_C_UBIGINT; elemsize = sizeof(ULong64_t); break;
513  case kLong64_t: sqltype = SQL_BIGINT; sqlctype = SQL_C_SBIGINT; elemsize = sizeof(Long64_t); break;
514 
515  case kUShort_t: sqltype = SQL_SMALLINT;sqlctype = SQL_C_USHORT; elemsize = sizeof(SQLUSMALLINT); break;
516  case kShort_t: sqltype = SQL_SMALLINT;sqlctype = SQL_C_SSHORT; elemsize = sizeof(SQLSMALLINT); break;
517  case kUChar_t: sqltype = SQL_TINYINT; sqlctype = SQL_C_UTINYINT; elemsize = sizeof(SQLCHAR); break;
518  case kChar_t: sqltype = SQL_TINYINT; sqlctype = SQL_C_STINYINT; elemsize = sizeof(SQLSCHAR); break;
519  case kBool_t: sqltype = SQL_TINYINT; sqlctype = SQL_C_UTINYINT; elemsize = sizeof(SQLCHAR); break;
520  case kFloat_t: sqltype = SQL_FLOAT; sqlctype = SQL_C_FLOAT; elemsize = sizeof(SQLREAL); break;
521  case kFloat16_t: sqltype = SQL_FLOAT; sqlctype = SQL_C_FLOAT; elemsize = sizeof(SQLREAL); break;
522  case kDouble_t: sqltype = SQL_DOUBLE; sqlctype = SQL_C_DOUBLE; elemsize = sizeof(SQLDOUBLE); break;
523  case kDouble32_t: sqltype = SQL_DOUBLE; sqlctype = SQL_C_DOUBLE; elemsize = sizeof(SQLDOUBLE); break;
524  case kCharStar: sqltype = SQL_CHAR; sqlctype = SQL_C_CHAR; elemsize = size; break;
525  case kSqlBinary: sqltype = SQL_BINARY; sqlctype = SQL_C_BINARY; elemsize = size; break;
526  case kSqlDate: sqltype = SQL_TYPE_DATE; sqlctype = SQL_C_TYPE_DATE; elemsize = sizeof(DATE_STRUCT); break;
527  case kSqlTime: sqltype = SQL_TYPE_TIME; sqlctype = SQL_C_TYPE_TIME; elemsize = sizeof(TIME_STRUCT); break;
528  case kSqlTimestamp: sqltype = SQL_TYPE_TIMESTAMP; sqlctype = SQL_C_TYPE_TIMESTAMP; elemsize = sizeof(TIMESTAMP_STRUCT); break;
529  default: {
530  SetError(-1, Form("Root type %d is not supported", roottype), "BindParam");
531  return kFALSE;
532  }
533  }
534 
535  void* buffer = malloc(elemsize * fBufferLength);
536  SQLLEN* lenarray = new SQLLEN[fBufferLength];
537  SQLRETURN retcode =
538  SQLBindParameter(fHstmt, npar+1, SQL_PARAM_INPUT,
539  sqlctype, sqltype, 0, 0,
540  buffer, elemsize, lenarray);
541 
542  if (ExtractErrors(retcode, "BindParam")) {
543  free(buffer);
544  delete[] lenarray;
545  return kFALSE;
546  }
547 
548  fBuffer[npar].fBroottype = roottype;
549  fBuffer[npar].fBsqlctype = sqlctype;
550  fBuffer[npar].fBsqltype = sqltype;
551  fBuffer[npar].fBbuffer = buffer;
552  fBuffer[npar].fBelementsize = elemsize;
553  fBuffer[npar].fBlenarray = lenarray;
554 
555  return kTRUE;
556 }
557 
558 ////////////////////////////////////////////////////////////////////////////////
559 /// Get parameter address
560 
561 void* TODBCStatement::GetParAddr(Int_t npar, Int_t roottype, Int_t length)
562 {
563  ClearError();
564 
565  if ((fBuffer==0) || (npar<0) || (npar>=fNumBuffers) || (fBufferCounter<0)) {
566  SetError(-1, "Invalid parameter number","GetParAddr");
567  return 0;
568  }
569 
570  if (fBuffer[npar].fBbuffer==0) {
571  if (IsParSettMode() && (roottype!=0) && (fBufferCounter==0))
572  if (!BindParam(npar, roottype, length)) return 0;
573 
574  if (fBuffer[npar].fBbuffer==0) return 0;
575  }
576 
577  if (roottype!=0)
578  if (fBuffer[npar].fBroottype!=roottype) return 0;
579 
