/* ****************************************************************************** * * Copyright (C) 1999-2001, International Business Machines * Corporation and others. All Rights Reserved. * ****************************************************************************** * file name: udata.c * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created on: 1999oct25 * created by: Markus W. Scherer */ #include "unicode/utypes.h" #include "unicode/putil.h" #include "umutex.h" #include "cmemory.h" #include "cstring.h" #include "unicode/udata.h" #include "unicode/uversion.h" #include "uhash.h" #include "ucln_cmn.h" #include "udatamem.h" #include "umapfile.h" #include "ucmndata.h" /*********************************************************************** * * Notes on the organization of the ICU data implementation * * All of the public API is defined in udata.h * * The implementation is split into several files... * * - udata.c (this file) contains higher level code that knows about * the search paths for locating data, caching opened data, etc. * * - umapfile.c contains the low level platform-specific code for actually loading * (memory mapping, file reading, whatever) data into memory. * * - ucmndata.c deals with the tables of contents of ICU data items within * an ICU common format data file. The implementation includes * an abstract interface and support for multiple TOC formats. * All knowledge of any specific TOC format is encapsulated here. * * - udatamem.c has code for managing UDataMemory structs. These are little * descriptor objects for blocks of memory holding ICU data of * various types. /* configuration ---------------------------------------------------------- */ /* If you are excruciatingly bored turn this on .. */ /* #define UDATA_DEBUG 1 */ #if defined(UDATA_DEBUG) # include #endif /*********************************************************************** * * static (Global) data * ************************************************************************/ static UDataMemory *gCommonICUData = NULL; static UHashtable *gCommonDataCache = NULL; UBool udata_cleanup() { if (gCommonDataCache) { /* Delete the cache of user data mappings. */ uhash_close(gCommonDataCache); /* Table owns the contents, and will delete them. */ gCommonDataCache = 0; /* Cleanup is not thread safe. */ } udata_close(gCommonICUData); /* Clean up common ICU Data */ gCommonICUData = NULL; return TRUE; /* Everything was cleaned up */ } /* * setCommonICUData. Set a UDataMemory to be the global ICU Data */ static void setCommonICUData(UDataMemory *pData, /* The new common data. Belongs to caller, we copy it. */ UDataMemory *oldData, /* Old ICUData ptr. Overwrite of this value is ok, */ /* of any others is not. */ UBool warn, /* If true, set USING_DEFAULT warning if ICUData was */ /* changed by another thread before we got to it. */ UErrorCode *pErr) { UDataMemory *newCommonData = UDataMemory_createNewInstance(pErr); if (U_FAILURE(*pErr)) { return; } /* For the assignment, other threads must cleanly see either the old */ /* or the new, not some partially initialized new. The old can not be */ /* deleted - someone may still have a pointer to it lying around in */ /* their locals. */ UDatamemory_assign(newCommonData, pData); umtx_lock(NULL); if (gCommonICUData==oldData) { gCommonICUData = newCommonData; } else { if (warn==TRUE) { *pErr = U_USING_DEFAULT_WARNING; } uprv_free(newCommonData); } umtx_unlock(NULL); return; } static char * strcpy_returnEnd(char *dest, const char *src) { while((*dest=*src)!=0) { ++dest; ++src; } return dest; } /*------------------------------------------------------------------------------* * * * setPathGetBasename given a (possibly partial) path of an item * * to be opened, compute a full directory path and leave * * it in pathBuffer. Returns a pointer to the null at * * the end of the computed path. * * Overwrites any contents in the output pathBuffer * * * *------------------------------------------------------------------------------*/ static char * setPathGetBasename(const char *path, char *pathBuffer) { if(path==NULL) { /* copy the ICU_DATA path to the path buffer */ path=u_getDataDirectory(); if(path!=NULL && *path!=0) { return strcpy_returnEnd(pathBuffer, path); } else { /* there is no path */ return pathBuffer; } } else { /* find the last file sepator in the input path */ char *basename=uprv_strrchr(path, U_FILE_SEP_CHAR); if(basename==NULL) { /* copy the ICU_DATA path to the path buffer */ path=u_getDataDirectory(); if(path!=NULL && *path!