public void MatchCaseInsensitive_MatchAndMove()
{
var value = new ValueCursor("abcd");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.MatchCaseInsensitive("AbC", CultureInfo.InvariantCulture.CompareInfo, true));
ValidateCurrentCharacter(value, 3, 'd');
}
public void MatchCaseInsensitive_StringNotMatched()
{
var value = new ValueCursor("xabcdef");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.False(value.MatchCaseInsensitive("abc", CultureInfo.InvariantCulture.CompareInfo, true));
ValidateCurrentCharacter(value, 0, 'x');
}
public void TestMatchCaseInsensitive_string()
{
var value = new ValueCursor("abc");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.MatchCaseInsensitive("AbC", CultureInfo.InvariantCulture.CompareInfo));
Assert.False(value.MoveNext(), "GetNext() end");
}
public void Match_String()
{
var value = new ValueCursor("abc");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.Match("abc"));
Assert.False(value.MoveNext(), "GetNext() end");
}
public void Match_StringNotMatched()
{
var value = new ValueCursor("xabcdef");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.False(value.Match("abc"));
ValidateCurrentCharacter(value, 0, 'x');
}
public void Match_StringOverLongStringToMatch()
{
var value = new ValueCursor("x");
Assert.True(value.MoveNext());
Assert.False(value.Match("long string"));
ValidateCurrentCharacter(value, 0, 'x');
}
public void Parse_Partial_Invalid()
{
var value = new ValueCursor("x17:y");
value.MoveNext();
value.MoveNext();
var result = SimpleOffsetPattern.ParsePartial(value);
Assert.Throws<UnparsableValueException>(() => result.GetValueOrThrow());
}
public void MatchCaseInsensitive_MatchWithoutMoving()
{
var value = new ValueCursor("abcd");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.MatchCaseInsensitive("AbC", CultureInfo.InvariantCulture.CompareInfo, false));
// We're still looking at the start
ValidateCurrentCharacter(value, 0, 'a');
}
public void Match_Char()
{
var value = new ValueCursor("abc");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.Match('a'), "First character");
Assert.True(value.Match('b'), "Second character");
Assert.True(value.Match('c'), "Third character");
Assert.False(value.MoveNext(), "GetNext() end");
}
public void ParsePartial_ValidAtEnd()
{
var value = new ValueCursor("x17:30");
value.MoveNext();
value.MoveNext();
var result = SimpleOffsetPattern.ParsePartial(value);
Assert.AreEqual(Offset.FromHoursAndMinutes(17, 30), result.Value);
// Finish just after the value, which in this case is at the end.
Assert.AreEqual(TextCursor.Nul, value.Current);
}
internal ParseResult <ZonedDateTime> ParseZone(ValueCursor value)
{
DateTimeZone zone = TryParseFixedZone(value) ?? TryParseProviderZone(value);
if (zone == null)
{
return(ParseResult <ZonedDateTime> .NoMatchingZoneId(value));
}
Zone = zone;
return(null);
}
internal static ParseResult <T> ForInvalidValue(ValueCursor cursor, string formatString, params object[] parameters)
{
return(ForInvalidValue(() =>
{
// Format the message which is specific to the kind of parse error.
string detailMessage = string.Format(CultureInfo.CurrentCulture, formatString, parameters);
// Format the overall message, containing the parse error and the value itself.
string overallMessage = string.Format(CultureInfo.CurrentCulture, Messages.Parse_UnparsableValue, detailMessage, cursor);
return new UnparsableValueException(overallMessage);
}));
}
/// <summary>
/// Attempts to parse a fixed time zone from "UTC" with an optional
/// offset, expressed as +HH, +HH:mm, +HH:mm:ss or +HH:mm:ss.fff - i.e. the
/// general format. If it manages, it will move the cursor and return the
/// zone. Otherwise, it will return null and the cursor will remain where
/// it was.
