icu4c/source/i18n/numparse_decimal.cpp - external/github.com/unicode-org/icu - Git at Google

 // © 2018 and later: Unicode, Inc. and others.
 // License & terms of use: http://www.unicode.org/copyright.html

 #include "unicode/utypes.h"

 #if !UCONFIG_NO_FORMATTING

 // Allow implicit conversion from char16_t* to UnicodeString for this file:
 // Helpful in toString methods and elsewhere.
 #define UNISTR_FROM_STRING_EXPLICIT

 #include "numparse_types.h"
 #include "numparse_decimal.h"
 #include "static_unicode_sets.h"
 #include "numparse_utils.h"
 #include "unicode/uchar.h"
 #include "putilimp.h"
 #include "number_decimalquantity.h"
 #include "string_segment.h"

 using namespace icu;
 using namespace icu::numparse;
 using namespace icu::numparse::impl;


 DecimalMatcher::DecimalMatcher(const DecimalFormatSymbols& symbols, const Grouper& grouper,
                                parse_flags_t parseFlags) {
     if (0 != (parseFlags & PARSE_FLAG_MONETARY_SEPARATORS)) {
         groupingSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kMonetaryGroupingSeparatorSymbol);
         decimalSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kMonetarySeparatorSymbol);
     } else {
         groupingSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kGroupingSeparatorSymbol);
         decimalSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kDecimalSeparatorSymbol);
     }
     bool strictSeparators = 0 != (parseFlags & PARSE_FLAG_STRICT_SEPARATORS);
     unisets::Key groupingKey = strictSeparators ? unisets::STRICT_ALL_SEPARATORS
                                                 : unisets::ALL_SEPARATORS;

     // Attempt to find separators in the static cache

     groupingUniSet = unisets::get(groupingKey);
     unisets::Key decimalKey = unisets::chooseFrom(
             decimalSeparator,
             strictSeparators ? unisets::STRICT_COMMA : unisets::COMMA,
             strictSeparators ? unisets::STRICT_PERIOD : unisets::PERIOD);
     if (decimalKey >= 0) {
         decimalUniSet = unisets::get(decimalKey);
     } else if (!decimalSeparator.isEmpty()) {
         auto* set = new UnicodeSet();
         set->add(decimalSeparator.char32At(0));
         set->freeze();
         decimalUniSet = set;
         fLocalDecimalUniSet.adoptInstead(set);
     } else {
         decimalUniSet = unisets::get(unisets::EMPTY);
     }

     if (groupingKey >= 0 && decimalKey >= 0) {
         // Everything is available in the static cache
         separatorSet = groupingUniSet;
         leadSet = unisets::get(
                 strictSeparators ? unisets::DIGITS_OR_ALL_SEPARATORS
                                  : unisets::DIGITS_OR_STRICT_ALL_SEPARATORS);
     } else {
         auto* set = new UnicodeSet();
         set->addAll(*groupingUniSet);
         set->addAll(*decimalUniSet);
         set->freeze();
         separatorSet = set;
         fLocalSeparatorSet.adoptInstead(set);
         leadSet = nullptr;
     }

     UChar32 cpZero = symbols.getCodePointZero();
     if (cpZero == -1 || !u_isdigit(cpZero) || u_digit(cpZero, 10) != 0) {
         // Uncommon case: okay to allocate.
         auto digitStrings = new UnicodeString[10];
         fLocalDigitStrings.adoptInstead(digitStrings);
         for (int32_t i = 0; i <= 9; i++) {
             digitStrings[i] = symbols.getConstDigitSymbol(i);
         }
     }

     requireGroupingMatch = 0 != (parseFlags & PARSE_FLAG_STRICT_GROUPING_SIZE);
     groupingDisabled = 0 != (parseFlags & PARSE_FLAG_GROUPING_DISABLED);
     integerOnly = 0 != (parseFlags & PARSE_FLAG_INTEGER_ONLY);
     grouping1 = grouper.getPrimary();
     grouping2 = grouper.getSecondary();

