/******************************************************************** * COPYRIGHT: * Copyright (C) 2001-2006 IBM, Inc. All Rights Reserved. * ********************************************************************/ #include #include #include #include #include #include "unicode/uperf.h" #include "uoptions.h" #include "unicode/coll.h" #include /* To store an array of string in continue space. Since string itself is treated as an array of UNIT, this class will ease our memory management for an array of string. */ //template #define COMPATCT_ARRAY(CompactArrays, UNIT) \ struct CompactArrays{\ CompactArrays(const CompactArrays & );\ CompactArrays & operator=(const CompactArrays & );\ int32_t count;/*total number of the strings*/ \ int32_t * index;/*relative offset in data*/ \ UNIT * data; /*the real space to hold strings*/ \ \ ~CompactArrays(){free(index);free(data);} \ CompactArrays():data(NULL), index(NULL), count(0){ \ index = (int32_t *) realloc(index, sizeof(int32_t)); \ index[0] = 0; \ } \ void append_one(int32_t theLen){ /*include terminal NULL*/ \ count++; \ index = (int32_t *) realloc(index, sizeof(int32_t) * (count + 1)); \ index[count] = index[count - 1] + theLen; \ data = (UNIT *) realloc(data, sizeof(UNIT) * index[count]); \ } \ UNIT * last(){return data + index[count - 1];} \ UNIT * dataOf(int32_t i){return data + index[i];} \ int32_t lengthOf(int i){return index[i+1] - index[i] - 1; } /*exclude terminating NULL*/ \ }; //typedef CompactArrays CA_uchar; //typedef CompactArrays CA_char; //typedef CompactArrays CA_uint8; //typedef CompactArrays CA_win_wchar; COMPATCT_ARRAY(CA_uchar, UChar) COMPATCT_ARRAY(CA_char, char) COMPATCT_ARRAY(CA_uint8, uint8_t) COMPATCT_ARRAY(CA_win_wchar, WCHAR) struct DataIndex { static DWORD win_langid; // for qsort callback function static UCollator * col; // for qsort callback function uint8_t * icu_key; UChar * icu_data; int32_t icu_data_len; char* posix_key; char* posix_data; int32_t posix_data_len; char* win_key; WCHAR * win_data; int32_t win_data_len; }; DWORD DataIndex::win_langid; UCollator * DataIndex::col; class CmdKeyGen : public UPerfFunction { typedef void (CmdKeyGen::* Func)(int32_t); enum{MAX_KEY_LENGTH = 5000}; UCollator * col; DWORD win_langid; int32_t count; DataIndex * data; Func fn; union { // to save sapce uint8_t icu_key[MAX_KEY_LENGTH]; char posix_key[MAX_KEY_LENGTH]; WCHAR win_key[MAX_KEY_LENGTH]; }; public: CmdKeyGen(UErrorCode, UCollator * col,DWORD win_langid, int32_t count, DataIndex * data,Func fn,int32_t) :col(col),win_langid(win_langid), count(count), data(data), fn(fn){} virtual long getOperationsPerIteration(){return count;} virtual void call(UErrorCode* status){ for(int32_t i = 0; i< count; i++){ (this->*fn)(i); } } void icu_key_null(int32_t i){ ucol_getSortKey(col, data[i].icu_data, -1, icu_key, MAX_KEY_LENGTH); } void icu_key_len(int32_t i){ ucol_getSortKey(col, data[i].icu_data, data[i].icu_data_len, icu_key, MAX_KEY_LENGTH); } // pre-generated in CollPerfTest::prepareData(), need not to check error here void win_key_null(int32_t i){ //LCMAP_SORTsk 0x00000400 // WC sort sk (normalize) LCMapStringW(win_langid, LCMAP_SORTKEY, data[i].win_data, -1, win_key, MAX_KEY_LENGTH); } void win_key_len(int32_t i){ LCMapStringW(win_langid, LCMAP_SORTKEY, data[i].win_data, data[i].win_data_len, win_key, MAX_KEY_LENGTH); } void posix_key_null(int32_t i){ strxfrm(posix_key, data[i].posix_data, MAX_KEY_LENGTH); } }; class