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unplugged-vendor/external/libtextclassifier/native/utils/utf8/unilib_test-include.cc

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Initial commit: AOSP 12 vendor with modifications for Unplugged OS
2025-10-06 13:59:42 +00:00
/*
* Copyright (C) 2018 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "utils/utf8/unilib_test-include.h"
#include "utils/base/logging.h"
#include "gmock/gmock.h"
namespace libtextclassifier3 {
namespace test_internal {
using ::testing::ElementsAre;
TEST_F(UniLibTest, CharacterClassesAscii) {
EXPECT_TRUE(unilib_->IsOpeningBracket('('));
EXPECT_TRUE(unilib_->IsClosingBracket(')'));
EXPECT_FALSE(unilib_->IsWhitespace(')'));
EXPECT_TRUE(unilib_->IsWhitespace(' '));
EXPECT_FALSE(unilib_->IsDigit(')'));
EXPECT_TRUE(unilib_->IsDigit('0'));
EXPECT_TRUE(unilib_->IsDigit('9'));
EXPECT_FALSE(unilib_->IsUpper(')'));
EXPECT_TRUE(unilib_->IsUpper('A'));
EXPECT_TRUE(unilib_->IsUpper('Z'));
EXPECT_FALSE(unilib_->IsLower(')'));
EXPECT_TRUE(unilib_->IsLower('a'));
EXPECT_TRUE(unilib_->IsLower('z'));
EXPECT_TRUE(unilib_->IsPunctuation('!'));
EXPECT_TRUE(unilib_->IsPunctuation('?'));
EXPECT_TRUE(unilib_->IsPunctuation('#'));
EXPECT_TRUE(unilib_->IsPunctuation('('));
EXPECT_FALSE(unilib_->IsPunctuation('0'));
EXPECT_FALSE(unilib_->IsPunctuation('$'));
EXPECT_TRUE(unilib_->IsPercentage('%'));
EXPECT_TRUE(unilib_->IsPercentage(u''));
EXPECT_TRUE(unilib_->IsSlash('/'));
EXPECT_TRUE(unilib_->IsSlash(u''));
EXPECT_TRUE(unilib_->IsMinus('-'));
EXPECT_TRUE(unilib_->IsMinus(u''));
EXPECT_TRUE(unilib_->IsNumberSign('#'));
EXPECT_TRUE(unilib_->IsNumberSign(u''));
EXPECT_TRUE(unilib_->IsDot('.'));
EXPECT_TRUE(unilib_->IsDot(u''));
EXPECT_TRUE(unilib_->IsApostrophe('\''));
EXPECT_TRUE(unilib_->IsApostrophe(u'ߴ'));
EXPECT_TRUE(unilib_->IsQuotation(u'"'));
EXPECT_TRUE(unilib_->IsQuotation(u''));
EXPECT_TRUE(unilib_->IsAmpersand(u'&'));
EXPECT_TRUE(unilib_->IsAmpersand(u''));
EXPECT_TRUE(unilib_->IsAmpersand(u''));
EXPECT_TRUE(unilib_->IsLatinLetter('A'));
EXPECT_TRUE(unilib_->IsArabicLetter(u'ب')); // ARABIC LETTER BEH
EXPECT_TRUE(
unilib_->IsCyrillicLetter(u'')); // CYRILLIC SMALL LETTER ROUNDED VE
EXPECT_TRUE(unilib_->IsChineseLetter(u'')); // CJK COMPATIBILITY IDEOGRAPH
EXPECT_TRUE(unilib_->IsJapaneseLetter(u'')); // HIRAGANA LETTER SMALL A
EXPECT_TRUE(unilib_->IsKoreanLetter(u'')); // HANGUL LETTER KIYEOK
EXPECT_TRUE(unilib_->IsThaiLetter(u'')); // THAI CHARACTER KO KAI
EXPECT_TRUE(unilib_->IsCJTletter(u'')); // THAI CHARACTER KO KAI
EXPECT_FALSE(unilib_->IsCJTletter('A'));
EXPECT_TRUE(unilib_->IsLetter('A'));
EXPECT_TRUE(unilib_->IsLetter(u''));
EXPECT_TRUE(unilib_->IsLetter(u'')); // KATAKANA LETTER TO
EXPECT_TRUE(unilib_->IsLetter(u'')); // HALFWIDTH KATAKANA LETTER TO
EXPECT_TRUE(unilib_->IsLetter(u'')); // CJK COMPATIBILITY IDEOGRAPH
EXPECT_EQ(unilib_->ToLower('A'), 'a');
EXPECT_EQ(unilib_->ToLower('Z'), 'z');
EXPECT_EQ(unilib_->ToLower(')'), ')');
EXPECT_EQ(unilib_->ToLowerText(UTF8ToUnicodeText("Never gonna give you up."))