     // Fraction grouping parsing is disabled for now but could be enabled later.
     // See http://bugs.icu-project.org/trac/ticket/10794
     // fractionGrouping = 0 != (parseFlags & PARSE_FLAG_FRACTION_GROUPING_ENABLED);
 }

 bool DecimalMatcher::match(StringSegment& segment, ParsedNumber& result, UErrorCode& status) const {
     return match(segment, result, 0, status);
 }

 bool DecimalMatcher::match(StringSegment& segment, ParsedNumber& result, int8_t exponentSign,
                            UErrorCode&) const {
     if (result.seenNumber() && exponentSign == 0) {
         // A number has already been consumed.
         return false;
     } else if (exponentSign != 0) {
         // scientific notation always comes after the number
         U_ASSERT(!result.quantity.bogus);
     }

     // Initial offset before any character consumption.
     int32_t initialOffset = segment.getOffset();

     // Return value: whether to ask for more characters.
     bool maybeMore = false;

     // All digits consumed so far.
     number::impl::DecimalQuantity digitsConsumed;
     digitsConsumed.bogus = true;

     // The total number of digits after the decimal place, used for scaling the result.
     int32_t digitsAfterDecimalPlace = 0;

     // The actual grouping and decimal separators used in the string.
     // If non-null, we have seen that token.
     UnicodeString actualGroupingString;
     UnicodeString actualDecimalString;
     actualGroupingString.setToBogus();
     actualDecimalString.setToBogus();

     // Information for two groups: the previous group and the current group.
     //
     // Each group has three pieces of information:
     //
     // Offset: the string position of the beginning of the group, including a leading separator
     // if there was a leading separator. This is needed in case we need to rewind the parse to
     // that position.
     //
     // Separator type:
     // 0 => beginning of string
     // 1 => lead separator is a grouping separator
     // 2 => lead separator is a decimal separator
     //
     // Count: the number of digits in the group. If -1, the group has been validated.
     int32_t currGroupOffset = 0;
     int32_t currGroupSepType = 0;
     int32_t currGroupCount = 0;
     int32_t prevGroupOffset = -1;
     int32_t prevGroupSepType = -1;
     int32_t prevGroupCount = -1;

     while (segment.length() > 0) {
         maybeMore = false;

         // Attempt to match a digit.
         int8_t digit = -1;

         // Try by code point digit value.
         UChar32 cp = segment.getCodePoint();
         if (u_isdigit(cp)) {
             segment.adjustOffset(U16_LENGTH(cp));
             digit = static_cast<int8_t>(u_digit(cp, 10));
         }

         // Try by digit string.
         if (digit == -1 && !fLocalDigitStrings.isNull()) {
             for (int32_t i = 0; i < 10; i++) {
                 const UnicodeString& str = fLocalDigitStrings[i];
                 if (str.isEmpty()) {
                     continue;
                 }
                 int32_t overlap = segment.getCommonPrefixLength(str);
                 if (overlap == str.length()) {
                     segment.adjustOffset(overlap);
                     digit = static_cast<int8_t>(i);
                     break;
                 }
                 maybeMore = maybeMore || (overlap == segment.length());
             }
         }

         if (digit >= 0) {
             // Digit was found.
             if (digitsConsumed.bogus) {
                 digitsConsumed.bogus = false;
                 digitsConsumed.clear();
             }
             digitsConsumed.appendDigit(digit, 0, true);
             currGroupCount++;
             if (!actualDecimalString.isBogus()) {
                 digitsAfterDecimalPlace++;
             }
             continue;
         }

         // Attempt to match a literal grouping or decimal separator.
         bool isDecimal = false;
         bool isGrouping = false;

         // 1) Attempt the decimal separator string literal.
         // if (we have not seen a decimal separator yet) { ... }
         if (actualDecimalString.isBogus() && !decimalSeparator.isEmpty()) {
             int32_t overlap = segment.getCommonPrefixLength(decimalSeparator);
             maybeMore = maybeMore || (overlap == segment.length());
             if (overlap == decimalSeparator.length()) {
                 isDecimal = true;
                 actualDecimalString = decimalSeparator;
             }
         }

         // 2) Attempt to match the actual grouping string literal.
         if (!actualGroupingString.isBogus()) {
             int32_t overlap = segment.getCommonPrefixLength(actualGroupingString);
             maybeMore = maybeMore || (overlap == segment.length());
             if (overlap == actualGroupingString.length()) {
                 isGrouping = true;
             }
         }

