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-rw-r--r--registry/tools/regcompare.cxx2399
1 files changed, 2399 insertions, 0 deletions
diff --git a/registry/tools/regcompare.cxx b/registry/tools/regcompare.cxx
new file mode 100644
index 000000000000..4e95d884de30
--- /dev/null
+++ b/registry/tools/regcompare.cxx
@@ -0,0 +1,2399 @@
+/*************************************************************************
+ *
+ * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
+ *
+ * Copyright 2000, 2010 Oracle and/or its affiliates.
+ *
+ * OpenOffice.org - a multi-platform office productivity suite
+ *
+ * This file is part of OpenOffice.org.
+ *
+ * OpenOffice.org is free software: you can redistribute it and/or modify
+ * it under the terms of the GNU Lesser General Public License version 3
+ * only, as published by the Free Software Foundation.
+ *
+ * OpenOffice.org is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ * GNU Lesser General Public License version 3 for more details
+ * (a copy is included in the LICENSE file that accompanied this code).
+ *
+ * You should have received a copy of the GNU Lesser General Public License
+ * version 3 along with OpenOffice.org. If not, see
+ * <http://www.openoffice.org/license.html>
+ * for a copy of the LGPLv3 License.
+ *
+ ************************************************************************/
+
+// MARKER(update_precomp.py): autogen include statement, do not remove
+#include "precompiled_registry.hxx"
+
+#include <stdio.h>
+#include <string.h>
+
+#include <set>
+#include <vector>
+#include "registry/registry.hxx"
+#include "registry/reader.hxx"
+#include "registry/version.h"
+#include <rtl/ustring.hxx>
+#include <rtl/alloc.h>
+#include <osl/process.h>
+#include <osl/diagnose.h>
+#include <osl/thread.h>
+#include <osl/file.hxx>
+
+#ifdef SAL_UNX
+#define SEPARATOR '/'
+#else
+#define SEPARATOR '\\'
+#endif
+
+using namespace ::rtl;
+using namespace ::osl;
+
+OUString shortName(const OUString& fullName)
+{
+ return fullName.copy(fullName.lastIndexOf('/') + 1);
+}
+
+sal_Bool isFileUrl(const OString& fileName)
+{
+ if (fileName.indexOf("file://") == 0 )
+ return sal_True;
+ return sal_False;
+}
+
+OUString convertToFileUrl(const OString& fileName)
+{
+ if ( isFileUrl(fileName) )
+ {
+ return OStringToOUString(fileName, osl_getThreadTextEncoding());
+ }
+
+ OUString uUrlFileName;
+ OUString uFileName(fileName.getStr(), fileName.getLength(), osl_getThreadTextEncoding());
+ if ( fileName.indexOf('.') == 0 || fileName.indexOf(SEPARATOR) < 0 )
+ {
+ OUString uWorkingDir;
+ if (osl_getProcessWorkingDir(&uWorkingDir.pData) != osl_Process_E_None)
+ {
+ OSL_ASSERT(false);
+ }
+ if (FileBase::getAbsoluteFileURL(uWorkingDir, uFileName, uUrlFileName)
+ != FileBase::E_None)
+ {
+ OSL_ASSERT(false);
+ }
+ } else
+ {
+ if (FileBase::getFileURLFromSystemPath(uFileName, uUrlFileName)
+ != FileBase::E_None)
+ {
+ OSL_ASSERT(false);
+ }
+ }
+
+ return uUrlFileName;
+}
+
+#define U2S( s ) \
+ OUStringToOString(s, RTL_TEXTENCODING_UTF8).getStr()
+#define S2U( s ) \
+ OStringToOUString(s, RTL_TEXTENCODING_UTF8)
+
+struct LessString
+{
+ sal_Bool operator()(const OUString& str1, const OUString& str2) const
+ {
+ return (str1 < str2);
+ }
+};
+
+typedef ::std::set< OUString > StringSet;
+
+class Options
+{
+public:
+ Options()
+ : m_bFullCheck(sal_False)
+ , m_bForceOutput(sal_False)
+ , m_bUnoTypeCheck(sal_False)
+ , m_checkUnpublished(false)
+ {}
+ ~Options()
+ {}
+
+ sal_Bool initOptions(int ac, char* av[], sal_Bool bCmdFile=sal_False);
+
+ OString prepareHelp();
+ OString prepareVersion();
+
+ const OString& getProgramName()
+ { return m_program; }
+ const OString& getRegName1()
+ { return m_regName1; }
+ const OString& getRegName2()
+ { return m_regName2; }
+ sal_Bool isStartKeyValid()
+ { return (m_startKey.getLength() > 0); };
+ const OString& getStartKey()
+ { return m_startKey; }
+ sal_Bool existsExcludeKeys()
+ { return !m_excludeKeys.empty(); };
+ StringSet& getExcludeKeys()
+ { return m_excludeKeys; }
+ sal_Bool matchedWithExcludeKey( const OUString& keyName);
+ sal_Bool fullCheck()
+ { return m_bFullCheck; }
+ sal_Bool forceOutput()
+ { return m_bForceOutput; }
+ sal_Bool unoTypeCheck()
+ { return m_bUnoTypeCheck; }
+ bool checkUnpublished() const { return m_checkUnpublished; }
+protected:
+ OString m_program;
+ OString m_regName1;
+ OString m_regName2;
+ OString m_startKey;
+ StringSet m_excludeKeys;
+ sal_Bool m_bFullCheck;
+ sal_Bool m_bForceOutput;
+ sal_Bool m_bUnoTypeCheck;
+ bool m_checkUnpublished;
+};
+
+sal_Bool Options::initOptions(int ac, char* av[], sal_Bool bCmdFile)
+{
+ sal_Bool bRet = sal_True;
+ sal_uInt16 i=0;
+
+ if (!bCmdFile)
+ {
+ bCmdFile = sal_True;
+
+ m_program = av[0];
+
+ if (ac < 2)
+ {
+ fprintf(stdout, "%s", prepareHelp().getStr());
+ bRet = sal_False;
+ }
+
+ i = 1;
+ } else
+ {
+ i = 0;
+ }
+
+ char *s=NULL;
+ for (; i < ac; i++)
+ {
+ if (av[i][0] == '-')
+ {
+ switch (av[i][1])
+ {
+ case 'r':
+ case 'R':
+ {
+ sal_Bool bFirst = sal_True;
+ if (av[i][2] == '2')
+ {
+ bFirst = sal_False;
+ } else if (av[i][2] != '1')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ }
+ if (av[i][3] == '\0')
+ {
+ if (i < ac - 1 && av[i+1][0] != '-')
+ {
+ i++;
+ s = av[i];
+ } else
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ break;
+ }
+ } else
+ {
+ s = av[i] + 2;
+ }
+
+ if ( bFirst )
+ {
+ m_regName1 = OString(s);
+ } else
+ {
+ m_regName2 = OString(s);
+ }
+ }
+ break;
+ case 's':
+ case 'S':
+ if (av[i][2] == '\0')
+ {
+ if (i < ac - 1 && av[i+1][0] != '-')
+ {
+ i++;
+ s = av[i];
+ } else
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ break;
+ }
+ } else
+ {
+ s = av[i] + 2;
+ }
+ m_startKey = OString(s);
+ break;
+ case 'x':
+ case 'X':
+ if (av[i][2] == '\0')
+ {
+ if (i < ac - 1 && av[i+1][0] != '-')
+ {
+ i++;
+ s = av[i];
+ } else
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ break;