.ToUTF8String(),
"never gonna give you up.");
EXPECT_EQ(unilib_->ToUpper('a'), 'A');
EXPECT_EQ(unilib_->ToUpper('z'), 'Z');
EXPECT_EQ(unilib_->ToUpper(')'), ')');
EXPECT_EQ(unilib_->ToUpperText(UTF8ToUnicodeText("Never gonna let you down."))
.ToUTF8String(),
"NEVER GONNA LET YOU DOWN.");
EXPECT_EQ(unilib_->GetPairedBracket(')'), '(');
EXPECT_EQ(unilib_->GetPairedBracket('}'), '{');
}
TEST_F(UniLibTest, CharacterClassesUnicode) {
EXPECT_TRUE(unilib_->IsOpeningBracket(0x0F3C)); // TIBET ANG KHANG GYON
EXPECT_TRUE(unilib_->IsClosingBracket(0x0F3D)); // TIBET ANG KHANG GYAS
EXPECT_FALSE(unilib_->IsWhitespace(0x23F0)); // ALARM CLOCK
EXPECT_TRUE(unilib_->IsWhitespace(0x2003)); // EM SPACE
EXPECT_FALSE(unilib_->IsDigit(0xA619)); // VAI SYMBOL JONG
EXPECT_TRUE(unilib_->IsDigit(0xA620)); // VAI DIGIT ZERO
EXPECT_TRUE(unilib_->IsDigit(0xA629)); // VAI DIGIT NINE
EXPECT_FALSE(unilib_->IsDigit(0xA62A)); // VAI SYLLABLE NDOLE MA
EXPECT_FALSE(unilib_->IsUpper(0x0211)); // SMALL R WITH DOUBLE GRAVE
EXPECT_TRUE(unilib_->IsUpper(0x0212)); // CAPITAL R WITH DOUBLE GRAVE
EXPECT_TRUE(unilib_->IsUpper(0x0391)); // GREEK CAPITAL ALPHA
EXPECT_TRUE(unilib_->IsUpper(0x03AB)); // GREEK CAPITAL UPSILON W DIAL
EXPECT_FALSE(unilib_->IsUpper(0x03AC)); // GREEK SMALL ALPHA WITH TONOS
EXPECT_TRUE(unilib_->IsLower(0x03AC)); // GREEK SMALL ALPHA WITH TONOS
EXPECT_TRUE(unilib_->IsLower(0x03B1)); // GREEK SMALL ALPHA
EXPECT_TRUE(unilib_->IsLower(0x03CB)); // GREEK SMALL UPSILON
EXPECT_TRUE(unilib_->IsLower(0x0211)); // SMALL R WITH DOUBLE GRAVE
EXPECT_TRUE(unilib_->IsLower(0x03C0)); // GREEK SMALL PI
EXPECT_TRUE(unilib_->IsLower(0x007A)); // SMALL Z
EXPECT_FALSE(unilib_->IsLower(0x005A)); // CAPITAL Z
EXPECT_FALSE(unilib_->IsLower(0x0212)); // CAPITAL R WITH DOUBLE GRAVE
EXPECT_FALSE(unilib_->IsLower(0x0391)); // GREEK CAPITAL ALPHA
EXPECT_TRUE(unilib_->IsPunctuation(0x055E)); // ARMENIAN QUESTION MARK
EXPECT_TRUE(unilib_->IsPunctuation(0x066C)); // ARABIC THOUSANDS SEPARATOR
EXPECT_TRUE(unilib_->IsPunctuation(0x07F7)); // NKO SYMBOL GBAKURUNEN
EXPECT_TRUE(unilib_->IsPunctuation(0x10AF2)); // DOUBLE DOT WITHIN DOT
EXPECT_FALSE(unilib_->IsPunctuation(0x00A3)); // POUND SIGN
EXPECT_FALSE(unilib_->IsPunctuation(0xA838)); // NORTH INDIC RUPEE MARK
EXPECT_TRUE(unilib_->IsPercentage(0x0025)); // PERCENT SIGN
EXPECT_TRUE(unilib_->IsPercentage(0xFF05)); // FULLWIDTH PERCENT SIGN
EXPECT_TRUE(unilib_->IsSlash(0x002F)); // SOLIDUS
EXPECT_TRUE(unilib_->IsSlash(0xFF0F)); // FULLWIDTH SOLIDUS
EXPECT_TRUE(unilib_->IsMinus(0x002D)); // HYPHEN-MINUS
EXPECT_TRUE(unilib_->IsMinus(0xFF0D)); // FULLWIDTH HYPHEN-MINUS
EXPECT_TRUE(unilib_->IsNumberSign(0x0023)); // NUMBER SIGN
EXPECT_TRUE(unilib_->IsNumberSign(0xFF03)); // FULLWIDTH NUMBER SIGN
EXPECT_TRUE(unilib_->IsDot(0x002E)); // FULL STOP
EXPECT_TRUE(unilib_->IsDot(0xFF0E)); // FULLWIDTH FULL STOP
EXPECT_TRUE(unilib_->IsLatinLetter(0x0041)); // LATIN CAPITAL LETTER A