         // 2.5) Attempt to match a new the grouping separator string literal.
         // if (we have not seen a grouping or decimal separator yet) { ... }
         if (!groupingDisabled && actualGroupingString.isBogus() && actualDecimalString.isBogus() &&
             !groupingSeparator.isEmpty()) {
             int32_t overlap = segment.getCommonPrefixLength(groupingSeparator);
             maybeMore = maybeMore || (overlap == segment.length());
             if (overlap == groupingSeparator.length()) {
                 isGrouping = true;
                 actualGroupingString = groupingSeparator;
             }
         }

         // 3) Attempt to match a decimal separator from the equivalence set.
         // if (we have not seen a decimal separator yet) { ... }
         // The !isGrouping is to confirm that we haven't yet matched the current character.
         if (!isGrouping && actualDecimalString.isBogus()) {
             if (decimalUniSet->contains(cp)) {
                 isDecimal = true;
                 actualDecimalString = UnicodeString(cp);
             }
         }

         // 4) Attempt to match a grouping separator from the equivalence set.
         // if (we have not seen a grouping or decimal separator yet) { ... }
         if (!groupingDisabled && actualGroupingString.isBogus() && actualDecimalString.isBogus()) {
             if (groupingUniSet->contains(cp)) {
                 isGrouping = true;
                 actualGroupingString = UnicodeString(cp);
             }
         }

         // Leave if we failed to match this as a separator.
         if (!isDecimal && !isGrouping) {
             break;
         }

         // Check for conditions when we don't want to accept the separator.
         if (isDecimal && integerOnly) {
             break;
         } else if (currGroupSepType == 2 && isGrouping) {
             // Fraction grouping
             break;
         }

         // Validate intermediate grouping sizes.
         bool prevValidSecondary = validateGroup(prevGroupSepType, prevGroupCount, false);
         bool currValidPrimary = validateGroup(currGroupSepType, currGroupCount, true);
         if (!prevValidSecondary || (isDecimal && !currValidPrimary)) {
             // Invalid grouping sizes.
             if (isGrouping && currGroupCount == 0) {
                 // Trailing grouping separators: these are taken care of below
                 U_ASSERT(currGroupSepType == 1);
             } else if (requireGroupingMatch) {
                 // Strict mode: reject the parse
                 digitsConsumed.clear();
                 digitsConsumed.bogus = true;
             }
             break;
         } else if (requireGroupingMatch && currGroupCount == 0 && currGroupSepType == 1) {
             break;
         } else {
             // Grouping sizes OK so far.
             prevGroupOffset = currGroupOffset;
             prevGroupCount = currGroupCount;
             if (isDecimal) {
                 // Do not validate this group any more.
                 prevGroupSepType = -1;
             } else {
                 prevGroupSepType = currGroupSepType;
             }
         }

         // OK to accept the separator.
         // Special case: don't update currGroup if it is empty; this allows two grouping
         // separators in a row in lenient mode.
         if (currGroupCount != 0) {
             currGroupOffset = segment.getOffset();
         }
         currGroupSepType = isGrouping ? 1 : 2;
         currGroupCount = 0;
         if (isGrouping) {
             segment.adjustOffset(actualGroupingString.length());
         } else {
             segment.adjustOffset(actualDecimalString.length());
         }
     }

     // End of main loop.
     // Back up if there was a trailing grouping separator.
     // Shift prev -> curr so we can check it as a final group.
     if (currGroupSepType != 2 && currGroupCount == 0) {
         maybeMore = true;
         segment.setOffset(currGroupOffset);
         currGroupOffset = prevGroupOffset;
         currGroupSepType = prevGroupSepType;
         currGroupCount = prevGroupCount;
         prevGroupOffset = -1;
         prevGroupSepType = 0;
         prevGroupCount = 1;
     }

