scuffed-code/icu4c/source/test/intltest/tsmthred.cpp
gnrunge 2b6b8c73c4
ICU-20119 urename.h update, header test fixes for icu 63 (#165)
* ICU-20119 Update and fixes for the following BRS tasks:
 - Update urename.h
 - Test uconfig.h variations

* ICU-20119 Updates copyright scanner script exclusions: don't scan ./git/*.

* ICU-20119 Changes in reply to comments for pull requst #165.
2018-09-27 14:27:41 -07:00

1588 lines
51 KiB
C++

// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/********************************************************************
* COPYRIGHT:
* Copyright (c) 1999-2015, International Business Machines Corporation and
* others. All Rights Reserved.
********************************************************************/
#include "simplethread.h"
#include "unicode/utypes.h"
#include "unicode/ustring.h"
#include "umutex.h"
#include "cmemory.h"
#include "cstring.h"
#include "indiancal.h"
#include "uparse.h"
#include "unicode/localpointer.h"
#include "unicode/resbund.h"
#include "unicode/udata.h"
#include "unicode/uloc.h"
#include "unicode/locid.h"
#include "putilimp.h"
#include "intltest.h"
#include "tsmthred.h"
#include "unicode/ushape.h"
#include "unicode/translit.h"
#include "sharedobject.h"
#include "unifiedcache.h"
#include "uassert.h"
#define TSMTHREAD_FAIL(msg) errln("%s at file %s, line %d", msg, __FILE__, __LINE__)
#define TSMTHREAD_ASSERT(expr) {if (!(expr)) {TSMTHREAD_FAIL("Fail");}}
#define TSMTHREAD_ASSERT_SUCCESS(status) {if (U_FAILURE(status)) { \
errln("file: %s:%d status = %s\n", __FILE__, __LINE__, u_errorName(status));}}
MultithreadTest::MultithreadTest()
{
}
MultithreadTest::~MultithreadTest()
{
}
#include <stdio.h>
#include <string.h>
#include <ctype.h> // tolower, toupper
#include <memory>
#include "unicode/putil.h"
// for mthreadtest
#include "unicode/numfmt.h"
#include "unicode/choicfmt.h"
#include "unicode/msgfmt.h"
#include "unicode/locid.h"
#include "unicode/coll.h"
#include "unicode/calendar.h"
#include "ucaconf.h"
void MultithreadTest::runIndexedTest( int32_t index, UBool exec,
const char* &name, char* /*par*/ ) {
if (exec)
logln("TestSuite MultithreadTest: ");
TESTCASE_AUTO_BEGIN;
TESTCASE_AUTO(TestThreads);
TESTCASE_AUTO(TestMutex);
#if !UCONFIG_NO_FORMATTING
TESTCASE_AUTO(TestThreadedIntl);
#endif
#if !UCONFIG_NO_COLLATION
TESTCASE_AUTO(TestCollators);
#endif /* #if !UCONFIG_NO_COLLATION */
TESTCASE_AUTO(TestString);
TESTCASE_AUTO(TestArabicShapingThreads);
TESTCASE_AUTO(TestAnyTranslit);
TESTCASE_AUTO(TestConditionVariables);
TESTCASE_AUTO(TestUnifiedCache);
#if !UCONFIG_NO_TRANSLITERATION
TESTCASE_AUTO(TestBreakTranslit);
TESTCASE_AUTO(TestIncDec);
#if !UCONFIG_NO_FORMATTING
TESTCASE_AUTO(Test20104);
#endif /* #if !UCONFIG_NO_FORMATTING */
#endif /* #if !UCONFIG_NO_TRANSLITERATION */
TESTCASE_AUTO_END
}
//-----------------------------------------------------------------------------------
//
// TestThreads -- see if threads really work at all.
//
// Set up N threads pointing at N chars. When they are started, they will
// set their chars. At the end we make sure they are all set.
//
//-----------------------------------------------------------------------------------
class TestThreadsThread : public SimpleThread
{
public:
TestThreadsThread(char* whatToChange) { fWhatToChange = whatToChange; }
virtual void run() { Mutex m;
*fWhatToChange = '*';
}
private:
char *fWhatToChange;
};
void MultithreadTest::TestThreads()
{
static const int32_t THREADTEST_NRTHREADS = 8;
char threadTestChars[THREADTEST_NRTHREADS + 1];
SimpleThread *threads[THREADTEST_NRTHREADS];
int32_t numThreadsStarted = 0;
int32_t i;
for(i=0;i<THREADTEST_NRTHREADS;i++)
{
threadTestChars[i] = ' ';
threads[i] = new TestThreadsThread(&threadTestChars[i]);
}
threadTestChars[THREADTEST_NRTHREADS] = '\0';
logln("->" + UnicodeString(threadTestChars) + "<- Firing off threads.. ");
for(i=0;i<THREADTEST_NRTHREADS;i++)
{
if (threads[i]->start() != 0) {
errln("Error starting thread %d", i);
}
else {
numThreadsStarted++;
}
logln(" Subthread started.");
}
if (numThreadsStarted != THREADTEST_NRTHREADS) {
errln("Not all threads could be started for testing!");
return;
}
logln("Waiting for threads to be set..");
for(i=0; i<THREADTEST_NRTHREADS; i++) {
threads[i]->join();
if (threadTestChars[i] != '*') {
errln("%s:%d Thread %d failed.", __FILE__, __LINE__, i);
}
delete threads[i];
}
}
//-----------------------------------------------------------------------------------
//
// TestArabicShapeThreads -- see if calls to u_shapeArabic in many threads works successfully
//
// Set up N threads pointing at N chars. When they are started, they will make calls to doTailTest which tests
// u_shapeArabic, if the calls are successful it will the set * chars.
// At the end we make sure all threads managed to run u_shapeArabic successfully.
