Microsoft KB Archive/244477

= How to Determine Max String Size in COMTI at Runtime =

Article ID: 244477

Article Last Modified on 2/22/2007

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APPLIES TO


 * Microsoft SNA Server 4.0
 * Microsoft SNA Server 4.0 Service Pack 1
 * Microsoft SNA Server 4.0 Service Pack 2
 * Microsoft SNA Server 4.0 Service Pack 3
 * Microsoft COM Transaction Integrator for CICS and IMS 1.0 SP1
 * Microsoft COM Transaction Integrator for CICS and IMS 4.0 SP2
 * Microsoft COM Transaction Integrator for CICS and IMS 4.0 SP3
 * Microsoft Host Integration Server 2000 Standard Edition

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This article was previously published under Q244477



SUMMARY
When communicating with mainframe applications, COM Transaction Integrator for CICS and IMS (COMTI) runtime transforms UNICODE strings that are received as parameters, fields, or columns into mainframe character strings. Likewise, when receiving data from a mainframe transaction program, the COMTI runtime converts mainframe character strings into UNICODE strings that are returned as output values to the calling client application. COMTI runtime determines which type of mainframe character string is being used based on how the parameter, field, or column is defined in Component Builder, and which code page is defined for the remote environment describing the mainframe environment.

In most situations, the developer who is providing the user interface to the COMTI component is familiar with the maximum field size associated with a given string value, and can provide the appropriate string validation to accommodate this. For example, with a COBOL data type of PIC X (100), the user interface limits the end user input to 100 characters. However, under rare conditions, the developer may want to determine the length of a particular string value at runtime. There are no built-in (intrinsic) mechanisms in COMTI to allow for this to be easily accomplished. However, if this functionality is essential, one can determine the string size by querying a custom property associated with the COMTI Type Library describing the component.

This article provides an Active Template Library (ATL) EXE sample (Readtlb.cpp) that demonstrates how to query the COMTI custom property associated with the maximum string size. It is beyond the scope of this article to discuss the various COM interfaces used however. For details concerning programmatic interfaces and methods supported for Type Library manipulation, please see the Microsoft Platform SDK.



MORE INFORMATION
The bulk of work performed in the ReadTLB program is handled by the ReadTLB function. Essentially, the function receives the name of the type library as input and proceeds to enumerate the various type descriptions associated with the library. A loop is constructed to search for the dispinterface. When this is found, another loop is constructed to parse through the various methods that are supported by the interface. The structure FUNCDESC is constructed for each method and provides relevant information concerning the parameters and return values for the method. Ultimately, the ITypeInfo2::GetParamCustData is called to retrieve the custom properties. When the custom properties have been determined, a comparison is performed to make sure we have the correct one (GUID CEDAR_MAXSTRSIZE_GUID). The LONG value, lMaxSize (by default), is set to 80. If a value has been predetermined using Component Builder (CB), the lMaxSize value is set to the specified value. The following code fragment shows where this occurs:

... if (VT_EMPTY != V_VT(&varProp)) {   varProp.ChangeType(VT_I4); lMaxSize = V_I4(&varProp); //assign lMaxSize the custom property value ... ...

Further details have been provided as remark statements within the code for handling string values associated with Recordsets.

// ReadTLB.cpp : Implementation of WinMain


 * 1) include "stdafx.h"
 * 2) include "resource.h"
 * 3) include 
 * 4) include "ReadTLB.h"
 * 5) include "comdef.h"
 * 6) include "ReadTLB_i.c"

const DWORD dwTimeOut = 5000; // time for EXE to be idle before shutting down const DWORD dwPause = 1000; // time to wait for threads to finish up

// Passed to CreateThread to monitor the shutdown event static DWORD WINAPI MonitorProc(void* pv) {   CExeModule* p = (CExeModule*)pv; p->MonitorShutdown; return 0; }

LONG CExeModule::Unlock {   LONG l = CComModule::Unlock; if (l == 0) {       bActivity = true; SetEvent(hEventShutdown); // tell monitor that we transitioned to zero }   return l; }