+ }
+ } else
+ {
+ s = av[i] + 2;
+ }
+ m_excludeKeys.insert(S2U(s));
+ break;
+ case 'c':
+ case 'C':
+ if (av[i][2] != '\0')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ }
+ m_bFullCheck = sal_True;
+ break;
+ case 'f':
+ case 'F':
+ if (av[i][2] != '\0')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ }
+ m_bForceOutput = sal_True;
+ break;
+ case 't':
+ case 'T':
+ if (av[i][2] != '\0')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ }
+ m_bUnoTypeCheck = sal_True;
+ break;
+ case 'u':
+ case 'U':
+ if (av[i][2] != '\0')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ }
+ m_checkUnpublished = true;
+ break;
+ case 'h':
+ case '?':
+ if (av[i][2] != '\0')
+ {
+ fprintf(stdout, "%s: invalid option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ } else
+ {
+ fprintf(stdout, "%s", prepareHelp().getStr());
+ exit(0);
+ }
+ break;
+ default:
+ fprintf(stdout, "%s: unknown option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ break;
+ }
+ } else
+ {
+ if (av[i][0] == '@')
+ {
+ FILE* cmdFile = fopen(av[i]+1, "r");
+ if( cmdFile == NULL )
+ {
+ fprintf(stdout, "%s", prepareHelp().getStr());
+ bRet = sal_False;
+ } else
+ {
+ int rargc=0;
+ char* rargv[512];
+ char buffer[512];
+
+ while ( fscanf(cmdFile, "%s", buffer) != EOF )
+ {
+ rargv[rargc]= strdup(buffer);
+ rargc++;
+ }
+ fclose(cmdFile);
+
+ bRet = initOptions(rargc, rargv, bCmdFile);
+
+ for (long j=0; j < rargc; j++)
+ {
+ free(rargv[j]);
+ }
+ }
+ } else
+ {
+ fprintf(stdout, "%s: unknown option '%s'\n", m_program.getStr(), av[i]);
+ bRet = sal_False;
+ }
+ }
+ }
+
+ if ( bRet )
+ {
+ if ( m_regName1.getLength() == 0 )
+ {
+ fprintf(stdout, "%s: missing option '-r1'\n", m_program.getStr());
+ bRet = sal_False;
+ }
+ if ( m_regName2.getLength() == 0 )
+ {
+ fprintf(stdout, "%s: missing option '-r2'\n", m_program.getStr());
+ bRet = sal_False;
+ }
+ }
+
+ return bRet;
+}
+
+OString Options::prepareHelp()
+{
+ OString help("\nusing: ");
+ help += m_program + " -r1<filename> -r2<filename> [-options] | @<filename>\n";
+ help += " -r1<filename> = filename specifies the name of the first registry.\n";
+ help += " -r2<filename> = filename specifies the name of the second registry.\n";
+ help += " @<filename> = filename specifies a command file.\n";
+ help += "Options:\n";
+ help += " -s<name> = name specifies the name of a start key. If no start key\n";
+ help += " |S<name> is specified the comparison starts with the root key.\n";
+ help += " -x<name> = name specifies the name of a key which won't be compared. All\n";
+ help += " |X<name> subkeys won't be compared also. This option can be used more than once.\n";
+ help += " -f|F = force the detailed output of any diffenrences. Default\n";
+ help += " is that only the number of differences is returned.\n";
+ help += " -c|C = make a complete check, that means any differences will be\n";
+ help += " detected. Default is only a compatibility check that means\n";
+ help += " only UNO typelibrary entries will be checked.\n";
+ help += " -t|T = make an UNO type compatiblity check. This means that registry 2\n";
+ help += " will be checked against registry 1. If a interface in r2 contains\n";
+ help += " more methods or the methods are in a different order as in r1, r2 is\n";
+ help += " incompatible to r1. But if a service in r2 supports more properties as\n";
+ help += " in r1 and the new properties are 'optonal' it is compatible.\n";
+ help += " -u|U = additionally check types that are unpublished in registry 1.\n";
+ help += " -h|-? = print this help message and exit.\n";
+ help += prepareVersion();
+
+ return help;
+}
+
+OString Options::prepareVersion()
+{
+ OString version("\nSun Microsystems (R) ");
+ version += m_program + " Version 1.0\n\n";
+ return version;
+}
+
+sal_Bool Options::matchedWithExcludeKey( const OUString& keyName)
+{
+ if ( m_excludeKeys.empty() )
+ return sal_False;
+
+ StringSet::const_iterator iter = m_excludeKeys.begin();
+ StringSet::const_iterator end = m_excludeKeys.end();
+
+ while ( iter != end )
+ {
+ if ( keyName.indexOf(*iter) == 0)
+ return sal_True;
+
+ ++iter;
+ }
+
+ return sal_False;
+}
+
+static Options options;
+
+static char const * getTypeClass(RTTypeClass typeClass)
+{
+ switch (typeClass)
+ {
+ case RT_TYPE_INTERFACE:
+ return "INTERFACE";
+ case RT_TYPE_MODULE:
+ return "MODULE";
+ case RT_TYPE_STRUCT:
+ return "STRUCT";
+ case RT_TYPE_ENUM:
+ return "ENUM";
+ case RT_TYPE_EXCEPTION:
+ return "EXCEPTION";
+ case RT_TYPE_TYPEDEF:
+ return "TYPEDEF";
+ case RT_TYPE_SERVICE:
+ return "SERVICE";
+ case RT_TYPE_OBJECT:
+ return "OBJECT";
+ case RT_TYPE_CONSTANTS:
+ return "CONSTANTS";
+ default:
+ return "INVALID";
+ }
+}
+
+static OString getFieldAccess(RTFieldAccess fieldAccess)
+{
+ OString ret;
+ if ( (fieldAccess & RT_ACCESS_INVALID) == RT_ACCESS_INVALID )
+ {
+ ret += OString("INVALID");
+ }
+ if ( (fieldAccess & RT_ACCESS_READONLY) == RT_ACCESS_READONLY )
+ {
+ ret += OString(ret.getLength() > 0 ? ",READONLY" : "READONLY");
+ }
+ if ( (fieldAccess & RT_ACCESS_OPTIONAL) == RT_ACCESS_OPTIONAL )
+ {
+ ret += OString(ret.getLength() > 0 ? ",OPTIONAL" : "OPTIONAL");
+ }
+ if ( (fieldAccess & RT_ACCESS_MAYBEVOID) == RT_ACCESS_MAYBEVOID )
+ {
+ ret += OString(ret.getLength() > 0 ? ",MAYBEVOID" : "MAYBEVOID");
+ }
+ if ( (fieldAccess & RT_ACCESS_BOUND) == RT_ACCESS_BOUND )
+ {
+ ret += OString(ret.getLength() > 0 ? ",BOUND" : "BOUND");
+ }
+ if ( (fieldAccess & RT_ACCESS_CONSTRAINED) == RT_ACCESS_CONSTRAINED )
+ {
+ ret += OString(ret.getLength() > 0 ? ",CONSTRAINED" : "CONSTRAINED");
+ }
+ if ( (fieldAccess & RT_ACCESS_TRANSIENT) == RT_ACCESS_TRANSIENT )
+ {
+ ret += OString(ret.getLength() > 0 ? ",TRANSIENT" : "TRANSIENT");
+ }
+ if ( (fieldAccess & RT_ACCESS_MAYBEAMBIGUOUS) == RT_ACCESS_MAYBEAMBIGUOUS )
+ {
+ ret += OString(ret.getLength() > 0 ? ",MAYBEAMBIGUOUS" : "MAYBEAMBIGUOUS");
