scuffed-code/icu4c/source/test/intltest/numbertest_decimalquantity.cpp
2020-03-06 01:34:51 -08:00

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// © 2017 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
#include "unicode/utypes.h"
#if !UCONFIG_NO_FORMATTING
#include "number_decimalquantity.h"
#include "number_decnum.h"
#include "math.h"
#include <cmath>
#include "number_utils.h"
#include "numbertest.h"
void DecimalQuantityTest::runIndexedTest(int32_t index, UBool exec, const char *&name, char *) {
if (exec) {
logln("TestSuite DecimalQuantityTest: ");
}
TESTCASE_AUTO_BEGIN;
TESTCASE_AUTO(testDecimalQuantityBehaviorStandalone);
TESTCASE_AUTO(testSwitchStorage);
TESTCASE_AUTO(testCopyMove);
TESTCASE_AUTO(testAppend);
if (!quick) {
// Slow test: run in exhaustive mode only
TESTCASE_AUTO(testConvertToAccurateDouble);
}
TESTCASE_AUTO(testUseApproximateDoubleWhenAble);
TESTCASE_AUTO(testHardDoubleConversion);
TESTCASE_AUTO(testToDouble);
TESTCASE_AUTO(testMaxDigits);
TESTCASE_AUTO(testNickelRounding);
TESTCASE_AUTO(testCompactDecimalSuppressedExponent);
TESTCASE_AUTO(testSuppressedExponentUnchangedByInitialScaling);
TESTCASE_AUTO_END;
}
void DecimalQuantityTest::assertDoubleEquals(UnicodeString message, double a, double b) {
if (a == b) {
return;
}
double diff = a - b;
diff = diff < 0 ? -diff : diff;
double bound = a < 0 ? -a * 1e-6 : a * 1e-6;
if (diff > bound) {
errln(message + u": " + DoubleToUnicodeString(a) + u" vs " + DoubleToUnicodeString(b) + u" differ by " + DoubleToUnicodeString(diff));
}
}
void DecimalQuantityTest::assertHealth(const DecimalQuantity &fq) {
const char16_t* health = fq.checkHealth();
if (health != nullptr) {
errln(UnicodeString(u"HEALTH FAILURE: ") + UnicodeString(health) + u": " + fq.toString());
}
}
void
DecimalQuantityTest::assertToStringAndHealth(const DecimalQuantity &fq, const UnicodeString &expected) {
UnicodeString actual = fq.toString();
assertEquals("DecimalQuantity toString failed", expected, actual);
assertHealth(fq);
}
void DecimalQuantityTest::checkDoubleBehavior(double d, bool explicitRequired) {
DecimalQuantity fq;
fq.setToDouble(d);
if (explicitRequired) {
assertTrue("Should be using approximate double", !fq.isExplicitExactDouble());
}
UnicodeString baseStr = fq.toString();
fq.roundToInfinity();
UnicodeString newStr = fq.toString();
if (explicitRequired) {
assertTrue("Should not be using approximate double", fq.isExplicitExactDouble());
}
assertDoubleEquals(
UnicodeString(u"After conversion to exact BCD (double): ") + baseStr + u" vs " + newStr,
d, fq.toDouble());
}
void DecimalQuantityTest::testDecimalQuantityBehaviorStandalone() {
UErrorCode status = U_ZERO_ERROR;
DecimalQuantity fq;
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 0E0>");
fq.setToInt(51423);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 51423E0>");
fq.adjustMagnitude(-3);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 51423E-3>");
fq.setToLong(90909090909000L);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 90909090909E3>");
fq.setMinInteger(2);
fq.applyMaxInteger(5);
assertToStringAndHealth(fq, u"<DecimalQuantity 2:0 long 9E3>");
fq.setMinFraction(3);
assertToStringAndHealth(fq, u"<DecimalQuantity 2:-3 long 9E3>");
fq.setToDouble(987.654321);
assertToStringAndHealth(fq, u"<DecimalQuantity 2:-3 long 987654321E-6>");
fq.roundToInfinity();
assertToStringAndHealth(fq, u"<DecimalQuantity 2:-3 long 987654321E-6>");
fq.roundToIncrement(0.005, RoundingMode::UNUM_ROUND_HALFEVEN, status);
assertSuccess("Rounding to increment", status);
assertToStringAndHealth(fq, u"<DecimalQuantity 2:-3 long 987655E-3>");
