1/*
2******************************************************************************
3*   Copyright (C) 1997-2012, International Business Machines
4*   Corporation and others.  All Rights Reserved.
5******************************************************************************
6*   file name:  nfsubs.cpp
7*   encoding:   US-ASCII
8*   tab size:   8 (not used)
9*   indentation:4
10*
11* Modification history
12* Date        Name      Comments
13* 10/11/2001  Doug      Ported from ICU4J
14*/
15
16#include <stdio.h>
17#include "utypeinfo.h"  // for 'typeid' to work
18
19#include "nfsubs.h"
20#include "digitlst.h"
21
22#if U_HAVE_RBNF
23
24static const UChar gLessThan = 0x003c;
25static const UChar gEquals = 0x003d;
26static const UChar gGreaterThan = 0x003e;
27static const UChar gPercent = 0x0025;
28static const UChar gPound = 0x0023;
29static const UChar gZero = 0x0030;
30static const UChar gSpace = 0x0020;
31
32static const UChar gEqualsEquals[] =
33{
34    0x3D, 0x3D, 0
35}; /* "==" */
36static const UChar gGreaterGreaterGreaterThan[] =
37{
38    0x3E, 0x3E, 0x3E, 0
39}; /* ">>>" */
40static const UChar gGreaterGreaterThan[] =
41{
42    0x3E, 0x3E, 0
43}; /* ">>" */
44
45U_NAMESPACE_BEGIN
46
47class SameValueSubstitution : public NFSubstitution {
48public:
49    SameValueSubstitution(int32_t pos,
50        const NFRuleSet* ruleset,
51        const RuleBasedNumberFormat* formatter,
52        const UnicodeString& description,
53        UErrorCode& status);
54    virtual ~SameValueSubstitution();
55
56    virtual int64_t transformNumber(int64_t number) const { return number; }
57    virtual double transformNumber(double number) const { return number; }
58    virtual double composeRuleValue(double newRuleValue, double /*oldRuleValue*/) const { return newRuleValue; }
59    virtual double calcUpperBound(double oldUpperBound) const { return oldUpperBound; }
60    virtual UChar tokenChar() const { return (UChar)0x003d; } // '='
61
62public:
63    static UClassID getStaticClassID(void);
64    virtual UClassID getDynamicClassID(void) const;
65};
66
67SameValueSubstitution::~SameValueSubstitution() {}
68
69class MultiplierSubstitution : public NFSubstitution {
70    double divisor;
71    int64_t ldivisor;
72
73public:
74    MultiplierSubstitution(int32_t _pos,
75        double _divisor,
76        const NFRuleSet* _ruleSet,
77        const RuleBasedNumberFormat* formatter,
78        const UnicodeString& description,
79        UErrorCode& status)
80        : NFSubstitution(_pos, _ruleSet, formatter, description, status), divisor(_divisor)
81    {
82        ldivisor = util64_fromDouble(divisor);
83        if (divisor == 0) {
84            status = U_PARSE_ERROR;
85        }
86    }
87    virtual ~MultiplierSubstitution();
88
89    virtual void setDivisor(int32_t radix, int32_t exponent, UErrorCode& status) {
90        divisor = uprv_pow(radix, exponent);
91        ldivisor = util64_fromDouble(divisor);
92
93        if(divisor == 0) {
94            status = U_PARSE_ERROR;
95        }
96    }
97
98    virtual UBool operator==(const NFSubstitution& rhs) const;
99
100    virtual int64_t transformNumber(int64_t number) const {
101        return number / ldivisor;
102    }
103
104    virtual double transformNumber(double number) const {
105        if (getRuleSet()) {
106            return uprv_floor(number / divisor);
107        } else {
108            return number/divisor;
109        }
110    }
111
112    virtual double composeRuleValue(double newRuleValue, double /*oldRuleValue*/) const {
113        return newRuleValue * divisor;
114    }
115
116    virtual double calcUpperBound(double /*oldUpperBound*/) const { return divisor; }
117
118    virtual UChar tokenChar() const { return (UChar)0x003c; } // '<'
119
120public:
121    static UClassID getStaticClassID(void);
122    virtual UClassID getDynamicClassID(void) const;
123};
124
125MultiplierSubstitution::~MultiplierSubstitution() {}
126
127class ModulusSubstitution : public NFSubstitution {
128    double divisor;
129    int64_t  ldivisor;
130    const NFRule* ruleToUse;
131public:
132    ModulusSubstitution(int32_t pos,
133        double _divisor,
134        const NFRule* rulePredecessor,
135        const NFRuleSet* ruleSet,
136        const RuleBasedNumberFormat* formatter,
137        const UnicodeString& description,
138        UErrorCode& status);
139    virtual ~ModulusSubstitution();
140
141    virtual void setDivisor(int32_t radix, int32_t exponent, UErrorCode& status) {
142        divisor = uprv_pow(radix, exponent);
143        ldivisor = util64_fromDouble(divisor);
144
145        if (divisor == 0) {
146            status = U_PARSE_ERROR;
147        }
148    }
149
150    virtual UBool operator==(const NFSubstitution& rhs) const;
151
152    virtual void doSubstitution(int64_t number, UnicodeString& toInsertInto, int32_t pos) const;
153    virtual void doSubstitution(double number, UnicodeString& toInsertInto, int32_t pos) const;
154
155    virtual int64_t transformNumber(int64_t number) const { return number % ldivisor; }
156    virtual double transformNumber(double number) const { return uprv_fmod(number, divisor); }
157
158    virtual UBool doParse(const UnicodeString& text,
159        ParsePosition& parsePosition,
160        double baseValue,
161        double upperBound,
162        UBool lenientParse,
163        Formattable& result) const;
164
165    virtual double composeRuleValue(double newRuleValue, double oldRuleValue) const {
166        return oldRuleValue - uprv_fmod(oldRuleValue, divisor) + newRuleValue;
167    }
168
169    virtual double calcUpperBound(double /*oldUpperBound*/) const { return divisor; }
170
171    virtual UBool isModulusSubstitution() const { return TRUE; }
172
173    virtual UChar tokenChar() const { return (UChar)0x003e; } // '>'
174
175	virtual void toString(UnicodeString& result) const;
176
177public:
178    static UClassID getStaticClassID(void);
179    virtual UClassID getDynamicClassID(void) const;
180};
181
182ModulusSubstitution::~ModulusSubstitution() {}
183
184class IntegralPartSubstitution : public NFSubstitution {
185public:
186    IntegralPartSubstitution(int32_t _pos,
187        const NFRuleSet* _ruleSet,
188        const RuleBasedNumberFormat* formatter,
189        const UnicodeString& description,
190        UErrorCode& status)
191        : NFSubstitution(_pos, _ruleSet, formatter, description, status) {}
192    virtual ~IntegralPartSubstitution();
193
194    virtual int64_t transformNumber(int64_t number) const { return number; }
195    virtual double transformNumber(double number) const { return uprv_floor(number); }
196    virtual double composeRuleValue(double newRuleValue, double oldRuleValue) const { return newRuleValue + oldRuleValue; }
197    virtual double calcUpperBound(double /*oldUpperBound*/) const { return DBL_MAX; }
198    virtual UChar tokenChar() const { return (UChar)0x003c; } // '<'
199
200public:
201    static UClassID getStaticClassID(void);
202    virtual UClassID getDynamicClassID(void) const;
203};
204
205IntegralPartSubstitution::~IntegralPartSubstitution() {}
206
207class FractionalPartSubstitution : public NFSubstitution {
208    UBool byDigits;