// This is a unit test for ticket 9473
//
//-----------------------------------------------------------------------------------
class TestArabicShapeThreads : public SimpleThread
{
public:
TestArabicShapeThreads() {};
virtual void run() { doTailTest(); };
private:
void doTailTest();
};
void TestArabicShapeThreads::doTailTest(void) {
static const UChar src[] = { 0x0020, 0x0633, 0 };
static const UChar dst_old[] = { 0xFEB1, 0x200B,0 };
static const UChar dst_new[] = { 0xFEB1, 0xFE73,0 };
UChar dst[3] = { 0x0000, 0x0000,0 };
int32_t length;
UErrorCode status;
for (int32_t loopCount = 0; loopCount < 100; loopCount++) {
status = U_ZERO_ERROR;
length = u_shapeArabic(src, -1, dst, UPRV_LENGTHOF(dst),
U_SHAPE_LETTERS_SHAPE|U_SHAPE_SEEN_TWOCELL_NEAR, &status);
if(U_FAILURE(status)) {
IntlTest::gTest->errln("Fail: status %s\n", u_errorName(status));
return;
} else if(length!=2) {
IntlTest::gTest->errln("Fail: len %d expected 3\n", length);
return;
} else if(u_strncmp(dst,dst_old,UPRV_LENGTHOF(dst))) {
IntlTest::gTest->errln("Fail: got U+%04X U+%04X expected U+%04X U+%04X\n",
dst[0],dst[1],dst_old[0],dst_old[1]);
return;
}
//"Trying new tail
status = U_ZERO_ERROR;
length = u_shapeArabic(src, -1, dst, UPRV_LENGTHOF(dst),
U_SHAPE_LETTERS_SHAPE|U_SHAPE_SEEN_TWOCELL_NEAR|U_SHAPE_TAIL_NEW_UNICODE, &status);
if(U_FAILURE(status)) {
IntlTest::gTest->errln("Fail: status %s\n", u_errorName(status));
return;
} else if(length!=2) {
IntlTest::gTest->errln("Fail: len %d expected 3\n", length);
return;
} else if(u_strncmp(dst,dst_new,UPRV_LENGTHOF(dst))) {
IntlTest::gTest->errln("Fail: got U+%04X U+%04X expected U+%04X U+%04X\n",
dst[0],dst[1],dst_new[0],dst_new[1]);
return;
}
}
return;
}
void MultithreadTest::TestArabicShapingThreads()
{
TestArabicShapeThreads threads[30];
int32_t i;
logln("-> do TestArabicShapingThreads <- Firing off threads.. ");
for(i=0; i < UPRV_LENGTHOF(threads); i++) {
if (threads[i].start() != 0) {
errln("Error starting thread %d", i);
}
}
for(i=0; i < UPRV_LENGTHOF(threads); i++) {
threads[i].join();
}
logln("->TestArabicShapingThreads <- Got all threads! cya");
}
//-----------------------------------------------------------------------
//
// TestMutex - a simple (non-stress) test to verify that ICU mutexes
// and condition variables are functioning. Does not test the use of
// mutexes within ICU services, but rather that the
// platform's mutex support is at least superficially there.
//
//----------------------------------------------------------------------
static UMutex gTestMutexA = U_MUTEX_INITIALIZER;
static UConditionVar gThreadsCountChanged = U_CONDITION_INITIALIZER;
static int gThreadsStarted = 0;
static int gThreadsInMiddle = 0;
static int gThreadsDone = 0;
static const int TESTMUTEX_THREAD_COUNT = 40;
class TestMutexThread : public SimpleThread
{
public:
virtual void run() {
// This is the code that each of the spawned threads runs.
// All threads move together throught the started - middle - done sequence together,
// waiting for all other threads to reach each point before advancing.
umtx_lock(&gTestMutexA);
gThreadsStarted += 1;
umtx_condBroadcast(&gThreadsCountChanged);
while (gThreadsStarted < TESTMUTEX_THREAD_COUNT) {
if (gThreadsInMiddle != 0) {
IntlTest::gTest->errln(
"%s:%d gThreadsInMiddle = %d. Expected 0.", __FILE__, __LINE__, gThreadsInMiddle);
return;
}
umtx_condWait(&gThreadsCountChanged, &gTestMutexA);
}
gThreadsInMiddle += 1;
umtx_condBroadcast(&gThreadsCountChanged);
while (gThreadsInMiddle < TESTMUTEX_THREAD_COUNT) {
if (gThreadsDone != 0) {
IntlTest::gTest->errln(
"%s:%d gThreadsDone = %d. Expected 0.", __FILE__, __LINE__, gThreadsDone);
return;
}
umtx_condWait(&gThreadsCountChanged, &gTestMutexA);
}
gThreadsDone += 1;
umtx_condBroadcast(&gThreadsCountChanged);
while (gThreadsDone < TESTMUTEX_THREAD_COUNT) {
umtx_condWait(&gThreadsCountChanged, &gTestMutexA);
}
umtx_unlock(&gTestMutexA);
}
};
void MultithreadTest::TestMutex()
{
gThreadsStarted = 0;
gThreadsInMiddle = 0;
gThreadsDone = 0;
int32_t i = 0;
TestMutexThread threads[TESTMUTEX_THREAD_COUNT];
umtx_lock(&gTestMutexA);
for (i=0; i<TESTMUTEX_THREAD_COUNT; i++) {
if (threads[i].start() != 0) {
errln("%s:%d Error starting thread %d", __FILE__, __LINE__, i);
return;
}
}
// Because we are holding gTestMutexA, all of the threads should be blocked
// at the start of their run() function.
if (gThreadsStarted != 0) {
errln("%s:%d gThreadsStarted=%d. Expected 0.", __FILE__, __LINE__, gThreadsStarted);
return;
}
while (gThreadsInMiddle < TESTMUTEX_THREAD_COUNT) {
if (gThreadsDone != 0) {
errln("%s:%d gThreadsDone=%d. Expected 0.", __FILE__, __LINE__, gThreadsStarted);
return;
}
umtx_condWait(&gThreadsCountChanged, &gTestMutexA);
}
while (gThreadsDone < TESTMUTEX_THREAD_COUNT) {
umtx_condWait(&gThreadsCountChanged, &gTestMutexA);
}
umtx_unlock(&gTestMutexA);
for (i=0; i<TESTMUTEX_THREAD_COUNT; i++) {
threads[i].join();
}
}
//-------------------------------------------------------------------------------------------
//
// TestMultithreadedIntl. Test ICU Formatting in a multi-threaded environment
//
//-------------------------------------------------------------------------------------------
// * Show exactly where the string's differences lie.
UnicodeString showDifference(const UnicodeString& expected, const UnicodeString& result)
{
UnicodeString res;
res = expected + "<Expected\n";
if(expected.length() != result.length())
res += " [ Different lengths ] \n";
else
{
for(int32_t i=0;i<expected.length();i++)
{
if(expected[i] == result[i])
{
res += " ";
}
else
{
res += "|";
}
}
res += "<Differences";
res += "\n";
}
res += result + "<Result\n";
return res;
}
//-------------------------------------------------------------------------------------------
//
// FormatThreadTest - a thread that tests performing a number of numberformats.