fq.roundToMagnitude(-2, RoundingMode::UNUM_ROUND_HALFEVEN, status);
assertSuccess("Rounding to magnitude", status);
assertToStringAndHealth(fq, u"<DecimalQuantity 2:-3 long 98766E-2>");
}
void DecimalQuantityTest::testSwitchStorage() {
UErrorCode status = U_ZERO_ERROR;
DecimalQuantity fq;
fq.setToLong(1234123412341234L);
assertFalse("Should not be using byte array", fq.isUsingBytes());
assertEquals("Failed on initialize", u"1.234123412341234E+15", fq.toScientificString());
assertHealth(fq);
// Long -> Bytes
fq.appendDigit(5, 0, true);
assertTrue("Should be using byte array", fq.isUsingBytes());
assertEquals("Failed on multiply", u"1.2341234123412345E+16", fq.toScientificString());
assertHealth(fq);
// Bytes -> Long
fq.roundToMagnitude(5, RoundingMode::UNUM_ROUND_HALFEVEN, status);
assertSuccess("Rounding to magnitude", status);
assertFalse("Should not be using byte array", fq.isUsingBytes());
assertEquals("Failed on round", u"1.23412341234E+16", fq.toScientificString());
assertHealth(fq);
// Bytes with popFromLeft
fq.setToDecNumber({"999999999999999999"}, status);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 bytes 999999999999999999E0>");
fq.applyMaxInteger(17);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 bytes 99999999999999999E0>");
fq.applyMaxInteger(16);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 9999999999999999E0>");
fq.applyMaxInteger(15);
assertToStringAndHealth(fq, u"<DecimalQuantity 0:0 long 999999999999999E0>");
}
void DecimalQuantityTest::testCopyMove() {
// Small numbers (fits in BCD long)
{
DecimalQuantity a;
a.setToLong(1234123412341234L);
DecimalQuantity b = a; // copy constructor
assertToStringAndHealth(a, u"<DecimalQuantity 0:0 long 1234123412341234E0>");
assertToStringAndHealth(b, u"<DecimalQuantity 0:0 long 1234123412341234E0>");
DecimalQuantity c(std::move(a)); // move constructor
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 long 1234123412341234E0>");
c.setToLong(54321L);
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 long 54321E0>");
c = b; // copy assignment
assertToStringAndHealth(b, u"<DecimalQuantity 0:0 long 1234123412341234E0>");
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 long 1234123412341234E0>");
b.setToLong(45678);
c.setToLong(56789);
c = std::move(b); // move assignment
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 long 45678E0>");
a = std::move(c); // move assignment to a defunct object
assertToStringAndHealth(a, u"<DecimalQuantity 0:0 long 45678E0>");
}
// Large numbers (requires byte allocation)
{
IcuTestErrorCode status(*this, "testCopyMove");
DecimalQuantity a;
a.setToDecNumber({"1234567890123456789", -1}, status);
DecimalQuantity b = a; // copy constructor
assertToStringAndHealth(a, u"<DecimalQuantity 0:0 bytes 1234567890123456789E0>");
assertToStringAndHealth(b, u"<DecimalQuantity 0:0 bytes 1234567890123456789E0>");
DecimalQuantity c(std::move(a)); // move constructor
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 bytes 1234567890123456789E0>");
c.setToDecNumber({"9876543210987654321", -1}, status);
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 bytes 9876543210987654321E0>");
c = b; // copy assignment
assertToStringAndHealth(b, u"<DecimalQuantity 0:0 bytes 1234567890123456789E0>");
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 bytes 1234567890123456789E0>");
b.setToDecNumber({"876543210987654321", -1}, status);
c.setToDecNumber({"987654321098765432", -1}, status);
c = std::move(b); // move assignment
assertToStringAndHealth(c, u"<DecimalQuantity 0:0 bytes 876543210987654321E0>");