209    UBool useSpaces;
210    enum { kMaxDecimalDigits = 8 };
211public:
212    FractionalPartSubstitution(int32_t pos,
213        const NFRuleSet* ruleSet,
214        const RuleBasedNumberFormat* formatter,
215        const UnicodeString& description,
216        UErrorCode& status);
217    virtual ~FractionalPartSubstitution();
218
219    virtual UBool operator==(const NFSubstitution& rhs) const;
220
221    virtual void doSubstitution(double number, UnicodeString& toInsertInto, int32_t pos) const;
222    virtual void doSubstitution(int64_t /*number*/, UnicodeString& /*toInsertInto*/, int32_t /*_pos*/) const {}
223    virtual int64_t transformNumber(int64_t /*number*/) const { return 0; }
224    virtual double transformNumber(double number) const { return number - uprv_floor(number); }
225
226    virtual UBool doParse(const UnicodeString& text,
227        ParsePosition& parsePosition,
228        double baseValue,
229        double upperBound,
230        UBool lenientParse,
231        Formattable& result) const;
232
233    virtual double composeRuleValue(double newRuleValue, double oldRuleValue) const { return newRuleValue + oldRuleValue; }
234    virtual double calcUpperBound(double /*oldUpperBound*/) const { return 0.0; }
235    virtual UChar tokenChar() const { return (UChar)0x003e; } // '>'
236
237public:
238    static UClassID getStaticClassID(void);
239    virtual UClassID getDynamicClassID(void) const;
240};
241
242FractionalPartSubstitution::~FractionalPartSubstitution() {}
243
244class AbsoluteValueSubstitution : public NFSubstitution {
245public:
246    AbsoluteValueSubstitution(int32_t _pos,
247        const NFRuleSet* _ruleSet,
248        const RuleBasedNumberFormat* formatter,
249        const UnicodeString& description,
250        UErrorCode& status)
251        : NFSubstitution(_pos, _ruleSet, formatter, description, status) {}
252    virtual ~AbsoluteValueSubstitution();
253
254    virtual int64_t transformNumber(int64_t number) const { return number >= 0 ? number : -number; }
255    virtual double transformNumber(double number) const { return uprv_fabs(number); }
256    virtual double composeRuleValue(double newRuleValue, double /*oldRuleValue*/) const { return -newRuleValue; }
257    virtual double calcUpperBound(double /*oldUpperBound*/) const { return DBL_MAX; }
258    virtual UChar tokenChar() const { return (UChar)0x003e; } // '>'
259
260public:
261    static UClassID getStaticClassID(void);
262    virtual UClassID getDynamicClassID(void) const;
263};
264
265AbsoluteValueSubstitution::~AbsoluteValueSubstitution() {}
266
267class NumeratorSubstitution : public NFSubstitution {
268    double denominator;
269    int64_t ldenominator;
270    UBool withZeros;
271public:
272    static inline UnicodeString fixdesc(const UnicodeString& desc) {
273        if (desc.endsWith(LTLT, 2)) {
274            UnicodeString result(desc, 0, desc.length()-1);
275            return result;
276        }
277        return desc;
278    }
279    NumeratorSubstitution(int32_t _pos,
280        double _denominator,
281        const NFRuleSet* _ruleSet,
282        const RuleBasedNumberFormat* formatter,
283        const UnicodeString& description,
284        UErrorCode& status)
285        : NFSubstitution(_pos, _ruleSet, formatter, fixdesc(description), status), denominator(_denominator)
286    {
287        ldenominator = util64_fromDouble(denominator);
288        withZeros = description.endsWith(LTLT, 2);
289    }
290    virtual ~NumeratorSubstitution();
291
292    virtual UBool operator==(const NFSubstitution& rhs) const;
293
294    virtual int64_t transformNumber(int64_t number) const { return number * ldenominator; }
295    virtual double transformNumber(double number) const { return uprv_round(number * denominator); }
296
297    virtual void doSubstitution(int64_t /*number*/, UnicodeString& /*toInsertInto*/, int32_t /*_pos*/) const {}
298    virtual void doSubstitution(double number, UnicodeString& toInsertInto, int32_t pos) const;
299    virtual UBool doParse(const UnicodeString& text,
300        ParsePosition& parsePosition,
301        double baseValue,
302        double upperBound,
303        UBool /*lenientParse*/,
304        Formattable& result) const;
305
306    virtual double composeRuleValue(double newRuleValue, double oldRuleValue) const { return newRuleValue / oldRuleValue; }
307    virtual double calcUpperBound(double /*oldUpperBound*/) const { return denominator; }
308    virtual UChar tokenChar() const { return (UChar)0x003c; } // '<'
309private:
310    static const UChar LTLT[2];
311
312public:
313    static UClassID getStaticClassID(void);
314    virtual UClassID getDynamicClassID(void) const;
315};
316
317NumeratorSubstitution::~NumeratorSubstitution() {}
318
319class NullSubstitution : public NFSubstitution {
320public:
321    NullSubstitution(int32_t _pos,
322        const NFRuleSet* _ruleSet,
323        const RuleBasedNumberFormat* formatter,
324        const UnicodeString& description,
325        UErrorCode& status)
326        : NFSubstitution(_pos, _ruleSet, formatter, description, status) {}
327    virtual ~NullSubstitution();
328
329    virtual void toString(UnicodeString& /*result*/) const {}
330    virtual void doSubstitution(double /*number*/, UnicodeString& /*toInsertInto*/, int32_t /*_pos*/) const {}
331    virtual void doSubstitution(int64_t /*number*/, UnicodeString& /*toInsertInto*/, int32_t /*_pos*/) const {}
332    virtual int64_t transformNumber(int64_t /*number*/) const { return 0; }
333    virtual double transformNumber(double /*number*/) const { return 0; }
334    virtual UBool doParse(const UnicodeString& /*text*/,
335        ParsePosition& /*parsePosition*/,
336        double baseValue,
337        double /*upperBound*/,
338        UBool /*lenientParse*/,
339        Formattable& result) const
340    { result.setDouble(baseValue); return TRUE; }
341    virtual double composeRuleValue(double /*newRuleValue*/, double /*oldRuleValue*/) const { return 0.0; } // never called
342    virtual double calcUpperBound(double /*oldUpperBound*/) const { return 0; } // never called
343    virtual UBool isNullSubstitution() const { return TRUE; }
344    virtual UChar tokenChar() const { return (UChar)0x0020; } // ' ' never called
345
346public:
347    static UClassID getStaticClassID(void);
348    virtual UClassID getDynamicClassID(void) const;
349};
350
351NullSubstitution::~NullSubstitution() {}
352
353NFSubstitution*
354NFSubstitution::makeSubstitution(int32_t pos,
355                                 const NFRule* rule,
356                                 const NFRule* predecessor,
357                                 const NFRuleSet* ruleSet,
358                                 const RuleBasedNumberFormat* formatter,
359                                 const UnicodeString& description,
360                                 UErrorCode& status)
361{
362    // if the description is empty, return a NullSubstitution
363    if (description.length() == 0) {
364        return new NullSubstitution(pos, ruleSet, formatter, description, status);
365    }
366
367    switch (description.charAt(0)) {
368        // if the description begins with '<'...