//
//-------------------------------------------------------------------------------------------
const int kFormatThreadIterations = 100; // # of iterations per thread
const int kFormatThreadThreads = 10; // # of threads to spawn
#if !UCONFIG_NO_FORMATTING
struct FormatThreadTestData
{
double number;
UnicodeString string;
FormatThreadTestData(double a, const UnicodeString& b) : number(a),string(b) {}
} ;
// "Someone from {2} is receiving a #{0} error - {1}. Their telephone call is costing {3 number,currency}."
static void formatErrorMessage(UErrorCode &realStatus, const UnicodeString& pattern, const Locale& theLocale,
UErrorCode inStatus0, // statusString 1
const Locale &inCountry2, double currency3, // these numbers are the message arguments.
UnicodeString &result)
{
if(U_FAILURE(realStatus))
return; // you messed up
UnicodeString errString1(u_errorName(inStatus0));
UnicodeString countryName2;
inCountry2.getDisplayCountry(theLocale,countryName2);
Formattable myArgs[] = {
Formattable((int32_t)inStatus0), // inStatus0 {0}
Formattable(errString1), // statusString1 {1}
Formattable(countryName2), // inCountry2 {2}
Formattable(currency3)// currency3 {3,number,currency}
};
MessageFormat *fmt = new MessageFormat("MessageFormat's API is broken!!!!!!!!!!!",realStatus);
fmt->setLocale(theLocale);
fmt->applyPattern(pattern, realStatus);
if (U_FAILURE(realStatus)) {
delete fmt;
return;
}
FieldPosition ignore = 0;
fmt->format(myArgs,4,result,ignore,realStatus);
delete fmt;
}
/**
* Shared formatters & data used by instances of ThreadSafeFormat.
* Exactly one instance of this class is created, and it is then shared concurrently
* by the multiple instances of ThreadSafeFormat.
*/
class ThreadSafeFormatSharedData {
public:
ThreadSafeFormatSharedData(UErrorCode &status);
~ThreadSafeFormatSharedData();
LocalPointer<NumberFormat> fFormat;
Formattable fYDDThing;
Formattable fBBDThing;
UnicodeString fYDDStr;
UnicodeString fBBDStr;
};
const ThreadSafeFormatSharedData *gSharedData = NULL;
ThreadSafeFormatSharedData::ThreadSafeFormatSharedData(UErrorCode &status) {
fFormat.adoptInstead(NumberFormat::createCurrencyInstance(Locale::getUS(), status));
static const UChar kYDD[] = { 0x59, 0x44, 0x44, 0x00 };
static const UChar kBBD[] = { 0x42, 0x42, 0x44, 0x00 };
fYDDThing.adoptObject(new CurrencyAmount(123.456, kYDD, status));
fBBDThing.adoptObject(new CurrencyAmount(987.654, kBBD, status));
if (U_FAILURE(status)) {
return;
}
fFormat->format(fYDDThing, fYDDStr, NULL, status);
fFormat->format(fBBDThing, fBBDStr, NULL, status);
gSharedData = this;
}
ThreadSafeFormatSharedData::~ThreadSafeFormatSharedData() {
gSharedData = NULL;
}
/**
* Class for thread-safe testing of format.
* Instances of this class appear as members of class FormatThreadTest.
* Multiple instances of FormatThreadTest coexist.
* ThreadSafeFormat::doStuff() is called concurrently to test the thread safety of
* various shared format operations.
*/
class ThreadSafeFormat {
public:
/* give a unique offset to each thread */
ThreadSafeFormat(UErrorCode &status);
UBool doStuff(int32_t offset, UnicodeString &appendErr, UErrorCode &status) const;
private:
LocalPointer<NumberFormat> fFormat; // formatter - en_US constructed currency
};
ThreadSafeFormat::ThreadSafeFormat(UErrorCode &status) {
fFormat.adoptInstead(NumberFormat::createCurrencyInstance(Locale::getUS(), status));
}
static const UChar kUSD[] = { 0x55, 0x53, 0x44, 0x00 };
UBool ThreadSafeFormat::doStuff(int32_t offset, UnicodeString &appendErr, UErrorCode &status) const {
UBool okay = TRUE;
if(u_strcmp(fFormat->getCurrency(), kUSD)) {
appendErr.append("fFormat currency != ")
.append(kUSD)
.append(", =")
.append(fFormat->getCurrency())
.append("! ");
okay = FALSE;
}
if(u_strcmp(gSharedData->fFormat->getCurrency(), kUSD)) {
appendErr.append("gFormat currency != ")
.append(kUSD)
.append(", =")
.append(gSharedData->fFormat->getCurrency())
.append("! ");
okay = FALSE;
}
UnicodeString str;
const UnicodeString *o=NULL;
Formattable f;
const NumberFormat *nf = NULL; // only operate on it as const.
switch(offset%4) {
case 0: f = gSharedData->fYDDThing; o = &gSharedData->fYDDStr; nf = gSharedData->fFormat.getAlias(); break;
case 1: f = gSharedData->fBBDThing; o = &gSharedData->fBBDStr; nf = gSharedData->fFormat.getAlias(); break;
case 2: f = gSharedData->fYDDThing; o = &gSharedData->fYDDStr; nf = fFormat.getAlias(); break;
case 3: f = gSharedData->fBBDThing; o = &gSharedData->fBBDStr; nf = fFormat.getAlias(); break;
}
nf->format(f, str, NULL, status);
if(*o != str) {
appendErr.append(showDifference(*o, str));
okay = FALSE;
}
return okay;
}
UBool U_CALLCONV isAcceptable(void *, const char *, const char *, const UDataInfo *) {
return TRUE;
}
//static UMTX debugMutex = NULL;
//static UMTX gDebugMutex;
class FormatThreadTest : public SimpleThread
{
public:
int fNum;
int fTraceInfo;
LocalPointer<ThreadSafeFormat> fTSF;
FormatThreadTest() // constructor is NOT multithread safe.
: SimpleThread(),
fNum(0),
fTraceInfo(0),
fTSF(NULL),
fOffset(0)
// the locale to use
{
UErrorCode status = U_ZERO_ERROR; // TODO: rearrange code to allow checking of status.
fTSF.adoptInstead(new ThreadSafeFormat(status));
static int32_t fgOffset = 0;
fgOffset += 3;
fOffset = fgOffset;
}
virtual void run()
{
fTraceInfo = 1;
LocalPointer<NumberFormat> percentFormatter;
UErrorCode status = U_ZERO_ERROR;
#if 0
// debugging code,
for (int i=0; i<4000; i++) {
status = U_ZERO_ERROR;
UDataMemory *data1 = udata_openChoice(0, "res", "en_US", isAcceptable, 0, &status);
UDataMemory *data2 = udata_openChoice(0, "res", "fr", isAcceptable, 0, &status);
udata_close(data1);
udata_close(data2);
if (U_FAILURE(status)) {
error("udata_openChoice failed.\n");
break;
}
}
return;
#endif
#if 0
// debugging code,
int m;
for (m=0; m<4000; m++) {
status = U_ZERO_ERROR;
UResourceBundle *res = NULL;
const char *localeName = NULL;
Locale loc = Locale::getEnglish();
localeName = loc.getName();
// localeName = "en";
// ResourceBundle bund = ResourceBundle(0, loc, status);
//umtx_lock(&gDebugMutex);
res = ures_open(NULL, localeName, &status);
//umtx_unlock(&gDebugMutex);
//umtx_lock(&gDebugMutex);
ures_close(res);
//umtx_unlock(&gDebugMutex);
if (U_FAILURE(status)) {
error("Resource bundle construction failed.\n");
break;
}
}
return;
#endif
// Keep this data here to avoid static initialization.