     // Validate final grouping sizes.
     bool prevValidSecondary = validateGroup(prevGroupSepType, prevGroupCount, false);
     bool currValidPrimary = validateGroup(currGroupSepType, currGroupCount, true);
     if (!requireGroupingMatch) {
         // The cases we need to handle here are lone digits.
         // Examples: "1,1"  "1,1,"  "1,1,1"  "1,1,1,"  ",1" (all parse as 1)
         // See more examples in numberformattestspecification.txt
         int32_t digitsToRemove = 0;
         if (!prevValidSecondary) {
             segment.setOffset(prevGroupOffset);
             digitsToRemove += prevGroupCount;
             digitsToRemove += currGroupCount;
         } else if (!currValidPrimary && (prevGroupSepType != 0 || prevGroupCount != 0)) {
             maybeMore = true;
             segment.setOffset(currGroupOffset);
             digitsToRemove += currGroupCount;
         }
         if (digitsToRemove != 0) {
             digitsConsumed.adjustMagnitude(-digitsToRemove);
             digitsConsumed.truncate();
         }
         prevValidSecondary = true;
         currValidPrimary = true;
     }
     if (currGroupSepType != 2 && (!prevValidSecondary || !currValidPrimary)) {
         // Grouping failure.
         digitsConsumed.bogus = true;
     }

     // Strings that start with a separator but have no digits,
     // or strings that failed a grouping size check.
     if (digitsConsumed.bogus) {
         maybeMore = maybeMore || (segment.length() == 0);
         segment.setOffset(initialOffset);
         return maybeMore;
     }

     // We passed all inspections. Start post-processing.

     // Adjust for fraction part.
     digitsConsumed.adjustMagnitude(-digitsAfterDecimalPlace);

     // Set the digits, either normal or exponent.
     if (exponentSign != 0 && segment.getOffset() != initialOffset) {
         bool overflow = false;
         if (digitsConsumed.fitsInLong()) {
             int64_t exponentLong = digitsConsumed.toLong(false);
             U_ASSERT(exponentLong >= 0);
             if (exponentLong <= INT32_MAX) {
                 auto exponentInt = static_cast<int32_t>(exponentLong);
                 if (result.quantity.adjustMagnitude(exponentSign * exponentInt)) {
                     overflow = true;
                 }
             } else {
                 overflow = true;
             }
         } else {
             overflow = true;
         }
         if (overflow) {
             if (exponentSign == -1) {
                 // Set to zero
                 result.quantity.clear();
             } else {
                 // Set to infinity
                 result.quantity.bogus = true;
                 result.flags |= FLAG_INFINITY;
             }
         }
     } else {
         result.quantity = digitsConsumed;
     }

     // Set other information into the result and return.
     if (!actualDecimalString.isBogus()) {
         result.flags |= FLAG_HAS_DECIMAL_SEPARATOR;
     }
     result.setCharsConsumed(segment);
     return segment.length() == 0 || maybeMore;
 }

 bool DecimalMatcher::validateGroup(int32_t sepType, int32_t count, bool isPrimary) const {
     if (requireGroupingMatch) {
         if (sepType == -1) {
             // No such group (prevGroup before first shift).
             return true;
         } else if (sepType == 0) {
             // First group.
             if (isPrimary) {
                 // No grouping separators is OK.
                 return true;
             } else {
                 return count != 0 && count <= grouping2;
             }
         } else if (sepType == 1) {
             // Middle group.
             if (isPrimary) {
                 return count == grouping1;
             } else {
                 return count == grouping2;
             }
         } else {
             U_ASSERT(sepType == 2);
             // After the decimal separator.
             return true;
         }
     } else {
         if (sepType == 1) {
             // #11230: don't accept middle groups with only 1 digit.
             return count != 1;
         } else {
             return true;
         }
     }
 }

 bool DecimalMatcher::smokeTest(const StringSegment& segment) const {
     // The common case uses a static leadSet for efficiency.
     if (fLocalDigitStrings.isNull() && leadSet != nullptr) {
         return segment.startsWith(*leadSet);
     }
     if (segment.startsWith(*separatorSet) || u_isdigit(segment.getCodePoint())) {
         return true;
     }
     if (fLocalDigitStrings.isNull()) {
         return false;
     }
     for (int32_t i = 0; i < 10; i++) {
         if (segment.startsWith(fLocalDigitStrings[i])) {
             return true;
         }
     }
     return false;
 }