+ }
+ if ( (fieldAccess & RT_ACCESS_MAYBEDEFAULT) == RT_ACCESS_MAYBEDEFAULT )
+ {
+ ret += OString(ret.getLength() > 0 ? ",MAYBEDEFAULT" : "MAYBEDEFAULT");
+ }
+ if ( (fieldAccess & RT_ACCESS_REMOVEABLE) == RT_ACCESS_REMOVEABLE )
+ {
+ ret += OString(ret.getLength() > 0 ? ",REMOVEABLE" : "REMOVEABLE");
+ }
+ if ( (fieldAccess & RT_ACCESS_ATTRIBUTE) == RT_ACCESS_ATTRIBUTE )
+ {
+ ret += OString(ret.getLength() > 0 ? ",ATTRIBUTE" : "ATTRIBUTE");
+ }
+ if ( (fieldAccess & RT_ACCESS_PROPERTY) == RT_ACCESS_PROPERTY )
+ {
+ ret += OString(ret.getLength() > 0 ? ",PROPERTY" : "PROPERTY");
+ }
+ if ( (fieldAccess & RT_ACCESS_CONST) == RT_ACCESS_CONST )
+ {
+ ret += OString(ret.getLength() > 0 ? ",CONST" : "CONST");
+ }
+ if ( (fieldAccess & RT_ACCESS_READWRITE) == RT_ACCESS_READWRITE )
+ {
+ ret += OString(ret.getLength() > 0 ? ",READWRITE" : "READWRITE");
+ }
+ return ret;
+}
+
+static char const * getConstValueType(RTConstValue& constValue)
+{
+ switch (constValue.m_type)
+ {
+ case RT_TYPE_BOOL:
+ return "sal_Bool";
+ case RT_TYPE_BYTE:
+ return "sal_uInt8";
+ case RT_TYPE_INT16:
+ return "sal_Int16";
+ case RT_TYPE_UINT16:
+ return "sal_uInt16";
+ case RT_TYPE_INT32:
+ return "sal_Int32";
+ case RT_TYPE_UINT32:
+ return "sal_uInt32";
+// case RT_TYPE_INT64:
+// return "sal_Int64";
+// case RT_TYPE_UINT64:
+// return "sal_uInt64";
+ case RT_TYPE_FLOAT:
+ return "float";
+ case RT_TYPE_DOUBLE:
+ return "double";
+ case RT_TYPE_STRING:
+ return "sal_Unicode*";
+ default:
+ return "NONE";
+ }
+}
+static void printConstValue(RTConstValue& constValue)
+{
+ switch (constValue.m_type)
+ {
+ case RT_TYPE_NONE:
+ fprintf(stdout, "none");
+ break;
+ case RT_TYPE_BOOL:
+ fprintf(stdout, "%s", constValue.m_value.aBool ? "TRUE" : "FALSE");
+ break;
+ case RT_TYPE_BYTE:
+ fprintf(stdout, "%d", constValue.m_value.aByte);
+ break;
+ case RT_TYPE_INT16:
+ fprintf(stdout, "%d", constValue.m_value.aShort);
+ break;
+ case RT_TYPE_UINT16:
+ fprintf(stdout, "%d", constValue.m_value.aUShort);
+ break;
+ case RT_TYPE_INT32:
+ fprintf(
+ stdout, "%ld",
+ sal::static_int_cast< long >(constValue.m_value.aLong));
+ break;
+ case RT_TYPE_UINT32:
+ fprintf(
+ stdout, "%lu",
+ sal::static_int_cast< unsigned long >(
+ constValue.m_value.aULong));
+ break;
+// case RT_TYPE_INT64:
+// fprintf(stdout, "%d", constValue.m_value.aHyper);
+// case RT_TYPE_UINT64:
+// fprintf(stdout, "%d", constValue.m_value.aUHyper);
+ case RT_TYPE_FLOAT:
+ fprintf(stdout, "%f", constValue.m_value.aFloat);
+ break;
+ case RT_TYPE_DOUBLE:
+ fprintf(stdout, "%f", constValue.m_value.aDouble);
+ break;
+ case RT_TYPE_STRING:
+ fprintf(
+ stdout, "%s",
+ (rtl::OUStringToOString(
+ constValue.m_value.aString, RTL_TEXTENCODING_UTF8).
+ getStr()));
+ break;
+ default:
+ break;
+ }
+}
+
+static sal_uInt32 checkConstValue(const OUString& keyName,
+ RTTypeClass typeClass,
+ sal_Bool& bDump,
+ RTConstValue& constValue1,
+ RTConstValue& constValue2,
+ sal_uInt16 index1)
+{
+ switch (constValue1.m_type)
+ {
+ case RT_TYPE_INVALID:
+ break;
+ case RT_TYPE_BOOL:
+ if (constValue1.m_value.aBool != constValue2.m_value.aBool)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %s != Value2 = %s\n", index1,
+ constValue1.m_value.aBool ? "TRUE" : "FALSE",
+ constValue2.m_value.aBool ? "TRUE" : "FALSE");
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_BYTE:
+ if (constValue1.m_value.aByte != constValue2.m_value.aByte)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %d != Value2 = %d\n", index1,
+ constValue1.m_value.aByte, constValue2.m_value.aByte);
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_INT16:
+ if (constValue1.m_value.aShort != constValue2.m_value.aShort)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %d != Value2 = %d\n", index1,
+ constValue1.m_value.aShort, constValue2.m_value.aShort);
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_UINT16:
+ if (constValue1.m_value.aUShort != constValue2.m_value.aUShort)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %d != Value2 = %d\n", index1,
+ constValue1.m_value.aUShort, constValue2.m_value.aUShort);
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_INT32:
+ if (constValue1.m_value.aLong != constValue2.m_value.aLong)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %ld != Value2 = %ld\n", index1,
+ sal::static_int_cast< long >(constValue1.m_value.aLong),
+ sal::static_int_cast< long >(constValue2.m_value.aLong));
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_UINT32:
+ if (constValue1.m_value.aULong != constValue2.m_value.aULong)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %lu != Value2 = %lu\n", index1,
+ sal::static_int_cast< unsigned long >(constValue1.m_value.aULong),
+ sal::static_int_cast< unsigned long >(constValue2.m_value.aULong));
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_INT64:
+ if (constValue1.m_value.aHyper != constValue2.m_value.aHyper)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(
+ stdout, " Field %d: Value1 = %s != Value2 = %s\n",
+ index1,
+ rtl::OUStringToOString(
+ rtl::OUString::valueOf(constValue1.m_value.aHyper),
+ RTL_TEXTENCODING_ASCII_US).getStr(),
+ rtl::OUStringToOString(
+ rtl::OUString::valueOf(constValue2.m_value.aHyper),
+ RTL_TEXTENCODING_ASCII_US).getStr());
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_UINT64:
+ if (constValue1.m_value.aUHyper != constValue2.m_value.aUHyper)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(
+ stdout, " Field %d: Value1 = %s != Value2 = %s\n",
+ index1,
+ rtl::OUStringToOString(
+ rtl::OUString::valueOf(
+ static_cast< sal_Int64 >(
+ constValue1.m_value.aUHyper)),
+ RTL_TEXTENCODING_ASCII_US).getStr(),
+ rtl::OUStringToOString(
+ rtl::OUString::valueOf(
+ static_cast< sal_Int64 >(
+ constValue2.m_value.aUHyper)),
+ RTL_TEXTENCODING_ASCII_US).getStr());
+ // printing the unsigned values as signed should be
+ // acceptable...