/// </summary>
private DateTimeZone TryParseFixedZone(ValueCursor value)
{
if (value.CompareOrdinal(DateTimeZone.UtcId) != 0)
{
return(null);
}
value.Move(value.Index + 3);
var pattern = OffsetPattern.GeneralInvariant.UnderlyingPattern;
var parseResult = pattern.ParsePartial(value);
return(parseResult.Success ? DateTimeZone.ForOffset(parseResult.Value) : DateTimeZone.Utc);
}
public void ParsePartial_ValidInMiddle()
{
var value = new ValueCursor("x17:30y");
value.MoveNext();
value.MoveNext();
// Start already looking at the value to parse
Assert.AreEqual('1', value.Current);
var result = SimpleOffsetPattern.ParsePartial(value);
Assert.AreEqual(Offset.FromHoursAndMinutes(17, 30), result.Value);
// Finish just after the value
Assert.AreEqual('y', value.Current);
}
public ParseResult <T> ParsePartial(ValueCursor cursor)
{
int index = cursor.Index;
foreach (IPartialPattern <T> pattern in patterns)
{
cursor.Move(index);
ParseResult <T> result = pattern.ParsePartial(cursor);
if (result.Success || !result.ContinueAfterErrorWithMultipleFormats)
{
return(result);
}
}
cursor.Move(index);
return(ParseResult <T> .NoMatchingFormat(cursor));
}
/// <summary>
/// Tries to parse a time zone ID from the provider. Returns the zone
/// on success (after moving the cursor to the end of the ID) or null on failure
/// (leaving the cursor where it was).
/// </summary>
private DateTimeZone TryParseProviderZone(ValueCursor value)
{
// The IDs from the provider are guaranteed to be in order (using ordinal comparisons).
// Use a binary search to find a match, then make sure it's the longest possible match.
var ids = zoneProvider.Ids;
int lowerBound = 0; // Inclusive
int upperBound = ids.Count; // Exclusive
while (lowerBound < upperBound)
{
int guess = (lowerBound + upperBound) / 2;
int result = value.CompareOrdinal(ids[guess]);
if (result < 0)
{
// Guess is later than our text: lower the upper bound
upperBound = guess;
}
else if (result > 0)
{
// Guess is earlier than our text: raise the lower bound
lowerBound = guess + 1;
}
else
{
// We've found a match! But it may not be as long as it
// could be. Keep looking until we find a value which isn't a match...
while (guess + 1 < upperBound && value.CompareOrdinal(ids[guess + 1]) == 0)
{
guess++;
}
string id = ids[guess];
value.Move(value.Index + id.Length);
return(zoneProvider[id]);
}
}
return(null);
}
public ParseResult <Offset> ParsePartial(ValueCursor cursor)
{
// TODO: Do better than this. It's horrible, and may well be invalid
// for some cultures. Or just remove the NumberPattern from 2.0...
int longestPossible = Math.Min(maxLength, cursor.Length - cursor.Index);
for (int length = longestPossible; length >= 0; length--)
{
string candidate = cursor.Value.Substring(cursor.Index, length);
int milliseconds;
if (Int32.TryParse(candidate, NumberStyles.Integer | NumberStyles.AllowThousands,
formatInfo.NumberFormat, out milliseconds))
{
if (milliseconds < -NodaConstants.MillisecondsPerStandardDay ||
NodaConstants.MillisecondsPerStandardDay < milliseconds)
{
return(ParseResult <Offset> .ValueOutOfRange(milliseconds));
}
cursor.Move(cursor.Index + length);
return(ParseResult <Offset> .ForValue(Offset.FromMilliseconds(milliseconds)));
}
}
return(ParseResult <Offset> .CannotParseValue(cursor.Value, "n"));
}
public void ParseInt64_Simple()
{
var value = new ValueCursor("56x");
Assert.True(value.MoveNext());
long result;
Assert.IsNull(value.ParseInt64<string>(out result));
Assert.AreEqual(56L, result);
// Cursor ends up post-number
Assert.AreEqual(2, value.Index);
}
internal static ParseResult <T> EscapedCharacterMismatch(ValueCursor cursor, char patternCharacter) => ForInvalidValue(cursor, Messages.Parse_EscapedCharacterMismatch, patternCharacter);
public void ParseInt64Digits_Minimum()
{
var value = new ValueCursor("1");
value.MoveNext();
long actual;
Assert.True(value.ParseInt64Digits(1, 2, out actual));
Assert.AreEqual(1, actual);
ValidateEndOfString(value);
}
public void ParseInt64Digits_LargeNumber()
{
var value = new ValueCursor("9999999999999");
Assert.True(value.MoveNext());
long actual;
Assert.True(value.ParseInt64Digits(1, 13, out actual));