 UnicodeString DecimalMatcher::toString() const {
     return u"<Decimal>";
 }


 #endif /* #if !UCONFIG_NO_FORMATTING */
	// © 2018 and later: Unicode, Inc. and others.
	// License & terms of use: http://www.unicode.org/copyright.html

	#include "unicode/utypes.h"

	#if !UCONFIG_NO_FORMATTING

	// Allow implicit conversion from char16_t* to UnicodeString for this file:
	// Helpful in toString methods and elsewhere.
	#define UNISTR_FROM_STRING_EXPLICIT

	#include "numparse_types.h"
	#include "numparse_decimal.h"
	#include "static_unicode_sets.h"
	#include "numparse_utils.h"
	#include "unicode/uchar.h"
	#include "putilimp.h"
	#include "number_decimalquantity.h"
	#include "string_segment.h"

	using namespace icu;
	using namespace icu::numparse;
	using namespace icu::numparse::impl;


	DecimalMatcher::DecimalMatcher(const DecimalFormatSymbols& symbols, const Grouper& grouper,
	parse_flags_t parseFlags) {
	if (0 != (parseFlags & PARSE_FLAG_MONETARY_SEPARATORS)) {
	groupingSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kMonetaryGroupingSeparatorSymbol);
	decimalSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kMonetarySeparatorSymbol);
	} else {
	groupingSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kGroupingSeparatorSymbol);
	decimalSeparator = symbols.getConstSymbol(DecimalFormatSymbols::kDecimalSeparatorSymbol);
	}
	bool strictSeparators = 0 != (parseFlags & PARSE_FLAG_STRICT_SEPARATORS);
	unisets::Key groupingKey = strictSeparators ? unisets::STRICT_ALL_SEPARATORS
	: unisets::ALL_SEPARATORS;

	// Attempt to find separators in the static cache

	groupingUniSet = unisets::get(groupingKey);
	unisets::Key decimalKey = unisets::chooseFrom(
	decimalSeparator,
	strictSeparators ? unisets::STRICT_COMMA : unisets::COMMA,
	strictSeparators ? unisets::STRICT_PERIOD : unisets::PERIOD);
	if (decimalKey >= 0) {
	decimalUniSet = unisets::get(decimalKey);
	} else if (!decimalSeparator.isEmpty()) {
	auto* set = new UnicodeSet();
	set->add(decimalSeparator.char32At(0));
	set->freeze();
	decimalUniSet = set;
	fLocalDecimalUniSet.adoptInstead(set);
	} else {
	decimalUniSet = unisets::get(unisets::EMPTY);
	}

	if (groupingKey >= 0 && decimalKey >= 0) {
	// Everything is available in the static cache
	separatorSet = groupingUniSet;
	leadSet = unisets::get(
	strictSeparators ? unisets::DIGITS_OR_ALL_SEPARATORS
	: unisets::DIGITS_OR_STRICT_ALL_SEPARATORS);
	} else {
	auto* set = new UnicodeSet();
	set->addAll(*groupingUniSet);
	set->addAll(*decimalUniSet);
	set->freeze();
	separatorSet = set;
	fLocalSeparatorSet.adoptInstead(set);
	leadSet = nullptr;
	}

	UChar32 cpZero = symbols.getCodePointZero();
	if (cpZero == -1 \|\| !u_isdigit(cpZero) \|\| u_digit(cpZero, 10) != 0) {
	// Uncommon case: okay to allocate.
	auto digitStrings = new UnicodeString[10];
	fLocalDigitStrings.adoptInstead(digitStrings);
	for (int32_t i = 0; i <= 9; i++) {
	digitStrings[i] = symbols.getConstDigitSymbol(i);
	}
	}

	requireGroupingMatch = 0 != (parseFlags & PARSE_FLAG_STRICT_GROUPING_SIZE);
	groupingDisabled = 0 != (parseFlags & PARSE_FLAG_GROUPING_DISABLED);
	integerOnly = 0 != (parseFlags & PARSE_FLAG_INTEGER_ONLY);
	grouping1 = grouper.getPrimary();
	grouping2 = grouper.getSecondary();