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_FLOAT:
+ if (constValue1.m_value.aFloat != constValue2.m_value.aFloat)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %f != Value2 = %f\n", index1,
+ constValue1.m_value.aFloat, constValue2.m_value.aFloat);
+ }
+ return 1;
+ }
+ break;
+ case RT_TYPE_DOUBLE:
+ if (constValue1.m_value.aDouble != constValue2.m_value.aDouble)
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Value1 = %f != Value2 = %f\n", index1,
+ constValue1.m_value.aDouble, constValue2.m_value.aDouble);
+ }
+ return 1;
+ }
+ break;
+ default:
+ OSL_ASSERT(false);
+ break;
+ }
+ return 0;
+}
+
+static sal_uInt32 checkField(const OUString& keyName,
+ RTTypeClass typeClass,
+ sal_Bool& bDump,
+ typereg::Reader& reader1,
+ typereg::Reader& reader2,
+ sal_uInt16 index1,
+ sal_uInt16 index2)
+{
+ sal_uInt32 nError = 0;
+ if ( reader1.getFieldName(index1) !=
+ reader2.getFieldName(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Name1 = %s != Name2 = %s\n", index1,
+ U2S(reader1.getFieldName(index1)), U2S(reader2.getFieldName(index2)));
+ }
+ nError++;
+ }
+ if ( reader1.getFieldTypeName(index1) !=
+ reader2.getFieldTypeName(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Type1 = %s != Type2 = %s\n", index1,
+ U2S(reader1.getFieldTypeName(index1)), U2S(reader2.getFieldTypeName(index2)));
+ }
+ nError++;
+ } else
+ {
+ RTConstValue constValue1 = reader1.getFieldValue(index1);
+ RTConstValue constValue2 = reader2.getFieldValue(index2);
+ if ( constValue1.m_type != constValue2.m_type )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Access1 = %s != Access2 = %s\n", index1,
+ getConstValueType(constValue1), getConstValueType(constValue2));
+ fprintf(stdout, " Field %d: Value1 = ", index1);
+ printConstValue(constValue1);
+ fprintf(stdout, " != Value2 = ");
+ printConstValue(constValue1);
+ fprintf(stdout, "\n;");
+ }
+ nError++;
+ } else
+ {
+ nError += checkConstValue(keyName, typeClass, bDump, constValue1, constValue2, index1);
+ }
+ }
+
+ if ( reader1.getFieldFlags(index1) != reader2.getFieldFlags(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: FieldAccess1 = %s != FieldAccess2 = %s\n", index1,
+ getFieldAccess(reader1.getFieldFlags(index1)).getStr(),
+ getFieldAccess(reader1.getFieldFlags(index2)).getStr());
+ }
+ nError++;
+ }
+
+ if ( options.fullCheck() &&
+ (reader1.getFieldDocumentation(index1) != reader2.getFieldDocumentation(index2)) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Field %d: Doku1 = %s\n Doku2 = %s\n", index1,
+ U2S(reader1.getFieldDocumentation(index1)), U2S(reader2.getFieldDocumentation(index2)));
+ }
+ nError++;
+ }
+ return nError;
+}
+
+static char const * getMethodMode(RTMethodMode methodMode)
+{
+ switch ( methodMode )
+ {
+ case RT_MODE_ONEWAY:
+ return "ONEWAY";
+ case RT_MODE_ONEWAY_CONST:
+ return "ONEWAY,CONST";
+ case RT_MODE_TWOWAY:
+ return "NONE";
+ case RT_MODE_TWOWAY_CONST:
+ return "CONST";
+ default:
+ return "INVALID";
+ }
+}
+
+static char const * getParamMode(RTParamMode paramMode)
+{
+ switch ( paramMode )
+ {
+ case RT_PARAM_IN:
+ return "IN";
+ case RT_PARAM_OUT:
+ return "OUT";
+ case RT_PARAM_INOUT:
+ return "INOUT";
+ default:
+ return "INVALID";
+ }
+}
+
+static sal_uInt32 checkMethod(const OUString& keyName,
+ RTTypeClass typeClass,
+ sal_Bool& bDump,
+ typereg::Reader& reader1,
+ typereg::Reader& reader2,
+ sal_uInt16 index)
+{
+ sal_uInt32 nError = 0;
+ if ( reader1.getMethodName(index) !=
+ reader2.getMethodName(index) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method1 %d: Name1 = %s != Name2 = %s\n", index,
+ U2S(reader1.getMethodName(index)),
+ U2S(reader2.getMethodName(index)));
+ }
+ nError++;
+ }
+
+ if ( reader1.getMethodReturnTypeName(index) !=
+ reader2.getMethodReturnTypeName(index) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method1 %d: ReturnType1 = %s != ReturnType2 = %s\n", index,
+ U2S(reader1.getMethodReturnTypeName(index)),
+ U2S(reader2.getMethodReturnTypeName(index)));
+ }
+ nError++;
+ }
+
+ sal_uInt16 nParams1 = (sal_uInt16)reader1.getMethodParameterCount(index);
+ sal_uInt16 nParams2 = (sal_uInt16)reader2.getMethodParameterCount(index);
+ if ( nParams1 != nParams2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d : nParameters1 = %d != nParameters2 = %d\n", index, nParams1, nParams2);
+ }
+ nError++;
+ }
+ sal_uInt16 i=0;
+ for (i=0; i < nParams1 && i < nParams2; i++)
+ {
+ if ( reader1.getMethodParameterTypeName(index, i) != reader2.getMethodParameterTypeName(index, i) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d, Parameter %d: Type1 = %s != Type2 = %s\n", index, i,
+ U2S(reader1.getMethodParameterTypeName(index, i)),
+ U2S(reader2.getMethodParameterTypeName(index, i)));
+ }
+ nError++;
+ }
+ if ( options.fullCheck() &&
+ (reader1.getMethodParameterName(index, i) != reader2.getMethodParameterName(index, i)) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d, Parameter %d: Name1 = %s != Name2 = %s\n", index, i,
+ U2S(reader1.getMethodParameterName(index, i)),
+ U2S(reader2.getMethodParameterName(index, i)));
+ }
+ nError++;
+ }
+ if ( reader1.getMethodParameterFlags(index, i) != reader2.getMethodParameterFlags(index, i) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d, Parameter %d: Mode1 = %s != Mode2 = %s\n", index, i,
+ getParamMode(reader1.getMethodParameterFlags(index, i)),
+ getParamMode(reader2.getMethodParameterFlags(index, i)));
+ }
+ nError++;
+ }
+ }
+ if ( i < nParams1 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry1: Method %d contains %d more parameters\n", index, nParams1 - i);
+ }
+ if ( i < nParams2 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry2: Method %d contains %d more parameters\n", index, nParams2 - i);
+ }
+
+ sal_uInt16 nExcep1 = (sal_uInt16)reader1.getMethodExceptionCount(index);
+ sal_uInt16 nExcep2 = (sal_uInt16)reader2.getMethodExceptionCount(index);
+ if ( nExcep1 != nExcep2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " nExceptions1 = %d != nExceptions2 = %d\n", nExcep1, nExcep2);
+ }
+ nError++;
+ }
+ for (i=0; i < nExcep1 && i < nExcep2; i++)
+ {
+ if ( reader1.getMethodExceptionTypeName(index, i) != reader2.getMethodExceptionTypeName(index, i) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d, Exception %d: Name1 = %s != Name2 = %s\n", index, i,
+ U2S(reader1.getMethodExceptionTypeName(index, i)),
+ U2S(reader2.getMethodExceptionTypeName(index, i)));
+ }
+ nError++;
+ }
+ }
+ if ( i < nExcep1 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry1: Method %d contains %d more exceptions\n", index, nExcep1 - i);
+ }
+ if ( i < nExcep2 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry2: Method %d contains %d more exceptions\n", index, nExcep2 - i);
+ }
+
+ if ( reader1.getMethodFlags(index) != reader2.getMethodFlags(index) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d: Mode1 = %s != Mode2 = %s\n", index,