580  return (char*)fBuffer[npar].fBbuffer + fBufferCounter*fBuffer[npar].fBelementsize;
581 }
582 
583 ////////////////////////////////////////////////////////////////////////////////
584 ///convert to numeric type
585 
587 {
588  void* addr = GetParAddr(npar);
589  if (addr==0) return 0;
590 
591  switch (fBuffer[npar].fBsqlctype) {
592  case SQL_C_ULONG: return *((SQLUINTEGER*) addr); break;
593  case SQL_C_SLONG: return *((SQLINTEGER*) addr); break;
594  case SQL_C_UBIGINT: return *((ULong64_t*) addr); break;
595  case SQL_C_SBIGINT: return *((Long64_t*) addr); break;
596  case SQL_C_USHORT: return *((SQLUSMALLINT*) addr); break;
597  case SQL_C_SSHORT: return *((SQLSMALLINT*) addr); break;
598  case SQL_C_UTINYINT: return *((SQLCHAR*) addr); break;
599  case SQL_C_STINYINT: return *((SQLSCHAR*) addr); break;
600  case SQL_C_FLOAT: return *((SQLREAL*) addr); break;
601  case SQL_C_DOUBLE: return *((SQLDOUBLE*) addr); break;
602  case SQL_C_TYPE_DATE: {
603  DATE_STRUCT* dt = (DATE_STRUCT*) addr;
604  TDatime rtm(dt->year, dt->month, dt->day, 0, 0, 0);
605  return rtm.GetDate();
606  break;
607  }
608  case SQL_C_TYPE_TIME: {
609  TIME_STRUCT* tm = (TIME_STRUCT*) addr;
610  TDatime rtm(2000, 1, 1, tm->hour, tm->minute, tm->second);
611  return rtm.GetTime();
612  break;
613  }
614  case SQL_C_TYPE_TIMESTAMP: {
615  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
616  TDatime rtm(tm->year, tm->month, tm->day,
617  tm->hour, tm->minute, tm->second);
618  return rtm.Get();
619  break;
620  }
621  }
622  return 0;
623 }
624 
625 ////////////////////////////////////////////////////////////////////////////////
626 ///convert to string
627 
629 {
630  void* addr = GetParAddr(npar);
631  if (addr==0) return 0;
632  if (fBuffer[npar].fBstrbuffer==0)
633  fBuffer[npar].fBstrbuffer = new char[100];
634 
635  char* buf = fBuffer[npar].fBstrbuffer;
636 
637  switch(fBuffer[npar].fBsqlctype) {
638 #if (SIZEOF_LONG == 8)
639  case SQL_C_SLONG: snprintf(buf, 100, "%d", *((SQLINTEGER*) addr)); break;
640  case SQL_C_ULONG: snprintf(buf, 100, "%u", *((SQLUINTEGER*) addr)); break;
641 #else
642  case SQL_C_SLONG: snprintf(buf, 100, "%ld", (long)*((SQLINTEGER*) addr)); break;
643  case SQL_C_ULONG: snprintf(buf, 100, "%lu", (unsigned long)*((SQLUINTEGER*) addr)); break;
644 #endif
645  case SQL_C_SBIGINT: snprintf(buf, 100, "%lld", *((Long64_t*) addr)); break;
646  case SQL_C_UBIGINT: snprintf(buf, 100, "%llu", *((ULong64_t*) addr)); break;
647  case SQL_C_SSHORT: snprintf(buf, 100, "%hd", *((SQLSMALLINT*) addr)); break;
648  case SQL_C_USHORT: snprintf(buf, 100, "%hu", *((SQLUSMALLINT*) addr)); break;
649  case SQL_C_STINYINT:snprintf(buf, 100, "%d", *((SQLSCHAR*) addr)); break;
650  case SQL_C_UTINYINT:snprintf(buf, 100, "%u", *((SQLCHAR*) addr)); break;
651  case SQL_C_FLOAT: snprintf(buf, 100, TSQLServer::GetFloatFormat(), *((SQLREAL*) addr)); break;
652  case SQL_C_DOUBLE: snprintf(buf, 100, TSQLServer::GetFloatFormat(), *((SQLDOUBLE*) addr)); break;
653  case SQL_C_TYPE_DATE: {
654  DATE_STRUCT* dt = (DATE_STRUCT*) addr;
655  snprintf(buf,100,"%4.4d-%2.2d-%2.2d",
656  dt->year, dt->month, dt->day);
657  break;
658  }
659  case SQL_C_TYPE_TIME: {