Assert.AreEqual(actual, 9999999999999L);
Assert.Greater(9999999999999L, int.MaxValue);
}
internal static ParseResult <T> FieldValueOutOfRange(ValueCursor cursor, long value, char field) => ForInvalidValue(cursor, Messages.Parse_FieldValueOutOfRange, value, field, typeof(T));
public void ParseInt64Digits_Maximum()
{
var value = new ValueCursor("12");
Assert.True(value.MoveNext());
long actual;
Assert.True(value.ParseInt64Digits(1, 2, out actual));
Assert.AreEqual(12, actual);
}
internal static ParseResult <T> MissingSign(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_MissingSign);
public void CompareOrdinal_LongMatch_ValueIsEarlier()
{
var value = new ValueCursor("xabc");
value.Move(1);
Assert.Less(value.CompareOrdinal("cccc"), 0);
Assert.AreEqual(1, value.Index); // Cursor hasn't moved
}
internal static ParseResult <T> NoMatchingCalendarSystem(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_NoMatchingCalendarSystem);
internal static ParseResult <T> MissingAmPmDesignator(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_MissingAmPmDesignator);
internal ParseResult <TResult> ParseEra <TResult>(NodaFormatInfo formatInfo, ValueCursor cursor)
{
var compareInfo = formatInfo.CompareInfo;
foreach (var era in Calendar.Eras)
{
foreach (string eraName in formatInfo.GetEraNames(era))
{
if (cursor.MatchCaseInsensitive(eraName, compareInfo, true))
{
Era = era;
return(null);
}
}
}
return(ParseResult <TResult> .MismatchedText(cursor, 'g'));
}
/// <summary>
/// Tries to parse a time zone ID from the provider. Returns the zone
/// on success (after moving the cursor to the end of the ID) or null on failure
/// (leaving the cursor where it was).
/// </summary>
private DateTimeZone TryParseProviderZone(ValueCursor value)
{
// The IDs from the provider are guaranteed to be in order (using ordinal comparisons).
// Use a binary search to find a match, then make sure it's the longest possible match.
var ids = zoneProvider.Ids;
int lowerBound = 0; // Inclusive
int upperBound = ids.Count; // Exclusive
while (lowerBound < upperBound)
{
int guess = (lowerBound + upperBound) / 2;
int result = value.CompareOrdinal(ids[guess]);
if (result < 0)
{
// Guess is later than our text: lower the upper bound
upperBound = guess;
}
else if (result > 0)
{
// Guess is earlier than our text: raise the lower bound
lowerBound = guess + 1;
}
else
{
// We've found a match! But it may not be as long as it
// could be. Keep track of a "longest match so far" (starting with the match we've found),
// and keep looking through the IDs until we find an ID which doesn't start with that "longest
// match so far", at which point we know we're done.
//
// We can't just look through all the IDs from "guess" to "lowerBound" and stop when we hit
// a non-match against "value", because of situations like this:
// value=Etc/GMT-12
// guess=Etc/GMT-1
// IDs includes { Etc/GMT-1, Etc/GMT-10, Etc/GMT-11, Etc/GMT-12, Etc/GMT-13 }
// We can't stop when we hit Etc/GMT-10, because otherwise we won't find Etc/GMT-12.
// We *can* stop when we get to Etc/GMT-13, because by then our longest match so far will
// be Etc/GMT-12, and we know that anything beyond Etc/GMT-13 won't match that.
// We can also stop when we hit upperBound, without any more comparisons.
string longestSoFar = ids[guess];
for (int i = guess + 1; i < upperBound; i++)
{
string candidate = ids[i];
if (candidate.Length < longestSoFar.Length)
{
break;
}
if (string.CompareOrdinal(longestSoFar, 0, candidate, 0, longestSoFar.Length) != 0)
{
break;
}
if (value.CompareOrdinal(candidate) == 0)
{
longestSoFar = candidate;
}
}
value.Move(value.Index + longestSoFar.Length);
return(zoneProvider[longestSoFar]);
}
}
return(null);
}
/// <summary> /// We'd expected to get to the end of the string now, but we haven't. /// </summary> internal static ParseResult <T> ExpectedEndOfString(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_ExpectedEndOfString);
public void ParseInt64_NumberOutOfRange_MinValueLeadingDigits()
{
var value = new ValueCursor("-9223372036854775809");
Assert.True(value.MoveNext());
long result;