CmdIter : public UPerfFunction { typedef void (CmdIter::* Func)(UErrorCode* , int32_t ); int32_t count; CA_uchar * data; Func fn; UCollationElements *iter; int32_t exec_count; public: CmdIter(UErrorCode & status, UCollator * col, int32_t count, CA_uchar *data, Func fn, int32_t,int32_t) :count(count), data(data), fn(fn){ exec_count = 0; UChar dummytext[] = {0, 0}; iter = ucol_openElements(col, NULL, 0, &status); ucol_setText(iter, dummytext, 1, &status); } ~CmdIter(){ ucol_closeElements(iter); } virtual long getOperationsPerIteration(){return exec_count ? exec_count : 1;} virtual void call(UErrorCode* status){ exec_count = 0; for(int32_t i = 0; i< count; i++){ (this->*fn)(status, i); } } void icu_forward_null(UErrorCode* status, int32_t i){ ucol_setText(iter, data->dataOf(i), -1, status); while (ucol_next(iter, status) != UCOL_NULLORDER) exec_count++; } void icu_forward_len(UErrorCode* status, int32_t i){ ucol_setText(iter, data->dataOf(i), data->lengthOf(i) , status); while (ucol_next(iter, status) != UCOL_NULLORDER) exec_count++; } void icu_backward_null(UErrorCode* status, int32_t i){ ucol_setText(iter, data->dataOf(i), -1, status); while (ucol_previous(iter, status) != UCOL_NULLORDER) exec_count++; } void icu_backward_len(UErrorCode* status, int32_t i){ ucol_setText(iter, data->dataOf(i), data->lengthOf(i) , status); while (ucol_previous(iter, status) != UCOL_NULLORDER) exec_count++; } }; class CmdIterAll : public UPerfFunction { typedef void (CmdIterAll::* Func)(UErrorCode* status); int32_t count; UChar * data; Func fn; UCollationElements *iter; int32_t exec_count; public: enum CALL {forward_null, forward_len, backward_null, backward_len}; ~CmdIterAll(){ ucol_closeElements(iter); } CmdIterAll(UErrorCode & status, UCollator * col, int32_t count, UChar * data, CALL call,int32_t,int32_t) :count(count),data(data) { exec_count = 0; if (call == forward_null || call == backward_null) { iter = ucol_openElements(col, data, -1, &status); } else { iter = ucol_openElements(col, data, count, &status); } if (call == forward_null || call == forward_len){ fn = &CmdIterAll::icu_forward_all; } else { fn = &CmdIterAll::icu_backward_all; } } virtual long getOperationsPerIteration(){return exec_count ? exec_count : 1;} virtual void call(UErrorCode* status){ (this->*fn)(status); } void icu_forward_all(UErrorCode* status){ int strlen = count - 5; int count5 = 5; int strindex = 0; ucol_setOffset(iter, strindex, status); while (TRUE) { if (ucol_next(iter, status) == UCOL_NULLORDER) { break; } exec_count++; count5 --; if (count5 == 0) { strindex += 10; if (strindex > strlen) { break; } ucol_setOffset(iter, strindex, status); count5 = 5; } } } void icu_backward_all(UErrorCode* status){ int strlen = count; int count5 = 5; int strindex = 5; ucol_setOffset(iter, strindex, status); while (TRUE) { if (ucol_previous(iter, status) == UCOL_NULLORDER) { break; } exec_count++; count5 --; if (count5 == 0) { strindex += 10; if (strindex > strlen) { break; } ucol_setOffset(iter, strindex, status); count5 = 5; } } } }; struct CmdQsort : public UPerfFunction{ static int q_random(const void * a, const void * b){ uint8_t * key_a = ((DataIndex *)a)->icu_key; uint8_t * key_b = ((DataIndex *)b)->icu_key; int val_a = 0; int val_b = 0; while (*key_a != 0) {val_a += val_a*37 + *key_a++;} while (*key_b != 0) {val_b += val_b*37 + *key_b++;} return val_a - val_b; } #define QCAST() \ DataIndex * da = (DataIndex *) a; \ DataIndex * db = (DataIndex *) b; \ ++exec_count static int icu_strcoll_null(const void *a, const void *b){ QCAST(); return ucol_strcoll(da->col, da->icu_data, -1, db->icu_data, -1) - UCOL_EQUAL; } static int icu_strcoll_len(const void *a, const void *b){ QCAST(); return ucol_strcoll(da->col, da->icu_data, da->icu_data_len, db->icu_data, db->icu_data_len) - UCOL_EQUAL; } static int icu_cmpkey (const void *a, const void *b){ QCAST(); return strcmp((char *) da->icu_key, (char *) db->icu_key); } static int win_cmp_null(const void *a, const void *b) { QCAST(); //CSTR_LESS_THAN 1 //CSTR_EQUAL 2 //CSTR_GREATER_THAN 3 int t = CompareStringW(da->win_langid, 0, da->win_data, -1, db->win_data, -1); if (t == 0){ fprintf(stderr, "CompareStringW error, error number %x\n", GetLastError()); exit(-1); } else{ return t - CSTR_EQUAL; } } static int win_cmp_len(const void *a, const void *b) { QCAST(); int t = CompareStringW(da->win_langid, 0, da->win_data, da->win_data_len, db->win_data, db->win_data_len); if (t == 0){ fprintf(stderr, "CompareStringW error, error number %x\n", GetLastError()); exit(-1); } else{ return t - CSTR_EQUAL; } } #define QFUNC(name, func, data) \ static int name (const void *a, const void *b){ \ QCAST(); \ return func(da->data, db->data); \ } QFUNC(posix_strcoll_null, strcoll, posix_data) QFUNC(posix_cmpkey, strcmp, posix_key) QFUNC(win_cmpkey, strcmp, win_key) QFUNC(win_wcscmp, wcscmp, win_data) QFUNC(icu_strcmp, u_strcmp, icu_data) QFUNC(icu_cmpcpo, u_strcmpCodePointOrder, icu_data) private: static int32_t exec_count; // potential muilt-thread problem typedef int (* Func)(const void *, const void *); Func fn; void * base; //Start of target array. int32_t num; //Array size in elements. int32_t width; //Element size in bytes. void * backup; //copy source of base public: CmdQsort(UErrorCode & status,void *theBase, int32_t num, int32_t width, Func fn, int32_t,int32_t) :backup(theBase),num(num),width(width),fn(fn){ base = malloc(num * width); time_empty(100, &status); // warm memory/cache } ~CmdQsort(){ free(base); } void empty_call(){ exec_count = 0; memcpy(base, backup, num * width); } double time_empty(int32_t n, UErrorCode* status) { UTimer start, stop; utimer_getTime(&start); while (n-- > 0) { empty_call(); } utimer_getTime(&stop); return utimer_getDeltaSeconds(&start,&stop); // ms } virtual void call(UErrorCode* status){ exec_count = 0; memcpy(base, backup, num * width); qsort(base, num, width, fn); } virtual double time(int32_t n, UErrorCode* status) { double t1 = time_empty(n,status); double t2 = UPerfFunction::time(n, status); return t2-t1;// < 0 ? t2 : t2-t1; } virtual long getOperationsPerIteration(){ return exec_count?exec_count:1;} }; int32_t CmdQsort::exec_count; class CmdBinSearch : public UPerfFunction{ public: typedef int (CmdBinSearch::* Func)(int, int); UCollator * col; DWORD win_langid; int32_t count; DataIndex * rnd; DataIndex * ord; Func fn; int32_t exec_count; CmdBinSearch(UErrorCode, UCollator * col,DWORD win_langid,int32_t count,DataIndex * rnd,DataIndex * ord,Func fn) :col(col),win_langid(win_langid), count(count), rnd(rnd), ord(ord), fn(fn),exec_count(0){} virtual void call(UErrorCode* status){ exec_count = 0; for(int32_t i = 0; i< count; i++){ // search all data binary_search(i); } } virtual long getOperationsPerIteration(){ return exec_count?exec_count:1;} void