a = std::move(c); // move assignment to a defunct object
assertToStringAndHealth(a, u"<DecimalQuantity 0:0 bytes 876543210987654321E0>");
}
}
void DecimalQuantityTest::testAppend() {
DecimalQuantity fq;
fq.appendDigit(1, 0, true);
assertEquals("Failed on append", u"1E+0", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(2, 0, true);
assertEquals("Failed on append", u"1.2E+1", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(3, 1, true);
assertEquals("Failed on append", u"1.203E+3", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(0, 1, true);
assertEquals("Failed on append", u"1.203E+5", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(4, 0, true);
assertEquals("Failed on append", u"1.203004E+6", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(0, 0, true);
assertEquals("Failed on append", u"1.203004E+7", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(5, 0, false);
assertEquals("Failed on append", u"1.20300405E+7", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(6, 0, false);
assertEquals("Failed on append", u"1.203004056E+7", fq.toScientificString());
assertHealth(fq);
fq.appendDigit(7, 3, false);
assertEquals("Failed on append", u"1.2030040560007E+7", fq.toScientificString());
assertHealth(fq);
UnicodeString baseExpected(u"1.2030040560007");
for (int i = 0; i < 10; i++) {
fq.appendDigit(8, 0, false);
baseExpected.append(u'8');
UnicodeString expected(baseExpected);
expected.append(u"E+7");
assertEquals("Failed on append", expected, fq.toScientificString());
assertHealth(fq);
}
fq.appendDigit(9, 2, false);
baseExpected.append(u"009");
UnicodeString expected(baseExpected);
expected.append(u"E+7");
assertEquals("Failed on append", expected, fq.toScientificString());
assertHealth(fq);
}
void DecimalQuantityTest::testConvertToAccurateDouble() {
// based on https://github.com/google/double-conversion/issues/28
static double hardDoubles[] = {
1651087494906221570.0,
2.207817077636718750000000000000,
1.818351745605468750000000000000,
3.941719055175781250000000000000,
3.738609313964843750000000000000,
3.967735290527343750000000000000,
1.328025817871093750000000000000,
3.920967102050781250000000000000,
1.015235900878906250000000000000,
1.335227966308593750000000000000,
1.344520568847656250000000000000,
2.879127502441406250000000000000,
3.695838928222656250000000000000,
1.845344543457031250000000000000,
3.793952941894531250000000000000,
3.211402893066406250000000000000,
2.565971374511718750000000000000,
0.965156555175781250000000000000,
2.700004577636718750000000000000,
0.767097473144531250000000000000,
1.780448913574218750000000000000,
2.624839782714843750000000000000,
1.305290222167968750000000000000,
3.834922790527343750000000000000,};
static double exactDoubles[] = {
51423,
51423e10,
-5074790912492772E-327,
83602530019752571E-327,
4.503599627370496E15,
6.789512076111555E15,
9.007199254740991E15,
9.007199254740992E15};
for (double d : hardDoubles) {
checkDoubleBehavior(d, true);
}
for (double d : exactDoubles) {
checkDoubleBehavior(d, false);
}
assertDoubleEquals(u"NaN check failed", NAN, DecimalQuantity().setToDouble(NAN).toDouble());
assertDoubleEquals(
u"Inf check failed", INFINITY, DecimalQuantity().setToDouble(INFINITY).toDouble());
assertDoubleEquals(
u"-Inf check failed", -INFINITY, DecimalQuantity().setToDouble(-INFINITY).toDouble());
// Generate random doubles
for (int32_t i = 0; i < 10000; i++) {
uint8_t bytes[8];
for (int32_t j = 0; j < 8; j++) {
bytes[j] = static_cast<uint8_t>(rand() % 256);
}
double d;
uprv_memcpy(&d, bytes, 8);