=0) { return strcpy_returnEnd(pathBuffer, path); } else { /* there is no path */ return pathBuffer; } } else { /* copy the path to the path buffer */ ++basename; uprv_memcpy(pathBuffer, path, basename-path); basename=pathBuffer+(basename-path); *basename=0; return basename; } } } static const char * findBasename(const char *path) { const char *basename=uprv_strrchr(path, U_FILE_SEP_CHAR); if(basename==NULL) { return path; } else { return basename+1; } } /*----------------------------------------------------------------------* * * * Cache for common data * * Functions for looking up or adding entries to a cache of * * data that has been previously opened. Avoids a potentially * * expensive operation of re-opening the data for subsequent * * uses. * * * * Data remains cached for the duration of the process. * * * *----------------------------------------------------------------------*/ typedef struct DataCacheElement { char *name; UDataMemory *item; } DataCacheElement; /* * Deleter function for DataCacheElements. * udata cleanup function closes the hash table; hash table in turn calls back to * here for each entry. */ static void U_CALLCONV DataCacheElement_deleter(void *pDCEl) { DataCacheElement *p = (DataCacheElement *)pDCEl; udata_close(p->item); /* unmaps storage */ uprv_free(p->name); /* delete the hash key string. */ uprv_free(pDCEl); /* delete 'this' */ } /* udata_getCacheHashTable() * Get the hash table used to store the data cache entries. * Lazy create it if it doesn't yet exist. */ static UHashtable *udata_getHashTable() { UErrorCode err = U_ZERO_ERROR; if (gCommonDataCache != NULL) { return gCommonDataCache; } umtx_lock(NULL); if (gCommonDataCache == NULL) { gCommonDataCache = uhash_open(uhash_hashChars, uhash_compareChars, &err); uhash_setValueDeleter(gCommonDataCache, DataCacheElement_deleter); } umtx_unlock(NULL); if (U_FAILURE(err)) { return NULL; /* TODO: handle this error better. */ } return gCommonDataCache; } static UDataMemory *udata_findCachedData(const char *path) { UHashtable *htable; UDataMemory *retVal = NULL; DataCacheElement *el; const char *baseName; baseName = findBasename(path); /* Cache remembers only the base name, not the full path. */ htable = udata_getHashTable(); umtx_lock(NULL); el = (DataCacheElement *)uhash_get(htable, baseName); umtx_unlock(NULL); if (el != NULL) { retVal = el->item; } return retVal; } static UDataMemory *udata_cacheDataItem(const char *path, UDataMemory *item, UErrorCode *pErr) { DataCacheElement *newElement; const char *baseName; int nameLen; UHashtable *htable; UDataMemory *oldValue = NULL; if (U_FAILURE(*pErr)) { return NULL; } /* Create a new DataCacheElement - the thingy we store in the hash table - * and copy the supplied path and UDataMemoryItems into it. */ newElement = uprv_malloc(sizeof(DataCacheElement)); if (newElement == NULL) { *pErr = U_MEMORY_ALLOCATION_ERROR; return NULL; } newElement->item = UDataMemory_createNewInstance(pErr); if (U_FAILURE(*pErr)) { return NULL; } UDatamemory_assign(newElement->item, item); baseName = findBasename(path); nameLen = uprv_strlen(baseName); newElement->name = uprv_malloc(nameLen+1); if (newElement->name == NULL) { *pErr = U_MEMORY_ALLOCATION_ERROR; return NULL; } uprv_strcpy(newElement->name, baseName); /* Stick the new DataCacheElement into the hash table. */ htable = udata_getHashTable(); umtx_lock(NULL); oldValue = uhash_get(htable, path); if (oldValue != NULL) { *pErr = U_USING_DEFAULT_WARNING; } else { uhash_put( htable, newElement->name, /* Key */ newElement, /* Value */ pErr); } umtx_unlock(NULL); if (*pErr == U_USING_DEFAULT_WARNING || U_FAILURE(*pErr)) { uprv_free(newElement->name); uprv_free(newElement); return oldValue; } return newElement->item; } /*----------------------------------------------------------------------* * * * Add a static reference to the common data library * * Unless overridden by an explicit u_setCommonData, this will be * * our common data. * * * *----------------------------------------------------------------------*/ #if defined(UDATA_STATIC_LIB) || defined(UDATA_DLL) extern const DataHeader U_IMPORT U_ICUDATA_ENTRY_POINT; #endif /*----------------------------------------------------------------------* * * * openCommonData Attempt to open a common format (.dat) file * * Map it into memory (if it's not there already) * * and return a UDataMemory object for it. * * * * If the requested data is already open and cached * * just return the cached UDataMem object. * * * *----------------------------------------------------------------------*/ static UDataMemory * openCommonData( const char *path, /* Path from OpenCHoice? */ UBool isICUData, /* ICU Data true if path == NULL */ UErrorCode *pErrorCode) { const char *inBasename; char *basename, *suffix; char pathBuffer[1024]; UDataMemory tData; if (U_FAILURE(*pErrorCode)) { return NULL; } UDataMemory_init(&tData); if (isICUData) { /* "mini-cache" for common ICU data */ if(gCommonICUData != NULL) { return gCommonICUData; } tData.pHeader = &U_ICUDATA_ENTRY_POINT; checkCommonData(&tData, pErrorCode); setCommonICUData(&tData, NULL, FALSE, pErrorCode); return gCommonICUData; } /* request is NOT for ICU Data. * Is the requested data already cached? */ inBasename=findBasename(path); { UDataMemory *dataToReturn = udata_findCachedData(inBasename); if (dataToReturn != NULL) { return dataToReturn; } } /* Requested item is not in the cache. * Hunt it down, trying all the fall back locations. */ basename=setPathGetBasename(path, pathBuffer); if(*inBasename==0) { /* no basename, no common data */ *pErrorCode=U_FILE_ACCESS_ERROR; return NULL; } /* set up the file name */ suffix=strcpy_returnEnd(basename, inBasename); uprv_strcpy(suffix, ".dat"); /* try path/basename first, then basename only */ uprv_mapFile(&tData, pathBuffer); if (!UDataMemory_isLoaded(&tData)) { if (basename!=pathBuffer) { uprv_mapFile(&tData, basename); } } if (!UDataMemory_isLoaded(&tData)) { /* no common data */ *pErrorCode=U_FILE_ACCESS_ERROR; return NULL; } /* we have mapped a file, check its header */ checkCommonData(&tData, pErrorCode); /* Cache the UDataMemory struct for this .dat file, * so we won't need to hunt it down and map it again next time * something is needed from it. */ return udata_cacheDataItem(inBasename, &tData, pErrorCode); } /*----------------------------------------------------------------------* * * * extendICUData If the full set of ICU data was not loaded at * * program startup, load it now. This function will * * be called when the lookup of an ICU data item in * * the common ICU data fails. * * * * The parameter is the UDataMemory in which the * * search for a requested item failed. * * * * return true if new data is loaded, false otherwise.* * * *----------------------------------------------------------------------*/ static UBool extendICUData(UDataMemory *failedData, UErrorCode *pErr) { /* If the data library that we are running with turns out to be the * stub library (or, on the 390, the subset library), we will try to * load a .dat file instead. The stub library has no entries in its * TOC, which is how we identify it here. */ UDataMemory *pData; if (failedData->vFuncs->NumEntries(failedData) > 0) { /* Not the stub. We can't extend. */ return FALSE; } /* See if we can explicitly open a .dat file for the ICUData. */ pData = openCommonData( U_ICUDATA_NAME, /* "icudt20l" , for example. */ FALSE, /* Pretend we're not opening ICUData */ pErr); setCommonICUData(pData, /* The new common data. */ failedData, /* Old ICUData ptr. Overwrite of this value is ok, */ FALSE, /* No warnings if write didn't happen */ pErr); /* setCommonICUData honors errors; NOP if error set */ return gCommonICUData != failedData; /* Return true if ICUData pointer was updated. */ /* (Could potentialy have been done by another thread racing */ /* us through here, but that's fine, we still return true */ /* so that current thread will also examine extended data. */ } /*----------------------------------------------------------------------* * * * udata_setCommonData * * * *----------------------------------------------------------------------*/ U_CAPI void U_EXPORT2 udata_setCommonData(const void *data, UErrorCode *pErrorCode) { UDataMemory dataMemory; if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) { return; } if(data==NULL) { *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR; return; } /* do we already have common ICU data set? */ if(gCommonICUData != NULL) { *pErrorCode=U_USING_DEFAULT_ERROR; return; } /* set the data pointer and test for validity */ UDataMemory_init(&dataMemory); UDataMemory_setData(&dataMemory, data); checkCommonData(&dataMemory, pErrorCode); if (U_FAILURE(*pErrorCode)) {return;} /* we have good data */ /* Set it up as the ICU Common Data. */ setCommonICUData(&dataMemory, NULL, TRUE, pErrorCode); } /*--------------------------------------------------------------------------- * * udata_setAppData * *---------------------------------------------------------------------------- */ U_CAPI void U_EXPORT2 udata_setAppData(const char *path, const void *data, UErrorCode *err) { UDataMemory udm; if(err==NULL || U_FAILURE(*err)) { return; } if(data==NULL) { *err=U_ILLEGAL_ARGUMENT_ERROR; return; } UDataMemory_init(&udm); udm.pHeader = data; checkCommonData(&udm, err); udata_cacheDataItem(path, &udm, err); } /*----------------------------------------------------------------------------* * * * checkDataItem Given a freshly located/loaded data item, either * * an entry in a common file or a separately loaded file, * * sanity check its header, and see if the data is * * acceptable to the app. * * If the data is good, create and return a UDataMemory * * object that can be returned to the application. * * Return NULL on any sort of failure. * * * *----------------------------------------------------------------------------*/ static UDataMemory * checkDataItem ( const DataHeader *pHeader, /* The data item to be checked. */ UDataMemoryIsAcceptable *isAcceptable, /* App's call-back function */ void *context, /* pass-thru param for above. */ const char *type, /* pass-thru param for above. */ const char *name, /* pass-thru param for above. */ UErrorCode *nonFatalErr, /* Error code if this data was not acceptable */ /* but openChoice should continue with */ /* trying to get data from fallback path. */ UErrorCode *fatalErr /* Bad error, caller should return immediately */ ) { UDataMemory *rDataMem = NULL; /* the new UDataMemory, to be returned. */ if (U_FAILURE(*fatalErr)) { return NULL; } if(pHeader->dataHeader.magic1==0xda && pHeader->dataHeader.magic2==0x27 && pHeader->info.isBigEndian==U_IS_BIG_ENDIAN && (isAcceptable==NULL || isAcceptable(context, type, name, &pHeader->info)) ) { rDataMem=UDataMemory_createNewInstance(fatalErr); if (U_FAILURE(*fatalErr)) { return NULL; } rDataMem->pHeader = pHeader; } else { /* the data is not acceptable, look further */ /* If we eventually find something good, this errorcode will be */ /* cleared out. */ *nonFatalErr=U_INVALID_FORMAT_ERROR; } return rDataMem; } /* * A note on the ownership of Mapped Memory * * For common format files, ownership resides with the UDataMemory object * that lives in the cache of opened common data. These UDataMemorys are private * to the udata implementation, and are never seen directly by users. * * The UDataMemory objects returned to users will have the address of some desired * data within the mapped region, but they wont have the mapping info itself, and thus * won't cause anything to be removed from memory when they are closed. * * For individual data files, the UDataMemory returned to the user holds the * information necessary to unmap the data on close. If the user independently * opens the same data file twice, two completely independent mappings will be made. * (There is no cache of opened data items from individual files, only a cache of * opened Common Data files, that is, files containing a collection of data items.) * * For common data passed in from the user via udata_setAppData() or * udata_setCommonData(), ownership remains with the user. * * UDataMemory objects themselves, as opposed to the memory they describe, * can be anywhere - heap, stack/local or global. * They have a flag to indicate when they're heap allocated and thus * must be deleted when closed. */ /*----------------------------------------------------------------------------* * * * main data loading functions * * * *----------------------------------------------------------------------------*/ static UDataMemory * doOpenChoice(const char *path, const char *type, const char *name, UDataMemoryIsAcceptable *isAcceptable, void *context, UErrorCode *pErrorCode) { char pathBuffer[1024]; char tocEntryName[100]; UDataMemory dataMemory; UDataMemory *pCommonData; UDataMemory *pEntryData; const DataHeader *pHeader; const char *inBasename; char *basename; char *suffix; UErrorCode errorCode=U_ZERO_ERROR; UBool isICUData= (UBool)(path==NULL); /* Make up a full mame by appending the type to the supplied * name, assuming that a type was supplied. */ uprv_strcpy(tocEntryName, name); if(type!=NULL && *type!=0) { uprv_strcat(tocEntryName, "."); uprv_strcat(tocEntryName, type); } /* try to get common data. The loop is for platforms such as the 390 that do * not initially load the full set of ICU data. If the lookup of an ICU data item * fails, the full (but slower to load) set is loaded, the and the loop repeats, * trying the lookup again. Once the full set of ICU data is loaded, the loop wont * repeat because the full set will be checked the first time through. * * The loop also handles the fallback to a .dat file if the application linked * to the stub data library rather than a real library. */ for (;;) { pCommonData=openCommonData(path, isICUData, &errorCode); if(U_SUCCESS(errorCode)) { /* look up the data piece in the common data */ pHeader=pCommonData->vFuncs->Lookup(pCommonData, tocEntryName, &errorCode); if(pHeader!