Assert.IsNotNull(value.ParseInt64<string>(out result));
// Cursor has not moved
Assert.AreEqual(0, value.Index);
}
private static ParseResult <ZonedDateTime> ParseZone(ValueCursor value, ZonedDateTimeParseBucket bucket) => bucket.ParseZone(value);
internal static ParseResult <T> QuotedStringMismatch(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_QuotedStringMismatch);
internal static ParseResult <T> ValueOutOfRange(ValueCursor cursor, object value) => ForInvalidValue(cursor, Messages.Parse_ValueOutOfRange, value, typeof(T));
internal static ParseResult <T> ExtraValueCharacters(ValueCursor cursor, string remainder) => ForInvalidValue(cursor, Messages.Parse_ExtraValueCharacters, remainder);
internal static ParseResult <T> MismatchedText(ValueCursor cursor, char field) => ForInvalidValue(cursor, Messages.Parse_MismatchedText, field);
public void ParseInt64Digits_NoNumber()
{
var value = new ValueCursor("abc");
Assert.True(value.MoveNext());
long actual;
Assert.False(value.ParseInt64Digits(1, 2, out actual));
ValidateCurrentCharacter(value, 0, 'a');
}
internal static ParseResult <T> MismatchedCharacter(ValueCursor cursor, char patternCharacter) => ForInvalidValue(cursor, Messages.Parse_MismatchedCharacter, patternCharacter);
public void ParseInt64Digits_MaximumMoreDigits()
{
var value = new ValueCursor("1234");
Assert.True(value.MoveNext());
long actual;
Assert.True(value.ParseInt64Digits(1, 2, out actual));
Assert.AreEqual(12, actual);
ValidateCurrentCharacter(value, 2, '3');
}
internal static ParseResult <T> MismatchedNumber(ValueCursor cursor, string pattern) => ForInvalidValue(cursor, Messages.Parse_MismatchedNumber, pattern);
public void ParseInt64Digits_MinimumNonDigits()
{
var value = new ValueCursor("1abc");
Assert.True(value.MoveNext());
long actual;
Assert.True(value.ParseInt64Digits(1, 2, out actual));
Assert.AreEqual(1, actual);
ValidateCurrentCharacter(value, 1, 'a');
}
internal static ParseResult <T> UnexpectedNegative(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_UnexpectedNegative);
public void ParseFraction_NonAscii_NeverMatches()
{
// Arabic-Indic digits 0 and 1. See
// http://www.unicode.org/charts/PDF/U0600.pdf
var value = new ValueCursor("\u0660\u0661");
Assert.True(value.MoveNext());
int actual;
Assert.False(value.ParseFraction(2, 2, out actual, 2));
}
public ParseResult <Period> Parse(string text)
{
if (text is null)
{
return(ParseResult <Period> .ArgumentNull("text"));
}
if (text.Length == 0)
{
return(ParseResult <Period> .ValueStringEmpty);
}
ValueCursor valueCursor = new ValueCursor(text);
valueCursor.MoveNext();
if (valueCursor.Current != 'P')
{
return(ParseResult <Period> .MismatchedCharacter(valueCursor, 'P'));
}
bool inDate = true;
PeriodBuilder builder = new PeriodBuilder();
PeriodUnits unitsSoFar = 0;
while (valueCursor.MoveNext())
{
if (inDate && valueCursor.Current == 'T')
{
inDate = false;
continue;
}
var failure = valueCursor.ParseInt64 <Period>(out long unitValue);
if (failure != null)
{
return(failure);
}
if (valueCursor.Length == valueCursor.Index)
{
return(ParseResult <Period> .EndOfString(valueCursor));
}
// Various failure cases:
// - Repeated unit (e.g. P1M2M)
// - Time unit is in date part (e.g. P5M)
// - Date unit is in time part (e.g. PT1D)
// - Unit is in incorrect order (e.g. P5D1Y)
// - Unit is invalid (e.g. P5J)
// - Unit is missing (e.g. P5)
PeriodUnits unit;
switch (valueCursor.Current)
{
case 'Y': unit = PeriodUnits.Years; break;
case 'M': unit = inDate ? PeriodUnits.Months : PeriodUnits.Minutes; break;
case 'W': unit = PeriodUnits.Weeks; break;
case 'D': unit = PeriodUnits.Days; break;
case 'H': unit = PeriodUnits.Hours; break;
case 'S': unit = PeriodUnits.Seconds; break;
case 's': unit = PeriodUnits.Milliseconds; break;
case 't': unit = PeriodUnits.Ticks; break;
case 'n': unit = PeriodUnits.Nanoseconds; break;
default: return(InvalidUnit(valueCursor, valueCursor.Current));
}
if ((unit & unitsSoFar) != 0)
{
return(RepeatedUnit(valueCursor, valueCursor.Current));
}
// This handles putting months before years, for example. Less significant units
// have higher integer representations.