	// Fraction grouping parsing is disabled for now but could be enabled later.
	// See http://bugs.icu-project.org/trac/ticket/10794
	// fractionGrouping = 0 != (parseFlags & PARSE_FLAG_FRACTION_GROUPING_ENABLED);
	}

	bool DecimalMatcher::match(StringSegment& segment, ParsedNumber& result, UErrorCode& status) const {
	return match(segment, result, 0, status);
	}

	bool DecimalMatcher::match(StringSegment& segment, ParsedNumber& result, int8_t exponentSign,
	UErrorCode&) const {
	if (result.seenNumber() && exponentSign == 0) {
	// A number has already been consumed.
	return false;
	} else if (exponentSign != 0) {
	// scientific notation always comes after the number
	U_ASSERT(!result.quantity.bogus);
	}

	// Initial offset before any character consumption.
	int32_t initialOffset = segment.getOffset();

	// Return value: whether to ask for more characters.
	bool maybeMore = false;

	// All digits consumed so far.
	number::impl::DecimalQuantity digitsConsumed;
	digitsConsumed.bogus = true;

	// The total number of digits after the decimal place, used for scaling the result.
	int32_t digitsAfterDecimalPlace = 0;

	// The actual grouping and decimal separators used in the string.
	// If non-null, we have seen that token.
	UnicodeString actualGroupingString;
	UnicodeString actualDecimalString;
	actualGroupingString.setToBogus();
	actualDecimalString.setToBogus();

	// Information for two groups: the previous group and the current group.
	//
	// Each group has three pieces of information:
	//
	// Offset: the string position of the beginning of the group, including a leading separator
	// if there was a leading separator. This is needed in case we need to rewind the parse to
	// that position.
	//
	// Separator type:
	// 0 => beginning of string
	// 1 => lead separator is a grouping separator
	// 2 => lead separator is a decimal separator
	//
	// Count: the number of digits in the group. If -1, the group has been validated.
	int32_t currGroupOffset = 0;
	int32_t currGroupSepType = 0;
	int32_t currGroupCount = 0;
	int32_t prevGroupOffset = -1;
	int32_t prevGroupSepType = -1;
	int32_t prevGroupCount = -1;

	while (segment.length() > 0) {
	maybeMore = false;

	// Attempt to match a digit.
	int8_t digit = -1;

	// Try by code point digit value.
	UChar32 cp = segment.getCodePoint();
	if (u_isdigit(cp)) {
	segment.adjustOffset(U16_LENGTH(cp));
	digit = static_cast<int8_t>(u_digit(cp, 10));
	}

	// Try by digit string.
	if (digit == -1 && !fLocalDigitStrings.isNull()) {
	for (int32_t i = 0; i < 10; i++) {
	const UnicodeString& str = fLocalDigitStrings[i];
	if (str.isEmpty()) {
	continue;
	}
	int32_t overlap = segment.getCommonPrefixLength(str);
	if (overlap == str.length()) {
	segment.adjustOffset(overlap);
	digit = static_cast<int8_t>(i);
	break;
	}
	maybeMore = maybeMore \|\| (overlap == segment.length());
	}
	}

	if (digit >= 0) {
	// Digit was found.
	if (digitsConsumed.bogus) {
	digitsConsumed.bogus = false;
	digitsConsumed.clear();
	}
	digitsConsumed.appendDigit(digit, 0, true);
	currGroupCount++;
	if (!actualDecimalString.isBogus()) {
	digitsAfterDecimalPlace++;
	}
	continue;
	}

	// Attempt to match a literal grouping or decimal separator.
	bool isDecimal = false;
	bool isGrouping = false;

	// 1) Attempt the decimal separator string literal.
	// if (we have not seen a decimal separator yet) { ... }
	if (actualDecimalString.isBogus() && !decimalSeparator.isEmpty()) {
	int32_t overlap = segment.getCommonPrefixLength(decimalSeparator);
	maybeMore = maybeMore \|\| (overlap == segment.length());
	if (overlap == decimalSeparator.length()) {
	isDecimal = true;
	actualDecimalString = decimalSeparator;
	}
	}

	// 2) Attempt to match the actual grouping string literal.
	if (!actualGroupingString.isBogus()) {
	int32_t overlap = segment.getCommonPrefixLength(actualGroupingString);
	maybeMore = maybeMore \|\| (overlap == segment.length());
	if (overlap == actualGroupingString.length()) {
	isGrouping = true;
	}
	}

