1 /*
2 *******************************************************************************
3 *   Copyright (C) 2010-2012, International Business Machines
4 *   Corporation and others.  All Rights Reserved.
5 *******************************************************************************
6 *   file name:  stringtriebuilder.cpp
7 *   encoding:   US-ASCII
8 *   tab size:   8 (not used)
9 *   indentation:4
10 *
11 *   created on: 2010dec24
12 *   created by: Markus W. Scherer
13 */
14 
15 #include "utypeinfo.h"  // for 'typeid' to work
16 #include "unicode/utypes.h"
17 #include "unicode/stringtriebuilder.h"
18 #include "uassert.h"
19 #include "uhash.h"
20 
21 U_CDECL_BEGIN
22 
23 static int32_t U_CALLCONV
hashStringTrieNode(const UHashTok key)24 hashStringTrieNode(const UHashTok key) {
25     return icu::StringTrieBuilder::hashNode(key.pointer);
26 }
27 
28 static UBool U_CALLCONV
equalStringTrieNodes(const UHashTok key1,const UHashTok key2)29 equalStringTrieNodes(const UHashTok key1, const UHashTok key2) {
30     return icu::StringTrieBuilder::equalNodes(key1.pointer, key2.pointer);
31 }
32 
33 U_CDECL_END
34 
35 U_NAMESPACE_BEGIN
36 
StringTrieBuilder()37 StringTrieBuilder::StringTrieBuilder() : nodes(NULL) {}
38 
~StringTrieBuilder()39 StringTrieBuilder::~StringTrieBuilder() {
40     deleteCompactBuilder();
41 }
42 
43 void
createCompactBuilder(int32_t sizeGuess,UErrorCode & errorCode)44 StringTrieBuilder::createCompactBuilder(int32_t sizeGuess, UErrorCode &errorCode) {
45     if(U_FAILURE(errorCode)) {
46         return;
47     }
48     nodes=uhash_openSize(hashStringTrieNode, equalStringTrieNodes, NULL,
49                          sizeGuess, &errorCode);
50     if(U_SUCCESS(errorCode)) {
51         if(nodes==NULL) {
52           errorCode=U_MEMORY_ALLOCATION_ERROR;
53         } else {
54           uhash_setKeyDeleter(nodes, uprv_deleteUObject);
55         }
56     }
57 }
58 
59 void
deleteCompactBuilder()60 StringTrieBuilder::deleteCompactBuilder() {
61     uhash_close(nodes);
62     nodes=NULL;
63 }
64 
65 void
build(UStringTrieBuildOption buildOption,int32_t elementsLength,UErrorCode & errorCode)66 StringTrieBuilder::build(UStringTrieBuildOption buildOption, int32_t elementsLength,
67                        UErrorCode &errorCode) {
68     if(buildOption==USTRINGTRIE_BUILD_FAST) {
69         writeNode(0, elementsLength, 0);
70     } else /* USTRINGTRIE_BUILD_SMALL */ {
71         createCompactBuilder(2*elementsLength, errorCode);
72         Node *root=makeNode(0, elementsLength, 0, errorCode);
73         if(U_SUCCESS(errorCode)) {
74             root->markRightEdgesFirst(-1);
75             root->write(*this);
76         }
77         deleteCompactBuilder();
78     }
79 }
80 
81 // Requires start<limit,
82 // and all strings of the [start..limit[ elements must be sorted and
83 // have a common prefix of length unitIndex.
84 int32_t
writeNode(int32_t start,int32_t limit,int32_t unitIndex)85 StringTrieBuilder::writeNode(int32_t start, int32_t limit, int32_t unitIndex) {
86     UBool hasValue=FALSE;
87     int32_t value=0;
88     int32_t type;
89     if(unitIndex==getElementStringLength(start)) {
90         // An intermediate or final value.
91         value=getElementValue(start++);
92         if(start==limit) {
93             return writeValueAndFinal(value, TRUE);  // final-value node
94         }
95         hasValue=TRUE;
96     }
97     // Now all [start..limit[ strings are longer than unitIndex.
98     int32_t minUnit=getElementUnit(start, unitIndex);
99     int32_t maxUnit=getElementUnit(limit-1, unitIndex);
100     if(minUnit==maxUnit) {
101         // Linear-match node: All strings have the same character at unitIndex.