+ getMethodMode(reader1.getMethodFlags(index)),
+ getMethodMode(reader2.getMethodFlags(index)));
+ }
+ nError++;
+ }
+
+ if ( options.fullCheck() &&
+ (reader1.getMethodDocumentation(index) != reader2.getMethodDocumentation(index)) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Method %d: Doku1 = %s\n Doku2 = %s\n", index,
+ U2S(reader1.getMethodDocumentation(index)),
+ U2S(reader2.getMethodDocumentation(index)));
+ }
+ nError++;
+ }
+ return nError;
+}
+
+static char const * getReferenceType(RTReferenceType refType)
+{
+ switch (refType)
+ {
+ case RT_REF_SUPPORTS:
+ return "RT_REF_SUPPORTS";
+ case RT_REF_OBSERVES:
+ return "RT_REF_OBSERVES";
+ case RT_REF_EXPORTS:
+ return "RT_REF_EXPORTS";
+ case RT_REF_NEEDS:
+ return "RT_REF_NEEDS";
+ default:
+ return "RT_REF_INVALID";
+ }
+}
+
+static sal_uInt32 checkReference(const OUString& keyName,
+ RTTypeClass typeClass,
+ sal_Bool& bDump,
+ typereg::Reader& reader1,
+ typereg::Reader& reader2,
+ sal_uInt16 index1,
+ sal_uInt16 index2)
+{
+ sal_uInt32 nError = 0;
+ if ( reader1.getReferenceTypeName(index1) !=
+ reader2.getReferenceTypeName(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Reference %d: Name1 = %s != Name2 = %s\n", index1,
+ U2S(reader1.getReferenceTypeName(index1)),
+ U2S(reader2.getReferenceTypeName(index2)));
+ }
+ nError++;
+ }
+ if ( reader1.getReferenceTypeName(index1) !=
+ reader2.getReferenceTypeName(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Reference %d: Type1 = %s != Type2 = %s\n", index1,
+ getReferenceType(reader1.getReferenceSort(index1)),
+ getReferenceType(reader2.getReferenceSort(index2)));
+ }
+ nError++;
+ }
+ if ( options.fullCheck() &&
+ (reader1.getReferenceDocumentation(index1) != reader2.getReferenceDocumentation(index2)) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Reference %d: Doku1 = %s\n Doku2 = %s\n", index1,
+ U2S(reader1.getReferenceDocumentation(index1)),
+ U2S(reader2.getReferenceDocumentation(index2)));
+ }
+ nError++;
+ }
+ if ( reader1.getReferenceFlags(index1) !=
+ reader2.getReferenceFlags(index2) )
+ {
+ if ( options.forceOutput() && !options.unoTypeCheck() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Reference %d: Access1 = %s != Access2 = %s\n", index1,
+ getFieldAccess(reader1.getReferenceFlags(index1)).getStr(),
+ getFieldAccess(reader1.getReferenceFlags(index2)).getStr());
+ }
+ nError++;
+ }
+ return nError;
+}
+
+static sal_uInt32 checkFieldsWithoutOrder(const OUString& keyName,
+ RTTypeClass typeClass,
+ sal_Bool& bDump,
+ typereg::Reader& reader1,
+ typereg::Reader& reader2)
+{
+ sal_uInt32 nError = 0;
+
+ sal_uInt16 nFields1 = (sal_uInt16)reader1.getFieldCount();
+ sal_uInt16 nFields2 = (sal_uInt16)reader2.getFieldCount();
+ sal_uInt16 i=0, j=0;
+
+ if ( nFields1 > nFields2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " %s1 contains %d more properties as %s2\n",
+ getTypeClass(typeClass), nFields1-nFields2, getTypeClass(typeClass));
+ }
+ }
+
+ sal_Bool bFound = sal_False;
+ ::std::set< sal_uInt16 > moreProps;
+
+ for (i=0; i < nFields1; i++)
+ {
+ for (j=0; j < nFields2; j++)
+ {
+ if (!checkField(keyName, typeClass, bDump, reader1, reader2, i, j))
+ {
+ bFound = sal_True;
+ moreProps.insert(j);
+ break;
+ }
+ }
+ if (!bFound)
+ {
+ if (options.forceOutput())
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " incompatible change: Field %d ('%s') of r1 is not longer a property of this %s in r2\n",
+ i, U2S(shortName(reader1.getFieldName(i))), getTypeClass(typeClass));
+ }
+ nError++;
+ } else
+ {
+ bFound = sal_False;
+ }
+ }
+
+ if ( typeClass == RT_TYPE_SERVICE && !moreProps.empty() )
+ {
+ for (j=0; j < nFields2; j++)
+ {
+ if ( moreProps.find(j) == moreProps.end() )
+ {
+ if ( (reader2.getFieldFlags(j) & RT_ACCESS_OPTIONAL) != RT_ACCESS_OPTIONAL )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " incompatible change: Field %d ('%s') of r2 is a new property compared to this %s in r1 and is not 'optional'\n",
+ j, U2S(shortName(reader2.getFieldName(j))), getTypeClass(typeClass));
+ }
+ nError++;
+ }
+ }
+ }
+ }
+
+ return nError;
+}
+
+static sal_uInt32 checkBlob(const OUString& keyName, typereg::Reader& reader1, sal_uInt32 size1,
+ typereg::Reader& reader2, sal_uInt32 size2)
+{
+ sal_uInt32 nError = 0;
+ sal_Bool bDump = sal_True;
+
+ if ( options.fullCheck() && (size1 != size2) )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(
+ stdout, " Size1 = %lu Size2 = %lu\n",
+ sal::static_int_cast< unsigned long >(size1),
+ sal::static_int_cast< unsigned long >(size2));
+ }
+ }
+ if (reader1.isPublished()) {
+ if (!reader2.isPublished()) {
+ if (options.forceOutput()) {
+ if (bDump) {
+ fprintf(stdout, "?: %s\n", U2S(keyName));
+ bDump = false;
+ }
+ fprintf(stdout, " published in 1 but unpublished in 2\n");
+ }
+ ++nError;
+ }
+ } else if (!options.checkUnpublished()) {
+ return nError;
+ }
+ if ( reader1.getTypeClass() != reader2.getTypeClass() )
+ {
+ if ( options.forceOutput() )
+ {
+ if (bDump) {
+ fprintf(stdout, "?: %s\n", U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " TypeClass1 = %s != TypeClass2 = %s\n",
+ getTypeClass(reader1.getTypeClass()),
+ getTypeClass(reader2.getTypeClass()));
+ }
+ return ++nError;
+ }
+
+ RTTypeClass typeClass = reader1.getTypeClass();
+
+ if ( reader1.getTypeName() != reader2.getTypeName() )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " TypeName1 = %s != TypeName2 = %s\n",
+ U2S(reader1.getTypeName()), U2S(reader2.getTypeName()));
+ }
+ nError++;
+ }
+ if ( (typeClass == RT_TYPE_INTERFACE ||
+ typeClass == RT_TYPE_STRUCT ||
+ typeClass == RT_TYPE_EXCEPTION) )
+ {
+ if (reader1.getSuperTypeCount() != reader2.getSuperTypeCount()) {
+ if (bDump) {
+ fprintf(
+ stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = false;
+ }
+ fprintf(
+ stdout, " SuperTypeCount1 = %d != SuperTypeCount2 = %d\n",
+ static_cast< int >(reader1.getSuperTypeCount()),
+ static_cast< int >(reader2.getSuperTypeCount()));
+ ++nError;
+ } else {
+ for (sal_Int16 i = 0; i < reader1.getSuperTypeCount(); ++i) {
+ if (reader1.getSuperTypeName(i) != reader2.getSuperTypeName(i))
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " SuperTypeName1 = %s != SuperTypeName2 = %s\n",
+ U2S(reader1.getSuperTypeName(i)), U2S(reader2.getSuperTypeName(i)));
+ }
+ nError++;
+ }
+ }
+ }
+ }
+ sal_uInt16 nFields1 = (sal_uInt16)reader1.getFieldCount();
+ sal_uInt16 nFields2 = (sal_uInt16)reader2.getFieldCount();
+ sal_Bool bCheckNormal = sal_True;
+
+ if ( (typeClass == RT_TYPE_SERVICE ||
+ typeClass == RT_TYPE_MODULE ||
+ typeClass == RT_TYPE_CONSTANTS) && options.unoTypeCheck() )
+ {
+ bCheckNormal = sal_False;
+ }
+
+ if ( bCheckNormal )
+ {
+ if ( nFields1 != nFields2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " nFields1 = %d != nFields2 = %d\n", nFields1, nFields2);
+ }
+ nError++;
+ }
+ sal_uInt16 i;
+ for (i=0; i < nFields1 && i < nFields2; i++)