660  TIME_STRUCT* tm = (TIME_STRUCT*) addr;
661  snprintf(buf,100,"%2.2d:%2.2d:%2.2d",
662  tm->hour, tm->minute, tm->second);
663  break;
664  }
665  case SQL_C_TYPE_TIMESTAMP: {
666  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
667  snprintf(buf,100,"%4.4d-%2.2d-%2.2d %2.2d:%2.2d:%2.2d",
668  tm->year, tm->month, tm->day,
669  tm->hour, tm->minute, tm->second);
670  break;
671  }
672  default: return 0;
673  }
674 
675  return buf;
676 }
677 
678 ////////////////////////////////////////////////////////////////////////////////
679 /// Verifies if field value is NULL
680 
682 {
683  void* addr = GetParAddr(npar);
684  if (addr==0) return kTRUE;
685 
686  return fBuffer[npar].fBlenarray[fBufferCounter] == SQL_NULL_DATA;
687 }
688 
689 ////////////////////////////////////////////////////////////////////////////////
690 ///get parameter as integer
691 
693 {
694  void* addr = GetParAddr(npar);
695  if (addr==0) return 0;
696 
697  if (fBuffer[npar].fBsqlctype==SQL_C_SLONG)
698  return (Int_t) *((SQLINTEGER*) addr);
699 
700  return (Int_t) ConvertToNumeric(npar);
701 }
702 
703 ////////////////////////////////////////////////////////////////////////////////
704 ///get parameter as unsigned integer
705 
707 {
708  void* addr = GetParAddr(npar);
709  if (addr==0) return 0;
710 
711  if (fBuffer[npar].fBsqlctype==SQL_C_ULONG)
712  return (UInt_t) *((SQLUINTEGER*) addr);
713 
714  return (UInt_t) ConvertToNumeric(npar);
715 }
716 
717 ////////////////////////////////////////////////////////////////////////////////
718 ///get parameter as Long_t
719 
721 {
722  void* addr = GetParAddr(npar);
723  if (addr==0) return 0;
724 
725  if (fBuffer[npar].fBsqlctype==SQL_C_SLONG)
726  return (Long_t) *((SQLINTEGER*) addr);
727 
728  return (Long_t) ConvertToNumeric(npar);
729 }
730 
731 ////////////////////////////////////////////////////////////////////////////////
732 ///get parameter as Long64_t
733 
735 {
736  void* addr = GetParAddr(npar);
737  if (addr==0) return 0;
738 
739  if (fBuffer[npar].fBsqlctype==SQL_C_SBIGINT)
740  return *((Long64_t*) addr);
741 
742  return (Long64_t) ConvertToNumeric(npar);
743 }
744 
745 ////////////////////////////////////////////////////////////////////////////////
746 ///get parameter as ULong64_t
747 
749 {
750  void* addr = GetParAddr(npar);
751  if (addr==0) return 0;
752 
753  if (fBuffer[npar].fBsqlctype==SQL_C_UBIGINT)
754  return *((ULong64_t*) addr);
755 
756  return (ULong64_t) ConvertToNumeric(npar);
757 }
758 
759 ////////////////////////////////////////////////////////////////////////////////
760 ///get parameter as Double_t
761 
763 {
764  void* addr = GetParAddr(npar);
765  if (addr==0) return 0;
766 
767  if (fBuffer[npar].fBsqlctype==SQL_C_DOUBLE)
768  return *((SQLDOUBLE*) addr);
769 
770  return (Double_t) ConvertToNumeric(npar);
771 }
772 
773 ////////////////////////////////////////////////////////////////////////////////
774 ///get parameter as string
775 
777 {
778  void* addr = GetParAddr(npar);
779  if (addr==0) return 0;
780 
781  if (fBuffer[npar].fBsqlctype==SQL_C_CHAR) {
782  // first check if string is null
783 
784  int len = fBuffer[npar].fBlenarray[fBufferCounter];