	// 2.5) Attempt to match a new the grouping separator string literal.
	// if (we have not seen a grouping or decimal separator yet) { ... }
	if (!groupingDisabled && actualGroupingString.isBogus() && actualDecimalString.isBogus() &&
	!groupingSeparator.isEmpty()) {
	int32_t overlap = segment.getCommonPrefixLength(groupingSeparator);
	maybeMore = maybeMore \|\| (overlap == segment.length());
	if (overlap == groupingSeparator.length()) {
	isGrouping = true;
	actualGroupingString = groupingSeparator;
	}
	}

	// 3) Attempt to match a decimal separator from the equivalence set.
	// if (we have not seen a decimal separator yet) { ... }
	// The !isGrouping is to confirm that we haven't yet matched the current character.
	if (!isGrouping && actualDecimalString.isBogus()) {
	if (decimalUniSet->contains(cp)) {
	isDecimal = true;
	actualDecimalString = UnicodeString(cp);
	}
	}

	// 4) Attempt to match a grouping separator from the equivalence set.
	// if (we have not seen a grouping or decimal separator yet) { ... }
	if (!groupingDisabled && actualGroupingString.isBogus() && actualDecimalString.isBogus()) {
	if (groupingUniSet->contains(cp)) {
	isGrouping = true;
	actualGroupingString = UnicodeString(cp);
	}
	}

	// Leave if we failed to match this as a separator.
	if (!isDecimal && !isGrouping) {
	break;
	}

	// Check for conditions when we don't want to accept the separator.
	if (isDecimal && integerOnly) {
	break;
	} else if (currGroupSepType == 2 && isGrouping) {
	// Fraction grouping
	break;
	}

	// Validate intermediate grouping sizes.
	bool prevValidSecondary = validateGroup(prevGroupSepType, prevGroupCount, false);
	bool currValidPrimary = validateGroup(currGroupSepType, currGroupCount, true);
	if (!prevValidSecondary \|\| (isDecimal && !currValidPrimary)) {
	// Invalid grouping sizes.
	if (isGrouping && currGroupCount == 0) {
	// Trailing grouping separators: these are taken care of below
	U_ASSERT(currGroupSepType == 1);
	} else if (requireGroupingMatch) {
	// Strict mode: reject the parse
	digitsConsumed.clear();
	digitsConsumed.bogus = true;
	}
	break;
	} else if (requireGroupingMatch && currGroupCount == 0 && currGroupSepType == 1) {
	break;
	} else {
	// Grouping sizes OK so far.
	prevGroupOffset = currGroupOffset;
	prevGroupCount = currGroupCount;
	if (isDecimal) {
	// Do not validate this group any more.
	prevGroupSepType = -1;
	} else {
	prevGroupSepType = currGroupSepType;
	}
	}

	// OK to accept the separator.
	// Special case: don't update currGroup if it is empty; this allows two grouping
	// separators in a row in lenient mode.
	if (currGroupCount != 0) {
	currGroupOffset = segment.getOffset();
	}
	currGroupSepType = isGrouping ? 1 : 2;
	currGroupCount = 0;
	if (isGrouping) {
	segment.adjustOffset(actualGroupingString.length());
	} else {
	segment.adjustOffset(actualDecimalString.length());
	}
	}

	// End of main loop.
	// Back up if there was a trailing grouping separator.
	// Shift prev -> curr so we can check it as a final group.
	if (currGroupSepType != 2 && currGroupCount == 0) {
	maybeMore = true;
	segment.setOffset(currGroupOffset);
	currGroupOffset = prevGroupOffset;
	currGroupSepType = prevGroupSepType;
	currGroupCount = prevGroupCount;
	prevGroupOffset = -1;
	prevGroupSepType = 0;
	prevGroupCount = 1;
	}