EXPECT_TRUE(unilib_->IsArabicLetter(0x0628)); // ARABIC LETTER BEH
EXPECT_TRUE(
unilib_->IsCyrillicLetter(0x1C80)); // CYRILLIC SMALL LETTER ROUNDED VE
EXPECT_TRUE(unilib_->IsChineseLetter(0xF900)); // CJK COMPATIBILITY IDEOGRAPH
EXPECT_TRUE(unilib_->IsJapaneseLetter(0x3041)); // HIRAGANA LETTER SMALL A
EXPECT_TRUE(unilib_->IsKoreanLetter(0x3131)); // HANGUL LETTER KIYEOK
EXPECT_TRUE(unilib_->IsThaiLetter(0x0E01)); // THAI CHARACTER KO KAI
EXPECT_TRUE(unilib_->IsCJTletter(0x0E01)); // THAI CHARACTER KO KAI
EXPECT_FALSE(unilib_->IsCJTletter(0x0041)); // LATIN CAPITAL LETTER A
EXPECT_TRUE(unilib_->IsLetter(0x0041)); // LATIN CAPITAL LETTER A
EXPECT_TRUE(unilib_->IsLetter(0xFF21)); // FULLWIDTH LATIN CAPITAL LETTER A
EXPECT_TRUE(unilib_->IsLetter(0x30C8)); // KATAKANA LETTER TO
EXPECT_TRUE(unilib_->IsLetter(0xFF84)); // HALFWIDTH KATAKANA LETTER TO
EXPECT_TRUE(unilib_->IsLetter(0xF900)); // CJK COMPATIBILITY IDEOGRAPH
EXPECT_EQ(unilib_->ToLower(0x0391), 0x03B1); // GREEK ALPHA
EXPECT_EQ(unilib_->ToLower(0x03AB), 0x03CB); // GREEK UPSILON WITH DIALYTIKA
EXPECT_EQ(unilib_->ToLower(0x03C0), 0x03C0); // GREEK SMALL PI
EXPECT_EQ(unilib_->ToLower(0x03A3), 0x03C3); // GREEK CAPITAL LETTER SIGMA
EXPECT_EQ(
unilib_->ToLowerText(UTF8ToUnicodeText("Κανένας άνθρωπος δεν ξέρει"))
.ToUTF8String(),
"κανένας άνθρωπος δεν ξέρει");
EXPECT_TRUE(unilib_->IsLowerText(UTF8ToUnicodeText("ξέρει")));
EXPECT_EQ(unilib_->ToUpper(0x03B1), 0x0391); // GREEK ALPHA
EXPECT_EQ(unilib_->ToUpper(0x03CB), 0x03AB); // GREEK UPSILON WITH DIALYTIKA
EXPECT_EQ(unilib_->ToUpper(0x0391), 0x0391); // GREEK CAPITAL ALPHA
EXPECT_EQ(unilib_->ToUpper(0x03C3), 0x03A3); // GREEK CAPITAL LETTER SIGMA
EXPECT_EQ(unilib_->ToUpper(0x03C2), 0x03A3); // GREEK CAPITAL LETTER SIGMA
EXPECT_EQ(
unilib_->ToUpperText(UTF8ToUnicodeText("Κανένας άνθρωπος δεν ξέρει"))
.ToUTF8String(),
"ΚΑΝΈΝΑΣ ΆΝΘΡΩΠΟΣ ΔΕΝ ΞΈΡΕΙ");
EXPECT_TRUE(unilib_->IsUpperText(UTF8ToUnicodeText("ΚΑΝΈΝΑΣ")));
EXPECT_EQ(unilib_->GetPairedBracket(0x0F3C), 0x0F3D);
EXPECT_EQ(unilib_->GetPairedBracket(0x0F3D), 0x0F3C);
}
TEST_F(UniLibTest, RegexInterface) {
const UnicodeText regex_pattern =
UTF8ToUnicodeText("[0-9]+", /*do_copy=*/true);
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateRegexPattern(regex_pattern);
const UnicodeText input = UTF8ToUnicodeText("hello 0123", /*do_copy=*/false);
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher = pattern->Matcher(input);
TC3_LOG(INFO) << matcher->Matches(&status);
TC3_LOG(INFO) << matcher->Find(&status);
TC3_LOG(INFO) << matcher->Start(0, &status);
TC3_LOG(INFO) << matcher->End(0, &status);
TC3_LOG(INFO) << matcher->Group(0, &status).size_codepoints();
}
TEST_F(UniLibTest, Regex) {
// The smiley face is a 4-byte UTF8 codepoint 0x1F60B, and it's important to
// test the regex functionality with it to verify we are handling the indices
// correctly.