102         int32_t lastUnitIndex=getLimitOfLinearMatch(start, limit-1, unitIndex);
103         writeNode(start, limit, lastUnitIndex);
104         // Break the linear-match sequence into chunks of at most kMaxLinearMatchLength.
105         int32_t length=lastUnitIndex-unitIndex;
106         int32_t maxLinearMatchLength=getMaxLinearMatchLength();
107         while(length>maxLinearMatchLength) {
108             lastUnitIndex-=maxLinearMatchLength;
109             length-=maxLinearMatchLength;
110             writeElementUnits(start, lastUnitIndex, maxLinearMatchLength);
111             write(getMinLinearMatch()+maxLinearMatchLength-1);
112         }
113         writeElementUnits(start, unitIndex, length);
114         type=getMinLinearMatch()+length-1;
115     } else {
116         // Branch node.
117         int32_t length=countElementUnits(start, limit, unitIndex);
118         // length>=2 because minUnit!=maxUnit.
119         writeBranchSubNode(start, limit, unitIndex, length);
120         if(--length<getMinLinearMatch()) {
121             type=length;
122         } else {
123             write(length);
124             type=0;
125         }
126     }
127     return writeValueAndType(hasValue, value, type);
128 }
129 
130 // start<limit && all strings longer than unitIndex &&
131 // length different units at unitIndex
132 int32_t
writeBranchSubNode(int32_t start,int32_t limit,int32_t unitIndex,int32_t length)133 StringTrieBuilder::writeBranchSubNode(int32_t start, int32_t limit, int32_t unitIndex, int32_t length) {
134     UChar middleUnits[kMaxSplitBranchLevels];
135     int32_t lessThan[kMaxSplitBranchLevels];
136     int32_t ltLength=0;
137     while(length>getMaxBranchLinearSubNodeLength()) {
138         // Branch on the middle unit.
139         // First, find the middle unit.
140         int32_t i=skipElementsBySomeUnits(start, unitIndex, length/2);
141         // Encode the less-than branch first.
142         middleUnits[ltLength]=getElementUnit(i, unitIndex);  // middle unit
143         lessThan[ltLength]=writeBranchSubNode(start, i, unitIndex, length/2);
144         ++ltLength;
145         // Continue for the greater-or-equal branch.
146         start=i;
147         length=length-length/2;
148     }
149     // For each unit, find its elements array start and whether it has a final value.
150     int32_t starts[kMaxBranchLinearSubNodeLength];
151     UBool isFinal[kMaxBranchLinearSubNodeLength-1];
152     int32_t unitNumber=0;
153     do {
154         int32_t i=starts[unitNumber]=start;
155         UChar unit=getElementUnit(i++, unitIndex);
156         i=indexOfElementWithNextUnit(i, unitIndex, unit);
157         isFinal[unitNumber]= start==i-1 && unitIndex+1==getElementStringLength(start);
158         start=i;
159     } while(++unitNumber<length-1);
160     // unitNumber==length-1, and the maxUnit elements range is [start..limit[
161     starts[unitNumber]=start;
162 
163     // Write the sub-nodes in reverse order: The jump lengths are deltas from
164     // after their own positions, so if we wrote the minUnit sub-node first,
165     // then its jump delta would be larger.
166     // Instead we write the minUnit sub-node last, for a shorter delta.
167     int32_t jumpTargets[kMaxBranchLinearSubNodeLength-1];
168     do {
169         --unitNumber;
170         if(!isFinal[unitNumber]) {
171             jumpTargets[unitNumber]=writeNode(starts[unitNumber], starts[unitNumber+1], unitIndex+1);
172         }
173     } while(unitNumber>0);
174     // The maxUnit sub-node is written as the very last one because we do
175     // not jump for it at all.
176     unitNumber=length-1;
177     writeNode(start, limit, unitIndex+1);
178     int32_t offset=write(getElementUnit(start, unitIndex));
179     // Write the rest of this node's unit-value pairs.
180     while(--unitNumber>=0) {
181         start=starts[unitNumber];
182         int32_t value;
183         if(isFinal[unitNumber]) {
184             // Write the final value for the one string ending with this unit.
185             value=getElementValue(start);
186         } else {
187             // Write the delta to the start position of the sub-node.
188             value=offset-jumpTargets[unitNumber];
189         }
190         writeValueAndFinal(value, isFinal[unitNumber]);
191         offset=write(getElementUnit(start, unitIndex));
192     }
193     // Write the split-branch nodes.
