icu4c/source/i18n/numparse_types.h - 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
 #ifndef __NUMPARSE_TYPES_H__
 #define __NUMPARSE_TYPES_H__

 #include "unicode/uobject.h"
 #include "number_decimalquantity.h"
 #include "string_segment.h"

 U_NAMESPACE_BEGIN
 namespace numparse {
 namespace impl {

 // Forward-declarations
 class ParsedNumber;

 typedef int32_t result_flags_t;
 typedef int32_t parse_flags_t;

 /** Flags for the type result_flags_t */
 enum ResultFlags {
     FLAG_NEGATIVE = 0x0001,
     FLAG_PERCENT = 0x0002,
     FLAG_PERMILLE = 0x0004,
     FLAG_HAS_EXPONENT = 0x0008,
     // FLAG_HAS_DEFAULT_CURRENCY = 0x0010, // no longer used
     FLAG_HAS_DECIMAL_SEPARATOR = 0x0020,
     FLAG_NAN = 0x0040,
     FLAG_INFINITY = 0x0080,
     FLAG_FAIL = 0x0100,
 };

 /** Flags for the type parse_flags_t */
 enum ParseFlags {
     PARSE_FLAG_IGNORE_CASE = 0x0001,
     PARSE_FLAG_MONETARY_SEPARATORS = 0x0002,
     PARSE_FLAG_STRICT_SEPARATORS = 0x0004,
     PARSE_FLAG_STRICT_GROUPING_SIZE = 0x0008,
     PARSE_FLAG_INTEGER_ONLY = 0x0010,
     PARSE_FLAG_GROUPING_DISABLED = 0x0020,
     // PARSE_FLAG_FRACTION_GROUPING_ENABLED = 0x0040, // see #10794
     PARSE_FLAG_INCLUDE_UNPAIRED_AFFIXES = 0x0080,
     PARSE_FLAG_USE_FULL_AFFIXES = 0x0100,
     PARSE_FLAG_EXACT_AFFIX = 0x0200,
     PARSE_FLAG_PLUS_SIGN_ALLOWED = 0x0400,
     // PARSE_FLAG_OPTIMIZE = 0x0800, // no longer used
     // PARSE_FLAG_FORCE_BIG_DECIMAL = 0x1000, // not used in ICU4C
     PARSE_FLAG_NO_FOREIGN_CURRENCY = 0x2000,
     PARSE_FLAG_ALLOW_INFINITE_RECURSION = 0x4000,
     PARSE_FLAG_STRICT_IGNORABLES = 0x8000,
 };


 // TODO: Is this class worthwhile?
 template<int32_t stackCapacity>
 class CompactUnicodeString {
   public:
     CompactUnicodeString() {
         static_assert(stackCapacity > 0, "cannot have zero space on stack");
         fBuffer[0] = 0;
     }

     CompactUnicodeString(const UnicodeString& text, UErrorCode& status)
             : fBuffer(text.length() + 1, status) {
         if (U_FAILURE(status)) { return; }
         uprv_memcpy(fBuffer.getAlias(), text.getBuffer(), sizeof(UChar) * text.length());
         fBuffer[text.length()] = 0;
     }

     inline UnicodeString toAliasedUnicodeString() const {
         return UnicodeString(true, fBuffer.getAlias(), -1);
     }

     bool operator==(const CompactUnicodeString& other) const {
         // Use the alias-only constructor and then call UnicodeString operator==
         return toAliasedUnicodeString() == other.toAliasedUnicodeString();
     }

   private:
     MaybeStackArray<UChar, stackCapacity> fBuffer;
 };


 /**
  * Struct-like class to hold the results of a parsing routine.
  *
  * @author sffc
  */
 // Exported as U_I18N_API for tests
 class U_I18N_API ParsedNumber {
   public:

     /**
      * The numerical value that was parsed.
      */
     ::icu::number::impl::DecimalQuantity quantity;

     /**
      * The index of the last char consumed during parsing. If parsing started at index 0, this is equal
      * to the number of chars consumed. This is NOT necessarily the same as the StringSegment offset;
      * "weak" chars, like whitespace, change the offset, but the charsConsumed is not touched until a
      * "strong" char is encountered.
      */
     int32_t charEnd;

     /**
      * Boolean flags (see constants above).
      */
     result_flags_t flags;

     /**
      * The pattern string corresponding to the prefix that got consumed.
      */
     UnicodeString prefix;

     /**
      * The pattern string corresponding to the suffix that got consumed.
      */
     UnicodeString suffix;

     /**
      * The currency that got consumed.
      */
     UChar currencyCode[4];

     ParsedNumber();

     ParsedNumber(const ParsedNumber& other) = default;

     ParsedNumber& operator=(const ParsedNumber& other) = default;

     void clear();