FormatThreadTestData kNumberFormatTestData[] =
{
FormatThreadTestData((double)5.0, UnicodeString(u"5")),
FormatThreadTestData( 6.0, UnicodeString(u"6")),
FormatThreadTestData( 20.0, UnicodeString(u"20")),
FormatThreadTestData( 8.0, UnicodeString(u"8")),
FormatThreadTestData( 8.3, UnicodeString(u"8.3")),
FormatThreadTestData( 12345, UnicodeString(u"12,345")),
FormatThreadTestData( 81890.23, UnicodeString(u"81,890.23")),
};
int32_t kNumberFormatTestDataLength = UPRV_LENGTHOF(kNumberFormatTestData);
// Keep this data here to avoid static initialization.
FormatThreadTestData kPercentFormatTestData[] =
{
FormatThreadTestData((double)5.0, CharsToUnicodeString("500\\u00a0%")),
FormatThreadTestData( 1.0, CharsToUnicodeString("100\\u00a0%")),
FormatThreadTestData( 0.26, CharsToUnicodeString("26\\u00a0%")),
FormatThreadTestData(
16384.99, CharsToUnicodeString("1\\u202F638\\u202F499\\u00a0%")), // U+202F = NNBSP
FormatThreadTestData(
81890.23, CharsToUnicodeString("8\\u202F189\\u202F023\\u00a0%")),
};
int32_t kPercentFormatTestDataLength = UPRV_LENGTHOF(kPercentFormatTestData);
int32_t iteration;
status = U_ZERO_ERROR;
LocalPointer<NumberFormat> formatter(NumberFormat::createInstance(Locale::getEnglish(),status));
if(U_FAILURE(status)) {
IntlTest::gTest->dataerrln("%s:%d Error %s on NumberFormat::createInstance().",
__FILE__, __LINE__, u_errorName(status));
goto cleanupAndReturn;
}
percentFormatter.adoptInstead(NumberFormat::createPercentInstance(Locale::getFrench(),status));
if(U_FAILURE(status)) {
IntlTest::gTest->errln("%s:%d Error %s on NumberFormat::createPercentInstance().",
__FILE__, __LINE__, u_errorName(status));
goto cleanupAndReturn;
}
for(iteration = 0;!IntlTest::gTest->getErrors() && iteration<kFormatThreadIterations;iteration++)
{
int32_t whichLine = (iteration + fOffset)%kNumberFormatTestDataLength;
UnicodeString output;
formatter->format(kNumberFormatTestData[whichLine].number, output);
if(0 != output.compare(kNumberFormatTestData[whichLine].string)) {
IntlTest::gTest->errln("format().. expected " + kNumberFormatTestData[whichLine].string
+ " got " + output);
goto cleanupAndReturn;
}
// Now check percent.
output.remove();
whichLine = (iteration + fOffset)%kPercentFormatTestDataLength;
percentFormatter->format(kPercentFormatTestData[whichLine].number, output);
if(0 != output.compare(kPercentFormatTestData[whichLine].string))
{
IntlTest::gTest->errln("percent format().. \n" +
showDifference(kPercentFormatTestData[whichLine].string,output));
goto cleanupAndReturn;
}
// Test message error
const int kNumberOfMessageTests = 3;
UErrorCode statusToCheck;
UnicodeString patternToCheck;
Locale messageLocale;
Locale countryToCheck;
double currencyToCheck;
UnicodeString expected;
// load the cases.
switch((iteration+fOffset) % kNumberOfMessageTests)
{
default:
case 0:
statusToCheck= U_FILE_ACCESS_ERROR;
patternToCheck= "0:Someone from {2} is receiving a #{0}"
" error - {1}. Their telephone call is costing "
"{3,number,currency}."; // number,currency
messageLocale= Locale("en","US");
countryToCheck= Locale("","HR");
currencyToCheck= 8192.77;
expected= "0:Someone from Croatia is receiving a #4 error - "
"U_FILE_ACCESS_ERROR. Their telephone call is costing $8,192.77.";
break;
case 1:
statusToCheck= U_INDEX_OUTOFBOUNDS_ERROR;
patternToCheck= "1:A customer in {2} is receiving a #{0} error - {1}. "
"Their telephone call is costing {3,number,currency}."; // number,currency
messageLocale= Locale("de","DE@currency=DEM");
countryToCheck= Locale("","BF");
currencyToCheck= 2.32;
expected= CharsToUnicodeString(
"1:A customer in Burkina Faso is receiving a #8 error - U_INDEX_OUTOFBOUNDS_ERROR. "
"Their telephone call is costing 2,32\\u00A0DM.");
break;
case 2:
statusToCheck= U_MEMORY_ALLOCATION_ERROR;
patternToCheck= "2:user in {2} is receiving a #{0} error - {1}. "
"They insist they just spent {3,number,currency} "
"on memory."; // number,currency
messageLocale= Locale("de","AT@currency=ATS"); // Austrian German
countryToCheck= Locale("","US"); // hmm
currencyToCheck= 40193.12;
expected= CharsToUnicodeString(
"2:user in Vereinigte Staaten is receiving a #7 error"
" - U_MEMORY_ALLOCATION_ERROR. They insist they just spent"
" \\u00f6S\\u00A040.193,12 on memory.");
break;
}
UnicodeString result;
UErrorCode status = U_ZERO_ERROR;
formatErrorMessage(status,patternToCheck,messageLocale,statusToCheck,
countryToCheck,currencyToCheck,result);
if(U_FAILURE(status))
{
UnicodeString tmp(u_errorName(status));
IntlTest::gTest->errln("Failure on message format, pattern=" + patternToCheck +
", error = " + tmp);
goto cleanupAndReturn;
}
if(result != expected)
{
IntlTest::gTest->errln("PatternFormat: \n" + showDifference(expected,result));
goto cleanupAndReturn;
}
// test the Thread Safe Format
UnicodeString appendErr;
if(!fTSF->doStuff(fNum, appendErr, status)) {
IntlTest::gTest->errln(appendErr);
goto cleanupAndReturn;
}
} /* end of for loop */
cleanupAndReturn:
fTraceInfo = 2;
}
private:
int32_t fOffset; // where we are testing from.