194     while(ltLength>0) {
195         --ltLength;
196         writeDeltaTo(lessThan[ltLength]);
197         offset=write(middleUnits[ltLength]);
198     }
199     return offset;
200 }
201 
202 // Requires start<limit,
203 // and all strings of the [start..limit[ elements must be sorted and
204 // have a common prefix of length unitIndex.
205 StringTrieBuilder::Node *
makeNode(int32_t start,int32_t limit,int32_t unitIndex,UErrorCode & errorCode)206 StringTrieBuilder::makeNode(int32_t start, int32_t limit, int32_t unitIndex, UErrorCode &errorCode) {
207     if(U_FAILURE(errorCode)) {
208         return NULL;
209     }
210     UBool hasValue=FALSE;
211     int32_t value=0;
212     if(unitIndex==getElementStringLength(start)) {
213         // An intermediate or final value.
214         value=getElementValue(start++);
215         if(start==limit) {
216             return registerFinalValue(value, errorCode);
217         }
218         hasValue=TRUE;
219     }
220     Node *node;
221     // Now all [start..limit[ strings are longer than unitIndex.
222     int32_t minUnit=getElementUnit(start, unitIndex);
223     int32_t maxUnit=getElementUnit(limit-1, unitIndex);
224     if(minUnit==maxUnit) {
225         // Linear-match node: All strings have the same character at unitIndex.
226         int32_t lastUnitIndex=getLimitOfLinearMatch(start, limit-1, unitIndex);
227         Node *nextNode=makeNode(start, limit, lastUnitIndex, errorCode);
228         // Break the linear-match sequence into chunks of at most kMaxLinearMatchLength.
229         int32_t length=lastUnitIndex-unitIndex;
230         int32_t maxLinearMatchLength=getMaxLinearMatchLength();
231         while(length>maxLinearMatchLength) {
232             lastUnitIndex-=maxLinearMatchLength;
233             length-=maxLinearMatchLength;
234             node=createLinearMatchNode(start, lastUnitIndex, maxLinearMatchLength, nextNode);
235             nextNode=registerNode(node, errorCode);
236         }
237         node=createLinearMatchNode(start, unitIndex, length, nextNode);
238     } else {
239         // Branch node.
240         int32_t length=countElementUnits(start, limit, unitIndex);
241         // length>=2 because minUnit!=maxUnit.
242         Node *subNode=makeBranchSubNode(start, limit, unitIndex, length, errorCode);
243         node=new BranchHeadNode(length, subNode);
244     }
245     if(hasValue && node!=NULL) {
246         if(matchNodesCanHaveValues()) {
247             ((ValueNode *)node)->setValue(value);
248         } else {
249             node=new IntermediateValueNode(value, registerNode(node, errorCode));
250         }
251     }
252     return registerNode(node, errorCode);
253 }
254 
255 // start<limit && all strings longer than unitIndex &&
256 // length different units at unitIndex
257 StringTrieBuilder::Node *
makeBranchSubNode(int32_t start,int32_t limit,int32_t unitIndex,int32_t length,UErrorCode & errorCode)258 StringTrieBuilder::makeBranchSubNode(int32_t start, int32_t limit, int32_t unitIndex,
259                                    int32_t length, UErrorCode &errorCode) {
260     if(U_FAILURE(errorCode)) {
261         return NULL;
262     }
263     UChar middleUnits[kMaxSplitBranchLevels];
264     Node *lessThan[kMaxSplitBranchLevels];
265     int32_t ltLength=0;
266     while(length>getMaxBranchLinearSubNodeLength()) {
267         // Branch on the middle unit.
268         // First, find the middle unit.
269         int32_t i=skipElementsBySomeUnits(start, unitIndex, length/2);
270         // Create the less-than branch.
271         middleUnits[ltLength]=getElementUnit(i, unitIndex);  // middle unit
272         lessThan[ltLength]=makeBranchSubNode(start, i, unitIndex, length/2, errorCode);
273         ++ltLength;
274         // Continue for the greater-or-equal branch.
275         start=i;
276         length=length-length/2;
277     }
278     if(U_FAILURE(errorCode)) {
279         return NULL;
280     }
281     ListBranchNode *listNode=new ListBranchNode();
282     if(listNode==NULL) {
283         errorCode=U_MEMORY_ALLOCATION_ERROR;
284         return NULL;
285     }
286     // For each unit, find its elements array start and whether it has a final value.