+ {
+ nError += checkField(keyName, typeClass, bDump, reader1, reader2, i, i);
+ }
+ if ( i < nFields1 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry1 contains %d more fields\n", nFields1 - i);
+ }
+ if ( i < nFields2 && options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Registry2 contains %d more fields\n", nFields2 - i);
+ }
+ } else
+ {
+ nError += checkFieldsWithoutOrder(keyName, typeClass, bDump, reader1, reader2);
+ }
+
+ if ( typeClass == RT_TYPE_INTERFACE )
+ {
+ sal_uInt16 nMethods1 = (sal_uInt16)reader1.getMethodCount();
+ sal_uInt16 nMethods2 = (sal_uInt16)reader2.getMethodCount();
+ if ( nMethods1 != nMethods2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " nMethods1 = %d != nMethods2 = %d\n", nMethods1, nMethods2);
+ }
+ nError++;
+ }
+ sal_uInt16 i;
+ for (i=0; i < nMethods1 && i < nMethods2; i++)
+ {
+ nError += checkMethod(keyName, typeClass, bDump, reader1, reader2, i);
+ }
+ if ( i < nMethods1 && options.forceOutput() )
+ {
+ fprintf(stdout, " Registry1 contains %d more methods\n", nMethods1 - i);
+ }
+ if ( i < nMethods2 && options.forceOutput() )
+ {
+ fprintf(stdout, " Registry2 contains %d more methods\n", nMethods2 - i);
+ }
+ }
+ if ( typeClass == RT_TYPE_SERVICE )
+ {
+ sal_uInt16 nReference1 = (sal_uInt16)reader1.getReferenceCount();
+ sal_uInt16 nReference2 = (sal_uInt16)reader2.getReferenceCount();
+
+ if ( !bCheckNormal )
+ {
+ sal_uInt16 i=0, j=0;
+
+ if ( nReference1 > nReference2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " service1 contains %d more references as service2\n",
+ nReference1-nReference2);
+ }
+ }
+
+ sal_Bool bFound = sal_False;
+ ::std::set< sal_uInt16 > moreReferences;
+
+ for (i=0; i < nReference1; i++)
+ {
+ for (j=0; j < nReference2; j++)
+ {
+ if (!checkReference(keyName, typeClass, bDump, reader1, reader2, i, j))
+ {
+ bFound = sal_True;
+ moreReferences.insert(j);
+ break;
+ }
+ }
+ if (!bFound)
+ {
+ if (options.forceOutput())
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " incompatible change: Reference %d ('%s') in 'r1' is not longer a reference of this service in 'r2'\n",
+ i, U2S(shortName(reader1.getReferenceTypeName(i))));
+ }
+ nError++;
+ } else
+ {
+ bFound = sal_False;
+ }
+ }
+
+ if ( !moreReferences.empty() )
+ {
+ for (j=0; j < nReference2; j++)
+ {
+ if ( moreReferences.find(j) == moreReferences.end() )
+ {
+ if ( (reader2.getReferenceFlags(j) & RT_ACCESS_OPTIONAL) != RT_ACCESS_OPTIONAL )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " incompatible change: Reference %d ('%s') of r2 is a new reference compared to this service in r1 and is not 'optional'\n",
+ j, U2S(shortName(reader2.getReferenceTypeName(j))));
+ }
+ nError++;
+ }
+ }
+ }
+ }
+ } else
+ {
+ if ( nReference1 != nReference2 )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " nReferences1 = %d != nReferences2 = %d\n", nReference1, nReference2);
+ }
+ nError++;
+ }
+ sal_uInt16 i;
+ for (i=0; i < nReference1 && i < nReference2; i++)
+ {
+ nError += checkReference(keyName, typeClass, bDump, reader1, reader2, i, i);
+ }
+ if ( i < nReference1 && options.forceOutput() )
+ {
+ fprintf(stdout, " Registry1 contains %d more references\n", nReference1 - i);
+ }
+ if ( i < nReference2 && options.forceOutput() )
+ {
+ fprintf(stdout, " Registry2 contains %d more references\n", nReference2 - i);
+ }
+ }
+ }
+
+ if ( options.fullCheck() && (reader1.getDocumentation() != reader2.getDocumentation()) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Doku1 = %s\n Doku2 = %s\n",
+ U2S(reader1.getDocumentation()), U2S(reader2.getDocumentation()));
+ }
+ nError++;
+ }
+/*
+ if ( nError &&
+ (!keyName.compareTo(OUString::createFromAscii("/UCR/drafts"), 11) ||
+ !keyName.compareTo(OUString::createFromAscii("/drafts"), 7)) )
+ {
+ if ( options.forceOutput() )
+ {
+ if ( bDump )
+ {
+ fprintf(stdout, "%s: %s\n", getTypeClass(typeClass), U2S(keyName));
+ bDump = sal_False;
+ }
+ fprintf(stdout, " Note: \"drafts\" type changed incompatible, no effect to the final API\n");
+ }
+ return 0;
+ }
+*/
+ return nError;
+}
+
+static sal_uInt32 checkValueDifference(RegistryKey& key1, RegValueType valueType1, sal_uInt32 size1,
+ RegistryKey& key2, RegValueType valueType2, sal_uInt32 size2)
+{
+ OUString tmpName;
+ sal_uInt32 nError = 0;
+
+ if ( valueType1 == valueType2 )
+ {
+ sal_Bool bEqual = sal_True;
+ switch (valueType1)
+ {
+ case RG_VALUETYPE_LONGLIST:
+ {
+ RegistryValueList<sal_Int32> valueList1;
+ RegistryValueList<sal_Int32> valueList2;
+ key1.getLongListValue(tmpName, valueList1);
+ key2.getLongListValue(tmpName, valueList2);
+ sal_uInt32 length1 = valueList1.getLength();
+ sal_uInt32 length2 = valueList1.getLength();
+ if ( length1 != length2 )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ for (sal_uInt32 i=0; i<length1; i++)
+ {
+ if ( valueList1.getElement(i) != valueList2.getElement(i) )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ }
+ }
+ break;
+ case RG_VALUETYPE_STRINGLIST:
+ {
+ RegistryValueList<sal_Char*> valueList1;
+ RegistryValueList<sal_Char*> valueList2;
+ key1.getStringListValue(tmpName, valueList1);
+ key2.getStringListValue(tmpName, valueList2);
+ sal_uInt32 length1 = valueList1.getLength();
+ sal_uInt32 length2 = valueList1.getLength();
+ if ( length1 != length2 )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ for (sal_uInt32 i=0; i<length1; i++)
+ {
+ if ( strcmp(valueList1.getElement(i), valueList2.getElement(i)) != 0 )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ }
+ }
+ break;
+ case RG_VALUETYPE_UNICODELIST:
+ {
+ RegistryValueList<sal_Unicode*> valueList1;
+ RegistryValueList<sal_Unicode*> valueList2;
+ key1.getUnicodeListValue(tmpName, valueList1);
+ key2.getUnicodeListValue(tmpName, valueList2);
+ sal_uInt32 length1 = valueList1.getLength();
+ sal_uInt32 length2 = valueList1.getLength();
+ if ( length1 != length2 )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ for (sal_uInt32 i=0; i<length1; i++)
+ {
+ if ( rtl_ustr_compare(valueList1.getElement(i), valueList2.getElement(i)) != 0 )
+ {
+ bEqual = sal_False;
+ break;
+ }
+ }
+ }
+ break;
+ default:
+ break;
+ }
+
+ if ( bEqual)
+ {
+ RegValue value1 = rtl_allocateMemory(size1);
+ RegValue value2 = rtl_allocateMemory(size2);
+
+ key1.getValue(tmpName, value1);
+ key2.getValue(tmpName, value2);
+
+ bEqual = (rtl_compareMemory(value1, value2, size1) == 0 );
+
+ if ( !bEqual && valueType1 == RG_VALUETYPE_BINARY && valueType2 == RG_VALUETYPE_BINARY )
+ {
+ typereg::Reader reader1(
+ value1, size1, false, TYPEREG_VERSION_1);
+ typereg::Reader reader2(
+ value2, size2, false, TYPEREG_VERSION_1);
+
+ if ( reader1.isValid() && reader2.isValid() )
+ {
+ return checkBlob(key1.getName(), reader1, size1, reader2, size2);
+ }
+ }
+
+ rtl_freeMemory(value1);
+ rtl_freeMemory(value2);
+
+ if ( bEqual )
+ {
+ return 0;
+ } else