};
// ** The actual test function.
void MultithreadTest::TestThreadedIntl()
{
UnicodeString theErr;
UErrorCode threadSafeErr = U_ZERO_ERROR;
ThreadSafeFormatSharedData sharedData(threadSafeErr);
assertSuccess("initializing ThreadSafeFormat", threadSafeErr, TRUE);
//
// Create and start the test threads
//
logln("Spawning: %d threads * %d iterations each.",
kFormatThreadThreads, kFormatThreadIterations);
FormatThreadTest tests[kFormatThreadThreads];
int32_t j;
for(j = 0; j < UPRV_LENGTHOF(tests); j++) {
tests[j].fNum = j;
int32_t threadStatus = tests[j].start();
if (threadStatus != 0) {
errln("%s:%d System Error %d starting thread number %d.",
__FILE__, __LINE__, threadStatus, j);
return;
}
}
for (j=0; j<UPRV_LENGTHOF(tests); j++) {
tests[j].join();
logln("Thread # %d is complete..", j);
}
}
#endif /* #if !UCONFIG_NO_FORMATTING */
//-------------------------------------------------------------------------------------------
//
// Collation threading test
//
//-------------------------------------------------------------------------------------------
#if !UCONFIG_NO_COLLATION
#define kCollatorThreadThreads 10 // # of threads to spawn
#define kCollatorThreadPatience kCollatorThreadThreads*30
struct Line {
UChar buff[25];
int32_t buflen;
} ;
static UBool
skipLineBecauseOfBug(const UChar *s, int32_t length) {
// TODO: Fix ICU ticket #8052
if(length >= 3 &&
(s[0] == 0xfb2 || s[0] == 0xfb3) &&
s[1] == 0x334 &&
(s[2] == 0xf73 || s[2] == 0xf75 || s[2] == 0xf81)) {
return TRUE;
}
return FALSE;
}
static UCollationResult
normalizeResult(int32_t result) {
return result<0 ? UCOL_LESS : result==0 ? UCOL_EQUAL : UCOL_GREATER;
}
class CollatorThreadTest : public SimpleThread
{
private:
const Collator *coll;
const Line *lines;
int32_t noLines;
UBool isAtLeastUCA62;
public:
CollatorThreadTest() : SimpleThread(),
coll(NULL),
lines(NULL),
noLines(0),
isAtLeastUCA62(TRUE)
{
};
void setCollator(Collator *c, Line *l, int32_t nl, UBool atLeastUCA62)
{
coll = c;
lines = l;
noLines = nl;
isAtLeastUCA62 = atLeastUCA62;
}
virtual void run() {
uint8_t sk1[1024], sk2[1024];
uint8_t *oldSk = NULL, *newSk = sk1;
int32_t oldLen = 0;
int32_t prev = 0;
int32_t i = 0;
for(i = 0; i < noLines; i++) {
if(lines[i].buflen == 0) { continue; }
if(skipLineBecauseOfBug(lines[i].buff, lines[i].buflen)) { continue; }
int32_t resLen = coll->getSortKey(lines[i].buff, lines[i].buflen, newSk, 1024);
if(oldSk != NULL) {
int32_t skres = strcmp((char *)oldSk, (char *)newSk);
int32_t cmpres = coll->compare(lines[prev].buff, lines[prev].buflen, lines[i].buff, lines[i].buflen);
int32_t cmpres2 = coll->compare(lines[i].buff, lines[i].buflen, lines[prev].buff, lines[prev].buflen);
if(cmpres != -cmpres2) {
IntlTest::gTest->errln(UnicodeString("Compare result not symmetrical on line ") + (i + 1));
break;
}
if(cmpres != normalizeResult(skres)) {
IntlTest::gTest->errln(UnicodeString("Difference between coll->compare and sortkey compare on line ") + (i + 1));
break;
}
int32_t res = cmpres;
if(res == 0 && !isAtLeastUCA62) {
// Up to UCA 6.1, the collation test files use a custom tie-breaker,
// comparing the raw input strings.
res = u_strcmpCodePointOrder(lines[prev].buff, lines[i].buff);
// Starting with UCA 6.2, the collation test files use the standard UCA tie-breaker,
// comparing the NFD versions of the input strings,
// which we do via setting strength=identical.
}
if(res > 0) {
IntlTest::gTest->errln(UnicodeString("Line is not greater or equal than previous line, for line ") + (i + 1));
break;
}
}
oldSk = newSk;
oldLen = resLen;
(void)oldLen; // Suppress set but not used warning.
prev = i;
newSk = (newSk == sk1)?sk2:sk1;
}
}
};
void MultithreadTest::TestCollators()
{
UErrorCode status = U_ZERO_ERROR;
FILE *testFile = NULL;
char testDataPath[1024];
strcpy(testDataPath, IntlTest::getSourceTestData(status));
if (U_FAILURE(status)) {
errln("ERROR: could not open test data %s", u_errorName(status));
return;
}
strcat(testDataPath, "CollationTest_");
const char* type = "NON_IGNORABLE";
const char *ext = ".txt";
if(testFile) {
fclose(testFile);
}
char buffer[1024];
strcpy(buffer, testDataPath);
strcat(buffer, type);
size_t bufLen = strlen(buffer);
// we try to open 3 files:
// path/CollationTest_type.txt
// path/CollationTest_type_SHORT.txt
// path/CollationTest_type_STUB.txt
// we are going to test with the first one that we manage to open.
strcpy(buffer+bufLen, ext);
testFile = fopen(buffer, "rb");
if(testFile == 0) {
strcpy(buffer+bufLen, "_SHORT");
strcat(buffer, ext);
testFile = fopen(buffer, "rb");
if(testFile == 0) {
strcpy(buffer+bufLen, "_STUB");
strcat(buffer, ext);
testFile = fopen(buffer, "rb");
if (testFile == 0) {
*(buffer+bufLen) = 0;
dataerrln("could not open any of the conformance test files, tried opening base %s", buffer);
return;
} else {
infoln(
"INFO: Working with the stub file.\n"
"If you need the full conformance test, please\n"
"download the appropriate data files from:\n"
"http://source.icu-project.org/repos/icu/tools/trunk/unicodetools/com/ibm/text/data/");
}
}
}
LocalArray<Line> lines(new Line[200000]);
memset(lines.getAlias(), 0, sizeof(Line)*200000);
int32_t lineNum = 0;
UChar bufferU[1024];
uint32_t first = 0;
while (fgets(buffer, 1024, testFile) != NULL) {
if(*buffer == 0 || buffer[0] == '#') {
// Store empty and comment lines so that errors are reported
// for the real test file lines.