287     int32_t unitNumber=0;
288     do {
289         int32_t i=start;
290         UChar unit=getElementUnit(i++, unitIndex);
291         i=indexOfElementWithNextUnit(i, unitIndex, unit);
292         if(start==i-1 && unitIndex+1==getElementStringLength(start)) {
293             listNode->add(unit, getElementValue(start));
294         } else {
295             listNode->add(unit, makeNode(start, i, unitIndex+1, errorCode));
296         }
297         start=i;
298     } while(++unitNumber<length-1);
299     // unitNumber==length-1, and the maxUnit elements range is [start..limit[
300     UChar unit=getElementUnit(start, unitIndex);
301     if(start==limit-1 && unitIndex+1==getElementStringLength(start)) {
302         listNode->add(unit, getElementValue(start));
303     } else {
304         listNode->add(unit, makeNode(start, limit, unitIndex+1, errorCode));
305     }
306     Node *node=registerNode(listNode, errorCode);
307     // Create the split-branch nodes.
308     while(ltLength>0) {
309         --ltLength;
310         node=registerNode(
311             new SplitBranchNode(middleUnits[ltLength], lessThan[ltLength], node), errorCode);
312     }
313     return node;
314 }
315 
316 StringTrieBuilder::Node *
registerNode(Node * newNode,UErrorCode & errorCode)317 StringTrieBuilder::registerNode(Node *newNode, UErrorCode &errorCode) {
318     if(U_FAILURE(errorCode)) {
319         delete newNode;
320         return NULL;
321     }
322     if(newNode==NULL) {
323         errorCode=U_MEMORY_ALLOCATION_ERROR;
324         return NULL;
325     }
326     const UHashElement *old=uhash_find(nodes, newNode);
327     if(old!=NULL) {
328         delete newNode;
329         return (Node *)old->key.pointer;
330     }
331     // If uhash_puti() returns a non-zero value from an equivalent, previously
332     // registered node, then uhash_find() failed to find that and we will leak newNode.
333 #if U_DEBUG
334     int32_t oldValue=  // Only in debug mode to avoid a compiler warning about unused oldValue.
335 #endif
336     uhash_puti(nodes, newNode, 1, &errorCode);
337     U_ASSERT(oldValue==0);
338     if(U_FAILURE(errorCode)) {
339         delete newNode;
340         return NULL;
341     }
342     return newNode;
343 }
344 
345 StringTrieBuilder::Node *
registerFinalValue(int32_t value,UErrorCode & errorCode)346 StringTrieBuilder::registerFinalValue(int32_t value, UErrorCode &errorCode) {
347     if(U_FAILURE(errorCode)) {
348         return NULL;
349     }
350     FinalValueNode key(value);
351     const UHashElement *old=uhash_find(nodes, &key);
352     if(old!=NULL) {
353         return (Node *)old->key.pointer;
354     }
355     Node *newNode=new FinalValueNode(value);
356     if(newNode==NULL) {
357         errorCode=U_MEMORY_ALLOCATION_ERROR;
358         return NULL;
359     }
360     // If uhash_puti() returns a non-zero value from an equivalent, previously
361     // registered node, then uhash_find() failed to find that and we will leak newNode.
362 #if U_DEBUG
363     int32_t oldValue=  // Only in debug mode to avoid a compiler warning about unused oldValue.