369    case gLessThan:
370        // throw an exception if the rule is a negative number
371        // rule
372        if (rule->getBaseValue() == NFRule::kNegativeNumberRule) {
373            // throw new IllegalArgumentException("<< not allowed in negative-number rule");
374            status = U_PARSE_ERROR;
375            return NULL;
376        }
377
378        // if the rule is a fraction rule, return an
379        // IntegralPartSubstitution
380        else if (rule->getBaseValue() == NFRule::kImproperFractionRule
381            || rule->getBaseValue() == NFRule::kProperFractionRule
382            || rule->getBaseValue() == NFRule::kMasterRule) {
383            return new IntegralPartSubstitution(pos, ruleSet, formatter, description, status);
384        }
385
386        // if the rule set containing the rule is a fraction
387        // rule set, return a NumeratorSubstitution
388        else if (ruleSet->isFractionRuleSet()) {
389            return new NumeratorSubstitution(pos, (double)rule->getBaseValue(),
390                formatter->getDefaultRuleSet(), formatter, description, status);
391        }
392
393        // otherwise, return a MultiplierSubstitution
394        else {
395            return new MultiplierSubstitution(pos, rule->getDivisor(), ruleSet,
396                formatter, description, status);
397        }
398
399        // if the description begins with '>'...
400    case gGreaterThan:
401        // if the rule is a negative-number rule, return
402        // an AbsoluteValueSubstitution
403        if (rule->getBaseValue() == NFRule::kNegativeNumberRule) {
404            return new AbsoluteValueSubstitution(pos, ruleSet, formatter, description, status);
405        }
406
407        // if the rule is a fraction rule, return a
408        // FractionalPartSubstitution
409        else if (rule->getBaseValue() == NFRule::kImproperFractionRule
410            || rule->getBaseValue() == NFRule::kProperFractionRule
411            || rule->getBaseValue() == NFRule::kMasterRule) {
412            return new FractionalPartSubstitution(pos, ruleSet, formatter, description, status);
413        }
414
415        // if the rule set owning the rule is a fraction rule set,
416        // throw an exception
417        else if (ruleSet->isFractionRuleSet()) {
418            // throw new IllegalArgumentException(">> not allowed in fraction rule set");
419            status = U_PARSE_ERROR;
420            return NULL;
421        }
422
423        // otherwise, return a ModulusSubstitution
424        else {
425            return new ModulusSubstitution(pos, rule->getDivisor(), predecessor,
426                ruleSet, formatter, description, status);
427        }
428
429        // if the description begins with '=', always return a
430        // SameValueSubstitution
431    case gEquals:
432        return new SameValueSubstitution(pos, ruleSet, formatter, description, status);
433
434        // and if it's anything else, throw an exception
435    default:
436        // throw new IllegalArgumentException("Illegal substitution character");
437        status = U_PARSE_ERROR;
438    }
439    return NULL;
440}
441
442NFSubstitution::NFSubstitution(int32_t _pos,
443                               const NFRuleSet* _ruleSet,
444                               const RuleBasedNumberFormat* formatter,
445                               const UnicodeString& description,
446                               UErrorCode& status)
447                               : pos(_pos), ruleSet(NULL), numberFormat(NULL)
448{
449    // the description should begin and end with the same character.
450    // If it doesn't that's a syntax error.  Otherwise,
451    // makeSubstitution() was the only thing that needed to know
452    // about these characters, so strip them off
453    UnicodeString workingDescription(description);
454    if (description.length() >= 2
455        && description.charAt(0) == description.charAt(description.length() - 1))
456    {
457        workingDescription.remove(description.length() - 1, 1);
458        workingDescription.remove(0, 1);
459    }
460    else if (description.length() != 0) {
461        // throw new IllegalArgumentException("Illegal substitution syntax");
462        status = U_PARSE_ERROR;
463        return;
464    }
465
466    // if the description was just two paired token characters
467    // (i.e., "<<" or ">>"), it uses the rule set it belongs to to
468    // format its result
469    if (workingDescription.length() == 0) {
470        this->ruleSet = _ruleSet;
471    }
472    // if the description contains a rule set name, that's the rule
473    // set we use to format the result: get a reference to the
474    // names rule set
475    else if (workingDescription.charAt(0) == gPercent) {
476        this->ruleSet = formatter->findRuleSet(workingDescription, status);
477    }
478    // if the description begins with 0 or #, treat it as a
479    // DecimalFormat pattern, and initialize a DecimalFormat with
480    // that pattern (then set it to use the DecimalFormatSymbols
481    // belonging to our formatter)
482    else if (workingDescription.charAt(0) == gPound || workingDescription.charAt(0) ==gZero) {
483        DecimalFormatSymbols* sym = formatter->getDecimalFormatSymbols();
484        if (!sym) {
485            status = U_MISSING_RESOURCE_ERROR;
486            return;
487        }
488        this->numberFormat = new DecimalFormat(workingDescription, *sym, status);
489        /* test for NULL */
490        if (this->numberFormat == 0) {
491            status = U_MEMORY_ALLOCATION_ERROR;
492            return;
493        }
494        if (U_FAILURE(status)) {
495            delete (DecimalFormat*)this->numberFormat;
496            this->numberFormat = NULL;
497            return;
498        }
499        // this->numberFormat->setDecimalFormatSymbols(formatter->getDecimalFormatSymbols());
500    }
501    // if the description is ">>>", this substitution bypasses the
502    // usual rule-search process and always uses the rule that precedes
503    // it in its own rule set's rule list (this is used for place-value
504    // notations: formats where you want to see a particular part of
505    // a number even when it's 0)
506    else if (workingDescription.charAt(0) == gGreaterThan) {
507        // this causes problems when >>> is used in a frationalPartSubstitution
508        // this->ruleSet = NULL;
509        this->ruleSet = _ruleSet;
510        this->numberFormat = NULL;
511    }
512    // and of the description is none of these things, it's a syntax error
513    else {
514        // throw new IllegalArgumentException("Illegal substitution syntax");
515        status = U_PARSE_ERROR;
516    }
517}
518
519NFSubstitution::~NFSubstitution()
520{
521  // cast away const
522  delete (NumberFormat*)numberFormat; numberFormat = NULL;
523}
524
525/**
526 * Set's the substitution's divisor.  Used by NFRule.setBaseValue().