binary_search(int32_t random) { int low = 0; int high = count - 1; int guess; int last_guess = -1; int r; while (TRUE) { guess = (high + low)/2; if (last_guess == guess) break; // nothing to search r = (this->*fn)(random, guess); exec_count++; if (r == 0) return; // found, search end. if (r < 0) { high = guess; } else { low = guess; } last_guess = guess; } } int icu_strcoll_null(int32_t i, int32_t j){ return ucol_strcoll(col, rnd[i].icu_data, -1, ord[j].icu_data,-1); } int icu_strcoll_len(int32_t i, int32_t j){ return ucol_strcoll(col, rnd[i].icu_data, rnd[i].icu_data_len, ord[j].icu_data, ord[j].icu_data_len); } int icu_cmpkey(int32_t i, int32_t j) { return strcmp( (char *) rnd[i].icu_key, (char *) ord[j].icu_key ); } int win_cmp_null(int32_t i, int32_t j) { int t = CompareStringW(win_langid, 0, rnd[i].win_data, -1, ord[j].win_data, -1); if (t == 0){ fprintf(stderr, "CompareStringW error, error number %x\n", GetLastError()); exit(-1); } else{ return t - CSTR_EQUAL; } } int win_cmp_len(int32_t i, int32_t j) { int t = CompareStringW(win_langid, 0, rnd[i].win_data, rnd[i].win_data_len, ord[j].win_data, ord[j].win_data_len); if (t == 0){ fprintf(stderr, "CompareStringW error, error number %x\n", GetLastError()); exit(-1); } else{ return t - CSTR_EQUAL; } } #define BFUNC(name, func, data) \ int name(int32_t i, int32_t j) { \ return func(rnd[i].data, ord[j].data); \ } BFUNC(posix_strcoll_null, strcoll, posix_data) BFUNC(posix_cmpkey, strcmp, posix_key) BFUNC(win_cmpkey, strcmp, win_key) BFUNC(win_wcscmp, wcscmp, win_data) BFUNC(icu_strcmp, u_strcmp, icu_data) BFUNC(icu_cmpcpo, u_strcmpCodePointOrder, icu_data) }; class CollPerfTest : public UPerfTest { public: UCollator * col; DWORD win_langid; UChar * icu_data_all; int32_t icu_data_all_len; int32_t count; CA_uchar * icu_data; CA_uint8 * icu_key; CA_char * posix_data; CA_char * posix_key; CA_win_wchar * win_data; CA_char * win_key; DataIndex * rnd_index; // random by icu key DataIndex * ord_win_data; DataIndex * ord_win_key; DataIndex * ord_posix_data; DataIndex * ord_posix_key; DataIndex * ord_icu_data; DataIndex * ord_icu_key; DataIndex * ord_win_wcscmp; DataIndex * ord_icu_strcmp; DataIndex * ord_icu_cmpcpo; virtual ~CollPerfTest(){ ucol_close(col); delete [] icu_data_all; delete icu_data; delete icu_key; delete posix_data; delete posix_key; delete win_data; delete win_key; delete[] rnd_index; delete[] ord_win_data; delete[] ord_win_key; delete[] ord_posix_data; delete[] ord_posix_key; delete[] ord_icu_data; delete[] ord_icu_key; delete[] ord_win_wcscmp; delete[] ord_icu_strcmp; delete[] ord_icu_cmpcpo; } CollPerfTest(int32_t argc, const char* argv[], UErrorCode& status):UPerfTest(argc, argv, status){ col = NULL; icu_data_all = NULL; icu_data = NULL; icu_key = NULL; posix_data = NULL; posix_key = NULL; win_data =NULL; win_key = NULL; rnd_index = NULL; ord_win_data= NULL; ord_win_key= NULL; ord_posix_data= NULL; ord_posix_key= NULL; ord_icu_data= NULL; ord_icu_key= NULL; ord_win_wcscmp = NULL; ord_icu_strcmp = NULL; ord_icu_cmpcpo = NULL; if (U_FAILURE(status)){ return; } // Parse additional arguments UOption options[] = { UOPTION_DEF("langid", 'i', UOPT_REQUIRES_ARG), // Windows Language ID number. UOPTION_DEF("rulefile", 'r', UOPT_REQUIRES_ARG), // --rulefile // Collation related arguments. All are optional. // To simplify parsing, two choice arguments are disigned as NO_ARG. // The