if (std::isnan(d) || !std::isfinite(d)) { continue; }
checkDoubleBehavior(d, false);
}
}
void DecimalQuantityTest::testUseApproximateDoubleWhenAble() {
static const struct TestCase {
double d;
int32_t maxFrac;
RoundingMode roundingMode;
bool usesExact;
} cases[] = {{1.2345678, 1, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.2345678, 7, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.2345678, 12, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.2345678, 13, RoundingMode::UNUM_ROUND_HALFEVEN, true},
{1.235, 1, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.235, 2, RoundingMode::UNUM_ROUND_HALFEVEN, true},
{1.235, 3, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.000000000000001, 0, RoundingMode::UNUM_ROUND_HALFEVEN, false},
{1.000000000000001, 0, RoundingMode::UNUM_ROUND_CEILING, true},
{1.235, 1, RoundingMode::UNUM_ROUND_CEILING, false},
{1.235, 2, RoundingMode::UNUM_ROUND_CEILING, false},
{1.235, 3, RoundingMode::UNUM_ROUND_CEILING, true}};
UErrorCode status = U_ZERO_ERROR;
for (TestCase cas : cases) {
DecimalQuantity fq;
fq.setToDouble(cas.d);
assertTrue("Should be using approximate double", !fq.isExplicitExactDouble());
fq.roundToMagnitude(-cas.maxFrac, cas.roundingMode, status);
assertSuccess("Rounding to magnitude", status);
if (cas.usesExact != fq.isExplicitExactDouble()) {
errln(UnicodeString(u"Using approximate double after rounding: ") + fq.toString());
}
}
}
void DecimalQuantityTest::testHardDoubleConversion() {
static const struct TestCase {
double input;
const char16_t* expectedOutput;
} cases[] = {
{ 512.0000000000017, u"512.0000000000017" },
{ 4095.9999999999977, u"4095.9999999999977" },
{ 4095.999999999998, u"4095.999999999998" },
{ 4095.9999999999986, u"4095.9999999999986" },
{ 4095.999999999999, u"4095.999999999999" },
{ 4095.9999999999995, u"4095.9999999999995" },
{ 4096.000000000001, u"4096.000000000001" },
{ 4096.000000000002, u"4096.000000000002" },
{ 4096.000000000003, u"4096.000000000003" },
{ 4096.000000000004, u"4096.000000000004" },
{ 4096.000000000005, u"4096.000000000005" },
{ 4096.0000000000055, u"4096.0000000000055" },
{ 4096.000000000006, u"4096.000000000006" },
{ 4096.000000000007, u"4096.000000000007" } };
for (auto& cas : cases) {
DecimalQuantity q;
q.setToDouble(cas.input);
q.roundToInfinity();
UnicodeString actualOutput = q.toPlainString();
assertEquals("", cas.expectedOutput, actualOutput);
}
}
void DecimalQuantityTest::testToDouble() {
IcuTestErrorCode status(*this, "testToDouble");
static const struct TestCase {
const char* input; // char* for the decNumber constructor
double expected;
} cases[] = {
{ "0", 0.0 },
{ "514.23", 514.23 },
{ "-3.142E-271", -3.142e-271 } };
for (auto& cas : cases) {
status.setScope(cas.input);
DecimalQuantity q;
q.setToDecNumber({cas.input, -1}, status);
double actual = q.toDouble();
assertEquals("Doubles should exactly equal", cas.expected, actual);
}
}
void DecimalQuantityTest::testMaxDigits() {
IcuTestErrorCode status(*this, "testMaxDigits");
DecimalQuantity dq;
dq.setToDouble(876.543);
dq.roundToInfinity();
dq.setMinInteger(0);
dq.applyMaxInteger(2);
dq.setMinFraction(0);
dq.roundToMagnitude(-2, UNUM_ROUND_FLOOR, status);
assertEquals("Should trim, toPlainString", "76.54", dq.toPlainString());
assertEquals("Should trim, toScientificString", "7.654E+1", dq.toScientificString());
assertEquals("Should trim, toLong", 76LL, dq.toLong(true));
assertEquals("Should trim, toFractionLong", (int64_t) 54, (int64_t) dq.toFractionLong(false));
assertEquals("Should trim, toDouble", 76.54, dq.toDouble());
// To test DecNum output, check the round-trip.