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "Difference: key values of key \"%s\" are different\n",
+ U2S(key1.getName()));
+ }
+ nError++;
+ }
+ }
+ }
+
+ if ( options.forceOutput() )
+ {
+ switch (valueType1)
+ {
+ case RG_VALUETYPE_NOT_DEFINED:
+ fprintf(stdout, " Registry 1: key has no value\n");
+ break;
+ case RG_VALUETYPE_LONG:
+ case RG_VALUETYPE_STRING:
+ case RG_VALUETYPE_UNICODE:
+ {
+ RegValue value1 = rtl_allocateMemory(size1);
+ key1.getValue(tmpName, value1);
+
+ switch (valueType1)
+ {
+ case RG_VALUETYPE_LONG:
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_LONG\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ fprintf(stdout, " Data = %p\n", value1);
+ break;
+ case RG_VALUETYPE_STRING:
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_STRING\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ fprintf(stdout, " Data = \"%s\"\n", (sal_Char*)value1);
+ break;
+ case RG_VALUETYPE_UNICODE:
+ {
+ OUString uStrValue((sal_Unicode*)value1);
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_UNICODE\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ fprintf(stdout, " Data = \"%s\"\n", U2S(uStrValue));
+ }
+ break;
+ default:
+ OSL_ASSERT(false);
+ break;
+ }
+
+ rtl_freeMemory(value1);
+ }
+ break;
+ case RG_VALUETYPE_BINARY:
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_BINARY\n");
+ break;
+ case RG_VALUETYPE_LONGLIST:
+ {
+ RegistryValueList<sal_Int32> valueList;
+ key1.getLongListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_LONGLIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ sal_uInt32 length = valueList.getLength();
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ fprintf(
+ stdout, " Data[%lu] = %ld\n",
+ sal::static_int_cast< unsigned long >(i),
+ sal::static_int_cast< long >(valueList.getElement(i)));
+ }
+ }
+ break;
+ case RG_VALUETYPE_STRINGLIST:
+ {
+ RegistryValueList<sal_Char*> valueList;
+ key1.getStringListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_STRINGLIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ sal_uInt32 length = valueList.getLength();
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ fprintf(
+ stdout, " Data[%lu] = \"%s\"\n",
+ sal::static_int_cast< unsigned long >(i),
+ valueList.getElement(i));
+ }
+ }
+ break;
+ case RG_VALUETYPE_UNICODELIST:
+ {
+ RegistryValueList<sal_Unicode*> valueList;
+ key1.getUnicodeListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 1: Value: Type = RG_VALUETYPE_UNICODELIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size1));
+ sal_uInt32 length = valueList.getLength();
+ OUString uStrValue;
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ uStrValue = OUString(valueList.getElement(i));
+ fprintf(
+ stdout, " Data[%lu] = \"%s\"\n",
+ sal::static_int_cast< unsigned long >(i), U2S(uStrValue));
+ }
+ }
+ break;
+ }
+
+ switch (valueType2)
+ {
+ case RG_VALUETYPE_NOT_DEFINED:
+ fprintf(stdout, " Registry 2: key has no value\n");
+ break;
+ case RG_VALUETYPE_LONG:
+ case RG_VALUETYPE_STRING:
+ case RG_VALUETYPE_UNICODE:
+ {
+ RegValue value2 = rtl_allocateMemory(size2);
+ key2.getValue(tmpName, value2);
+
+ switch (valueType2)
+ {
+ case RG_VALUETYPE_LONG:
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_LONG\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ fprintf(stdout, " Data = %p\n", value2);
+ break;
+ case RG_VALUETYPE_STRING:
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_STRING\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ fprintf(stdout, " Data = \"%s\"\n", (sal_Char*)value2);
+ break;
+ case RG_VALUETYPE_UNICODE:
+ {
+ OUString uStrValue((sal_Unicode*)value2);
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_UNICODE\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ fprintf(stdout, " Data = \"%s\"\n", U2S(uStrValue));
+ }
+ break;
+ default:
+ OSL_ASSERT(false);
+ break;
+ }
+
+ rtl_freeMemory(value2);
+ }
+ break;
+ case RG_VALUETYPE_BINARY:
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_BINARY\n");
+ break;
+ case RG_VALUETYPE_LONGLIST:
+ {
+ RegistryValueList<sal_Int32> valueList;
+ key2.getLongListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_LONGLIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ sal_uInt32 length = valueList.getLength();
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ fprintf(
+ stdout, " Data[%lu] = %ld\n",
+ sal::static_int_cast< unsigned long >(i),
+ sal::static_int_cast< long >(valueList.getElement(i)));
+ }
+ }
+ break;
+ case RG_VALUETYPE_STRINGLIST:
+ {
+ RegistryValueList<sal_Char*> valueList;
+ key2.getStringListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_STRINGLIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ sal_uInt32 length = valueList.getLength();
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ fprintf(
+ stdout, " Data[%lu] = \"%s\"\n",
+ sal::static_int_cast< unsigned long >(i),
+ valueList.getElement(i));
+ }
+ }
+ break;
+ case RG_VALUETYPE_UNICODELIST:
+ {
+ RegistryValueList<sal_Unicode*> valueList;
+ key2.getUnicodeListValue(tmpName, valueList);
+ fprintf(stdout, " Registry 2: Value: Type = RG_VALUETYPE_UNICODELIST\n");
+ fprintf(
+ stdout, " Size = %lu\n",
+ sal::static_int_cast< unsigned long >(size2));
+ sal_uInt32 length = valueList.getLength();
+ OUString uStrValue;
+ for (sal_uInt32 i=0; i<length; i++)
+ {
+ uStrValue = OUString(valueList.getElement(i));
+ fprintf(
+ stdout, " Data[%lu] = \"%s\"\n",
+ sal::static_int_cast< unsigned long >(i), U2S(uStrValue));
+ }
+ }
+ break;
+ }
+ }
+ return nError;
+}
+
+static bool hasPublishedChildren(RegistryKey & key) {
+ RegistryKeyNames subKeyNames;
+ key.getKeyNames(rtl::OUString(), subKeyNames);
+ for (sal_uInt32 i = 0; i < subKeyNames.getLength(); ++i) {
+ rtl::OUString keyName(subKeyNames.getElement(i));
+ if (!options.matchedWithExcludeKey(keyName)) {
+ keyName = keyName.copy(keyName.lastIndexOf('/') + 1);
+ RegistryKey subKey;
+ if (!key.openKey(keyName, subKey)) {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("WARNING: could not open key \"%s\" in registry"
+ " \"%s\"\n"),
+ U2S(subKeyNames.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ }
+ if (subKey.isValid()) {
+ RegValueType type;
+ sal_uInt32 size;
+ if (subKey.getValueInfo(rtl::OUString(), &type, &size)
+ != REG_NO_ERROR)
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("WARNING: could not read key \"%s\" in registry"
+ " \"%s\"\n"),
+ U2S(subKeyNames.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ } else if (type == RG_VALUETYPE_BINARY) {
+ char * value = new char[size];
+ bool published = false;
+ if (subKey.getValue(rtl::OUString(), value) != REG_NO_ERROR)
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("WARNING: could not read key \"%s\" in"
+ " registry \"%s\"\n"),
+ U2S(subKeyNames.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ } else {
+ published = typereg::Reader(
+ value, size, false, TYPEREG_VERSION_1).