if (unit < unitsSoFar)
{
return(MisplacedUnit(valueCursor, valueCursor.Current));
}
// The result of checking "there aren't any time units in this unit" should be
// equal to "we're still in the date part".
if ((unit & PeriodUnits.AllTimeUnits) == 0 != inDate)
{
return(MisplacedUnit(valueCursor, valueCursor.Current));
}
builder[unit] = unitValue;
unitsSoFar |= unit;
}
return(ParseResult <Period> .ForValue(builder.Build()));
}
public void ParseInt64_Negative()
{
var value = new ValueCursor("-56x");
Assert.True(value.MoveNext());
long result;
Assert.IsNull(value.ParseInt64<string>(out result));
Assert.AreEqual(-56L, result);
}
// TODO(misc): Tidy this up a *lot*.
public ParseResult <Period> Parse(string text)
{
if (text is null)
{
return(ParseResult <Period> .ArgumentNull("text"));
}
if (text.Length == 0)
{
return(ParseResult <Period> .ValueStringEmpty);
}
ValueCursor valueCursor = new ValueCursor(text);
valueCursor.MoveNext();
if (valueCursor.Current != 'P')
{
return(ParseResult <Period> .MismatchedCharacter(valueCursor, 'P'));
}
bool inDate = true;
PeriodBuilder builder = new PeriodBuilder();
PeriodUnits unitsSoFar = 0;
while (valueCursor.MoveNext())
{
if (inDate && valueCursor.Current == 'T')
{
inDate = false;
continue;
}
bool negative = valueCursor.Current == '-';
var failure = valueCursor.ParseInt64 <Period>(out long unitValue);
if (failure != null)
{
return(failure);
}
if (valueCursor.Length == valueCursor.Index)
{
return(ParseResult <Period> .EndOfString(valueCursor));
}
// Various failure cases:
// - Repeated unit (e.g. P1M2M)
// - Time unit is in date part (e.g. P5M)
// - Date unit is in time part (e.g. PT1D)
// - Unit is in incorrect order (e.g. P5D1Y)
// - Unit is invalid (e.g. P5J)
// - Unit is missing (e.g. P5)
PeriodUnits unit;
switch (valueCursor.Current)
{
case 'Y': unit = PeriodUnits.Years; break;
case 'M': unit = inDate ? PeriodUnits.Months : PeriodUnits.Minutes; break;
case 'W': unit = PeriodUnits.Weeks; break;
case 'D': unit = PeriodUnits.Days; break;
case 'H': unit = PeriodUnits.Hours; break;
case 'S': unit = PeriodUnits.Seconds; break;
case ',':
case '.': unit = PeriodUnits.Nanoseconds; break; // Special handling below
default: return(InvalidUnit(valueCursor, valueCursor.Current));
}
if ((unit & unitsSoFar) != 0)
{
return(RepeatedUnit(valueCursor, valueCursor.Current));
}
// This handles putting months before years, for example. Less significant units
// have higher integer representations.
if (unit < unitsSoFar)
{
return(MisplacedUnit(valueCursor, valueCursor.Current));
}
// The result of checking "there aren't any time units in this unit" should be
// equal to "we're still in the date part".
if ((unit & PeriodUnits.AllTimeUnits) == 0 != inDate)
{
return(MisplacedUnit(valueCursor, valueCursor.Current));
}
// Seen a . or , which need special handling.
if (unit == PeriodUnits.Nanoseconds)
{
// Check for already having seen seconds, e.g. PT5S0.5
if ((unitsSoFar & PeriodUnits.Seconds) != 0)
{
return(MisplacedUnit(valueCursor, valueCursor.Current));
}
builder.Seconds = unitValue;
if (!valueCursor.MoveNext())
{
return(ParseResult <Period> .MissingNumber(valueCursor));
}
// Can cope with at most 999999999 nanoseconds
if (!valueCursor.ParseFraction(9, 9, out int totalNanoseconds, 1))
{
return(ParseResult <Period> .MissingNumber(valueCursor));
}
// Use whether or not the seconds value was negative (even if 0)
// as the indication of whether this value is negative.