const UnicodeText regex_pattern =
UTF8ToUnicodeText("[0-9]+😋", /*do_copy=*/false);
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateRegexPattern(regex_pattern);
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher;
matcher = pattern->Matcher(UTF8ToUnicodeText("0123😋", /*do_copy=*/false));
EXPECT_TRUE(matcher->Matches(&status));
EXPECT_TRUE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_TRUE(matcher->Matches(&status)); // Check that the state is reset.
EXPECT_TRUE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
matcher = pattern->Matcher(
UTF8ToUnicodeText("hello😋😋 0123😋 world", /*do_copy=*/false));
EXPECT_FALSE(matcher->Matches(&status));
EXPECT_FALSE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
matcher = pattern->Matcher(
UTF8ToUnicodeText("hello😋😋 0123😋 world", /*do_copy=*/false));
EXPECT_TRUE(matcher->Find(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Start(0, &status), 8);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->End(0, &status), 13);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(0, &status).ToUTF8String(), "0123😋");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
}
TEST_F(UniLibTest, RegexLazy) {
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateLazyRegexPattern(
UTF8ToUnicodeText("[a-z][0-9]", /*do_copy=*/false));
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher;
matcher = pattern->Matcher(UTF8ToUnicodeText("a3", /*do_copy=*/false));
EXPECT_TRUE(matcher->Matches(&status));
EXPECT_TRUE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_TRUE(matcher->Matches(&status)); // Check that the state is reset.
EXPECT_TRUE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
matcher = pattern->Matcher(UTF8ToUnicodeText("3a", /*do_copy=*/false));
EXPECT_FALSE(matcher->Matches(&status));
EXPECT_FALSE(matcher->ApproximatelyMatches(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
}
TEST_F(UniLibTest, RegexGroups) {
// The smiley face is a 4-byte UTF8 codepoint 0x1F60B, and it's important to
// test the regex functionality with it to verify we are handling the indices
// correctly.