DecNum dn;
dq.toDecNum(dn, status);
DecimalQuantity copy;
copy.setToDecNum(dn, status);
assertEquals("Should trim, toDecNum", "76.54", copy.toPlainString());
}
void DecimalQuantityTest::testNickelRounding() {
IcuTestErrorCode status(*this, "testNickelRounding");
struct TestCase {
double input;
int32_t magnitude;
UNumberFormatRoundingMode roundingMode;
const char16_t* expected;
} cases[] = {
{1.000, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.001, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.010, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.020, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.024, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.025, -2, UNUM_ROUND_HALFEVEN, u"1"},
{1.025, -2, UNUM_ROUND_HALFDOWN, u"1"},
{1.025, -2, UNUM_ROUND_HALFUP, u"1.05"},
{1.026, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.030, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.040, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.050, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.060, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.070, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.074, -2, UNUM_ROUND_HALFEVEN, u"1.05"},
{1.075, -2, UNUM_ROUND_HALFDOWN, u"1.05"},
{1.075, -2, UNUM_ROUND_HALFUP, u"1.1"},
{1.075, -2, UNUM_ROUND_HALFEVEN, u"1.1"},
{1.076, -2, UNUM_ROUND_HALFEVEN, u"1.1"},
{1.080, -2, UNUM_ROUND_HALFEVEN, u"1.1"},
{1.090, -2, UNUM_ROUND_HALFEVEN, u"1.1"},
{1.099, -2, UNUM_ROUND_HALFEVEN, u"1.1"},
{1.999, -2, UNUM_ROUND_HALFEVEN, u"2"},
{2.25, -1, UNUM_ROUND_HALFEVEN, u"2"},
{2.25, -1, UNUM_ROUND_HALFUP, u"2.5"},
{2.75, -1, UNUM_ROUND_HALFDOWN, u"2.5"},
{2.75, -1, UNUM_ROUND_HALFEVEN, u"3"},
{3.00, -1, UNUM_ROUND_CEILING, u"3"},
{3.25, -1, UNUM_ROUND_CEILING, u"3.5"},
{3.50, -1, UNUM_ROUND_CEILING, u"3.5"},
{3.75, -1, UNUM_ROUND_CEILING, u"4"},
{4.00, -1, UNUM_ROUND_FLOOR, u"4"},
{4.25, -1, UNUM_ROUND_FLOOR, u"4"},
{4.50, -1, UNUM_ROUND_FLOOR, u"4.5"},
{4.75, -1, UNUM_ROUND_FLOOR, u"4.5"},
{5.00, -1, UNUM_ROUND_UP, u"5"},
{5.25, -1, UNUM_ROUND_UP, u"5.5"},
{5.50, -1, UNUM_ROUND_UP, u"5.5"},
{5.75, -1, UNUM_ROUND_UP, u"6"},
{6.00, -1, UNUM_ROUND_DOWN, u"6"},
{6.25, -1, UNUM_ROUND_DOWN, u"6"},
{6.50, -1, UNUM_ROUND_DOWN, u"6.5"},
{6.75, -1, UNUM_ROUND_DOWN, u"6.5"},
{7.00, -1, UNUM_ROUND_UNNECESSARY, u"7"},
{7.50, -1, UNUM_ROUND_UNNECESSARY, u"7.5"},
};
for (const auto& cas : cases) {
UnicodeString message = DoubleToUnicodeString(cas.input) + u" @ " + Int64ToUnicodeString(cas.magnitude) + u" / " + Int64ToUnicodeString(cas.roundingMode);
status.setScope(message);
DecimalQuantity dq;
dq.setToDouble(cas.input);
dq.roundToNickel(cas.magnitude, cas.roundingMode, status);
status.errIfFailureAndReset();
UnicodeString actual = dq.toPlainString();
assertEquals(message, cas.expected, actual);
}
status.setScope("");
DecimalQuantity dq;
dq.setToDouble(7.1);
dq.roundToNickel(-1, UNUM_ROUND_UNNECESSARY, status);
status.expectErrorAndReset(U_FORMAT_INEXACT_ERROR);
}
void DecimalQuantityTest::testCompactDecimalSuppressedExponent() {
IcuTestErrorCode status(*this, "testCompactDecimalSuppressedExponent");
Locale ulocale("fr-FR");
struct TestCase {
UnicodeString skeleton;
double input;
const char16_t* expectedString;
int64_t expectedLong;
double expectedDouble;
const char16_t* expectedPlainString;
int32_t expectedSuppressedExponent;
} cases[] = {
// unlocalized formatter skeleton, input, string output, long output, double output, BigDecimal output, plain string, suppressed exponent