527 * A no-op for all substitutions except multiplier and modulus
528 * substitutions.
529 * @param radix The radix of the divisor
530 * @param exponent The exponent of the divisor
531 */
532void
533NFSubstitution::setDivisor(int32_t /*radix*/, int32_t /*exponent*/, UErrorCode& /*status*/) {
534  // a no-op for all substitutions except multiplier and modulus substitutions
535}
536
537
538//-----------------------------------------------------------------------
539// boilerplate
540//-----------------------------------------------------------------------
541
542UOBJECT_DEFINE_RTTI_IMPLEMENTATION(NFSubstitution)
543
544/**
545 * Compares two substitutions for equality
546 * @param The substitution to compare this one to
547 * @return true if the two substitutions are functionally equivalent
548 */
549UBool
550NFSubstitution::operator==(const NFSubstitution& rhs) const
551{
552  // compare class and all of the fields all substitutions have
553  // in common
554  // this should be called by subclasses before their own equality tests
555  return typeid(*this) == typeid(rhs)
556  && pos == rhs.pos
557  && (ruleSet == NULL) == (rhs.ruleSet == NULL)
558  // && ruleSet == rhs.ruleSet causes circularity, other checks to make instead?
559  && (numberFormat == NULL
560      ? (rhs.numberFormat == NULL)
561      : (*numberFormat == *rhs.numberFormat));
562}
563
564/**
565 * Returns a textual description of the substitution
566 * @return A textual description of the substitution.  This might
567 * not be identical to the description it was created from, but
568 * it'll produce the same result.
569 */
570void
571NFSubstitution::toString(UnicodeString& text) const
572{
573  // use tokenChar() to get the character at the beginning and
574  // end of the substitutin token.  In between them will go
575  // either the name of the rule set it uses, or the pattern of
576  // the DecimalFormat it uses
577  text.remove();
578  text.append(tokenChar());
579
580  UnicodeString temp;
581  if (ruleSet != NULL) {
582    ruleSet->getName(temp);
583  } else if (numberFormat != NULL) {
584    numberFormat->toPattern(temp);
585  }
586  text.append(temp);
587  text.append(tokenChar());
588}
589
590//-----------------------------------------------------------------------
591// formatting
592//-----------------------------------------------------------------------
593
594/**
595 * Performs a mathematical operation on the number, formats it using
596 * either ruleSet or decimalFormat, and inserts the result into
597 * toInsertInto.
598 * @param number The number being formatted.
599 * @param toInsertInto The string we insert the result into
600 * @param pos The position in toInsertInto where the owning rule's
601 * rule text begins (this value is added to this substitution's
602 * position to determine exactly where to insert the new text)
603 */
604void
605NFSubstitution::doSubstitution(int64_t number, UnicodeString& toInsertInto, int32_t _pos) const
606{
607    if (ruleSet != NULL) {
608        // perform a transformation on the number that is dependent
609        // on the type of substitution this is, then just call its
610        // rule set's format() method to format the result
611        ruleSet->format(transformNumber(number), toInsertInto, _pos + this->pos);
612    } else if (numberFormat != NULL) {
613        // or perform the transformation on the number (preserving
614        // the result's fractional part if the formatter it set
615        // to show it), then use that formatter's format() method
616        // to format the result
617        double numberToFormat = transformNumber((double)number);
618        if (numberFormat->getMaximumFractionDigits() == 0) {
619            numberToFormat = uprv_floor(numberToFormat);
620        }
621
622        UnicodeString temp;
623        numberFormat->format(numberToFormat, temp);
624        toInsertInto.insert(_pos + this->pos, temp);
625    }
626}
627
628/**
629 * Performs a mathematical operation on the number, formats it using
630 * either ruleSet or decimalFormat, and inserts the result into
631 * toInsertInto.
632 * @param number The number being formatted.
633 * @param toInsertInto The string we insert the result into
634 * @param pos The position in toInsertInto where the owning rule's
635 * rule text begins (this value is added to this substitution's
636 * position to determine exactly where to insert the new text)
637 */
638void
639NFSubstitution::doSubstitution(double number, UnicodeString& toInsertInto, int32_t _pos) const {
640    // perform a transformation on the number being formatted that
641    // is dependent on the type of substitution this is
642    double numberToFormat = transformNumber(number);
643
644    // if the result is an integer, from here on out we work in integer
645    // space (saving time and memory and preserving accuracy)
646    if (numberToFormat == uprv_floor(numberToFormat) && ruleSet != NULL) {
647        ruleSet->format(util64_fromDouble(numberToFormat), toInsertInto, _pos + this->pos);
648
649        // if the result isn't an integer, then call either our rule set's
650        // format() method or our DecimalFormat's format() method to
651        // format the result
652    } else {
653        if (ruleSet != NULL) {
654            ruleSet->format(numberToFormat, toInsertInto, _pos + this->pos);
655        } else if (numberFormat != NULL) {
656            UnicodeString temp;
657            numberFormat->format(numberToFormat, temp);
658            toInsertInto.insert(_pos + this->pos, temp);
659        }
660    }
661}
662
663
664    //-----------------------------------------------------------------------
665    // parsing
666    //-----------------------------------------------------------------------
667
668#ifdef RBNF_DEBUG
669#include <stdio.h>
670#endif
671
672/**
673 * Parses a string using the rule set or DecimalFormat belonging
674 * to this substitution.  If there's a match, a mathematical
675 * operation (the inverse of the one used in formatting) is
676 * performed on the result of the parse and the value passed in
677 * and returned as the result.  The parse position is updated to
678 * point to the first unmatched character in the string.