if (negative)
{
totalNanoseconds = -totalNanoseconds;
}
builder.Milliseconds = (totalNanoseconds / NanosecondsPerMillisecond) % MillisecondsPerSecond;
builder.Ticks = (totalNanoseconds / NanosecondsPerTick) % TicksPerMillisecond;
builder.Nanoseconds = totalNanoseconds % NanosecondsPerTick;
if (valueCursor.Current != 'S')
{
return(ParseResult <Period> .MismatchedCharacter(valueCursor, 'S'));
}
if (valueCursor.MoveNext())
{
return(ParseResult <Period> .ExpectedEndOfString(valueCursor));
}
return(ParseResult <Period> .ForValue(builder.Build()));
}
builder[unit] = unitValue;
unitsSoFar |= unit;
}
if (unitsSoFar == 0)
{
return(ParseResult <Period> .ForInvalidValue(valueCursor, TextErrorMessages.EmptyPeriod));
}
return(ParseResult <Period> .ForValue(builder.Build()));
}
public void ParseInt64_NegativeThenNonDigit()
{
var value = new ValueCursor("-x");
Assert.True(value.MoveNext());
long result;
Assert.IsNotNull(value.ParseInt64<string>(out result));
// Cursor has not moved
Assert.AreEqual(0, value.Index);
}
private static ParseResult <Period> RepeatedUnit(ValueCursor cursor, char unitCharacter) => ParseResult <Period> .ForInvalidValue(cursor, TextErrorMessages.RepeatedUnitSpecifier, unitCharacter);
public void ParseInt64_MinValue()
{
var value = new ValueCursor("-9223372036854775808");
Assert.True(value.MoveNext());
long result;
Assert.IsNull(value.ParseInt64<string>(out result));
Assert.AreEqual(long.MinValue, result);
}
internal ParseResult <TResult> ParseEra <TResult>(NodaFormatInfo formatInfo, ValueCursor cursor)
{
var compareInfo = formatInfo.CompareInfo;
var eras = Calendar.Eras;
for (int i = 0; i < eras.Count; i++)
{
foreach (string eraName in formatInfo.GetEraNames(eras[i]))
{
if (cursor.MatchCaseInsensitive(eraName, compareInfo, true))
{
EraIndex = i;
return(null);
}
}
}
return(ParseResult <TResult> .MismatchedText('g'));
}
public void CompareOrdinal_ExactMatchValueContinues()
{
var value = new ValueCursor("xabc");
value.Move(1);
Assert.AreEqual(0, value.CompareOrdinal("ab"));
Assert.AreEqual(1, value.Index); // Cursor hasn't moved
}
public void ParseInt64Digits_TooFewDigits()
{
var value = new ValueCursor("a12b");
Assert.True(value.MoveNext());
ValidateCurrentCharacter(value, 0, 'a');
Assert.True(value.MoveNext());
long actual;
Assert.False(value.ParseInt64Digits(3, 3, out actual));
ValidateCurrentCharacter(value, 1, '1');
}
public void CompareOrdinal_LongMatch_ValueIsLater()
{
var value = new ValueCursor("xabc");
value.Move(1);
Assert.Greater(value.CompareOrdinal("aaaa"), 0);
Assert.AreEqual(1, value.Index); // Cursor hasn't moved
}
internal static ParseResult <T> DateSeparatorMismatch(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_DateSeparatorMismatch);
public void MatchCaseInsensitive_StringOverLongStringToMatch()
{
var value = new ValueCursor("x");
Assert.True(value.MoveNext());
Assert.False(value.MatchCaseInsensitive("long string", CultureInfo.InvariantCulture.CompareInfo, true));
ValidateCurrentCharacter(value, 0, 'x');
}
internal static ParseResult <T> NoMatchingZoneId(ValueCursor cursor) => ForInvalidValue(cursor, Messages.Parse_NoMatchingZoneId);
private static ParseResult <Period> InvalidUnit(ValueCursor cursor, char unitCharacter) => ParseResult <Period> .ForInvalidValue(cursor, Messages.Parse_InvalidUnitSpecifier, unitCharacter);
private static ParseResult <Period> MisplacedUnit(ValueCursor cursor, char unitCharacter)
{
return(ParseResult <Period> .ForInvalidValue(cursor, Messages.Parse_MisplacedUnitSpecifier, unitCharacter));
}
public void Match_StringPartial()
{
var value = new ValueCursor("abcdef");
Assert.True(value.MoveNext(), "GetNext() 1");
Assert.True(value.Match("abc"));
ValidateCurrentCharacter(value, 3, 'd');
}
public void TestParseDigit_nonASCII_NeverMatches()
{
// Arabic-Indic digits 0 and 1. See
// http://www.unicode.org/charts/PDF/U0600.pdf
var value = new ValueCursor("\u0660\u0661");
Assert.True(value.MoveNext());
int actual;
Assert.False(value.ParseDigits(1, 2, out actual));
}