lines[lineNum].buflen = 0;
lines[lineNum].buff[0] = 0;
} else {
int32_t buflen = u_parseString(buffer, bufferU, 1024, &first, &status);
lines[lineNum].buflen = buflen;
u_memcpy(lines[lineNum].buff, bufferU, buflen);
lines[lineNum].buff[buflen] = 0;
}
lineNum++;
}
fclose(testFile);
if(U_FAILURE(status)) {
dataerrln("Couldn't read the test file!");
return;
}
UVersionInfo uniVersion;
static const UVersionInfo v62 = { 6, 2, 0, 0 };
u_getUnicodeVersion(uniVersion);
UBool isAtLeastUCA62 = uprv_memcmp(uniVersion, v62, 4) >= 0;
LocalPointer<Collator> coll(Collator::createInstance(Locale::getRoot(), status));
if(U_FAILURE(status)) {
errcheckln(status, "Couldn't open UCA collator");
return;
}
coll->setAttribute(UCOL_NORMALIZATION_MODE, UCOL_ON, status);
coll->setAttribute(UCOL_CASE_FIRST, UCOL_OFF, status);
coll->setAttribute(UCOL_CASE_LEVEL, UCOL_OFF, status);
coll->setAttribute(UCOL_STRENGTH, isAtLeastUCA62 ? UCOL_IDENTICAL : UCOL_TERTIARY, status);
coll->setAttribute(UCOL_ALTERNATE_HANDLING, UCOL_NON_IGNORABLE, status);
int32_t spawnResult = 0;
LocalArray<CollatorThreadTest> tests(new CollatorThreadTest[kCollatorThreadThreads]);
logln(UnicodeString("Spawning: ") + kCollatorThreadThreads + " threads * " + kFormatThreadIterations + " iterations each.");
int32_t j = 0;
for(j = 0; j < kCollatorThreadThreads; j++) {
//logln("Setting collator %i", j);
tests[j].setCollator(coll.getAlias(), lines.getAlias(), lineNum, isAtLeastUCA62);
}
for(j = 0; j < kCollatorThreadThreads; j++) {
log("%i ", j);
spawnResult = tests[j].start();
if(spawnResult != 0) {
errln("%s:%d THREAD INFO: thread %d failed to start with status %d", __FILE__, __LINE__, j, spawnResult);
return;
}
}
logln("Spawned all");
for(int32_t i=0;i<kCollatorThreadThreads;i++) {
tests[i].join();
//logln(UnicodeString("Test #") + i + " is complete.. ");
}
}
#endif /* #if !UCONFIG_NO_COLLATION */
//-------------------------------------------------------------------------------------------
//
// StringThreadTest2
//
//-------------------------------------------------------------------------------------------
const int kStringThreadIterations = 2500;// # of iterations per thread
const int kStringThreadThreads = 10; // # of threads to spawn
class StringThreadTest2 : public SimpleThread
{
public:
int fNum;
int fTraceInfo;
static const UnicodeString *gSharedString;
StringThreadTest2() // constructor is NOT multithread safe.
: SimpleThread(),
fTraceInfo(0)
{
};
virtual void run()
{
fTraceInfo = 1;
int loopCount = 0;
for (loopCount = 0; loopCount < kStringThreadIterations; loopCount++) {
if (*gSharedString != "This is the original test string.") {
IntlTest::gTest->errln("%s:%d Original string is corrupt.", __FILE__, __LINE__);
break;
}
UnicodeString s1 = *gSharedString;
s1 += "cat this";
UnicodeString s2(s1);
UnicodeString s3 = *gSharedString;
s2 = s3;
s3.truncate(12);
s2.truncate(0);
}
fTraceInfo = 2;
}
};
const UnicodeString *StringThreadTest2::gSharedString = NULL;
// ** The actual test function.
void MultithreadTest::TestString()
{
int j;
StringThreadTest2::gSharedString = new UnicodeString("This is the original test string.");
StringThreadTest2 tests[kStringThreadThreads];
logln(UnicodeString("Spawning: ") + kStringThreadThreads + " threads * " + kStringThreadIterations + " iterations each.");
for(j = 0; j < kStringThreadThreads; j++) {
int32_t threadStatus = tests[j].start();
if (threadStatus != 0) {
errln("%s:%d System Error %d starting thread number %d.", __FILE__, __LINE__, threadStatus, j);
}
}
// Force a failure, to verify test is functioning and can report errors.
// const_cast<UnicodeString *>(StringThreadTest2::gSharedString)->setCharAt(5, 'x');
for(j=0; j<kStringThreadThreads; j++) {
tests[j].join();
logln(UnicodeString("Test #") + j + " is complete.. ");
}
delete StringThreadTest2::gSharedString;
StringThreadTest2::gSharedString = NULL;
}
//
// Test for ticket #10673, race in cache code in AnyTransliterator.
// It's difficult to make the original unsafe code actually fail, but
// this test will fairly reliably take the code path for races in
// populating the cache.
//
#if !UCONFIG_NO_TRANSLITERATION
Transliterator *gSharedTranslit = NULL;
class TxThread: public SimpleThread {
public:
TxThread() {};
~TxThread();
void run();
};
TxThread::~TxThread() {}
void TxThread::run() {
UnicodeString greekString("\\u03B4\\u03B9\\u03B1\\u03C6\\u03BF\\u03C1\\u03B5\\u03C4\\u03B9\\u03BA\\u03BF\\u03CD\\u03C2");
greekString = greekString.unescape();
gSharedTranslit->transliterate(greekString);
if (greekString[0] != 0x64) // 'd'. The whole transliterated string is "diaphoretikous" (accented u).
{
IntlTest::gTest->errln("%s:%d Transliteration failed.", __FILE__, __LINE__);
}
}
#endif
void MultithreadTest::TestAnyTranslit() {
#if !UCONFIG_NO_TRANSLITERATION
UErrorCode status = U_ZERO_ERROR;
LocalPointer<Transliterator> tx(Transliterator::createInstance("Any-Latin", UTRANS_FORWARD, status));
if (U_FAILURE(status)) {
dataerrln("File %s, Line %d: Error, status = %s", __FILE__, __LINE__, u_errorName(status));
return;
}
gSharedTranslit = tx.getAlias();
TxThread threads[4];
int32_t i;
for (i=0; i<UPRV_LENGTHOF(threads); i++) {
threads[i].start();
}
for (i=0; i<UPRV_LENGTHOF(threads); i++) {
threads[i].join();
}
gSharedTranslit = NULL;
#endif // !UCONFIG_NO_TRANSLITERATION
}
//
// Condition Variables Test
// Create a swarm of threads.