     /**
      * Call this method to register that a "strong" char was consumed. This should be done after calling
      * {@link StringSegment#setOffset} or {@link StringSegment#adjustOffset} except when the char is
      * "weak", like whitespace.
      *
      * <p>
      * <strong>What is a strong versus weak char?</strong> The behavior of number parsing is to "stop"
      * after reading the number, even if there is other content following the number. For example, after
      * parsing the string "123 " (123 followed by a space), the cursor should be set to 3, not 4, even
      * though there are matchers that accept whitespace. In this example, the digits are strong, whereas
      * the whitespace is weak. Grouping separators are weak, whereas decimal separators are strong. Most
      * other chars are strong.
      *
      * @param segment
      *            The current StringSegment, usually immediately following a call to setOffset.
      */
     void setCharsConsumed(const StringSegment& segment);

     /** Apply certain number-related flags to the DecimalQuantity. */
     void postProcess();

     /**
      * Returns whether this the parse was successful. To be successful, at least one char must have been
      * consumed, and the failure flag must not be set.
      */
     bool success() const;

     bool seenNumber() const;

     double getDouble(UErrorCode& status) const;

     void populateFormattable(Formattable& output, parse_flags_t parseFlags) const;

     bool isBetterThan(const ParsedNumber& other);
 };


 /**
  * The core interface implemented by all matchers used for number parsing.
  *
  * Given a string, there should NOT be more than one way to consume the string with the same matcher
  * applied multiple times. If there is, the non-greedy parsing algorithm will be unhappy and may enter an
  * exponential-time loop. For example, consider the "A Matcher" that accepts "any number of As". Given
  * the string "AAAA", there are 2^N = 8 ways to apply the A Matcher to this string: you could have the A
  * Matcher apply 4 times to each character; you could have it apply just once to all the characters; you
  * could have it apply to the first 2 characters and the second 2 characters; and so on. A better version
  * of the "A Matcher" would be for it to accept exactly one A, and allow the algorithm to run it
  * repeatedly to consume a string of multiple As. The A Matcher can implement the Flexible interface
  * below to signal that it can be applied multiple times in a row.
  *
  * @author sffc
  */
 // Exported as U_I18N_API for tests
 class U_I18N_API NumberParseMatcher {
   public:
     virtual ~NumberParseMatcher();

     /**
      * Matchers can override this method to return true to indicate that they are optional and can be run
      * repeatedly. Used by SeriesMatcher, primarily in the context of IgnorablesMatcher.
      */
     virtual bool isFlexible() const {
         return false;
     }

     /**
      * Runs this matcher starting at the beginning of the given StringSegment. If this matcher finds
      * something interesting in the StringSegment, it should update the offset of the StringSegment
      * corresponding to how many chars were matched.
      *
      * This method is thread-safe.
      *
      * @param segment
      *            The StringSegment to match against. Matches always start at the beginning of the
      *            segment. The segment is guaranteed to contain at least one char.
      * @param result
      *            The data structure to store results if the match succeeds.
      * @return Whether this matcher thinks there may be more interesting chars beyond the end of the
      *         string segment.
      */
     virtual bool match(StringSegment& segment, ParsedNumber& result, UErrorCode& status) const = 0;

     /**
      * Performs a fast "smoke check" for whether or not this matcher could possibly match against the
      * given string segment. The test should be as fast as possible but also as restrictive as possible.
      * For example, matchers can maintain a UnicodeSet of all code points that count possibly start a
      * match. Matchers should use the {@link StringSegment#startsWith} method in order to correctly
      * handle case folding.
      *
      * @param segment
      *            The segment to check against.
      * @return true if the matcher might be able to match against this segment; false if it definitely
      *         will not be able to match.
      */
     virtual bool smokeTest(const StringSegment& segment) const = 0;

     /**
      * Method called at the end of a parse, after all matchers have failed to consume any more chars.
      * Allows a matcher to make final modifications to the result given the knowledge that no more
      * matches are possible.
      *
      * @param result
      *            The data structure to store results.
      */
     virtual void postProcess(ParsedNumber&) const {
         // Default implementation: no-op
     }

     // String for debugging
     virtual UnicodeString toString() const = 0;

   protected:
     // No construction except by subclasses!
     NumberParseMatcher() = default;
 };


 /**
  * Interface for use in arguments.
  */
 // Exported as U_I18N_API for tests
 class U_I18N_API MutableMatcherCollection {
   public:
     virtual ~MutableMatcherCollection() = default;

     virtual void addMatcher(NumberParseMatcher& matcher) = 0;
 };


 } // namespace impl
 } // namespace numparse
 U_NAMESPACE_END

 #endif //__NUMPARSE_TYPES_H__
 #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
	#ifndef __NUMPARSE_TYPES_H__
	#define __NUMPARSE_TYPES_H__