785 
786  if ((len == SQL_NULL_DATA) || (len==0)) return 0;
787 
788  char* res = (char*) addr;
789  if (len < fBuffer[npar].fBelementsize) {
790  *(res + len) = 0;
791  return res;
792  }
793 
794  if (len > fBuffer[npar].fBelementsize) {
795  SetError(-1, Form("Problems with string size %d", len), "GetString");
796  return 0;
797  }
798 
799  if (fBuffer[npar].fBstrbuffer==0)
800  fBuffer[npar].fBstrbuffer = new char[len+1];
801 
802  strlcpy(fBuffer[npar].fBstrbuffer, res, len+1);
803 
804  res = fBuffer[npar].fBstrbuffer;
805  *(res + len) = 0;
806  return res;
807  }
808 
809  return ConvertToString(npar);
810 }
811 
812 ////////////////////////////////////////////////////////////////////////////////
813 /// return parameter as binary data
814 
816 {
817  mem = 0;
818  size = 0;
819 
820  void* addr = GetParAddr(npar);
821  if (addr==0) return kFALSE;
822 
823  if ((fBuffer[npar].fBsqlctype==SQL_C_BINARY) ||
824  (fBuffer[npar].fBsqlctype==SQL_C_CHAR)) {
825 
826  // first check if data length is null
827  int len = fBuffer[npar].fBlenarray[fBufferCounter];
828 
829  if ((len == SQL_NULL_DATA) || (len==0)) return kTRUE;
830 
831  size = len;
832 
833  if (fBuffer[npar].fBstrbuffer==0)
834  fBuffer[npar].fBstrbuffer = new char[size];
835 
836  memcpy(fBuffer[npar].fBstrbuffer, addr, size);
837 
838  mem = fBuffer[npar].fBstrbuffer;
839 
840  return kTRUE;
841  }
842 
843  return kFALSE;
844 }
845 
846 
847 ////////////////////////////////////////////////////////////////////////////////
848 /// return field value as date
849 
851 {
852  void* addr = GetParAddr(npar);
853  if (addr==0) return kFALSE;
854 
855  if (fBuffer[npar].fBsqlctype!=SQL_C_TYPE_DATE) return kFALSE;
856 
857  DATE_STRUCT* dt = (DATE_STRUCT*) addr;
858  year = dt->year;
859  month = dt->month;
860  day = dt->day;
861 
862  return kTRUE;
863 }
864 
865 ////////////////////////////////////////////////////////////////////////////////
866 /// return field value as time
867 
869 {
870  void* addr = GetParAddr(npar);
871  if (addr==0) return kFALSE;
872 
873  if (fBuffer[npar].fBsqlctype!=SQL_C_TYPE_TIME) return kFALSE;
874 
875  TIME_STRUCT* tm = (TIME_STRUCT*) addr;
876  hour = tm->hour;
877  min = tm->minute;
878  sec = tm->second;
879 
880  return kTRUE;
881 }
882 
883 ////////////////////////////////////////////////////////////////////////////////
884 /// return field value as date & time
885 
886 Bool_t TODBCStatement::GetDatime(Int_t npar, Int_t& year, Int_t& month, Int_t& day, Int_t& hour, Int_t& min, Int_t& sec)
887 {
888  void* addr = GetParAddr(npar);
889  if (addr==0) return kFALSE;
890 
891  if (fBuffer[npar].fBsqlctype!=SQL_C_TYPE_TIMESTAMP) return kFALSE;
892 
893  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
894 
895  year = tm->year;
896  month = tm->month;
897  day = tm->day;
898  hour = tm->hour;
899  min = tm->minute;
900  sec = tm->second;
901  return kTRUE;
902 }
903 
904 ////////////////////////////////////////////////////////////////////////////////
905 /// return field value as time stamp
906 
907 Bool_t TODBCStatement::GetTimestamp(Int_t npar, Int_t& year, Int_t& month, Int_t& day, Int_t& hour, Int_t& min, Int_t& sec, Int_t& frac)
