/* -*- Mode: C; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "nsBidi.h" #include "nsUnicodeProperties.h" #include "nsCRTGlue.h" using namespace mozilla::unicode; static_assert(mozilla::kBidiLevelNone > NSBIDI_MAX_EXPLICIT_LEVEL + 1, "The pseudo embedding level should be out-of-range"); // These are #defined in under Solaris 10 x86 #undef CS #undef ES /* Comparing the description of the Bidi algorithm with this implementation is easier with the same names for the Bidi types in the code as there. */ enum { L = eCharType_LeftToRight, R = eCharType_RightToLeft, EN = eCharType_EuropeanNumber, ES = eCharType_EuropeanNumberSeparator, ET = eCharType_EuropeanNumberTerminator, AN = eCharType_ArabicNumber, CS = eCharType_CommonNumberSeparator, B = eCharType_BlockSeparator, S = eCharType_SegmentSeparator, WS = eCharType_WhiteSpaceNeutral, O_N = eCharType_OtherNeutral, LRE = eCharType_LeftToRightEmbedding, LRO = eCharType_LeftToRightOverride, AL = eCharType_RightToLeftArabic, RLE = eCharType_RightToLeftEmbedding, RLO = eCharType_RightToLeftOverride, PDF = eCharType_PopDirectionalFormat, NSM = eCharType_DirNonSpacingMark, BN = eCharType_BoundaryNeutral, LRI = eCharType_LeftToRightIsolate, RLI = eCharType_RightToLeftIsolate, FSI = eCharType_FirstStrongIsolate, PDI = eCharType_PopDirectionalIsolate, ENL, /* EN after W7 */ /* 23 */ ENR, /* EN not subject to W7 */ /* 24 */ dirPropCount }; #define IS_STRONG_TYPE(dirProp) ((dirProp) <= R || (dirProp) == AL) /* to avoid some conditional statements, use tiny constant arrays */ static Flags flagLR[2]={ DIRPROP_FLAG(L), DIRPROP_FLAG(R) }; static Flags flagE[2]={ DIRPROP_FLAG(LRE), DIRPROP_FLAG(RLE) }; static Flags flagO[2]={ DIRPROP_FLAG(LRO), DIRPROP_FLAG(RLO) }; #define DIRPROP_FLAG_LR(level) flagLR[(level)&1] #define DIRPROP_FLAG_E(level) flagE[(level)&1] #define DIRPROP_FLAG_O(level) flagO[(level)&1] #define NO_OVERRIDE(level) ((level)&~NSBIDI_LEVEL_OVERRIDE) static inline uint8_t DirFromStrong(uint8_t aDirProp) { MOZ_ASSERT(IS_STRONG_TYPE(aDirProp)); return aDirProp == L ? L : R; } /* * General implementation notes: * * Throughout the implementation, there are comments like (W2) that refer to * rules of the Bidi algorithm in its version 5, in this example to the second * rule of the resolution of weak types. * * For handling surrogate pairs, where two UChar's form one "abstract" (or UTF-32) * character according to UTF-16, the second UChar gets the directional property of * the entire character assigned, while the first one gets a BN, a boundary * neutral, type, which is ignored by most of the algorithm according to * rule (X9) and the implementation suggestions of the Bidi algorithm. * * Later, AdjustWSLevels() will set the level for each BN to that of the * following character (UChar), which results in surrogate pairs getting the * same level on each of their surrogates. * * In a UTF-8 implementation, the same thing could be done: the last byte of * a multi-byte sequence would get the "real" property, while all previous * bytes of that sequence would get BN. * * It is not possible to assign all those parts of a character the same real * property because this would fail in the resolution of weak types with rules * that look at immediately surrounding types. * * As a related topic, this implementation does not remove Boundary Neutral * types from the input, but ignores them whenever this is relevant. * For example, the loop for the resolution of the weak types reads * types until it finds a non-BN. * Also, explicit embedding codes are neither changed into BN nor removed. * They are only treated the same way real BNs are. * As stated before, AdjustWSLevels() takes care of them at the end. * For the purpose of conformance, the levels of all these codes * do not matter. * * Note that this implementation never modifies the dirProps * after the initial setup, except for FSI which is changed to either * LRI or RLI in GetDirProps(), and paired brackets which may be changed * to L or R according to N0. * * * In this implementation, the resolution of weak types (Wn), * neutrals (Nn), and the assignment of the resolved level (In) * are all done in one single loop, in ResolveImplicitLevels(). * Changes of dirProp values are done on the fly, without writing * them back to the dirProps array. * * * This implementation