// Using a mutex and a condition variables each thread
// Increments a global count of started threads.
// Broadcasts that it has started.
// Waits on the condition that all threads have started.
// Increments a global count of finished threads.
// Waits on the condition that all threads have finished.
// Exits.
//
class CondThread: public SimpleThread {
public:
CondThread() :fFinished(false) {};
~CondThread() {};
void run();
bool fFinished;
};
static UMutex gCTMutex = U_MUTEX_INITIALIZER;
static UConditionVar gCTConditionVar = U_CONDITION_INITIALIZER;
int gConditionTestOne = 1; // Value one. Non-const, extern linkage to inhibit
// compiler assuming a known value.
int gStartedThreads;
int gFinishedThreads;
static const int NUMTHREADS = 10;
// Worker thread function.
void CondThread::run() {
umtx_lock(&gCTMutex);
gStartedThreads += gConditionTestOne;
umtx_condBroadcast(&gCTConditionVar);
while (gStartedThreads < NUMTHREADS) {
if (gFinishedThreads != 0) {
IntlTest::gTest->errln("File %s, Line %d: Error, gStartedThreads = %d, gFinishedThreads = %d",
__FILE__, __LINE__, gStartedThreads, gFinishedThreads);
}
umtx_condWait(&gCTConditionVar, &gCTMutex);
}
gFinishedThreads += gConditionTestOne;
fFinished = true;
umtx_condBroadcast(&gCTConditionVar);
while (gFinishedThreads < NUMTHREADS) {
umtx_condWait(&gCTConditionVar, &gCTMutex);
}
umtx_unlock(&gCTMutex);
}
void MultithreadTest::TestConditionVariables() {
gStartedThreads = 0;
gFinishedThreads = 0;
int i;
umtx_lock(&gCTMutex);
CondThread *threads[NUMTHREADS];
for (i=0; i<NUMTHREADS; ++i) {
threads[i] = new CondThread;
threads[i]->start();
}
while (gStartedThreads < NUMTHREADS) {
umtx_condWait(&gCTConditionVar, &gCTMutex);
}
while (gFinishedThreads < NUMTHREADS) {
umtx_condWait(&gCTConditionVar, &gCTMutex);
}
umtx_unlock(&gCTMutex);
for (i=0; i<NUMTHREADS; ++i) {
if (!threads[i]->fFinished) {
errln("File %s, Line %d: Error, threads[%d]->fFinished == false", __FILE__, __LINE__, i);
}
}
for (i=0; i<NUMTHREADS; ++i) {
threads[i]->join();
delete threads[i];
}
}
//
// Unified Cache Test
//
// Each thread fetches a pair of objects. There are 8 distinct pairs:
// ("en_US", "bs"), ("en_GB", "ca"), ("fr_FR", "ca_AD") etc.
// These pairs represent 8 distinct languages
// Note that only one value per language gets created in the cache.
// In particular each cached value can have multiple keys.
static const char *gCacheLocales[] = {
"en_US", "en_GB", "fr_FR", "fr",
"de", "sr_ME", "sr_BA", "sr_CS"};
static const char *gCacheLocales2[] = {
"bs", "ca", "ca_AD", "ca_ES",
"en_US", "fi", "ff_CM", "ff_GN"};
static int32_t gObjectsCreated = 0; // protected by gCTMutex
static const int32_t CACHE_LOAD = 3;
class UCTMultiThreadItem : public SharedObject {
public:
char *value;
UCTMultiThreadItem(const char *x) : value(NULL) {
value = uprv_strdup(x);
}
virtual ~UCTMultiThreadItem() {
uprv_free(value);
}
};
U_NAMESPACE_BEGIN
template<> U_EXPORT
const UCTMultiThreadItem *LocaleCacheKey<UCTMultiThreadItem>::createObject(
const void *context, UErrorCode &status) const {
const UnifiedCache *cacheContext = (const UnifiedCache *) context;
if (uprv_strcmp(fLoc.getLanguage(), fLoc.getName()) != 0) {
const UCTMultiThreadItem *result = NULL;
if (cacheContext == NULL) {
UnifiedCache::getByLocale(fLoc.getLanguage(), result, status);
return result;
}
cacheContext->get(LocaleCacheKey<UCTMultiThreadItem>(fLoc.getLanguage()), result, status);
return result;
}
umtx_lock(&gCTMutex);
bool firstObject = (gObjectsCreated == 0);
if (firstObject) {
// Force the first object creation that comes through to wait
// until other have completed. Verifies that cache doesn't
// deadlock when a creation is slow.
// Note that gObjectsCreated needs to be incremeneted from 0 to 1
// early, to keep subsequent threads from entering this path.
gObjectsCreated = 1;
while (gObjectsCreated < 3) {
umtx_condWait(&gCTConditionVar, &gCTMutex);
}
}
umtx_unlock(&gCTMutex);
const UCTMultiThreadItem *result =
new UCTMultiThreadItem(fLoc.getLanguage());
if (result == NULL) {
status = U_MEMORY_ALLOCATION_ERROR;
} else {
result->addRef();
}
// Log that we created an object. The first object was already counted,
// don't do it again.
umtx_lock(&gCTMutex);
if (!firstObject) {
gObjectsCreated += 1;
}
umtx_condBroadcast(&gCTConditionVar);
umtx_unlock(&gCTMutex);
return result;
}
U_NAMESPACE_END
class UnifiedCacheThread: public SimpleThread {
public:
UnifiedCacheThread(
const UnifiedCache *cache,
const char *loc,
const char *loc2) : fCache(cache), fLoc(loc), fLoc2(loc2) {};
~UnifiedCacheThread() {};
void run();
void exerciseByLocale(const Locale &);
const UnifiedCache *fCache;
Locale fLoc;
Locale fLoc2;
};
void UnifiedCacheThread::exerciseByLocale(const Locale &locale) {
UErrorCode status = U_ZERO_ERROR;
const UCTMultiThreadItem *origItem = NULL;
fCache->get(
LocaleCacheKey<UCTMultiThreadItem>(locale), fCache, origItem, status);
U_ASSERT(U_SUCCESS(status));
if (uprv_strcmp(locale.getLanguage(), origItem->value)) {
IntlTest::gTest->errln(
"%s:%d Expected %s, got %s", __FILE__, __LINE__,
locale.getLanguage(),
origItem->value);
}
// Fetch the same item again many times. We should always get the same
// pointer since this client is already holding onto it
for (int32_t i = 0; i < 1000; ++i) {
const UCTMultiThreadItem *item = NULL;
fCache->get(
LocaleCacheKey<UCTMultiThreadItem>(locale), fCache, item, status);
if (item != origItem) {
IntlTest::gTest->errln(
"%s:%d Expected to get the same pointer",
__FILE__,
__LINE__);
}
if (item != NULL) {
item->removeRef();
}
}
origItem->removeRef();
}
void UnifiedCacheThread::run() {
// Run the exercise with 2 different locales so that we can exercise
// eviction more. If each thread exercises just one locale, then
// eviction can't start until the threads end.