908 {
909  void* addr = GetParAddr(npar);
910  if (addr==0) return kFALSE;
911 
912  if (fBuffer[npar].fBsqlctype!=SQL_C_TYPE_TIMESTAMP) return kFALSE;
913 
914  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
915 
916  year = tm->year;
917  month = tm->month;
918  day = tm->day;
919  hour = tm->hour;
920  min = tm->minute;
921  sec = tm->second;
922  frac = tm->fraction;
923  return kTRUE;
924 }
925 
926 
927 ////////////////////////////////////////////////////////////////////////////////
928 /// Set NULL as parameter value
929 /// If NULL should be set for statement parameter during first iteration,
930 /// one should call before proper Set... method to identify type of argument for
931 /// the future. For instance, if one suppose to have double as type of parameter,
932 /// code should look like:
933 /// stmt->SetDouble(2, 0.);
934 /// stmt->SetNull(2);
935 
937 {
938  void* addr = GetParAddr(npar, kInt_t);
939  if (addr!=0)
940  *((SQLINTEGER*) addr) = 0;
941 
942  if ((npar>=0) && (npar<fNumBuffers))
943  fBuffer[npar].fBlenarray[fBufferCounter] = SQL_NULL_DATA;
944 
945  return kTRUE;
946 }
947 
948 ////////////////////////////////////////////////////////////////////////////////
949 ///set parameter as Int_t
950 
952 {
953  void* addr = GetParAddr(npar, kInt_t);
954  if (addr==0) return kFALSE;
955 
956  *((SQLINTEGER*) addr) = value;
957 
958  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
959 
960  return kTRUE;
961 }
962 
963 ////////////////////////////////////////////////////////////////////////////////
964 ///set parameter as UInt_t
965 
967 {
968  void* addr = GetParAddr(npar, kUInt_t);
969  if (addr==0) return kFALSE;
970 
971  *((SQLUINTEGER*) addr) = value;
972 
973  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
974 
975  return kTRUE;
976 }
977 
978 ////////////////////////////////////////////////////////////////////////////////
979 ///set parameter as Long_t
980 
982 {
983  void* addr = GetParAddr(npar, kLong_t);
984  if (addr==0) return kFALSE;
985 
986  *((SQLINTEGER*) addr) = value;
987 
988  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
989 
990  return kTRUE;
991 }
992 
993 ////////////////////////////////////////////////////////////////////////////////
994 ///set parameter as Long64_t
995 
997 {
998  void* addr = GetParAddr(npar, kLong64_t);
999  if (addr==0) return kFALSE;
1000 
1001  *((Long64_t*) addr) = value;
1002 
1003  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1004 
1005  return kTRUE;
1006 }
1007 
1008 ////////////////////////////////////////////////////////////////////////////////
1009 ///set parameter as ULong64_t
1010 
1012 {
1013  void* addr = GetParAddr(npar, kULong64_t);
1014  if (addr==0) return kFALSE;
1015 
1016  *((ULong64_t*) addr) = value;
1017 
1018  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1019 
1020  return kTRUE;
1021 }
1022 
1023 ////////////////////////////////////////////////////////////////////////////////
1024 ///set parameter as Double_t
1025 
1027 {
1028  void* addr = GetParAddr(npar, kDouble_t);
1029  if (addr==0) return kFALSE;
1030 
1031  *((SQLDOUBLE*) addr) = value;
1032 
