/* ******************************************************************************* * Copyright (C) 2010-2012, International Business Machines * Corporation and others. All Rights Reserved. ******************************************************************************* * file name: bytestrieiterator.cpp * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created on: 2010nov03 * created by: Markus W. Scherer */ #include "unicode/utypes.h" #include "unicode/bytestrie.h" #include "unicode/stringpiece.h" #include "charstr.h" #include "uvectr32.h" U_NAMESPACE_BEGIN BytesTrie::Iterator::Iterator(const void *trieBytes, int32_t maxStringLength, UErrorCode &errorCode) : bytes_(static_cast(trieBytes)), pos_(bytes_), initialPos_(bytes_), remainingMatchLength_(-1), initialRemainingMatchLength_(-1), str_(NULL), maxLength_(maxStringLength), value_(0), stack_(NULL) { if(U_FAILURE(errorCode)) { return; } // str_ and stack_ are pointers so that it's easy to turn bytestrie.h into // a public API header for which we would want it to depend only on // other public headers. // Unlike BytesTrie itself, its Iterator performs memory allocations anyway // via the CharString and UVector32 implementations, so this additional // cost is minimal. str_=new CharString(); stack_=new UVector32(errorCode); if(U_SUCCESS(errorCode) && (str_==NULL || stack_==NULL)) { errorCode=U_MEMORY_ALLOCATION_ERROR; } } BytesTrie::Iterator::Iterator(const BytesTrie &trie, int32_t maxStringLength, UErrorCode &errorCode) : bytes_(trie.bytes_), pos_(trie.pos_), initialPos_(trie.pos_), remainingMatchLength_(trie.remainingMatchLength_), initialRemainingMatchLength_(trie.remainingMatchLength_), str_(NULL), maxLength_(maxStringLength), value_(0), stack_(NULL) { if(U_FAILURE(errorCode)) { return; } str_=new CharString(); stack_=new UVector32(errorCode); if(U_FAILURE(errorCode)) { return; } if(str_==NULL || stack_==NULL) { errorCode=U_MEMORY_ALLOCATION_ERROR; return; } int32_t length=remainingMatchLength_; // Actual remaining match length minus 1. if(length>=0) { // Pending linear-match node, append remaining bytes to str_. ++length; if(maxLength_>0 && length>maxLength_) { length=maxLength_; // This will leave remainingMatchLength>=0 as a signal. } str_->append(reinterpret_cast(pos_), length, errorCode); pos_+=length; remainingMatchLength_-=length; } } BytesTrie::Iterator::~Iterator() { delete str_; delete stack_; } BytesTrie::Iterator & BytesTrie::Iterator::reset() { pos_=initialPos_; remainingMatchLength_=initialRemainingMatchLength_; int32_t length=remainingMatchLength_+1; // Remaining match length. if(maxLength_>0 && length>maxLength_) { length=maxLength_; } str_->truncate(length); pos_+=length; remainingMatchLength_-=length; stack_->setSize(0); return *this; } UBool BytesTrie::Iterator::hasNext() const { return pos_!=NULL || !stack_->isEmpty(); } UBool BytesTrie::Iterator::next(UErrorCode &errorCode) { if(U_FAILURE(errorCode)) { return FALSE; } const uint8_t *pos=pos_; if(pos==NULL) { if(stack_->isEmpty()) { return FALSE; } // Pop the state off the stack and continue with the next outbound edge of // the branch node. int32_t stackSize=stack_->size(); int32_t length=stack_->elementAti(stackSize-1); pos=bytes_+stack_->elementAti(stackSize-2); stack_->setSize(stackSize-2); str_->truncate(length&0xffff); length=(int32_t)((uint32_t)length>>16); if(length>1) { pos=branchNext(pos, length, errorCode); if(pos==NULL) { return TRUE; // Reached a final value. } } else { str_->append((char)*pos++, errorCode); } } if(remainingMatchLength_>=0) { // We only get here if we started in a pending linear-match node // with more than maxLength remaining bytes. return truncateAndStop(); } for(;;) { int32_t node=*pos++; if(node>=kMinValueLead) { // Deliver value for the byte sequence so far. UBool isFinal=(UBool)(node&kValueIsFinal); value_=readValue(pos, node>>1); if(isFinal || (maxLength_>0 && str_->length()==maxLength_)) { pos_=NULL; } else { pos_=skipValue(pos, node); } sp_.set(str_->data(), str_->length()); return TRUE; } if(maxLength_>0 && str_->length()==maxLength_) { return truncateAndStop(); } if(node0 && str_->length()+length>maxLength_) { str_->append(reinterpret_cast(pos), maxLength_-str_->length(), errorCode); return truncateAndStop(); } str_->append(reinterpret_cast(pos), length, errorCode); pos+=length; } } } UBool BytesTrie::Iterator::truncateAndStop() { pos_=NULL; sp_.set(str_->data(), str_->length()); value_=-1; // no real value for str return TRUE; } // Branch node, needs to take the first outbound edge and push state for the rest. const uint8_t * BytesTrie::Iterator::branchNext(const uint8_t *pos, int32_t length, UErrorCode &errorCode) { while(length>kMaxBranchLinearSubNodeLength) { ++pos; // ignore the comparison byte // Push state for the greater-or-equal edge. stack_->addElement((int32_t)(skipDelta(pos)-bytes_), errorCode); stack_->addElement(((length-(length>>1))<<16)|str_->length(), errorCode); // Follow the less-than edge. length>>=1; pos=jumpByDelta(pos); } // List of key-value pairs where values are either final values or jump deltas. // Read the first (key, value) pair. uint8_t trieByte=*pos++; int32_t node=*pos++; UBool isFinal=(UBool)(node&kValueIsFinal); int32_t value=readValue(pos, node>>1); pos=skipValue(pos, node); stack_->addElement((int32_t)(pos-bytes_), errorCode); stack_->addElement(((length-1)<<16)|str_->length(), errorCode); str_->append((char)trieByte, errorCode); if(isFinal) { pos_=NULL; sp_.set(str_->data(), str_->length()); value_=value; return NULL; } else { return pos+value; } } U_NAMESPACE_END