+ isPublished();
+ }
+ delete[] value;
+ if (published) {
+ return true;
+ }
+ }
+ }
+ }
+ }
+ return false;
+}
+
+static sal_uInt32 checkDifferences(
+ RegistryKey& key, StringSet& keys, RegistryKeyNames& subKeyNames1,
+ RegistryKeyNames& subKeyNames2)
+{
+ sal_uInt32 nError = 0;
+ sal_uInt32 length1 = subKeyNames1.getLength();
+ sal_uInt32 length2 = subKeyNames2.getLength();
+ sal_uInt32 i,j;
+
+ for (i=0; i<length1; i++)
+ {
+ sal_Bool bFound = sal_False;
+ for (j=0; j<length2; j++)
+ {
+ if ( subKeyNames1.getElement(i) == subKeyNames2.getElement(j) )
+ {
+ bFound = sal_True;
+ keys.insert(subKeyNames1.getElement(i));
+ break;
+ }
+ }
+ if ( !bFound )
+ {
+ if ( options.fullCheck() )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "EXISTENCE: key \"%s\" exists only in registry \"%s\"\n",
+ U2S(subKeyNames1.getElement(i)), options.getRegName1().getStr());
+ }
+ nError++;
+ }
+ else
+ {
+ rtl::OUString keyName(subKeyNames1.getElement(i));
+ if (!options.matchedWithExcludeKey(keyName)) {
+ keyName = keyName.copy(keyName.lastIndexOf('/') + 1);
+ RegistryKey subKey;
+ if (key.openKey(keyName, subKey)) {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("ERROR: could not open key \"%s\" in registry"
+ " \"%s\"\n"),
+ U2S(subKeyNames1.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ ++nError;
+ }
+ if (subKey.isValid()) {
+ RegValueType type;
+ sal_uInt32 size;
+ if (subKey.getValueInfo(rtl::OUString(), &type, &size)
+ != REG_NO_ERROR)
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("ERROR: could not read key \"%s\" in"
+ " registry \"%s\"\n"),
+ U2S(subKeyNames1.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ ++nError;
+ } else if (type == RG_VALUETYPE_BINARY) {
+ char * value = new char[size];
+ if (subKey.getValue(rtl::OUString(), value)
+ != REG_NO_ERROR)
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("ERROR: could not read key \"%s\" in"
+ " registry \"%s\"\n"),
+ U2S(subKeyNames1.getElement(i)),
+ options.getRegName1().getStr());
+ }
+ ++nError;
+ } else {
+ typereg::Reader reader(
+ value, size, false, TYPEREG_VERSION_1);
+ if (reader.getTypeClass() == RT_TYPE_MODULE) {
+ if (options.checkUnpublished()
+ || hasPublishedChildren(subKey))
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("EXISTENCE: module \"%s\""
+ " %sexists only in registry"
+ " 1\n"),
+ U2S(subKeyNames1.getElement(
+ i)),
+ (options.checkUnpublished()
+ ? ""
+ : "with published children "));
+ }
+ ++nError;
+ }
+ } else if (options.checkUnpublished()
+ || reader.isPublished())
+ {
+ if (options.forceOutput()) {
+ fprintf(
+ stdout,
+ ("EXISTENCE: %spublished key \"%s\""
+ " exists only in registry 1\n"),
+ reader.isPublished() ? "" : "un",
+ U2S(subKeyNames1.getElement(i)));
+ }
+ ++nError;
+ }
+ }
+ delete[] value;
+ }
+ }
+ }
+ }
+ }
+ }
+
+ for (i=0; i<length2; i++)
+ {
+ sal_Bool bFound = sal_False;
+ for (j=0; j<length1; j++)
+ {
+ if ( subKeyNames2.getElement(i) == subKeyNames1.getElement(j) )
+ {
+ bFound = sal_True;
+ keys.insert(subKeyNames2.getElement(i));
+ break;
+ }
+ }
+ if ( !bFound && options.fullCheck() )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "EXISTENCE: key \"%s\" exists only in registry \"%s\"\n",
+ U2S(subKeyNames2.getElement(i)), options.getRegName2().getStr());
+ }
+ nError++;
+ }
+ }
+ return nError;
+}
+
+static sal_uInt32 compareKeys(RegistryKey& key1, RegistryKey& key2)
+{
+ sal_uInt32 nError = 0;
+
+ RegValueType valueType1 = RG_VALUETYPE_NOT_DEFINED;
+ RegValueType valueType2 = RG_VALUETYPE_NOT_DEFINED;
+ sal_uInt32 size1 = 0;
+ sal_uInt32 size2 = 0;
+ OUString tmpName;
+ RegError e1 = key1.getValueInfo(tmpName, &valueType1, &size1);
+ RegError e2 = key2.getValueInfo(tmpName, &valueType2, &size2);
+
+ if ( e1 == e2 && e1 != REG_VALUE_NOT_EXISTS && e1 != REG_INVALID_VALUE )
+ {
+ nError += checkValueDifference(key1, valueType1, size1, key2, valueType2, size2);
+ } else
+ {
+ if ( e1 != REG_INVALID_VALUE || e2 != REG_INVALID_VALUE )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "VALUES: key values of key \"%s\" are different\n", U2S(key1.getName()));
+ }
+ nError++;
+ }
+ }
+
+ RegistryKeyNames subKeyNames1;
+ RegistryKeyNames subKeyNames2;
+
+ key1.getKeyNames(tmpName, subKeyNames1);
+ key2.getKeyNames(tmpName, subKeyNames2);
+
+ StringSet keys;
+ nError += checkDifferences(key1, keys, subKeyNames1, subKeyNames2);
+
+ StringSet::iterator iter = keys.begin();
+ StringSet::iterator end = keys.end();
+
+ RegistryKey subKey1, subKey2;
+ OUString keyName;
+ while ( iter != end )
+ {
+ keyName = OUString(*iter);
+ if ( options.matchedWithExcludeKey(keyName) )
+ {
+ ++iter;
+ continue;
+ }
+
+ sal_Int32 nPos = keyName.lastIndexOf( '/' );
+ keyName = keyName.copy( nPos != -1 ? nPos+1 : 0 );
+ if ( key1.openKey(keyName, subKey1) )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "ERROR: could not open key \"%s\" in registry \"%s\"\n",
+ U2S(*iter), options.getRegName1().getStr());
+ }
+ nError++;
+ }
+ if ( key2.openKey(keyName, subKey2) )
+ {
+ if ( options.forceOutput() )
+ {
+ fprintf(stdout, "ERROR: could not open key \"%s\" in registry \"%s\"\n",
+ U2S(*iter), options.getRegName2().getStr());
+ }
+ nError++;
+ }
+ if ( subKey1.isValid() && subKey2.isValid() )
+ {
+ nError += compareKeys(subKey1, subKey2);
+ }
+ subKey1.releaseKey();
+ subKey2.releaseKey();
+ ++iter;
+ }
+
+ return nError;
+}
+
+#if (defined UNX) || (defined OS2) || defined __MINGW32__
+int main( int argc, char * argv[] )
+#else
+int _cdecl main( int argc, char * argv[] )
+#endif
+{
+ if ( !options.initOptions(argc, argv) )
+ {
+ exit(1);
+ }
+
+ OUString regName1( convertToFileUrl(options.getRegName1()) );
+ OUString regName2( convertToFileUrl(options.getRegName2()) );
+
+ Registry reg1;
+ Registry reg2;
+
+ if ( reg1.open(regName1, REG_READONLY) )
+ {
+ fprintf(stdout, "%s: open registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName1().getStr());
+ exit(2);
+ }
+ if ( reg2.open(regName2, REG_READONLY) )
+ {
+ fprintf(stdout, "%s: open registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName2().getStr());
+ exit(3);
+ }
+
+ RegistryKey key1, key2;
+ if ( reg1.openRootKey(key1) )
+ {
+ fprintf(stdout, "%s: open root key of registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName1().getStr());
+ exit(4);
+ }
+ if ( reg2.openRootKey(key2) )
+ {
+ fprintf(stdout, "%s: open root key of registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName2().getStr());
+ exit(5);
+ }
+ if ( options.isStartKeyValid() )
+ {
+ if ( options.matchedWithExcludeKey( S2U(options.getStartKey()) ) )
+ {
+ fprintf(stdout, "%s: start key is equal to one of the exclude keys\n",
+ options.getProgramName().getStr());
+ exit(6);
+ }
+ RegistryKey sk1, sk2;
+ if ( key1.openKey(S2U(options.getStartKey()), sk1) )
+ {
+ fprintf(stdout, "%s: open start key of registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName1().getStr());
+ exit(7);
+ }
+ if ( key2.openKey(S2U(options.getStartKey()), sk2) )
+ {
+ fprintf(stdout, "%s: open start key of registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName2().getStr());
+ exit(8);
+ }
+
+ key1 = sk1;
+ key2 = sk2;
+ }
+
+ sal_uInt32 nError = compareKeys(key1, key2);
+ if ( nError )
+ {
+ if ( options.unoTypeCheck() )
+ {
+ fprintf(stdout, "%s: registries are incompatible: %lu differences!\n",
+ options.getProgramName().getStr(),
+ sal::static_int_cast< unsigned long >(nError));
+ } else
+ {
+ fprintf(stdout, "%s: registries contain %lu differences!\n",
+ options.getProgramName().getStr(),
+ sal::static_int_cast< unsigned long >(nError));
+ }
+ } else
+ {
+ if ( options.unoTypeCheck() )
+ {
+ fprintf(stdout, "%s: registries are compatible!\n",
+ options.getProgramName().getStr());
+ } else
+ {
+ fprintf(stdout, "%s: registries are equal!\n",
+ options.getProgramName().getStr());
+ }
+ }
+
+ key1.releaseKey();
+ key2.releaseKey();
+ if ( reg1.close() )
+ {
+ fprintf(stdout, "%s: closing registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName1().getStr());
+ exit(9);
+ }
+ if ( reg2.close() )
+ {
+ fprintf(stdout, "%s: closing registry \"%s\" failed\n",
+ options.getProgramName().getStr(), options.getRegName2().getStr());
+ exit(10);
+ }
+
+ return nError > 0 ? 11 : 0;
+}
+
+
generated by cgit v1.2.3 (git 2.39.1) at 2024-05-22 13:28:12 +0000