1033  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1034 
1035  return kTRUE;
1036 }
1037 
1038 ////////////////////////////////////////////////////////////////////////////////
1039 ///set parameter as string
1040 
1042 {
1043  void* addr = GetParAddr(npar, kCharStar, maxsize);
1044 
1045  if (addr==0) return kFALSE;
1046 
1047  if (value) {
1048  int len = strlen(value);
1049 
1050  if (len>=fBuffer[npar].fBelementsize) {
1051  len = fBuffer[npar].fBelementsize;
1052  strlcpy((char*) addr, value, len+1);
1053  fBuffer[npar].fBlenarray[fBufferCounter] = len;
1054 
1055  } else if (len>0) {
1056  strlcpy((char*) addr, value, maxsize);
1057  fBuffer[npar].fBlenarray[fBufferCounter] = SQL_NTS;
1058  } else {
1059  *((char*) addr) = 0;
1060  fBuffer[npar].fBlenarray[fBufferCounter] = SQL_NTS;
1061  }
1062  } else {
1063  *((char*) addr) = 0;
1064  fBuffer[npar].fBlenarray[fBufferCounter] = SQL_NTS;
1065  }
1066 
1067  return kTRUE;
1068 }
1069 
1070 ////////////////////////////////////////////////////////////////////////////////
1071 ///set parameter value as binary data
1072 
1074 {
1075  void* addr = GetParAddr(npar, kSqlBinary, maxsize);
1076  if (addr==0) return kFALSE;
1077 
1078  if (size>fBuffer[npar].fBelementsize)
1079  size = fBuffer[npar].fBelementsize;
1080 
1081  memcpy(addr, mem, size);
1082  fBuffer[npar].fBlenarray[fBufferCounter] = size;
1083 
1084  return kTRUE;
1085 }
1086 
1087 ////////////////////////////////////////////////////////////////////////////////
1088 /// set parameter value as date
1089 
1091 {
1092  void* addr = GetParAddr(npar, kSqlDate);
1093  if (addr==0) return kFALSE;
1094 
1095  DATE_STRUCT* dt = (DATE_STRUCT*) addr;
1096  dt->year = year;
1097  dt->month = month;
1098  dt->day = day;
1099 
1100  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1101 
1102  return kTRUE;
1103 }
1104 
1105 ////////////////////////////////////////////////////////////////////////////////
1106 /// set parameter value as time
1107 
1109 {
1110  void* addr = GetParAddr(npar, kSqlTime);
1111  if (addr==0) return kFALSE;
1112 
1113  TIME_STRUCT* tm = (TIME_STRUCT*) addr;
1114  tm->hour = hour;
1115  tm->minute = min;
1116  tm->second = sec;
1117 
1118  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1119 
1120  return kTRUE;
1121 }
1122 
1123 ////////////////////////////////////////////////////////////////////////////////
1124 /// set parameter value as date & time
1125 
1126 Bool_t TODBCStatement::SetDatime(Int_t npar, Int_t year, Int_t month, Int_t day, Int_t hour, Int_t min, Int_t sec)
1127 {
1128  void* addr = GetParAddr(npar, kSqlTimestamp);
1129  if (addr==0) return kFALSE;
1130 
1131  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
1132  tm->year = year;
1133  tm->month = month;
1134  tm->day = day;
1135  tm->hour = hour;
1136  tm->minute = min;
1137  tm->second = sec;
1138  tm->fraction = 0;
1139 
1140  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1141 
1142  return kTRUE;
1143 }
1144 
1145 ////////////////////////////////////////////////////////////////////////////////
1146 /// set parameter value as timestamp
1147 
1148 Bool_t TODBCStatement::SetTimestamp(Int_t npar, Int_t year, Int_t month, Int_t day, Int_t hour, Int_t min, Int_t sec, Int_t frac)