const UnicodeText regex_pattern =
UTF8ToUnicodeText("([0-9])([0-9]+)😋", /*do_copy=*/false);
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateRegexPattern(regex_pattern);
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher;
matcher = pattern->Matcher(
UTF8ToUnicodeText("hello😋😋 0123😋 world", /*do_copy=*/false));
EXPECT_TRUE(matcher->Find(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Start(0, &status), 8);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Start(1, &status), 8);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Start(2, &status), 9);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->End(0, &status), 13);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->End(1, &status), 9);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->End(2, &status), 12);
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(0, &status).ToUTF8String(), "0123😋");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(1, &status).ToUTF8String(), "0");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(2, &status).ToUTF8String(), "123");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
}
TEST_F(UniLibTest, RegexGroupsNotAllGroupsInvolved) {
const UnicodeText regex_pattern =
UTF8ToUnicodeText("([0-9])([a-z])?", /*do_copy=*/false);
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateRegexPattern(regex_pattern);
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher;
matcher = pattern->Matcher(UTF8ToUnicodeText("7", /*do_copy=*/false));
EXPECT_TRUE(matcher->Find(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(0, &status).ToUTF8String(), "7");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(1, &status).ToUTF8String(), "7");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(2, &status).ToUTF8String(), "");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
}
TEST_F(UniLibTest, RegexGroupsEmptyResult) {
const UnicodeText regex_pattern =
UTF8ToUnicodeText("(.*)", /*do_copy=*/false);
std::unique_ptr<UniLib::RegexPattern> pattern =
unilib_->CreateRegexPattern(regex_pattern);
int status;
std::unique_ptr<UniLib::RegexMatcher> matcher;
matcher = pattern->Matcher(UTF8ToUnicodeText("", /*do_copy=*/false));
EXPECT_TRUE(matcher->Find(&status));
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(0, &status).ToUTF8String(), "");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
EXPECT_EQ(matcher->Group(1, &status).ToUTF8String(), "");
EXPECT_EQ(status, UniLib::RegexMatcher::kNoError);
}
TEST_F(UniLibTest, BreakIterator) {
const UnicodeText text = UTF8ToUnicodeText("some text", /*do_copy=*/false);
std::unique_ptr<UniLib::BreakIterator> iterator =
unilib_->CreateBreakIterator(text);
std::vector<int> break_indices;
int break_index = 0;
while ((break_index = iterator->Next()) != UniLib::BreakIterator::kDone) {
break_indices.push_back(break_index);
}
EXPECT_THAT(break_indices, ElementsAre(4, 5, 9));
}
TEST_F(UniLibTest, BreakIterator4ByteUTF8) {
const UnicodeText text = UTF8ToUnicodeText("😀😂😋", /*do_copy=*/false);
std::unique_ptr<UniLib::BreakIterator> iterator =
unilib_->CreateBreakIterator(text);
std::vector<int> break_indices;
int break_index = 0;
while ((break_index = iterator->Next()) != UniLib::BreakIterator::kDone) {
break_indices.push_back(break_index);
}
EXPECT_THAT(break_indices, ElementsAre(1, 2, 3));
}
TEST_F(UniLibTest, Integer32Parse) {
int result;
EXPECT_TRUE(unilib_->ParseInt32(UTF8ToUnicodeText("123", /*do_copy=*/false),
&result));
EXPECT_EQ(result, 123);
}
TEST_F(UniLibTest, Integer32ParseFloatNumber) {
int result;
EXPECT_FALSE(unilib_->ParseInt32(UTF8ToUnicodeText("12.3", /*do_copy=*/false),
&result));
}
TEST_F(UniLibTest, Integer32ParseLongNumber) {
int32 result;
EXPECT_TRUE(unilib_->ParseInt32(
UTF8ToUnicodeText("1000000000", /*do_copy=*/false), &result));
EXPECT_EQ(result, 1000000000);
}
TEST_F(UniLibTest, Integer32ParseOverflowNumber) {
int32 result;
EXPECT_FALSE(unilib_->ParseInt32(
UTF8ToUnicodeText("9123456789", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer32ParseEmptyString) {
int result;
EXPECT_FALSE(
unilib_->ParseInt32(UTF8ToUnicodeText("", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer32ParseFullWidth) {
int result;
// The input string here is full width
EXPECT_TRUE(unilib_->ParseInt32(
UTF8ToUnicodeText("", /*do_copy=*/false), &result));
EXPECT_EQ(result, 123);
}
TEST_F(UniLibTest, Integer32ParseNotNumber) {
int result;
// The input string here is full width
EXPECT_FALSE(unilib_->ParseInt32(
UTF8ToUnicodeText("a", /*do_copy=*/false), &result));
// Strings starting with "nan" are not numbers.
EXPECT_FALSE(unilib_->ParseInt32(UTF8ToUnicodeText("Nancy",
/*do_copy=*/false),
&result));
// Strings starting with "inf" are not numbers
EXPECT_FALSE(unilib_->ParseInt32(
UTF8ToUnicodeText("Information", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer64Parse) {
int64 result;
EXPECT_TRUE(unilib_->ParseInt64(UTF8ToUnicodeText("123", /*do_copy=*/false),
&result));
EXPECT_EQ(result, 123);
}
TEST_F(UniLibTest, Integer64ParseFloatNumber) {
int64 result;
EXPECT_FALSE(unilib_->ParseInt64(UTF8ToUnicodeText("12.3", /*do_copy=*/false),
&result));
}
TEST_F(UniLibTest, Integer64ParseLongNumber) {
int64 result;
// The limitation comes from the javaicu implementation: parseDouble does not
// have ICU support and parseInt limit the size of the number.