364 #endif
365     uhash_puti(nodes, newNode, 1, &errorCode);
366     U_ASSERT(oldValue==0);
367     if(U_FAILURE(errorCode)) {
368         delete newNode;
369         return NULL;
370     }
371     return newNode;
372 }
373 
374 UBool
hashNode(const void * node)375 StringTrieBuilder::hashNode(const void *node) {
376     return ((const Node *)node)->hashCode();
377 }
378 
379 UBool
equalNodes(const void * left,const void * right)380 StringTrieBuilder::equalNodes(const void *left, const void *right) {
381     return *(const Node *)left==*(const Node *)right;
382 }
383 
384 UBool
operator ==(const Node & other) const385 StringTrieBuilder::Node::operator==(const Node &other) const {
386     return this==&other || (typeid(*this)==typeid(other) && hash==other.hash);
387 }
388 
389 int32_t
markRightEdgesFirst(int32_t edgeNumber)390 StringTrieBuilder::Node::markRightEdgesFirst(int32_t edgeNumber) {
391     if(offset==0) {
392         offset=edgeNumber;
393     }
394     return edgeNumber;
395 }
396 
397 UBool
operator ==(const Node & other) const398 StringTrieBuilder::FinalValueNode::operator==(const Node &other) const {
399     if(this==&other) {
400         return TRUE;
401     }
402     if(!Node::operator==(other)) {
403         return FALSE;
404     }
405     const FinalValueNode &o=(const FinalValueNode &)other;
406     return value==o.value;
407 }
408 
409 void
write(StringTrieBuilder & builder)410 StringTrieBuilder::FinalValueNode::write(StringTrieBuilder &builder) {
411     offset=builder.writeValueAndFinal(value, TRUE);
412 }
413 
414 UBool
operator ==(const Node & other) const415 StringTrieBuilder::ValueNode::operator==(const Node &other) const {
416     if(this==&other) {
417         return TRUE;
418     }
419     if(!Node::operator==(other)) {
420         return FALSE;
421     }
422     const ValueNode &o=(const ValueNode &)other;
423     return hasValue==o.hasValue && (!hasValue || value==o.value);
424 }
425 
426 UBool
operator ==(const Node & other) const427 StringTrieBuilder::IntermediateValueNode::operator==(const Node &other) const {
428     if(this==&other) {
429         return TRUE;
430     }
431     if(!ValueNode::operator==(other)) {
432         return FALSE;
433     }
434     const IntermediateValueNode &o=(const IntermediateValueNode &)other;
435     return next==o.next;
436 }
437 
438 int32_t
markRightEdgesFirst(int32_t edgeNumber)439 StringTrieBuilder::IntermediateValueNode::markRightEdgesFirst(int32_t edgeNumber) {
440     if(offset==0) {
441         offset=edgeNumber=next->markRightEdgesFirst(edgeNumber);
442     }
443     return edgeNumber;
444 }
445 
446 void
write(StringTrieBuilder & builder)447 StringTrieBuilder::IntermediateValueNode::write(StringTrieBuilder &builder) {
448     next->write(builder);
449     offset=builder.writeValueAndFinal(value, FALSE);
450 }
451 
452 UBool
operator ==(const Node & other) const453 StringTrieBuilder::LinearMatchNode::operator==(const Node &other) const {
454     if(this==&other) {
455         return TRUE;
456     }
457     if(!ValueNode::operator==(other)) {
458         return FALSE;
459     }
460     const LinearMatchNode &o=(const LinearMatchNode &)other;
461     return length==o.length && next==o.next;
462 }
463 
464 int32_t
markRightEdgesFirst(int32_t edgeNumber)465 StringTrieBuilder::LinearMatchNode::markRightEdgesFirst(int32_t edgeNumber) {
466     if(offset==0) {
467         offset=edgeNumber=next->markRightEdgesFirst(edgeNumber);
468     }
469     return edgeNumber;
470 }
471 
472 UBool
operator ==(const Node & other) const473 StringTrieBuilder::ListBranchNode::operator==(const Node &other) const {
474     if(this==&other) {
475         return TRUE;
476     }
477     if(!Node::operator==(other)) {
478         return FALSE;
479     }
480     const ListBranchNode &o=(const ListBranchNode &)other;
481     for(int32_t i=0; i<length; ++i) {
482         if(units[i]!=o.units[i] || values[i]!=o.values[i] || equal[i]!=o.equal[i]) {
483             return FALSE;
484         }
485     }
486     return TRUE;
487 }
488 
489 int32_t
markRightEdgesFirst(int32_t edgeNumber)490 StringTrieBuilder::ListBranchNode::markRightEdgesFirst(int32_t edgeNumber) {
491     if(offset==0) {
492         firstEdgeNumber=edgeNumber;
493         int32_t step=0;
494         int32_t i=length;
495         do {
496             Node *edge=equal[--i];
497             if(edge!=NULL) {
498                 edgeNumber=edge->markRightEdgesFirst(edgeNumber-step);
499             }
500             // For all but the rightmost edge, decrement the edge number.
501             step=1;
502         } while(i>0);
503         offset=edgeNumber;
504     }
505     return edgeNumber;
506 }
507 
508 void
write(StringTrieBuilder & builder)509 StringTrieBuilder::ListBranchNode::write(StringTrieBuilder &builder) {
510     // Write the sub-nodes in reverse order: The jump lengths are deltas from
511     // after their own positions, so if we wrote the minUnit sub-node first,
512     // then its jump delta would be larger.