default value is UPPER word in the comment UOPTION_DEF("c_french", 'f', UOPT_NO_ARG), // --french UOPTION_DEF("c_alternate", 'a', UOPT_NO_ARG), // --alternate UOPTION_DEF("c_casefirst", 'c', UOPT_REQUIRES_ARG), // --casefirst UOPTION_DEF("c_caselevel", 'l', UOPT_NO_ARG), // --caselevel UOPTION_DEF("c_normal", 'n', UOPT_NO_ARG), // --normal UOPTION_DEF("c_strength", 's', UOPT_REQUIRES_ARG), // --strength <1-5> }; int32_t opt_len = (sizeof(options)/sizeof(options[0])); enum {i, r,f,a,c,l,n,s}; // The buffer between the option items' order and their references _remainingArgc = u_parseArgs(_remainingArgc, (char**)argv, opt_len, options); if (_remainingArgc < 0){ status = U_ILLEGAL_ARGUMENT_ERROR; return; } if (locale == NULL){ locale = "en_US"; // set default locale } //#ifdef U_WINDOWS if (options[i].doesOccur) { char *endp; int tmp = strtol(options[i].value, &endp, 0); if (endp == options[i].value) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } win_langid = MAKELCID(tmp, SORT_DEFAULT); } else { win_langid = uloc_getLCID(locale); } //#endif // Set up an ICU collator if (options[r].doesOccur) { // TODO: implement it } else { col = ucol_open(locale, &status); if (U_FAILURE(status)) { return; } } if (options[f].doesOccur) { ucol_setAttribute(col, UCOL_FRENCH_COLLATION, UCOL_ON, &status); } else { ucol_setAttribute(col, UCOL_FRENCH_COLLATION, UCOL_OFF, &status); } if (options[a].doesOccur) { ucol_setAttribute(col, UCOL_ALTERNATE_HANDLING, UCOL_SHIFTED, &status); } if (options[c].doesOccur) { // strcmp() has i18n encoding problem if (strcmp("lower", options[c].value) == 0){ ucol_setAttribute(col, UCOL_CASE_FIRST, UCOL_LOWER_FIRST, &status); } else if (strcmp("upper", options[c].value) == 0) { ucol_setAttribute(col, UCOL_CASE_FIRST, UCOL_UPPER_FIRST, &status); } else { status = U_ILLEGAL_ARGUMENT_ERROR; return; } } if (options[l].doesOccur){ ucol_setAttribute(col, UCOL_CASE_LEVEL, UCOL_ON, &status); } if (options[n].doesOccur){ ucol_setAttribute(col, UCOL_NORMALIZATION_MODE, UCOL_ON, &status); } if (options[s].doesOccur) { char *endp; int tmp = strtol(options[l].value, &endp, 0); if (endp == options[l].value) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } switch (tmp) { case 1: ucol_setAttribute(col, UCOL_STRENGTH, UCOL_PRIMARY, &status); break; case 2: ucol_setAttribute(col, UCOL_STRENGTH, UCOL_SECONDARY, &status); break; case 3: ucol_setAttribute(col, UCOL_STRENGTH, UCOL_TERTIARY, &status); break; case 4: ucol_setAttribute(col, UCOL_STRENGTH, UCOL_QUATERNARY, &status); break; case 5: ucol_setAttribute(col, UCOL_STRENGTH, UCOL_IDENTICAL, &status); break; default: status = U_ILLEGAL_ARGUMENT_ERROR; return; } } prepareData(status); } //to avoid use the annoying 'id' in TESTCASE(id,test) macro or the like #define TEST(testname, classname, arg1, arg2, arg3, arg4, arg5, arg6) \ if(temp == index) {\ name = #testname;\ if (exec) {\ UErrorCode status = U_ZERO_ERROR;\ UPerfFunction * t = new classname(status,arg1, arg2, arg3, arg4, arg5, arg6);\ if (U_FAILURE(status)) {\ delete t;\ return NULL;\ } else {\ return t;\ }\ } else {\ return NULL;\ }\ }\ temp++\ virtual UPerfFunction* runIndexedTest( /*[in]*/int32_t index, /*[in]*/UBool exec, /*[out]*/const char* &name, /*[in]*/ char* par = NULL ){ int temp = 0; #define TEST_KEYGEN(testname, func)\ TEST(testname, CmdKeyGen, col, win_langid, count, rnd_index, &CmdKeyGen::func, 