{u"", 123456789, u"123456789", 123456789L, 123456789.0, u"123456789", 0},
{u"compact-long", 123456789, u"123 millions", 123000000L, 123000000.0, u"123000000", 6},
{u"compact-short", 123456789, u"123 M", 123000000L, 123000000.0, u"123000000", 6},
{u"scientific", 123456789, u"1,234568E8", 123456800L, 123456800.0, u"123456800", 8},
{u"", 1234567, u"1234567", 1234567L, 1234567.0, u"1234567", 0},
{u"compact-long", 1234567, u"1,2 million", 1200000L, 1200000.0, u"1200000", 6},
{u"compact-short", 1234567, u"1,2 M", 1200000L, 1200000.0, u"1200000", 6},
{u"scientific", 1234567, u"1,234567E6", 1234567L, 1234567.0, u"1234567", 6},
{u"", 123456, u"123456", 123456L, 123456.0, u"123456", 0},
{u"compact-long", 123456, u"123 mille", 123000L, 123000.0, u"123000", 3},
{u"compact-short", 123456, u"123 k", 123000L, 123000.0, u"123000", 3},
{u"scientific", 123456, u"1,23456E5", 123456L, 123456.0, u"123456", 5},
{u"", 123, u"123", 123L, 123.0, u"123", 0},
{u"compact-long", 123, u"123", 123L, 123.0, u"123", 0},
{u"compact-short", 123, u"123", 123L, 123.0, u"123", 0},
{u"scientific", 123, u"1,23E2", 123L, 123.0, u"123", 2},
{u"", 1.2, u"1,2", 1L, 1.2, u"1.2", 0},
{u"compact-long", 1.2, u"1,2", 1L, 1.2, u"1.2", 0},
{u"compact-short", 1.2, u"1,2", 1L, 1.2, u"1.2", 0},
{u"scientific", 1.2, u"1,2E0", 1L, 1.2, u"1.2", 0},
{u"", 0.12, u"0,12", 0L, 0.12, u"0.12", 0},
{u"compact-long", 0.12, u"0,12", 0L, 0.12, u"0.12", 0},
{u"compact-short", 0.12, u"0,12", 0L, 0.12, u"0.12", 0},
{u"scientific", 0.12, u"1,2E-1", 0L, 0.12, u"0.12", -1},
{u"", 0.012, u"0,012", 0L, 0.012, u"0.012", 0},
{u"compact-long", 0.012, u"0,012", 0L, 0.012, u"0.012", 0},
{u"compact-short", 0.012, u"0,012", 0L, 0.012, u"0.012", 0},
{u"scientific", 0.012, u"1,2E-2", 0L, 0.012, u"0.012", -2},
{u"", 999.9, u"999,9", 999L, 999.9, u"999.9", 0},
{u"compact-long", 999.9, u"1 millier", 1000L, 1000.0, u"1000", 3},
{u"compact-short", 999.9, u"1 k", 1000L, 1000.0, u"1000", 3},
{u"scientific", 999.9, u"9,999E2", 999L, 999.9, u"999.9", 2},
{u"", 1000.0, u"1000", 1000L, 1000.0, u"1000", 0},
{u"compact-long", 1000.0, u"1 millier", 1000L, 1000.0, u"1000", 3},
{u"compact-short", 1000.0, u"1 k", 1000L, 1000.0, u"1000", 3},
{u"scientific", 1000.0, u"1E3", 1000L, 1000.0, u"1000", 3},
};
for (const auto& cas : cases) {
// test the helper methods used to compute plural operand values
LocalizedNumberFormatter formatter =
NumberFormatter::forSkeleton(cas.skeleton, status)
.locale(ulocale);
FormattedNumber fn = formatter.formatDouble(cas.input, status);
DecimalQuantity dq;
fn.getDecimalQuantity(dq, status);
UnicodeString actualString = fn.toString(status);
int64_t actualLong = dq.toLong();
double actualDouble = dq.toDouble();
UnicodeString actualPlainString = dq.toPlainString();
int32_t actualSuppressedExponent = dq.getExponent();
assertEquals(
u"formatted number " + cas.skeleton + u" toString: " + cas.input,
cas.expectedString,
actualString);
assertEquals(
u"compact decimal " + cas.skeleton + u" toLong: " + cas.input,
cas.expectedLong,
actualLong);
assertDoubleEquals(
u"compact decimal " + cas.skeleton + u" toDouble: " + cas.input,
cas.expectedDouble,
actualDouble);
assertEquals(
u"formatted number " + cas.skeleton + u" toPlainString: " + cas.input,
cas.expectedPlainString,
actualPlainString);
assertEquals(
u"compact decimal " + cas.skeleton + u" suppressed exponent: " + cas.input,