	#include "unicode/uobject.h"
	#include "number_decimalquantity.h"
	#include "string_segment.h"

	U_NAMESPACE_BEGIN
	namespace numparse {
	namespace impl {

	// Forward-declarations
	class ParsedNumber;

	typedef int32_t result_flags_t;
	typedef int32_t parse_flags_t;

	/** Flags for the type result_flags_t */
	enum ResultFlags {
	FLAG_NEGATIVE = 0x0001,
	FLAG_PERCENT = 0x0002,
	FLAG_PERMILLE = 0x0004,
	FLAG_HAS_EXPONENT = 0x0008,
	// FLAG_HAS_DEFAULT_CURRENCY = 0x0010, // no longer used
	FLAG_HAS_DECIMAL_SEPARATOR = 0x0020,
	FLAG_NAN = 0x0040,
	FLAG_INFINITY = 0x0080,
	FLAG_FAIL = 0x0100,
	};

	/** Flags for the type parse_flags_t */
	enum ParseFlags {
	PARSE_FLAG_IGNORE_CASE = 0x0001,
	PARSE_FLAG_MONETARY_SEPARATORS = 0x0002,
	PARSE_FLAG_STRICT_SEPARATORS = 0x0004,
	PARSE_FLAG_STRICT_GROUPING_SIZE = 0x0008,
	PARSE_FLAG_INTEGER_ONLY = 0x0010,
	PARSE_FLAG_GROUPING_DISABLED = 0x0020,
	// PARSE_FLAG_FRACTION_GROUPING_ENABLED = 0x0040, // see #10794
	PARSE_FLAG_INCLUDE_UNPAIRED_AFFIXES = 0x0080,
	PARSE_FLAG_USE_FULL_AFFIXES = 0x0100,
	PARSE_FLAG_EXACT_AFFIX = 0x0200,
	PARSE_FLAG_PLUS_SIGN_ALLOWED = 0x0400,
	// PARSE_FLAG_OPTIMIZE = 0x0800, // no longer used
	// PARSE_FLAG_FORCE_BIG_DECIMAL = 0x1000, // not used in ICU4C
	PARSE_FLAG_NO_FOREIGN_CURRENCY = 0x2000,
	PARSE_FLAG_ALLOW_INFINITE_RECURSION = 0x4000,
	PARSE_FLAG_STRICT_IGNORABLES = 0x8000,
	};


	// TODO: Is this class worthwhile?
	template<int32_t stackCapacity>
	class CompactUnicodeString {
	public:
	CompactUnicodeString() {
	static_assert(stackCapacity > 0, "cannot have zero space on stack");
	fBuffer[0] = 0;
	}

	CompactUnicodeString(const UnicodeString& text, UErrorCode& status)
	: fBuffer(text.length() + 1, status) {
	if (U_FAILURE(status)) { return; }
	uprv_memcpy(fBuffer.getAlias(), text.getBuffer(), sizeof(UChar) * text.length());
	fBuffer[text.length()] = 0;
	}

	inline UnicodeString toAliasedUnicodeString() const {
	return UnicodeString(true, fBuffer.getAlias(), -1);
	}

	bool operator==(const CompactUnicodeString& other) const {
	// Use the alias-only constructor and then call UnicodeString operator==
	return toAliasedUnicodeString() == other.toAliasedUnicodeString();
	}

	private:
	MaybeStackArray<UChar, stackCapacity> fBuffer;
	};


	/**
	* Struct-like class to hold the results of a parsing routine.
	*
	* @author sffc
	*/
	// Exported as U_I18N_API for tests
	class U_I18N_API ParsedNumber {
	public:

	/**
	* The numerical value that was parsed.
	*/
	::icu::number::impl::DecimalQuantity quantity;

	/**
	* The index of the last char consumed during parsing. If parsing started at index 0, this is equal
	* to the number of chars consumed. This is NOT necessarily the same as the StringSegment offset;
	* "weak" chars, like whitespace, change the offset, but the charsConsumed is not touched until a
	* "strong" char is encountered.
	*/
	int32_t charEnd;

	/**
	* Boolean flags (see constants above).
	*/
	result_flags_t flags;

	/**
	* The pattern string corresponding to the prefix that got consumed.
	*/
	UnicodeString prefix;

	/**
	* The pattern string corresponding to the suffix that got consumed.
	*/
	UnicodeString suffix;

	/**
	* The currency that got consumed.
	*/
	UChar currencyCode[4];

	ParsedNumber();

	ParsedNumber(const ParsedNumber& other) = default;

	ParsedNumber& operator=(const ParsedNumber& other) = default;

	void clear();