679 * @param text The string to parse
680 * @param parsePosition On entry, ignored, but assumed to be 0.
681 * On exit, this is updated to point to the first unmatched
682 * character (or 0 if the substitution didn't match)
683 * @param baseValue A partial parse result that should be
684 * combined with the result of this parse
685 * @param upperBound When searching the rule set for a rule
686 * matching the string passed in, only rules with base values
687 * lower than this are considered
688 * @param lenientParse If true and matching against rules fails,
689 * the substitution will also try matching the text against
690 * numerals using a default-costructed NumberFormat.  If false,
691 * no extra work is done.  (This value is false whenever the
692 * formatter isn't in lenient-parse mode, but is also false
693 * under some conditions even when the formatter _is_ in
694 * lenient-parse mode.)
695 * @return If there's a match, this is the result of composing
696 * baseValue with whatever was returned from matching the
697 * characters.  This will be either a Long or a Double.  If there's
698 * no match this is new Long(0) (not null), and parsePosition
699 * is left unchanged.
700 */
701UBool
702NFSubstitution::doParse(const UnicodeString& text,
703                        ParsePosition& parsePosition,
704                        double baseValue,
705                        double upperBound,
706                        UBool lenientParse,
707                        Formattable& result) const
708{
709#ifdef RBNF_DEBUG
710    fprintf(stderr, "<nfsubs> %x bv: %g ub: %g\n", this, baseValue, upperBound);
711#endif
712    // figure out the highest base value a rule can have and match
713    // the text being parsed (this varies according to the type of
714    // substitutions: multiplier, modulus, and numerator substitutions
715    // restrict the search to rules with base values lower than their
716    // own; same-value substitutions leave the upper bound wherever
717    // it was, and the others allow any rule to match
718    upperBound = calcUpperBound(upperBound);
719
720    // use our rule set to parse the text.  If that fails and
721    // lenient parsing is enabled (this is always false if the
722    // formatter's lenient-parsing mode is off, but it may also
723    // be false even when the formatter's lenient-parse mode is
724    // on), then also try parsing the text using a default-
725    // constructed NumberFormat
726    if (ruleSet != NULL) {
727        ruleSet->parse(text, parsePosition, upperBound, result);
728        if (lenientParse && !ruleSet->isFractionRuleSet() && parsePosition.getIndex() == 0) {
729            UErrorCode status = U_ZERO_ERROR;
730            NumberFormat* fmt = NumberFormat::createInstance(status);
731            if (U_SUCCESS(status)) {
732                fmt->parse(text, result, parsePosition);
733            }
734            delete fmt;
735        }
736
737        // ...or use our DecimalFormat to parse the text
738    } else if (numberFormat != NULL) {
739        numberFormat->parse(text, result, parsePosition);
740    }
741
742    // if the parse was successful, we've already advanced the caller's
743    // parse position (this is the one function that doesn't have one
744    // of its own).  Derive a parse result and return it as a Long,
745    // if possible, or a Double
746    if (parsePosition.getIndex() != 0) {
747        UErrorCode status = U_ZERO_ERROR;
748        double tempResult = result.getDouble(status);
749
750        // composeRuleValue() produces a full parse result from
751        // the partial parse result passed to this function from
752        // the caller (this is either the owning rule's base value
753        // or the partial result obtained from composing the
754        // owning rule's base value with its other substitution's
755        // parse result) and the partial parse result obtained by
756        // matching the substitution (which will be the same value
757        // the caller would get by parsing just this part of the
758        // text with RuleBasedNumberFormat.parse() ).  How the two
759        // values are used to derive the full parse result depends
760        // on the types of substitutions: For a regular rule, the
761        // ultimate result is its multiplier substitution's result
762        // times the rule's divisor (or the rule's base value) plus
763        // the modulus substitution's result (which will actually
764        // supersede part of the rule's base value).  For a negative-
765        // number rule, the result is the negative of its substitution's
766        // result.  For a fraction rule, it's the sum of its two
767        // substitution results.  For a rule in a fraction rule set,
768        // it's the numerator substitution's result divided by
769        // the rule's base value.  Results from same-value substitutions
770        // propagate back upard, and null substitutions don't affect
771        // the result.
772        tempResult = composeRuleValue(tempResult, baseValue);
773        result.setDouble(tempResult);
774        return TRUE;
775        // if the parse was UNsuccessful, return 0
776    } else {
777        result.setLong(0);
778        return FALSE;
779    }
780}
781
782UBool
783NFSubstitution::isNullSubstitution() const {
784    return FALSE;
785}
786
787    /**
788     * Returns true if this is a modulus substitution.  (We didn't do this
789     * with instanceof partially because it causes source files to
790     * proliferate and partially because we have to port this to C++.)
791     * @return true if this object is an instance of ModulusSubstitution
792     */
793UBool
794NFSubstitution::isModulusSubstitution() const {
795    return FALSE;
796}
797
798//===================================================================
799// SameValueSubstitution
800//===================================================================
801
802/**
803 * A substitution that passes the value passed to it through unchanged.
804 * Represented by == in rule descriptions.
805 */
806SameValueSubstitution::SameValueSubstitution(int32_t _pos,
807                        const NFRuleSet* _ruleSet,
808                        const RuleBasedNumberFormat* formatter,
809                        const UnicodeString& description,
810                        UErrorCode& status)
811: NFSubstitution(_pos, _ruleSet, formatter, description, status)
812{
813    if (0 == description.compare(gEqualsEquals, 2)) {
814        // throw new IllegalArgumentException("== is not a legal token");
815        status = U_PARSE_ERROR;
816    }
817}
818
819UOBJECT_DEFINE_RTTI_IMPLEMENTATION(SameValueSubstitution)
820
821//===================================================================
822// MultiplierSubstitution
823//===================================================================
824
825UOBJECT_DEFINE_RTTI_IMPLEMENTATION(MultiplierSubstitution)
826
827UBool MultiplierSubstitution::operator==(const NFSubstitution& rhs) const
828{
829    return NFSubstitution::operator==(rhs) &&
830        divisor == ((const MultiplierSubstitution*)&rhs)->divisor;
831}
832
833
834//===================================================================
835// ModulusSubstitution
836//===================================================================
837
838/**
839 * A substitution that divides the number being formatted by the its rule's
840 * divisor and formats the remainder.  Represented by "&gt;&gt;" in a
841 * regular rule.