	// Validate final grouping sizes.
	bool prevValidSecondary = validateGroup(prevGroupSepType, prevGroupCount, false);
	bool currValidPrimary = validateGroup(currGroupSepType, currGroupCount, true);
	if (!requireGroupingMatch) {
	// The cases we need to handle here are lone digits.
	// Examples: "1,1" "1,1," "1,1,1" "1,1,1," ",1" (all parse as 1)
	// See more examples in numberformattestspecification.txt
	int32_t digitsToRemove = 0;
	if (!prevValidSecondary) {
	segment.setOffset(prevGroupOffset);
	digitsToRemove += prevGroupCount;
	digitsToRemove += currGroupCount;
	} else if (!currValidPrimary && (prevGroupSepType != 0 \|\| prevGroupCount != 0)) {
	maybeMore = true;
	segment.setOffset(currGroupOffset);
	digitsToRemove += currGroupCount;
	}
	if (digitsToRemove != 0) {
	digitsConsumed.adjustMagnitude(-digitsToRemove);
	digitsConsumed.truncate();
	}
	prevValidSecondary = true;
	currValidPrimary = true;
	}
	if (currGroupSepType != 2 && (!prevValidSecondary \|\| !currValidPrimary)) {
	// Grouping failure.
	digitsConsumed.bogus = true;
	}

	// Strings that start with a separator but have no digits,
	// or strings that failed a grouping size check.
	if (digitsConsumed.bogus) {
	maybeMore = maybeMore \|\| (segment.length() == 0);
	segment.setOffset(initialOffset);
	return maybeMore;
	}

	// We passed all inspections. Start post-processing.

	// Adjust for fraction part.
	digitsConsumed.adjustMagnitude(-digitsAfterDecimalPlace);

	// Set the digits, either normal or exponent.
	if (exponentSign != 0 && segment.getOffset() != initialOffset) {
	bool overflow = false;
	if (digitsConsumed.fitsInLong()) {
	int64_t exponentLong = digitsConsumed.toLong(false);
	U_ASSERT(exponentLong >= 0);
	if (exponentLong <= INT32_MAX) {
	auto exponentInt = static_cast<int32_t>(exponentLong);
	if (result.quantity.adjustMagnitude(exponentSign * exponentInt)) {
	overflow = true;
	}
	} else {
	overflow = true;
	}
	} else {
	overflow = true;
	}
	if (overflow) {
	if (exponentSign == -1) {
	// Set to zero
	result.quantity.clear();
	} else {
	// Set to infinity
	result.quantity.bogus = true;
	result.flags \|= FLAG_INFINITY;
	}
	}
	} else {
	result.quantity = digitsConsumed;
	}

	// Set other information into the result and return.
	if (!actualDecimalString.isBogus()) {
	result.flags \|= FLAG_HAS_DECIMAL_SEPARATOR;
	}
	result.setCharsConsumed(segment);
	return segment.length() == 0 \|\| maybeMore;
	}

	bool DecimalMatcher::validateGroup(int32_t sepType, int32_t count, bool isPrimary) const {
	if (requireGroupingMatch) {
	if (sepType == -1) {
	// No such group (prevGroup before first shift).
	return true;
	} else if (sepType == 0) {
	// First group.
	if (isPrimary) {
	// No grouping separators is OK.
	return true;
	} else {
	return count != 0 && count <= grouping2;
	}
	} else if (sepType == 1) {
	// Middle group.
	if (isPrimary) {
	return count == grouping1;
	} else {
	return count == grouping2;
	}
	} else {
	U_ASSERT(sepType == 2);
	// After the decimal separator.
	return true;
	}
	} else {
	if (sepType == 1) {
	// #11230: don't accept middle groups with only 1 digit.
	return count != 1;
	} else {
	return true;
	}
	}
	}

	bool DecimalMatcher::smokeTest(const StringSegment& segment) const {
	// The common case uses a static leadSet for efficiency.
	if (fLocalDigitStrings.isNull() && leadSet != nullptr) {
	return segment.startsWith(*leadSet);
	}
	if (segment.startsWith(*separatorSet) \|\| u_isdigit(segment.getCodePoint())) {
	return true;
	}
	if (fLocalDigitStrings.isNull()) {
	return false;
	}
	for (int32_t i = 0; i < 10; i++) {
	if (segment.startsWith(fLocalDigitStrings[i])) {
	return true;
	}
	}
	return false;
	}

	UnicodeString DecimalMatcher::toString() const {
	return u"<Decimal>";
	}


	#endif /* #if !UCONFIG_NO_FORMATTING */