	/**
	* Call this method to register that a "strong" char was consumed. This should be done after calling
	* {@link StringSegment#setOffset} or {@link StringSegment#adjustOffset} except when the char is
	* "weak", like whitespace.
	*
	* <p>
	* <strong>What is a strong versus weak char?</strong> The behavior of number parsing is to "stop"
	* after reading the number, even if there is other content following the number. For example, after
	* parsing the string "123 " (123 followed by a space), the cursor should be set to 3, not 4, even
	* though there are matchers that accept whitespace. In this example, the digits are strong, whereas
	* the whitespace is weak. Grouping separators are weak, whereas decimal separators are strong. Most
	* other chars are strong.
	*
	* @param segment
	* The current StringSegment, usually immediately following a call to setOffset.
	*/
	void setCharsConsumed(const StringSegment& segment);

	/** Apply certain number-related flags to the DecimalQuantity. */
	void postProcess();

	/**
	* Returns whether this the parse was successful. To be successful, at least one char must have been
	* consumed, and the failure flag must not be set.
	*/
	bool success() const;

	bool seenNumber() const;

	double getDouble(UErrorCode& status) const;

	void populateFormattable(Formattable& output, parse_flags_t parseFlags) const;

	bool isBetterThan(const ParsedNumber& other);
	};


	/**
	* The core interface implemented by all matchers used for number parsing.
	*
	* Given a string, there should NOT be more than one way to consume the string with the same matcher
	* applied multiple times. If there is, the non-greedy parsing algorithm will be unhappy and may enter an
	* exponential-time loop. For example, consider the "A Matcher" that accepts "any number of As". Given
	* the string "AAAA", there are 2^N = 8 ways to apply the A Matcher to this string: you could have the A
	* Matcher apply 4 times to each character; you could have it apply just once to all the characters; you
	* could have it apply to the first 2 characters and the second 2 characters; and so on. A better version
	* of the "A Matcher" would be for it to accept exactly one A, and allow the algorithm to run it
	* repeatedly to consume a string of multiple As. The A Matcher can implement the Flexible interface
	* below to signal that it can be applied multiple times in a row.
	*
	* @author sffc
	*/
	// Exported as U_I18N_API for tests
	class U_I18N_API NumberParseMatcher {
	public:
	virtual ~NumberParseMatcher();

	/**
	* Matchers can override this method to return true to indicate that they are optional and can be run
	* repeatedly. Used by SeriesMatcher, primarily in the context of IgnorablesMatcher.
	*/
	virtual bool isFlexible() const {
	return false;
	}

	/**
	* Runs this matcher starting at the beginning of the given StringSegment. If this matcher finds
	* something interesting in the StringSegment, it should update the offset of the StringSegment
	* corresponding to how many chars were matched.
	*
	* This method is thread-safe.
	*
	* @param segment
	* The StringSegment to match against. Matches always start at the beginning of the
	* segment. The segment is guaranteed to contain at least one char.
	* @param result
	* The data structure to store results if the match succeeds.
	* @return Whether this matcher thinks there may be more interesting chars beyond the end of the
	* string segment.
	*/
	virtual bool match(StringSegment& segment, ParsedNumber& result, UErrorCode& status) const = 0;

	/**
	* Performs a fast "smoke check" for whether or not this matcher could possibly match against the
	* given string segment. The test should be as fast as possible but also as restrictive as possible.
	* For example, matchers can maintain a UnicodeSet of all code points that count possibly start a
	* match. Matchers should use the {@link StringSegment#startsWith} method in order to correctly
	* handle case folding.
	*
	* @param segment
	* The segment to check against.
	* @return true if the matcher might be able to match against this segment; false if it definitely
	* will not be able to match.
	*/
	virtual bool smokeTest(const StringSegment& segment) const = 0;

	/**
	* Method called at the end of a parse, after all matchers have failed to consume any more chars.
	* Allows a matcher to make final modifications to the result given the knowledge that no more
	* matches are possible.
	*
	* @param result
	* The data structure to store results.
	*/
	virtual void postProcess(ParsedNumber&) const {
	// Default implementation: no-op
	}

	// String for debugging
	virtual UnicodeString toString() const = 0;

	protected:
	// No construction except by subclasses!
	NumberParseMatcher() = default;
	};


	/**
	* Interface for use in arguments.
	*/
	// Exported as U_I18N_API for tests
	class U_I18N_API MutableMatcherCollection {
	public:
	virtual ~MutableMatcherCollection() = default;

	virtual void addMatcher(NumberParseMatcher& matcher) = 0;
	};


	} // namespace impl
	} // namespace numparse
	U_NAMESPACE_END

	#endif //__NUMPARSE_TYPES_H__
	#endif /* #if !UCONFIG_NO_FORMATTING */