exerciseByLocale(fLoc);
exerciseByLocale(fLoc2);
}
void MultithreadTest::TestUnifiedCache() {
// Start with our own local cache so that we have complete control
// and set the eviction policy to evict starting with 2 unused
// values
UErrorCode status = U_ZERO_ERROR;
UnifiedCache::getInstance(status);
UnifiedCache cache(status);
cache.setEvictionPolicy(2, 0, status);
U_ASSERT(U_SUCCESS(status));
gFinishedThreads = 0;
gObjectsCreated = 0;
UnifiedCacheThread *threads[CACHE_LOAD][UPRV_LENGTHOF(gCacheLocales)];
for (int32_t i=0; i<CACHE_LOAD; ++i) {
for (int32_t j=0; j<UPRV_LENGTHOF(gCacheLocales); ++j) {
// Each thread works with a pair of locales.
threads[i][j] = new UnifiedCacheThread(
&cache, gCacheLocales[j], gCacheLocales2[j]);
threads[i][j]->start();
}
}
for (int32_t i=0; i<CACHE_LOAD; ++i) {
for (int32_t j=0; j<UPRV_LENGTHOF(gCacheLocales); ++j) {
threads[i][j]->join();
}
}
// Because of cache eviction, we can't assert exactly how many
// distinct objects get created over the course of this run.
// However we know that at least 8 objects get created because that
// is how many distinct languages we have in our test.
if (gObjectsCreated < 8) {
errln("%s:%d Too few objects created.", __FILE__, __LINE__);
}
// We know that each thread cannot create more than 2 objects in
// the cache, and there are UPRV_LENGTHOF(gCacheLocales) pairs of
// objects fetched from the cache. If the threads run in series because
// of eviction, at worst case each thread creates two objects.
if (gObjectsCreated > 2 * CACHE_LOAD * UPRV_LENGTHOF(gCacheLocales)) {
errln("%s:%d Too many objects created, got %d, expected %d", __FILE__, __LINE__, gObjectsCreated, 2 * CACHE_LOAD * UPRV_LENGTHOF(gCacheLocales));
}
assertEquals("unused values", 2, cache.unusedCount());
// clean up threads
for (int32_t i=0; i<CACHE_LOAD; ++i) {
for (int32_t j=0; j<UPRV_LENGTHOF(gCacheLocales); ++j) {
delete threads[i][j];
}
}
}
#if !UCONFIG_NO_TRANSLITERATION
//
// BreakTransliterator Threading Test
// This is a test for bug #11603. Test verified to fail prior to fix.
//
static const Transliterator *gSharedTransliterator;
static const UnicodeString *gTranslitInput;
static const UnicodeString *gTranslitExpected;
class BreakTranslitThread: public SimpleThread {
public:
BreakTranslitThread() {};
~BreakTranslitThread() {};
void run();
};
void BreakTranslitThread::run() {
for (int i=0; i<10; i++) {
icu::UnicodeString s(*gTranslitInput);
gSharedTransliterator->transliterate(s);
if (*gTranslitExpected != s) {
IntlTest::gTest->errln("%s:%d Transliteration threading failure.", __FILE__, __LINE__);
break;
}
}
}
void MultithreadTest::TestBreakTranslit() {
UErrorCode status = U_ZERO_ERROR;
UnicodeString input(
"\\u0E42\\u0E14\\u0E22\\u0E1E\\u0E37\\u0E49\\u0E19\\u0E10\\u0E32\\u0E19\\u0E41\\u0E25\\u0E49\\u0E27,");
input = input.unescape();
gTranslitInput = &input;
gSharedTransliterator = Transliterator::createInstance(
UNICODE_STRING_SIMPLE("Any-Latin; Lower; NFD; [:Diacritic:]Remove; NFC; Latin-ASCII;"), UTRANS_FORWARD, status);
if (!gSharedTransliterator) {
return;
}
TSMTHREAD_ASSERT_SUCCESS(status);
UnicodeString expected(*gTranslitInput);
gSharedTransliterator->transliterate(expected);
gTranslitExpected = &expected;
BreakTranslitThread threads[4];
for (int i=0; i<UPRV_LENGTHOF(threads); ++i) {
threads[i].start();
}
for (int i=0; i<UPRV_LENGTHOF(threads); ++i) {
threads[i].join();
}
delete gSharedTransliterator;
gTranslitInput = NULL;
gTranslitExpected = NULL;
}
class TestIncDecThread : public SimpleThread {
public:
TestIncDecThread() { };
virtual void run();
};
static u_atomic_int32_t gIncDecCounter;
void TestIncDecThread::run() {
umtx_atomic_inc(&gIncDecCounter);
for (int32_t i=0; i<5000000; ++i) {
umtx_atomic_inc(&gIncDecCounter);
umtx_atomic_dec(&gIncDecCounter);
}
}
void MultithreadTest::TestIncDec()
{
static constexpr int NUM_THREADS = 4;
gIncDecCounter = 0;
TestIncDecThread threads[NUM_THREADS];
for (auto &thread:threads) {
thread.start();
}
for (auto &thread:threads) {
thread.join();
}
assertEquals("TestIncDec", NUM_THREADS, gIncDecCounter);
}
#if !UCONFIG_NO_FORMATTING
static Calendar *gSharedCalendar = {};
class Test20104Thread : public SimpleThread {
public:
Test20104Thread() { };
virtual void run();
};
void Test20104Thread::run() {
gSharedCalendar->defaultCenturyStartYear();
}
void MultithreadTest::Test20104() {
UErrorCode status = U_ZERO_ERROR;
Locale loc("hi_IN");
gSharedCalendar = new IndianCalendar(loc, status);
assertSuccess("Test20104", status);
static constexpr int NUM_THREADS = 4;
Test20104Thread threads[NUM_THREADS];
for (auto &thread:threads) {
thread.start();
}
for (auto &thread:threads) {
thread.join();
}
delete gSharedCalendar;
// Note: failure is reported by Thread Sanitizer. Test itself succeeds.
}
#endif /* !UCONFIG_NO_FORMATTING */
#endif /* !UCONFIG_NO_TRANSLITERATION */