//Monitors the shutdown event void CExeModule::MonitorShutdown {   while (1) {       WaitForSingleObject(hEventShutdown, INFINITE); DWORD dwWait=0; do       { bActivity = false; dwWait = WaitForSingleObject(hEventShutdown, dwTimeOut); } while (dwWait == WAIT_OBJECT_0); // timed out if (!bActivity && m_nLockCnt == 0) // if no activity let's really bail {           CoSuspendClassObjects; if (!bActivity && m_nLockCnt == 0) break; }   }    CloseHandle(hEventShutdown); PostThreadMessage(dwThreadID, WM_QUIT, 0, 0); }
 * 1) if _WIN32_WINNT >= 0x0400 & defined(_ATL_FREE_THREADED)
 * 1) endif

bool CExeModule::StartMonitor {   hEventShutdown = CreateEvent(NULL, false, false, NULL); if (hEventShutdown == NULL) return false; DWORD dwThreadID; HANDLE h = CreateThread(NULL, 0, MonitorProc, this, 0, &dwThreadID); return (h != NULL); }

CExeModule _Module;

BEGIN_OBJECT_MAP(ObjectMap) END_OBJECT_MAP

LPCTSTR FindOneOf(LPCTSTR p1, LPCTSTR p2) {   while (p1 != NULL && *p1 != NULL) {       LPCTSTR p = p2; while (p != NULL && *p != NULL) {           if (*p1 == *p) return CharNext(p1); p = CharNext(p); }       p1 = CharNext(p1); }   return NULL; }

void TypeDescToDWord(TYPEDESC *ptdescSrc, VARTYPE *pvt, BOOL fIsRval) {   *pvt = 0; switch (ptdescSrc->vt) {       case VT_I2: case VT_I4: case VT_R4: case VT_R8: case VT_CY: case VT_BOOL: case VT_BSTR: case VT_DATE: case VT_UI1: case VT_DISPATCH: case VT_USERDEFINED: case VT_VARIANT: case VT_VOID: // Elemental types signal end of type description (*pvt)|=ptdescSrc->vt; break;

case VT_PTR: // Pointers are byref (skip byref on return value) then recurse if (!fIsRval) (*pvt)|=VT_BYREF; TypeDescToDWord(ptdescSrc->lptdesc, pvt, FALSE); break;

case VT_SAFEARRAY: // Arrays (safearray) get array attribute then recurse (*pvt)|=VT_ARRAY; TypeDescToDWord(ptdescSrc->lptdesc, pvt, FALSE); break;

default: _ASSERT(0); break; } }

void ReadTLB(LPCTSTR lpszTLBFile) {   USES_CONVERSION; HRESULT hr; CComPtr pITypeLib; const GUID CEDAR_MAXSTRSIZE_GUID = { 0x07257f20,0xfb76,0x11cf,{0xb9,0x49,0x00,0xa0,0xc9,0x03,0x48,0x17} };

try {       // Load the typelib

hr = LoadTypeLib(T2W(lpszTLBFile), &pITypeLib); if (FAILED(hr)) _com_issue_error(hr);

// Look thru all type info's to find the dispinterface. If looking // for recordset columns then look for TKIND_RECORD.

UINT cTypeInfos = pITypeLib->GetTypeInfoCount; for (UINT ui=0;ui pITypeInfo; hr = pITypeLib->GetTypeInfo(ui, &pITypeInfo); if (FAILED(hr)) _com_issue_error(hr);

TYPEATTR *pTA; hr = pITypeInfo->GetTypeAttr(&pTA); if (FAILED(hr)) _com_issue_error(hr);

// Find the dispinterface information in the typelib (look for           // TKIND_RECORD to find structs that describe Recordsets)

if (TKIND_DISPATCH != pTA->typekind) {               pITypeInfo->ReleaseTypeAttr(pTA); continue; }           // QI for the ITypeInfo2 interface to get custom properties

CComPtr pITypeInfo2; pITypeInfo->QueryInterface(IID_ITypeInfo2              , reinterpret_cast(&pITypeInfo2)); _ASSERT(pITypeInfo2);

_variant_t varProp; long lMaxSize; VARTYPE vt;

USHORT cFuncs = pTA->cFuncs; for (USHORT usFunc=0;usFuncGetFuncDesc(usFunc, &pFD); if (FAILED(hr)) _com_issue_error(hr);

// GetDocumentation will return the function name

CComBSTR bstrFuncName; hr = pITypeInfo->GetDocumentation(pFD->memid, &bstrFuncName                  , 0, 0, 0); if (FAILED(hr)) _com_issue_error(hr);

// You could skip IUnknown and IDispatch methods here // as well as the COMTI-supplied properties.