=NULL) { pEntryData = checkDataItem(pHeader, isAcceptable, context, type, name, &errorCode, pErrorCode); if (U_FAILURE(*pErrorCode)) { return NULL; } if (pEntryData != NULL) { return pEntryData; } } } /* Data wasn't found. If we were looking for an ICUData item and there is * more data available, load it and try again, * otherwise break out of this loop. */ if (!(isICUData && extendICUData(pCommonData, &errorCode))) { break; } }; /* the data was not found in the common data, look further, */ /* try to get an individual data file */ basename=setPathGetBasename(path, pathBuffer); if(isICUData) { inBasename=COMMON_DATA_NAME; } else { inBasename=findBasename(path); } #ifdef UDATA_DEBUG fprintf(stderr, "looking for ind. file\n"); #endif /* try path+basename+"_"+entryName first */ if(*inBasename!=0) { suffix=strcpy_returnEnd(basename, inBasename); *suffix++='_'; uprv_strcpy(suffix, tocEntryName); if( uprv_mapFile(&dataMemory, pathBuffer) || (basename!=pathBuffer && uprv_mapFile(&dataMemory, basename))) { /* We mapped a file. Check out its contents. */ pEntryData = checkDataItem(dataMemory.pHeader, isAcceptable, context, type, name, &errorCode, pErrorCode); if (pEntryData != NULL) { /* Got good data. * Hand off ownership of the backing memory to the user's UDataMemory. * and return it. */ pEntryData->mapAddr = dataMemory.mapAddr; pEntryData->map = dataMemory.map; return pEntryData; } /* the data is not acceptable, or some error occured. Either way, unmap the memory */ udata_close(&dataMemory); /* If we had a nasty error, bail out completely. */ if (U_FAILURE(*pErrorCode)) { return NULL; } /* Otherwise remember that we found data but didn't like it for some reason, * and continue looking */ errorCode=U_INVALID_FORMAT_ERROR; } } /* try path+entryName next */ uprv_strcpy(basename, tocEntryName); if( uprv_mapFile(&dataMemory, pathBuffer) || (basename!=pathBuffer && uprv_mapFile(&dataMemory, basename))) { pEntryData = checkDataItem(dataMemory.pHeader, isAcceptable, context, type, name, &errorCode, pErrorCode); if (pEntryData != NULL) { /* Data is good. * Hand off ownership of the backing memory to the user's UDataMemory. * and return it. */ pEntryData->mapAddr = dataMemory.mapAddr; pEntryData->map = dataMemory.map; return pEntryData; } /* the data is not acceptable, or some error occured. Either way, unmap the memory */ udata_close(&dataMemory); /* If we had a nasty error, bail out completely. */ if (U_FAILURE(*pErrorCode)) { return NULL; } /* Otherwise remember that we found data but didn't like it for some reason */ errorCode=U_INVALID_FORMAT_ERROR; } /* data not found */ if(U_SUCCESS(*pErrorCode)) { if(U_SUCCESS(errorCode)) { /* file not found */ *pErrorCode=U_FILE_ACCESS_ERROR; } else { /* entry point not found or rejected */ *pErrorCode=errorCode; } } return NULL; } /* API ---------------------------------------------------------------------- */ U_CAPI UDataMemory * U_EXPORT2 udata_open(const char *path, const char *type, const char *name, UErrorCode *pErrorCode) { #ifdef UDATA_DEBUG fprintf(stderr, "udata_open(): Opening: %s . %s\n", name, type); fflush(stderr); #endif if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) { return NULL; } else if(name==NULL || *name==0) { *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR; return NULL; } else { return doOpenChoice(path, type, name, NULL, NULL, pErrorCode); } } U_CAPI UDataMemory * U_EXPORT2 udata_openChoice(const char *path, const char *type, const char *name, UDataMemoryIsAcceptable *isAcceptable, void *context, UErrorCode *pErrorCode) { #ifdef UDATA_DEBUG fprintf(stderr, "udata_openChoice(): Opening: %s . %s\n", name, type);fflush(stderr); #endif if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) { return NULL; } else if(name==NULL || *name==0 || isAcceptable==NULL) { *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR; return NULL; } else { return doOpenChoice(path, type, name, isAcceptable, context, pErrorCode); } } U_CAPI void U_EXPORT2 udata_getInfo(UDataMemory *pData, UDataInfo *pInfo) { if(pInfo!=NULL) { if(pData!=NULL && pData->pHeader!=NULL) { const UDataInfo *info=&pData->pHeader->info; if(pInfo->size>info->size) { pInfo->size=info->size; } uprv_memcpy((uint16_t *)pInfo+1, (uint16_t *)info+1, pInfo->size-2); } else { pInfo->size=0; } } }