EXPECT_TRUE(unilib_->ParseInt64(
UTF8ToUnicodeText("1000000000", /*do_copy=*/false), &result));
EXPECT_EQ(result, 1000000000);
}
TEST_F(UniLibTest, Integer64ParseOverflowNumber) {
int64 result;
EXPECT_FALSE(unilib_->ParseInt64(
UTF8ToUnicodeText("92233720368547758099", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer64ParseOverflowNegativeNumber) {
int64 result;
EXPECT_FALSE(unilib_->ParseInt64(
UTF8ToUnicodeText("-92233720368547758099", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer64ParseEmptyString) {
int64 result;
EXPECT_FALSE(
unilib_->ParseInt64(UTF8ToUnicodeText("", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Integer64ParseFullWidth) {
int64 result;
// The input string here is full width
EXPECT_TRUE(unilib_->ParseInt64(
UTF8ToUnicodeText("", /*do_copy=*/false), &result));
EXPECT_EQ(result, 123);
}
TEST_F(UniLibTest, Integer64ParseNotNumber) {
int64 result;
// The input string here is full width
EXPECT_FALSE(unilib_->ParseInt64(
UTF8ToUnicodeText("a", /*do_copy=*/false), &result));
// Strings starting with "nan" are not numbers.
EXPECT_FALSE(unilib_->ParseInt64(UTF8ToUnicodeText("Nancy",
/*do_copy=*/false),
&result));
// Strings starting with "inf" are not numbers
EXPECT_FALSE(unilib_->ParseInt64(
UTF8ToUnicodeText("Information", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, DoubleParse) {
double result;
EXPECT_TRUE(unilib_->ParseDouble(UTF8ToUnicodeText("1.23", /*do_copy=*/false),
&result));
EXPECT_EQ(result, 1.23);
}
TEST_F(UniLibTest, DoubleParseLongNumber) {
double result;
// The limitation comes from the javaicu implementation: parseDouble does not
// have ICU support and parseInt limit the size of the number.
EXPECT_TRUE(unilib_->ParseDouble(
UTF8ToUnicodeText("999999999.999999999", /*do_copy=*/false), &result));
EXPECT_EQ(result, 999999999.999999999);
}
TEST_F(UniLibTest, DoubleParseWithoutFractionalPart) {
double result;
EXPECT_TRUE(unilib_->ParseDouble(UTF8ToUnicodeText("123", /*do_copy=*/false),
&result));
EXPECT_EQ(result, 123);
}
TEST_F(UniLibTest, DoubleParseEmptyString) {
double result;
EXPECT_FALSE(
unilib_->ParseDouble(UTF8ToUnicodeText("", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, DoubleParsePrecedingDot) {
double result;
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText(".123", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, DoubleParseLeadingDot) {
double result;
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText("123.", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, DoubleParseMultipleDots) {
double result;
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText("1.2.3", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, DoubleParseFullWidth) {
double result;
// The input string here is full width
EXPECT_TRUE(unilib_->ParseDouble(
UTF8ToUnicodeText(".", /*do_copy=*/false), &result));
EXPECT_EQ(result, 1.23);
}
TEST_F(UniLibTest, DoubleParseNotNumber) {
double result;
// The input string here is full width
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText("a", /*do_copy=*/false), &result));
// Strings starting with "nan" are not numbers.
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText("Nancy", /*do_copy=*/false), &result));
// Strings starting with "inf" are not numbers
EXPECT_FALSE(unilib_->ParseDouble(
UTF8ToUnicodeText("Information", /*do_copy=*/false), &result));
}
TEST_F(UniLibTest, Length) {
EXPECT_EQ(unilib_->Length(UTF8ToUnicodeText("hello", /*do_copy=*/false))
.ValueOrDie(),
5);
EXPECT_EQ(unilib_->Length(UTF8ToUnicodeText("ěščřž", /*do_copy=*/false))
.ValueOrDie(),
5);
// Test Invalid UTF8.
// This testing condition needs to be != 1, as Apple character counting seems
// to return 0 when the input is invalid UTF8, while ICU will treat the
// invalid codepoint as 3 separate bytes.
EXPECT_NE(
unilib_->Length(UTF8ToUnicodeText("\xed\xa0\x80", /*do_copy=*/false))
.ValueOrDie(),
1);
}
} // namespace test_internal
} // namespace libtextclassifier3
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