// See if the return value is a string (if looking               // at TKIND_RECORD look at elemdescVar.tdesc.vt in                // the VARDESC struct)

TypeDescToDWord(&pFD->elemdescFunc.tdesc, &vt, true); if (VT_BSTR == vt) {                   // Get the custom property for max string size (if                    // looking at TKIND_RECORD use GetVarCustData)

hr = pITypeInfo2->GetFuncCustData(                        usFunc                       , CEDAR_MAXSTRSIZE_GUID                        , &varProp); if (FAILED(hr)) _com_issue_error(hr);

// if the custom property exists then that's the max // string size else the default is 80

lMaxSize = 80; if (VT_EMPTY != V_VT(&varProp)) {                       varProp.ChangeType(VT_I4); lMaxSize = V_I4(&varProp); }               }

// Check if any parameters are string (if looking at               // TKIND_RECORD you won't have this code)

short cParams = pFD->cParams; for (short sParm=0;sParmlprgelemdescParam[sParm].tdesc, &vt, false); if (VT_BSTR == vt) {                       hr = pITypeInfo2->GetParamCustData(                             usFunc                           , sParm                            , CEDAR_MAXSTRSIZE_GUID                            , &varProp); if (FAILED(hr)) _com_issue_error(hr);

// if the custom property exists then that's the // max string size else the default is 80

lMaxSize = 80; if (VT_EMPTY != V_VT(&varProp)) {                           varProp.ChangeType(VT_I4); lMaxSize = V_I4(&varProp); }                   }                }                pITypeInfo->ReleaseFuncDesc(pFD); }           pITypeInfo->ReleaseTypeAttr(pTA); }       return; }   catch (_com_error &e) {       // report error return; } }

///////////////////////////////////////////////////////////////////////////// // extern "C" int WINAPI _tWinMain(HINSTANCE hInstance,    HINSTANCE /*hPrevInstance*/, LPTSTR lpCmdLine, int /*nShowCmd*/) {   lpCmdLine = GetCommandLine; //this line necessary for _ATL_MIN_CRT

HRESULT hRes = CoInitializeEx(NULL, COINIT_MULTITHREADED); HRESULT hRes = CoInitialize(NULL); _ASSERTE(SUCCEEDED(hRes)); _Module.Init(ObjectMap, hInstance, &LIBID_READTLBLib); _Module.dwThreadID = GetCurrentThreadId; TCHAR szTokens[] = _T("-/");
 * 1) if _WIN32_WINNT >= 0x0400 & defined(_ATL_FREE_THREADED)
 * 1) else
 * 1) endif

int nRet = 0; BOOL bRun = TRUE; LPCTSTR lpszToken = FindOneOf(lpCmdLine, szTokens); while (lpszToken != NULL) {       if (lstrcmpi(lpszToken, _T("UnregServer"))==0) {           _Module.UpdateRegistryFromResource(IDR_Readtlb, FALSE); nRet = _Module.UnregisterServer(TRUE); bRun = FALSE; break; }       if (lstrcmpi(lpszToken, _T("RegServer"))==0) {           _Module.UpdateRegistryFromResource(IDR_Readtlb, TRUE); nRet = _Module.RegisterServer(TRUE); bRun = FALSE; break; }

ReadTLB(lpszToken);

lpszToken = FindOneOf(lpszToken, szTokens); }

if (bRun) {       _Module.StartMonitor; hRes = _Module.RegisterClassObjects(CLSCTX_LOCAL_SERVER,            REGCLS_MULTIPLEUSE | REGCLS_SUSPENDED); _ASSERTE(SUCCEEDED(hRes)); hRes = CoResumeClassObjects; hRes = _Module.RegisterClassObjects(CLSCTX_LOCAL_SERVER,            REGCLS_MULTIPLEUSE); _ASSERTE(SUCCEEDED(hRes));
 * 1) if _WIN32_WINNT >= 0x0400 & defined(_ATL_FREE_THREADED)
 * 1) else
 * 1) endif

_Module.RevokeClassObjects; Sleep(dwPause); //wait for any threads to finish }

_Module.Term; CoUninitialize; return nRet; }

Additional query words: HIS 2000

Keywords: KB244477

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