513     // Instead we write the minUnit sub-node last, for a shorter delta.
514     int32_t unitNumber=length-1;
515     Node *rightEdge=equal[unitNumber];
516     int32_t rightEdgeNumber= rightEdge==NULL ? firstEdgeNumber : rightEdge->getOffset();
517     do {
518         --unitNumber;
519         if(equal[unitNumber]!=NULL) {
520             equal[unitNumber]->writeUnlessInsideRightEdge(firstEdgeNumber, rightEdgeNumber, builder);
521         }
522     } while(unitNumber>0);
523     // The maxUnit sub-node is written as the very last one because we do
524     // not jump for it at all.
525     unitNumber=length-1;
526     if(rightEdge==NULL) {
527         builder.writeValueAndFinal(values[unitNumber], TRUE);
528     } else {
529         rightEdge->write(builder);
530     }
531     offset=builder.write(units[unitNumber]);
532     // Write the rest of this node's unit-value pairs.
533     while(--unitNumber>=0) {
534         int32_t value;
535         UBool isFinal;
536         if(equal[unitNumber]==NULL) {
537             // Write the final value for the one string ending with this unit.
538             value=values[unitNumber];
539             isFinal=TRUE;
540         } else {
541             // Write the delta to the start position of the sub-node.
542             U_ASSERT(equal[unitNumber]->getOffset()>0);
543             value=offset-equal[unitNumber]->getOffset();
544             isFinal=FALSE;
545         }
546         builder.writeValueAndFinal(value, isFinal);
547         offset=builder.write(units[unitNumber]);
548     }
549 }
550 
551 UBool
operator ==(const Node & other) const552 StringTrieBuilder::SplitBranchNode::operator==(const Node &other) const {
553     if(this==&other) {
554         return TRUE;
555     }
556     if(!Node::operator==(other)) {
557         return FALSE;
558     }
559     const SplitBranchNode &o=(const SplitBranchNode &)other;
560     return unit==o.unit && lessThan==o.lessThan && greaterOrEqual==o.greaterOrEqual;
561 }
562 
563 int32_t
markRightEdgesFirst(int32_t edgeNumber)564 StringTrieBuilder::SplitBranchNode::markRightEdgesFirst(int32_t edgeNumber) {
565     if(offset==0) {
566         firstEdgeNumber=edgeNumber;
567         edgeNumber=greaterOrEqual->markRightEdgesFirst(edgeNumber);
568         offset=edgeNumber=lessThan->markRightEdgesFirst(edgeNumber-1);
569     }
570     return edgeNumber;
571 }
572 
573 void
write(StringTrieBuilder & builder)574 StringTrieBuilder::SplitBranchNode::write(StringTrieBuilder &builder) {
575     // Encode the less-than branch first.
576     lessThan->writeUnlessInsideRightEdge(firstEdgeNumber, greaterOrEqual->getOffset(), builder);
577     // Encode the greater-or-equal branch last because we do not jump for it at all.
578     greaterOrEqual->write(builder);
579     // Write this node.
580     U_ASSERT(lessThan->getOffset()>0);
581     builder.writeDeltaTo(lessThan->getOffset());  // less-than
582     offset=builder.write(unit);
583 }
584 
585 UBool
operator ==(const Node & other) const586 StringTrieBuilder::BranchHeadNode::operator==(const Node &other) const {
587     if(this==&other) {
588         return TRUE;
589     }
590     if(!ValueNode::operator==(other)) {
591         return FALSE;
592     }
593     const BranchHeadNode &o=(const BranchHeadNode &)other;
594     return length==o.length && next==o.next;
595 }
596 
597 int32_t
markRightEdgesFirst(int32_t edgeNumber)598 StringTrieBuilder::BranchHeadNode::markRightEdgesFirst(int32_t edgeNumber) {
599     if(offset==0) {
600         offset=edgeNumber=next->markRightEdgesFirst(edgeNumber);
601     }
602     return edgeNumber;
603 }
604 
605 void
write(StringTrieBuilder & builder)606 StringTrieBuilder::BranchHeadNode::write(StringTrieBuilder &builder) {
607     next->write(builder);
608     if(length<=builder.getMinLinearMatch()) {
609         offset=builder.writeValueAndType(hasValue, value, length-1);
610     } else {
611         builder.write(length-1);
612         offset=builder.writeValueAndType(hasValue, value, 0);
613     }
614 }
615 
616 U_NAMESPACE_END
617