1149 {
1150  void* addr = GetParAddr(npar, kSqlTimestamp);
1151  if (addr==0) return kFALSE;
1152 
1153  TIMESTAMP_STRUCT* tm = (TIMESTAMP_STRUCT*) addr;
1154  tm->year = year;
1155  tm->month = month;
1156  tm->day = day;
1157  tm->hour = hour;
1158  tm->minute = min;
1159  tm->second = sec;
1160  tm->fraction = frac;
1161 
1162  fBuffer[npar].fBlenarray[fBufferCounter] = 0;
1163 
1164  return kTRUE;
1165 }
virtual const char * GetFieldName(Int_t nfield)
return field name
SQLUINTEGER fNumRowsFetched
Int_t fBufferPreferredSize
virtual Bool_t GetDatime(Int_t npar, Int_t &year, Int_t &month, Int_t &day, Int_t &hour, Int_t &min, Int_t &sec)
return field value as date & time
virtual void Info(const char *method, const char *msgfmt,...) const
Issue info message.
Definition: TObject.cxx:899
long long Long64_t
Definition: RtypesCore.h:69
virtual const char * GetString(Int_t npar)
get parameter as string
const char Option_t
Definition: RtypesCore.h:62
virtual Bool_t NextResultRow()
next result row
void ClearError()
reset error fields
void SetError(Int_t code, const char *msg, const char *method=0)
set new values for error fields if method specified, displays error message
virtual Bool_t SetTimestamp(Int_t npar, Int_t year, Int_t month, Int_t day, Int_t hour, Int_t min, Int_t sec, Int_t frac=0)
set parameter value as timestamp
virtual Bool_t GetDate(Int_t npar, Int_t &year, Int_t &month, Int_t &day)
return field value as date
virtual Bool_t SetInt(Int_t npar, Int_t value)
set parameter as Int_t
virtual Bool_t SetDate(Int_t npar, Int_t year, Int_t month, Int_t day)
set parameter value as date
int Int_t
Definition: RtypesCore.h:41
bool Bool_t
Definition: RtypesCore.h:59
virtual UInt_t GetUInt(Int_t npar)
get parameter as unsigned integer
const Bool_t kFALSE
Definition: Rtypes.h:92
virtual Bool_t SetTime(Int_t npar, Int_t hour, Int_t min, Int_t sec)
set parameter value as time
#define malloc
Definition: civetweb.c:818
static const char * GetFloatFormat()
return current printf format for float/double members, default "%e"
Definition: TSQLServer.cxx:269
Int_t GetDate() const
Return date in form of 19971224 (i.e. 24/12/1997)
Definition: TDatime.cxx:247
virtual Bool_t SetLong(Int_t npar, Long_t value)
set parameter as Long_t
virtual Int_t GetInt(Int_t npar)
get parameter as integer
virtual ~TODBCStatement()
destructor
const int maxsize
Bool_t BindParam(Int_t n, Int_t type, Int_t size=1024)
Bind query parameter with buffer. Creates buffer of appropriate type.
virtual Int_t GetNumAffectedRows()
get number of affected rows
Bool_t ExtractErrors(SQLRETURN retcode, const char *method)
Extract errors, produced by last ODBC function call.
void * GetParAddr(Int_t npar, Int_t roottype=0, Int_t length=0)
Get parameter address.
virtual Double_t GetDouble(Int_t npar)
get parameter as Double_t
const char * ConvertToString(Int_t npar)
convert to string
virtual Bool_t SetString(Int_t npar, const char *value, Int_t maxsize=256)
set parameter as string
Bool_t BindColumn(Int_t ncol, SQLSMALLINT sqltype, SQLUINTEGER size)
Bind result column to buffer. Allocate buffer of appropriate type.