842 */
843ModulusSubstitution::ModulusSubstitution(int32_t _pos,
844                                         double _divisor,
845                                         const NFRule* predecessor,
846                                         const NFRuleSet* _ruleSet,
847                                         const RuleBasedNumberFormat* formatter,
848                                         const UnicodeString& description,
849                                         UErrorCode& status)
850 : NFSubstitution(_pos, _ruleSet, formatter, description, status)
851 , divisor(_divisor)
852 , ruleToUse(NULL)
853{
854  ldivisor = util64_fromDouble(_divisor);
855
856  // the owning rule's divisor controls the behavior of this
857  // substitution: rather than keeping a backpointer to the rule,
858  // we keep a copy of the divisor
859
860  if (ldivisor == 0) {
861      status = U_PARSE_ERROR;
862  }
863
864  if (0 == description.compare(gGreaterGreaterGreaterThan, 3)) {
865    // the >>> token doesn't alter how this substituion calculates the
866    // values it uses for formatting and parsing, but it changes
867    // what's done with that value after it's obtained: >>> short-
868    // circuits the rule-search process and goes straight to the
869    // specified rule to format the substitution value
870    ruleToUse = predecessor;
871  }
872}
873
874UOBJECT_DEFINE_RTTI_IMPLEMENTATION(ModulusSubstitution)
875
876UBool ModulusSubstitution::operator==(const NFSubstitution& rhs) const
877{
878  return NFSubstitution::operator==(rhs) &&
879  divisor == ((const ModulusSubstitution*)&rhs)->divisor &&
880  ruleToUse == ((const ModulusSubstitution*)&rhs)->ruleToUse;
881}
882
883//-----------------------------------------------------------------------
884// formatting
885//-----------------------------------------------------------------------
886
887
888/**
889 * If this is a &gt;&gt;&gt; substitution, use ruleToUse to fill in
890 * the substitution.  Otherwise, just use the superclass function.
891 * @param number The number being formatted
892 * @toInsertInto The string to insert the result of this substitution
893 * into
894 * @param pos The position of the rule text in toInsertInto
895 */
896void
897ModulusSubstitution::doSubstitution(int64_t number, UnicodeString& toInsertInto, int32_t _pos) const
898{
899    // if this isn't a >>> substitution, just use the inherited version
900    // of this function (which uses either a rule set or a DecimalFormat
901    // to format its substitution value)
902    if (ruleToUse == NULL) {
903        NFSubstitution::doSubstitution(number, toInsertInto, _pos);
904
905        // a >>> substitution goes straight to a particular rule to
906        // format the substitution value
907    } else {
908        int64_t numberToFormat = transformNumber(number);
909        ruleToUse->doFormat(numberToFormat, toInsertInto, _pos + getPos());
910    }
911}
912
913/**
914* If this is a &gt;&gt;&gt; substitution, use ruleToUse to fill in
915* the substitution.  Otherwise, just use the superclass function.
916* @param number The number being formatted
917* @toInsertInto The string to insert the result of this substitution
918* into
919* @param pos The position of the rule text in toInsertInto
920*/
921void
922ModulusSubstitution::doSubstitution(double number, UnicodeString& toInsertInto, int32_t _pos) const
923{
924    // if this isn't a >>> substitution, just use the inherited version
925    // of this function (which uses either a rule set or a DecimalFormat
926    // to format its substitution value)
927    if (ruleToUse == NULL) {
928        NFSubstitution::doSubstitution(number, toInsertInto, _pos);
929
930        // a >>> substitution goes straight to a particular rule to
931        // format the substitution value
932    } else {
933        double numberToFormat = transformNumber(number);
934
935        ruleToUse->doFormat(numberToFormat, toInsertInto, _pos + getPos());
936    }
937}
938
939//-----------------------------------------------------------------------
940// parsing
941//-----------------------------------------------------------------------
942
943/**
944 * If this is a &gt;&gt;&gt; substitution, match only against ruleToUse.
945 * Otherwise, use the superclass function.
946 * @param text The string to parse
947 * @param parsePosition Ignored on entry, updated on exit to point to
948 * the first unmatched character.
949 * @param baseValue The partial parse result prior to calling this
950 * routine.
951 */
952UBool
953ModulusSubstitution::doParse(const UnicodeString& text,
954                             ParsePosition& parsePosition,
955                             double baseValue,
956                             double upperBound,
957                             UBool lenientParse,
958                             Formattable& result) const
959{
960    // if this isn't a >>> substitution, we can just use the
961    // inherited parse() routine to do the parsing
962    if (ruleToUse == NULL) {
963        return NFSubstitution::doParse(text, parsePosition, baseValue, upperBound, lenientParse, result);
964
965        // but if it IS a >>> substitution, we have to do it here: we
966        // use the specific rule's doParse() method, and then we have to
967        // do some of the other work of NFRuleSet.parse()
968    } else {
969        ruleToUse->doParse(text, parsePosition, FALSE, upperBound, result);
970
971        if (parsePosition.getIndex() != 0) {
972            UErrorCode status = U_ZERO_ERROR;
973            double tempResult = result.getDouble(status);
974            tempResult = composeRuleValue(tempResult, baseValue);
975            result.setDouble(tempResult);
976        }
977
978        return TRUE;
979    }
980}
981/**
982 * Returns a textual description of the substitution
983 * @return A textual description of the substitution.  This might
984 * not be identical to the description it was created from, but
985 * it'll produce the same result.
986 */
987void
988ModulusSubstitution::toString(UnicodeString& text) const
989{
990  // use tokenChar() to get the character at the beginning and
991  // end of the substitutin token.  In between them will go
992  // either the name of the rule set it uses, or the pattern of
993  // the DecimalFormat it uses
994
995  if ( ruleToUse != NULL ) { // Must have been a >>> substitution.
996      text.remove();
997      text.append(tokenChar());
998      text.append(tokenChar());
999      text.append(tokenChar());
1000  } else { // Otherwise just use the super-class function.
1001	  NFSubstitution::toString(text);
1002  }
1003}
1004//===================================================================
1005// IntegralPartSubstitution
1006//===================================================================
1007
1008UOBJECT_DEFINE_RTTI_IMPLEMENTATION(IntegralPartSubstitution)
1009
1010
1011//===================================================================
1012// FractionalPartSubstitution
1013//===================================================================
1014
1015
1016    /**
1017     * Constructs a FractionalPartSubstitution.  This object keeps a flag
1018     * telling whether it should format by digits or not.  In addition,
1019     * it marks the rule set it calls (if any) as a fraction rule set.