0) TEST_KEYGEN(TestIcu_KeyGen_null, icu_key_null); TEST_KEYGEN(TestIcu_KeyGen_len, icu_key_len); TEST_KEYGEN(TestPosix_KeyGen_null, posix_key_null); TEST_KEYGEN(TestWin_KeyGen_null, win_key_null); TEST_KEYGEN(TestWin_KeyGen_len, win_key_len); #define TEST_ITER(testname, func)\ TEST(testname, CmdIter, col, count, icu_data, &CmdIter::func,0,0) TEST_ITER(TestIcu_ForwardIter_null, icu_forward_null); TEST_ITER(TestIcu_ForwardIter_len, icu_forward_len); TEST_ITER(TestIcu_BackwardIter_null, icu_backward_null); TEST_ITER(TestIcu_BackwardIter_len, icu_backward_len); #define TEST_ITER_ALL(testname, func)\ TEST(testname, CmdIterAll, col, icu_data_all_len, icu_data_all, CmdIterAll::func,0,0) TEST_ITER_ALL(TestIcu_ForwardIter_all_null, forward_null); TEST_ITER_ALL(TestIcu_ForwardIter_all_len, forward_len); TEST_ITER_ALL(TestIcu_BackwardIter_all_null, backward_null); TEST_ITER_ALL(TestIcu_BackwardIter_all_len, backward_len); #define TEST_QSORT(testname, func)\ TEST(testname, CmdQsort, rnd_index, count, sizeof(DataIndex), CmdQsort::func,0,0) TEST_QSORT(TestIcu_qsort_strcoll_null, icu_strcoll_null); TEST_QSORT(TestIcu_qsort_strcoll_len, icu_strcoll_len); TEST_QSORT(TestIcu_qsort_usekey, icu_cmpkey); TEST_QSORT(TestPosix_qsort_strcoll_null, posix_strcoll_null); TEST_QSORT(TestPosix_qsort_usekey, posix_cmpkey); TEST_QSORT(TestWin_qsort_CompareStringW_null, win_cmp_null); TEST_QSORT(TestWin_qsort_CompareStringW_len, win_cmp_len); TEST_QSORT(TestWin_qsort_usekey, win_cmpkey); #define TEST_BIN(testname, func)\ TEST(testname, CmdBinSearch, col, win_langid, count, rnd_index, ord_icu_key, &CmdBinSearch::func) TEST_BIN(TestIcu_BinarySearch_strcoll_null, icu_strcoll_null); TEST_BIN(TestIcu_BinarySearch_strcoll_len, icu_strcoll_len); TEST_BIN(TestIcu_BinarySearch_usekey, icu_cmpkey); TEST_BIN(TestIcu_BinarySearch_strcmp, icu_strcmp); TEST_BIN(TestIcu_BinarySearch_cmpCPO, icu_cmpcpo); TEST_BIN(TestPosix_BinarySearch_strcoll_null, posix_strcoll_null); TEST_BIN(TestPosix_BinarySearch_usekey, posix_cmpkey); TEST_BIN(TestWin_BinarySearch_CompareStringW_null, win_cmp_null); TEST_BIN(TestWin_BinarySearch_CompareStringW_len, win_cmp_len); TEST_BIN(TestWin_BinarySearch_usekey, win_cmpkey); TEST_BIN(TestWin_BinarySearch_wcscmp, win_wcscmp); name=""; return NULL; } void prepareData(UErrorCode& status){ if(U_FAILURE(status)) return; if (icu_data) return; // prepared icu_data = new CA_uchar(); // Following code is borrowed from UPerfTest::getLines(); const UChar* line=NULL; int32_t len =0; for (;;) { line = ucbuf_readline(ucharBuf,&len,&status); if(line == NULL || U_FAILURE(status)){break;} // Refer to the source code of ucbuf_readline() // 1. 'len' includs the line terminal symbols // 2. The length of the line terminal symbols is only one character // 3. The Windows CR LF line terminal symbols will be converted to CR if (len == 1) { continue; //skip empty line } else { icu_data->append_one(len); memcpy(icu_data->last(), line, len * sizeof(UChar)); icu_data->last()[len -1] = NULL; } } if(U_FAILURE(status)) return; // UTF-16 -> UTF-8 conversion. UConverter *conv = ucnv_open("utf-8", &status); // just UTF-8 for now. if (U_FAILURE(status)) return; count = icu_data->count; icu_data_all_len = icu_data->index[count]; // includes all NULLs icu_data_all_len -= count; // excludes all NULLs icu_data_all_len += 1; // the terminal NULL icu_data_all = new UChar[icu_data_all_len]; icu_data_all[icu_data_all_len - 1] = 0; //the