cas.expectedSuppressedExponent,
actualSuppressedExponent);
// test the actual computed values of the plural operands
double expectedNOperand = cas.expectedDouble;
double expectedIOperand = cas.expectedLong;
double expectedEOperand = cas.expectedSuppressedExponent;
double actualNOperand = dq.getPluralOperand(PLURAL_OPERAND_N);
double actualIOperand = dq.getPluralOperand(PLURAL_OPERAND_I);
double actualEOperand = dq.getPluralOperand(PLURAL_OPERAND_E);
assertEquals(
u"formatted number " + cas.skeleton + u" toString: " + cas.input,
cas.expectedString,
actualString);
assertDoubleEquals(
u"compact decimal " + cas.skeleton + u" n operand: " + cas.input,
expectedNOperand,
actualNOperand);
assertDoubleEquals(
u"compact decimal " + cas.skeleton + u" i operand: " + cas.input,
expectedIOperand,
actualIOperand);
assertDoubleEquals(
u"compact decimal " + cas.skeleton + " e operand: " + cas.input,
expectedEOperand,
actualEOperand);
}
}
void DecimalQuantityTest::testSuppressedExponentUnchangedByInitialScaling() {
IcuTestErrorCode status(*this, "testCompactDecimalSuppressedExponent");
Locale ulocale("fr-FR");
LocalizedNumberFormatter withLocale = NumberFormatter::withLocale(ulocale);
LocalizedNumberFormatter compactLong =
withLocale.notation(Notation::compactLong());
LocalizedNumberFormatter compactScaled =
compactLong.scale(Scale::powerOfTen(3));
struct TestCase {
int32_t input;
UnicodeString expectedString;
double expectedNOperand;
double expectedIOperand;
double expectedEOperand;
} cases[] = {
// input, compact long string output,
// compact n operand, compact i operand, compact e operand
{123456789, "123 millions", 123000000.0, 123000000.0, 6.0},
{1234567, "1,2 million", 1200000.0, 1200000.0, 6.0},
{123456, "123 mille", 123000.0, 123000.0, 3.0},
{123, "123", 123.0, 123.0, 0.0},
};
for (const auto& cas : cases) {
FormattedNumber fnCompactScaled = compactScaled.formatInt(cas.input, status);
DecimalQuantity dqCompactScaled;
fnCompactScaled.getDecimalQuantity(dqCompactScaled, status);
double compactScaledEOperand = dqCompactScaled.getPluralOperand(PLURAL_OPERAND_E);
FormattedNumber fnCompact = compactLong.formatInt(cas.input, status);
DecimalQuantity dqCompact;
fnCompact.getDecimalQuantity(dqCompact, status);
UnicodeString actualString = fnCompact.toString(status);
double compactNOperand = dqCompact.getPluralOperand(PLURAL_OPERAND_N);
double compactIOperand = dqCompact.getPluralOperand(PLURAL_OPERAND_I);
double compactEOperand = dqCompact.getPluralOperand(PLURAL_OPERAND_E);
assertEquals(
u"formatted number " + Int64ToUnicodeString(cas.input) + " compactLong toString: ",
cas.expectedString,
actualString);
assertDoubleEquals(
u"compact decimal " + DoubleToUnicodeString(cas.input) + ", n operand vs. expected",
cas.expectedNOperand,
compactNOperand);
assertDoubleEquals(
u"compact decimal " + DoubleToUnicodeString(cas.input) + ", i operand vs. expected",
cas.expectedIOperand,
compactIOperand);
assertDoubleEquals(
u"compact decimal " + DoubleToUnicodeString(cas.input) + ", e operand vs. expected",
cas.expectedEOperand,
compactEOperand);
// By scaling by 10^3 in a locale that has words / compact notation
// based on powers of 10^3, we guarantee that the suppressed
// exponent will differ by 3.
assertDoubleEquals(
u"decimal " + DoubleToUnicodeString(cas.input) + ", e operand for compact vs. compact scaled",
compactEOperand + 3,
compactScaledEOperand);
}
}
#endif /* #if !UCONFIG_NO_FORMATTING */