1020     */
1021FractionalPartSubstitution::FractionalPartSubstitution(int32_t _pos,
1022                             const NFRuleSet* _ruleSet,
1023                             const RuleBasedNumberFormat* formatter,
1024                             const UnicodeString& description,
1025                             UErrorCode& status)
1026 : NFSubstitution(_pos, _ruleSet, formatter, description, status)
1027 , byDigits(FALSE)
1028 , useSpaces(TRUE)
1029
1030{
1031    // akk, ruleSet can change in superclass constructor
1032    if (0 == description.compare(gGreaterGreaterThan, 2) ||
1033        0 == description.compare(gGreaterGreaterGreaterThan, 3) ||
1034        _ruleSet == getRuleSet()) {
1035        byDigits = TRUE;
1036        if (0 == description.compare(gGreaterGreaterGreaterThan, 3)) {
1037            useSpaces = FALSE;
1038        }
1039    } else {
1040        // cast away const
1041        ((NFRuleSet*)getRuleSet())->makeIntoFractionRuleSet();
1042    }
1043}
1044
1045//-----------------------------------------------------------------------
1046// formatting
1047//-----------------------------------------------------------------------
1048
1049/**
1050 * If in "by digits" mode, fills in the substitution one decimal digit
1051 * at a time using the rule set containing this substitution.
1052 * Otherwise, uses the superclass function.
1053 * @param number The number being formatted
1054 * @param toInsertInto The string to insert the result of formatting
1055 * the substitution into
1056 * @param pos The position of the owning rule's rule text in
1057 * toInsertInto
1058 */
1059void
1060FractionalPartSubstitution::doSubstitution(double number, UnicodeString& toInsertInto, int32_t _pos) const
1061{
1062  // if we're not in "byDigits" mode, just use the inherited
1063  // doSubstitution() routine
1064  if (!byDigits) {
1065    NFSubstitution::doSubstitution(number, toInsertInto, _pos);
1066
1067    // if we're in "byDigits" mode, transform the value into an integer
1068    // by moving the decimal point eight places to the right and
1069    // pulling digits off the right one at a time, formatting each digit
1070    // as an integer using this substitution's owning rule set
1071    // (this is slower, but more accurate, than doing it from the
1072    // other end)
1073  } else {
1074    //          int32_t numberToFormat = (int32_t)uprv_round(transformNumber(number) * uprv_pow(10, kMaxDecimalDigits));
1075    //          // this flag keeps us from formatting trailing zeros.  It starts
1076    //          // out false because we're pulling from the right, and switches
1077    //          // to true the first time we encounter a non-zero digit
1078    //          UBool doZeros = FALSE;
1079    //          for (int32_t i = 0; i < kMaxDecimalDigits; i++) {
1080    //              int64_t digit = numberToFormat % 10;
1081    //              if (digit != 0 || doZeros) {
1082    //                  if (doZeros && useSpaces) {
1083    //                      toInsertInto.insert(_pos + getPos(), gSpace);
1084    //                  }
1085    //                  doZeros = TRUE;
1086    //                  getRuleSet()->format(digit, toInsertInto, _pos + getPos());
1087    //              }
1088    //              numberToFormat /= 10;
1089    //          }
1090
1091    DigitList dl;
1092    dl.set(number);
1093    dl.roundFixedPoint(20);     // round to 20 fraction digits.
1094    dl.reduce();                // Removes any trailing zeros.
1095
1096    UBool pad = FALSE;
1097    for (int32_t didx = dl.getCount()-1; didx>=dl.getDecimalAt(); didx--) {
1098      // Loop iterates over fraction digits, starting with the LSD.
1099      //   include both real digits from the number, and zeros
1100      //   to the left of the MSD but to the right of the decimal point.
1101      if (pad && useSpaces) {
1102        toInsertInto.insert(_pos + getPos(), gSpace);
1103      } else {
1104        pad = TRUE;
1105      }
1106      int64_t digit = didx>=0 ? dl.getDigit(didx) - '0' : 0;
1107      getRuleSet()->format(digit, toInsertInto, _pos + getPos());
1108    }
1109
1110    if (!pad) {
1111      // hack around lack of precision in digitlist. if we would end up with
1112      // "foo point" make sure we add a " zero" to the end.
1113      getRuleSet()->format((int64_t)0, toInsertInto, _pos + getPos());
1114    }
1115  }
1116}
1117
1118//-----------------------------------------------------------------------
1119// parsing
1120//-----------------------------------------------------------------------
1121
1122/**
1123 * If in "by digits" mode, parses the string as if it were a string
1124 * of individual digits; otherwise, uses the superclass function.
1125 * @param text The string to parse
1126 * @param parsePosition Ignored on entry, but updated on exit to point
1127 * to the first unmatched character
1128 * @param baseValue The partial parse result prior to entering this
1129 * function
1130 * @param upperBound Only consider rules with base values lower than
1131 * this when filling in the substitution
1132 * @param lenientParse If true, try matching the text as numerals if
1133 * matching as words doesn't work
1134 * @return If the match was successful, the current partial parse
1135 * result; otherwise new Long(0).  The result is either a Long or
1136 * a Double.
1137 */
1138
1139UBool
1140FractionalPartSubstitution::doParse(const UnicodeString& text,
1141                ParsePosition& parsePosition,
1142                double baseValue,
1143                double /*upperBound*/,
1144                UBool lenientParse,
1145                Formattable& resVal) const
1146{
1147    // if we're not in byDigits mode, we can just use the inherited
1148    // doParse()
1149    if (!byDigits) {
1150        return NFSubstitution::doParse(text, parsePosition, baseValue, 0, lenientParse, resVal);
1151
1152        // if we ARE in byDigits mode, parse the text one digit at a time
1153        // using this substitution's owning rule set (we do this by setting
1154        // upperBound to 10 when calling doParse() ) until we reach
1155        // nonmatching text
1156    } else {
1157        UnicodeString workText(text);
1158        ParsePosition workPos(1);
1159        double result = 0;
1160        int32_t digit;
1161//          double p10 = 0.1;
1162
1163        DigitList dl;
1164        NumberFormat* fmt = NULL;
1165        while (workText.length() > 0 && workPos.getIndex() != 0) {
1166            workPos.setIndex(0);
1167            Formattable temp;
1168            getRuleSet()->parse(workText, workPos, 10, temp);
1169            UErrorCode status = U_ZERO_ERROR;
1170            digit = temp.getLong(status);
1171//            digit = temp.getType() == Formattable::kLong ?