terminal NULL icu_key = new CA_uint8; win_data = new CA_win_wchar; win_key = new CA_char; posix_data = new CA_char; posix_key = new CA_char; rnd_index = new DataIndex[count]; DataIndex::win_langid = win_langid; DataIndex::col = col; UChar * p = icu_data_all; int32_t s; int32_t t; for (int i=0; i < count; i++) { // ICU all data s = sizeof(UChar) * icu_data->lengthOf(i); memcpy(p, icu_data->dataOf(i), s); p += icu_data->lengthOf(i); // ICU data // ICU key s = ucol_getSortKey(col, icu_data->dataOf(i), -1,NULL, 0); icu_key->append_one(s); t = ucol_getSortKey(col, icu_data->dataOf(i), -1,icu_key->last(), s); if (t != s) {status = U_INVALID_FORMAT_ERROR;return;} // POSIX data s = ucnv_fromUChars(conv,NULL, 0, icu_data->dataOf(i), icu_data->lengthOf(i), &status); if (status == U_BUFFER_OVERFLOW_ERROR || status == U_ZERO_ERROR){ status = U_ZERO_ERROR; } else { return; } posix_data->append_one(s + 1); // plus terminal NULL t = ucnv_fromUChars(conv,posix_data->last(), s, icu_data->dataOf(i), icu_data->lengthOf(i), &status); if (U_FAILURE(status)) return; if ( t != s){status = U_INVALID_FORMAT_ERROR;return;} posix_data->last()[s] = 0; // POSIX key s = strxfrm(NULL, posix_data->dataOf(i), 0); if (s == INT_MAX){status = U_INVALID_FORMAT_ERROR;return;} posix_key->append_one(s); t = strxfrm(posix_key->last(), posix_data->dataOf(i), s); if (t != s) {status = U_INVALID_FORMAT_ERROR;return;} // Win data s = icu_data->lengthOf(i) + 1; // plus terminal NULL win_data->append_one(s); memcpy(win_data->last(), icu_data->dataOf(i), sizeof(WCHAR) * s); // Win key s = LCMapStringW(win_langid, LCMAP_SORTKEY, win_data->dataOf(i), win_data->lengthOf(i), NULL,0); if (s == 0) {status = U_INVALID_FORMAT_ERROR;return;} win_key->append_one(s); t = LCMapStringW(win_langid, LCMAP_SORTKEY, win_data->dataOf(i), win_data->lengthOf(i), (WCHAR *)(win_key->last()),s); if (t != s) {status = U_INVALID_FORMAT_ERROR;return;} }; // append_one() will make points shifting, should not merge following code into previous iteration for (int i=0; i < count; i++) { rnd_index[i].icu_key = icu_key->dataOf(i); rnd_index[i].icu_data = icu_data->dataOf(i); rnd_index[i].icu_data_len = icu_data->lengthOf(i); rnd_index[i].posix_key = posix_key->last(); rnd_index[i].posix_data = posix_data->dataOf(i); rnd_index[i].posix_data_len = posix_data->lengthOf(i); rnd_index[i].win_key = win_key->dataOf(i); rnd_index[i].win_data = win_data->dataOf(i); rnd_index[i].win_data_len = win_data->lengthOf(i); }; ucnv_close(conv); qsort(rnd_index, count, sizeof(DataIndex), CmdQsort::q_random); #define SORT(data, func) \ data = new DataIndex[count];\ memcpy(data, rnd_index, count * sizeof(DataIndex));\ qsort(data, count, sizeof(DataIndex), CmdQsort::func) SORT(ord_icu_data, icu_strcoll_len); SORT(ord_icu_key, icu_cmpkey); SORT(ord_posix_data, posix_strcoll_null); SORT(ord_posix_key, posix_cmpkey); SORT(ord_win_data, win_cmp_len); SORT(ord_win_key, win_cmpkey); SORT(ord_win_wcscmp, win_wcscmp); SORT(ord_icu_strcmp, icu_strcmp); SORT(ord_icu_cmpcpo, icu_cmpcpo); } }; int main(int argc, const char *argv[]) { UErrorCode status = U_ZERO_ERROR; CollPerfTest test(argc, argv, status); if (U_FAILURE(status)){ printf("The error is %s\n", u_errorName(status)); //TODO: print usage here return status; } if (test.run() == FALSE){ fprintf(stderr, "FAILED: Tests could not be run please check the " "arguments.\n"); return -1; } return 0; }