Bool_t IsParSettMode() const
long double ConvertToNumeric(Int_t npar)
convert to numeric type
virtual Bool_t Process()
process statement
UInt_t Get() const
Return raw date/time as encoded by TDatime.
Definition: TDatime.cxx:239
ODBCBufferRec_t * fBuffer
unsigned int UInt_t
Definition: RtypesCore.h:42
char * Form(const char *fmt,...)
virtual Bool_t IsError() const
virtual Int_t GetNumParameters()
return number of parameters
virtual Bool_t SetLong64(Int_t npar, Long64_t value)
set parameter as Long64_t
Int_t GetTime() const
Return time in form of 123623 (i.e. 12:36:23)
Definition: TDatime.cxx:258
virtual ULong64_t GetULong64(Int_t npar)
get parameter as ULong64_t
virtual Bool_t GetTimestamp(Int_t npar, Int_t &year, Int_t &month, Int_t &day, Int_t &hour, Int_t &min, Int_t &sec, Int_t &)
return field value as time stamp
long Long_t
Definition: RtypesCore.h:50
#define kSqlBinary
#define ClassImp(name)
Definition: Rtypes.h:279
virtual Bool_t IsNull(Int_t)
Verifies if field value is NULL.
Bool_t IsResultSet() const
double Double_t
Definition: RtypesCore.h:55
TText * text
unsigned long long ULong64_t
Definition: RtypesCore.h:70
#define free
Definition: civetweb.c:821
virtual Bool_t SetNull(Int_t npar)
Set NULL as parameter value If NULL should be set for statement parameter during first iteration...
virtual Bool_t GetBinary(Int_t npar, void *&mem, Long_t &size)
return parameter as binary data
virtual Bool_t GetTime(Int_t npar, Int_t &hour, Int_t &min, Int_t &sec)
return field value as time
virtual Bool_t SetDouble(Int_t npar, Double_t value)
set parameter as Double_t
void FreeBuffers()
Free allocated buffers.
ULong64_t fLastResultRow
virtual Bool_t SetBinary(Int_t npar, void *mem, Long_t size, Long_t maxsize=0x1000)
set parameter value as binary data
#define kSqlTimestamp
#define kSqlDate
virtual Bool_t SetULong64(Int_t npar, ULong64_t value)
set parameter as ULong64_t
virtual Long64_t GetLong64(Int_t npar)
get parameter as Long64_t
#define snprintf
Definition: civetweb.c:822
virtual void Close(Option_t *="")
Close statement.
virtual Bool_t SetUInt(Int_t npar, UInt_t value)
set parameter as UInt_t
SQLUSMALLINT * fStatusBuffer
const Bool_t kTRUE
Definition: Rtypes.h:91
virtual Bool_t SetDatime(Int_t npar, Int_t year, Int_t month, Int_t day, Int_t hour, Int_t min, Int_t sec)
set parameter value as date & time
void SetNumBuffers(Int_t isize, Int_t ilen)
set number of buffers
const Int_t n
Definition: legend1.C:16
#define kSqlTime
This class stores the date and time with a precision of one second in an unsigned 32 bit word (950130...
Definition: TDatime.h:39
virtual Bool_t NextIteration()
run next iteration
virtual Int_t GetNumFields()
return number of fields
virtual Bool_t StoreResult()
Store result of statement processing.
virtual Long_t GetLong(Int_t npar)
get parameter as Long_t