1172//               temp.getLong() :
1173//            (int32_t)temp.getDouble();
1174
1175            if (lenientParse && workPos.getIndex() == 0) {
1176                if (!fmt) {
1177                    status = U_ZERO_ERROR;
1178                    fmt = NumberFormat::createInstance(status);
1179                    if (U_FAILURE(status)) {
1180                        delete fmt;
1181                        fmt = NULL;
1182                    }
1183                }
1184                if (fmt) {
1185                    fmt->parse(workText, temp, workPos);
1186                    digit = temp.getLong(status);
1187                }
1188            }
1189
1190            if (workPos.getIndex() != 0) {
1191                dl.append((char)('0' + digit));
1192//                  result += digit * p10;
1193//                  p10 /= 10;
1194                parsePosition.setIndex(parsePosition.getIndex() + workPos.getIndex());
1195                workText.removeBetween(0, workPos.getIndex());
1196                while (workText.length() > 0 && workText.charAt(0) == gSpace) {
1197                    workText.removeBetween(0, 1);
1198                    parsePosition.setIndex(parsePosition.getIndex() + 1);
1199                }
1200            }
1201        }
1202        delete fmt;
1203
1204        result = dl.getCount() == 0 ? 0 : dl.getDouble();
1205        result = composeRuleValue(result, baseValue);
1206        resVal.setDouble(result);
1207        return TRUE;
1208    }
1209}
1210
1211UBool
1212FractionalPartSubstitution::operator==(const NFSubstitution& rhs) const
1213{
1214  return NFSubstitution::operator==(rhs) &&
1215  ((const FractionalPartSubstitution*)&rhs)->byDigits == byDigits;
1216}
1217
1218UOBJECT_DEFINE_RTTI_IMPLEMENTATION(FractionalPartSubstitution)
1219
1220
1221//===================================================================
1222// AbsoluteValueSubstitution
1223//===================================================================
1224
1225UOBJECT_DEFINE_RTTI_IMPLEMENTATION(AbsoluteValueSubstitution)
1226
1227//===================================================================
1228// NumeratorSubstitution
1229//===================================================================
1230
1231void
1232NumeratorSubstitution::doSubstitution(double number, UnicodeString& toInsertInto, int32_t apos) const {
1233    // perform a transformation on the number being formatted that
1234    // is dependent on the type of substitution this is
1235
1236    double numberToFormat = transformNumber(number);
1237    int64_t longNF = util64_fromDouble(numberToFormat);
1238
1239    const NFRuleSet* aruleSet = getRuleSet();
1240    if (withZeros && aruleSet != NULL) {
1241        // if there are leading zeros in the decimal expansion then emit them
1242        int64_t nf =longNF;
1243        int32_t len = toInsertInto.length();
1244        while ((nf *= 10) < denominator) {
1245            toInsertInto.insert(apos + getPos(), gSpace);
1246            aruleSet->format((int64_t)0, toInsertInto, apos + getPos());
1247        }
1248        apos += toInsertInto.length() - len;
1249    }
1250
1251    // if the result is an integer, from here on out we work in integer
1252    // space (saving time and memory and preserving accuracy)
1253    if (numberToFormat == longNF && aruleSet != NULL) {
1254        aruleSet->format(longNF, toInsertInto, apos + getPos());
1255
1256        // if the result isn't an integer, then call either our rule set's
1257        // format() method or our DecimalFormat's format() method to
1258        // format the result
1259    } else {
1260        if (aruleSet != NULL) {
1261            aruleSet->format(numberToFormat, toInsertInto, apos + getPos());
1262        } else {
1263            UErrorCode status = U_ZERO_ERROR;
1264            UnicodeString temp;
1265            getNumberFormat()->format(numberToFormat, temp, status);
1266            toInsertInto.insert(apos + getPos(), temp);
1267        }
1268    }
1269}
1270
1271UBool
1272NumeratorSubstitution::doParse(const UnicodeString& text,
1273                               ParsePosition& parsePosition,
1274                               double baseValue,
1275                               double upperBound,
1276                               UBool /*lenientParse*/,
1277                               Formattable& result) const
1278{
1279    // we don't have to do anything special to do the parsing here,
1280    // but we have to turn lenient parsing off-- if we leave it on,
1281    // it SERIOUSLY messes up the algorithm
1282
1283    // if withZeros is true, we need to count the zeros
1284    // and use that to adjust the parse result
1285    UErrorCode status = U_ZERO_ERROR;
1286    int32_t zeroCount = 0;
1287    UnicodeString workText(text);
1288
1289    if (withZeros) {
1290        ParsePosition workPos(1);
1291        Formattable temp;
1292
1293        while (workText.length() > 0 && workPos.getIndex() != 0) {
1294            workPos.setIndex(0);
1295            getRuleSet()->parse(workText, workPos, 1, temp); // parse zero or nothing at all
1296            if (workPos.getIndex() == 0) {
1297                // we failed, either there were no more zeros, or the number was formatted with digits
1298                // either way, we're done
1299                break;
1300            }
1301
1302            ++zeroCount;
1303            parsePosition.setIndex(parsePosition.getIndex() + workPos.getIndex());
1304            workText.remove(0, workPos.getIndex());
1305            while (workText.length() > 0 && workText.charAt(0) == gSpace) {
1306                workText.remove(0, 1);
1307                parsePosition.setIndex(parsePosition.getIndex() + 1);
1308            }
1309        }
1310
1311        workText = text;
1312        workText.remove(0, (int32_t)parsePosition.getIndex());
1313        parsePosition.setIndex(0);
1314    }
1315
1316    // we've parsed off the zeros, now let's parse the rest from our current position
1317    NFSubstitution::doParse(workText, parsePosition, withZeros ? 1 : baseValue, upperBound, FALSE, result);
1318
1319    if (withZeros) {
1320        // any base value will do in this case.  is there a way to
1321        // force this to not bother trying all the base values?
1322
1323        // compute the 'effective' base and prescale the value down
1324        int64_t n = result.getLong(status); // force conversion!
1325        int64_t d = 1;
1326        int32_t pow = 0;
1327        while (d <= n) {
1328            d *= 10;
1329            ++pow;
1330        }
1331        // now add the zeros
1332        while (zeroCount > 0) {
1333            d *= 10;
1334            --zeroCount;
1335        }
1336        // d is now our true denominator
1337        result.setDouble((double)n/(double)d);
1338    }
1339
1340    return TRUE;
1341}
1342
1343UBool
1344NumeratorSubstitution::operator==(const NFSubstitution& rhs) const
1345{
1346    return NFSubstitution::operator==(rhs) &&
1347        denominator == ((const NumeratorSubstitution*)&rhs)->denominator;
1348}
1349
1350UOBJECT_DEFINE_RTTI_IMPLEMENTATION(NumeratorSubstitution)
1351
1352const UChar NumeratorSubstitution::LTLT[] = { 0x003c, 0x003c };
1353
1354//===================================================================
1355// NullSubstitution
1356//===================================================================
1357
1358UOBJECT_DEFINE_RTTI_IMPLEMENTATION(NullSubstitution)
1359
1360U_NAMESPACE_END
1361
1362/* U_HAVE_RBNF */
1363#endif
1364
1365