contains code that allows to bypass steps of the * algorithm that are not needed on the specific paragraph * in order to speed up the most common cases considerably, * like text that is entirely LTR, or RTL text without numbers. * * Most of this is done by setting a bit for each directional property * in a flags variable and later checking for whether there are * any LTR characters or any RTL characters, or both, whether * there are any explicit embedding codes, etc. * * If the (Xn) steps are performed, then the flags are re-evaluated, * because they will then not contain the embedding codes any more * and will be adjusted for override codes, so that subsequently * more bypassing may be possible than what the initial flags suggested. * * If the text is not mixed-directional, then the * algorithm steps for the weak type resolution are not performed, * and all levels are set to the paragraph level. * * If there are no explicit embedding codes, then the (Xn) steps * are not performed. * * If embedding levels are supplied as a parameter, then all * explicit embedding codes are ignored, and the (Xn) steps * are not performed. * * White Space types could get the level of the run they belong to, * and are checked with a test of (flags&MASK_EMBEDDING) to * consider if the paragraph direction should be considered in * the flags variable. * * If there are no White Space types in the paragraph, then * (L1) is not necessary in AdjustWSLevels(). */ nsBidi::nsBidi() { Init(); } nsBidi::~nsBidi() { Free(); } void nsBidi::Init() { /* reset the object, all pointers nullptr, all flags false, all sizes 0 */ mLength = 0; mParaLevel = 0; mFlags = 0; mDirection = NSBIDI_LTR; mTrailingWSStart = 0; mDirPropsSize = 0; mLevelsSize = 0; mRunsSize = 0; mIsolatesSize = 0; mRunCount = -1; mIsolateCount = -1; mDirProps=nullptr; mLevels=nullptr; mRuns=nullptr; mIsolates=nullptr; mDirPropsMemory=nullptr; mLevelsMemory=nullptr; mRunsMemory=nullptr; mIsolatesMemory=nullptr; } /* * We are allowed to allocate memory if aMemory==nullptr * for each array that we need. * We also try to grow and shrink memory as needed if we * allocate it. * * Assume aSizeNeeded>0. * If *aMemory!=nullptr, then assume *aSize>0. * * ### this realloc() may unnecessarily copy the old data, * which we know we don't need any more; * is this the best way to do this?? */ /*static*/ bool nsBidi::GetMemory(void **aMemory, size_t *aSize, size_t aSizeNeeded) { /* check for existing memory */ if(*aMemory==nullptr) { /* we need to allocate memory */ *aMemory=malloc(aSizeNeeded); if (*aMemory!=nullptr) { *aSize=aSizeNeeded; return true; } else { *aSize=0; return false; } } else { /* there is some memory, is it enough or too much? */ if(aSizeNeeded!=*aSize) { /* we may try to grow or shrink */ void *memory=realloc(*aMemory, aSizeNeeded); if(memory!=nullptr) { *aMemory=memory; *aSize=aSizeNeeded; return true; } else { /* we failed to grow */ return false; } } else { /* we have at least enough memory and must not allocate */ return true; } } } void nsBidi::Free() { free(mDirPropsMemory); mDirPropsMemory = nullptr; free(mLevelsMemory); mLevelsMemory = nullptr; free(mRunsMemory); mRunsMemory = nullptr; free(mIsolatesMemory); mIsolatesMemory = nullptr; } /* SetPara ------------------------------------------------------------ */ nsresult nsBidi::SetPara(const char16_t *aText, int32_t aLength, nsBidiLevel aParaLevel) { nsBidiDirection direction; /* check the argument values */ if(aText==nullptr || ((NSBIDI_MAX_EXPLICIT_LEVEL= 0) { if (stackLast <= NSBIDI_MAX_EXPLICIT_LEVEL) { state = previousStateStack[stackLast]; } stackLast--; } break; case B: // This shouldn't happen, since we don't support multiple paragraphs. NS_NOTREACHED("Unexpected paragraph separator"); break; default: break; } } /* Ignore still open isolate sequences with overflow */ if (stackLast > NSBIDI_MAX_EXPLICIT_LEVEL) { stackLast = NSBIDI_MAX_EXPLICIT_LEVEL; if (dirProps[previousStateStack[NSBIDI_MAX_EXPLICIT_LEVEL]] != FSI) { state = LOOKING_FOR_PDI; } } /* Resolve direction of still unresolved open FSI sequences */ while (stackLast >= 0) { if (state == SEEKING_STRONG_FOR_FSI) { dirProps[isolateStartStack[stackLast]] = LRI; flags |= DIRPROP_FLAG(LRI); } state = previousStateStack[stackLast]; stackLast--; } flags|=DIRPROP_FLAG_LR(mParaLevel); mFlags = flags; } /* Functions for handling paired brackets ----------------------------------- */ /* In the mIsoRuns array, the first entry is used for text outside of any isolate sequence. Higher entries are used for each more deeply nested isolate sequence. mIsoRunLast is the index of the last used entry. The mOpenings array is used to note the data of opening brackets not yet matched by a closing bracket, or matched but still susceptible to change level. Each isoRun entry contains the index of the first and one-after-last openings entries for pending opening brackets it contains. The next mOpenings entry to use is the one-after-last of the most deeply nested isoRun entry. mIsoRuns entries also contain their current embedding level and the bidi class of the last-encountered strong character, since these will be needed to resolve the level of paired brackets. */ nsBidi::BracketData::BracketData(const nsBidi *aBidi) { mIsoRunLast = 0; mIsoRuns[0].start = 0; mIsoRuns[0].limit = 0; mIsoRuns[0].level = aBidi->mParaLevel; mIsoRuns[0].lastStrong = mIsoRuns[0].lastBase = mIsoRuns[0].contextDir = GET_LR_FROM_LEVEL(aBidi->mParaLevel); mIsoRuns[0].contextPos = 0; mOpenings = mSimpleOpenings; mOpeningsCount = SIMPLE_OPENINGS_COUNT; mOpeningsMemory = nullptr; } nsBidi::BracketData::~BracketData() { free(mOpeningsMemory); } /* LRE, LRO, RLE, RLO, PDF */ void nsBidi::BracketData::ProcessBoundary(int32_t aLastDirControlCharPos, nsBidiLevel aContextLevel, nsBidiLevel aEmbeddingLevel, const DirProp* aDirProps) { IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; if (DIRPROP_FLAG(aDirProps[aLastDirControlCharPos]) & MASK_ISO) { /* after an isolate */ return; } if (NO_OVERRIDE(aEmbeddingLevel) > NO_OVERRIDE(aContextLevel)) { /* not PDF */ aContextLevel = aEmbeddingLevel; } lastIsoRun.limit = lastIsoRun.start; lastIsoRun.level = aEmbeddingLevel; lastIsoRun.lastStrong = lastIsoRun.lastBase = lastIsoRun.contextDir = GET_LR_FROM_LEVEL(aContextLevel); lastIsoRun.contextPos = aLastDirControlCharPos; } /* LRI or RLI */ void nsBidi::BracketData::ProcessLRI_RLI(nsBidiLevel aLevel) { MOZ_ASSERT(mIsoRunLast <= NSBIDI_MAX_EXPLICIT_LEVEL); IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; lastIsoRun.lastBase = O_N; IsoRun& currIsoRun = mIsoRuns[++mIsoRunLast]; currIsoRun.start = currIsoRun.limit = lastIsoRun.limit; currIsoRun.level = aLevel; currIsoRun.lastStrong = currIsoRun.lastBase = currIsoRun.contextDir = GET_LR_FROM_LEVEL(aLevel); currIsoRun.contextPos = 0; } /* PDI */ void nsBidi::BracketData::ProcessPDI() { MOZ_ASSERT(mIsoRunLast > 0); mIsoRuns[--mIsoRunLast].lastBase = O_N; } /* newly found opening bracket: create an openings entry */ bool /* return true if success */ nsBidi::BracketData::AddOpening(char16_t aMatch, int32_t aPosition) { IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; if (lastIsoRun.limit >= mOpeningsCount) { /* no available new entry */ if (!GETOPENINGSMEMORY(lastIsoRun.limit * 2)) { return false; } if (mOpenings == mSimpleOpenings) { memcpy(mOpeningsMemory, mSimpleOpenings, SIMPLE_OPENINGS_COUNT * sizeof(Opening)); } mOpenings = mOpeningsMemory; /* may have changed */ mOpeningsCount = mOpeningsSize / sizeof(Opening); } Opening& o = mOpenings[lastIsoRun.limit]; o.position = aPosition; o.match = aMatch; o.contextDir = lastIsoRun.contextDir; o.contextPos = lastIsoRun.contextPos; o.flags = 0; lastIsoRun.limit++; return true; } /* change N0c1 to N0c2 when a preceding bracket is assigned the embedding level */ void nsBidi::BracketData::FixN0c(int32_t aOpeningIndex, int32_t aNewPropPosition, DirProp aNewProp, DirProp* aDirProps) { /* This function calls itself recursively */ IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; for (int32_t k = aOpeningIndex + 1; k < lastIsoRun.limit; k++) { Opening& o = mOpenings[k]; if (o.match >= 0) { /* not an N0c match */ continue; } if (aNewPropPosition < o.contextPos) { break; } int32_t openingPosition = o.position; if (aNewPropPosition >= openingPosition) { continue; } if (aNewProp == o.contextDir) { break; } aDirProps[openingPosition] = aNewProp; int32_t closingPosition = -(o.match); aDirProps[closingPosition] = aNewProp; o.match = 0; /* prevent further changes */ FixN0c(k, openingPosition, aNewProp, aDirProps); FixN0c(k, closingPosition, aNewProp, aDirProps); } } /* process closing bracket */ DirProp /* return L or R if N0b or N0c, ON if N0d */ nsBidi::BracketData::ProcessClosing(int32_t aOpenIdx, int32_t aPosition, DirProp* aDirProps) { IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; Opening& o = mOpenings[aOpenIdx]; DirProp newProp; DirProp direction = GET_LR_FROM_LEVEL(lastIsoRun.level); bool stable = true; // assume stable until proved otherwise /* The stable flag is set when brackets are paired and their level is resolved and cannot be changed by what will be found later in the source string. An unstable match can occur only when applying N0c, where the resolved level depends on the preceding context, and this context may be affected by text occurring later. Example: RTL paragraph containing: abc[(latin) HEBREW] When the closing parenthesis is encountered, it appears that N0c1 must be applied since 'abc' sets an opposite direction context and both parentheses receive level 2. However, when the closing square bracket is processed, N0b applies because of 'HEBREW' being included within the brackets, thus the square brackets are treated like R and receive level 1. However, this changes the preceding context of the opening parenthesis, and it now appears that N0c2 must be applied to the parentheses rather than N0c1. */ if ((direction == 0 && o.flags & FOUND_L) || (direction == 1 && o.flags & FOUND_R)) { /* N0b */ newProp = direction; } else if (o.flags & (FOUND_L|FOUND_R)) { /* N0c */ /* it is stable if there is no containing pair or in conditions too complicated and not worth checking */ stable = (aOpenIdx == lastIsoRun.start); if (direction != o.contextDir) { newProp = o.contextDir; /* N0c1 */ } else { newProp = direction; /* N0c2 */ } } else { /* forget this and any brackets nested within this pair */ lastIsoRun.limit = aOpenIdx; return O_N; /* N0d */ } aDirProps[o.position] = newProp; aDirProps[aPosition] = newProp; /* Update nested N0c pairs that may be affected */ FixN0c(aOpenIdx, o.position, newProp, aDirProps); if (stable) { /* forget any brackets nested within this pair */ lastIsoRun.limit = aOpenIdx; } else { int32_t k; o.match = -aPosition; /* neutralize any unmatched opening between the current pair */ for (k = aOpenIdx + 1; k < lastIsoRun.limit; k++) { Opening& oo = mOpenings[k]; if (oo.position > aPosition) { break; } if (oo.match > 0) { oo.match = 0; } } } return newProp; } static inline bool IsMatchingCloseBracket(char16_t aCh1, char16_t aCh2) { // U+232A RIGHT-POINTING ANGLE BRACKET and U+3009 RIGHT ANGLE BRACKET // are canonical equivalents, so we special-case them here. return (aCh1 == aCh2) || (aCh1 == 0x232A && aCh2 == 0x3009) || (aCh2 == 0x232A && aCh1 == 0x3009); } /* Handle strong characters, digits and candidates for closing brackets. */ /* Returns true if success. (The only failure mode is an OOM when trying to allocate memory for the Openings array.) */ bool nsBidi::BracketData::ProcessChar(int32_t aPosition, char16_t aCh, DirProp* aDirProps, nsBidiLevel* aLevels) { IsoRun& lastIsoRun = mIsoRuns[mIsoRunLast]; DirProp newProp; DirProp dirProp = aDirProps[aPosition]; nsBidiLevel level = aLevels[aPosition]; if (dirProp == O_N) { /* First see if it is a matching closing bracket. Hopefully, this is more efficient than checking if it is a closing bracket at all */ for (int32_t idx = lastIsoRun.limit - 1; idx >= lastIsoRun.start; idx--) { if (!IsMatchingCloseBracket(aCh, mOpenings[idx].match)) { continue; } /* We have a match */ newProp = ProcessClosing(idx, aPosition, aDirProps); if (newProp == O_N) { /* N0d */ aCh = 0; /* prevent handling as an opening */ break; } lastIsoRun.lastBase = O_N; lastIsoRun.contextDir = newProp; lastIsoRun.contextPos = aPosition; if (level & NSBIDI_LEVEL_OVERRIDE) { /* X4, X5 */ newProp = GET_LR_FROM_LEVEL(level); lastIsoRun.lastStrong = newProp; uint16_t flag = DIRPROP_FLAG(newProp); for (int32_t i = lastIsoRun.start; i < idx; i++) { mOpenings[i].flags |= flag; } /* matching brackets are not overridden by LRO/RLO */ aLevels[aPosition] &= ~NSBIDI_LEVEL_OVERRIDE; } /* matching brackets are not overridden by LRO/RLO */ aLevels[mOpenings[idx].position] &= ~NSBIDI_LEVEL_OVERRIDE; return true; } /* We get here only if the ON character is not a matching closing bracket or it is a case of N0d */ /* Now see if it is an opening bracket */ char16_t match = GetPairedBracket(aCh); if (match != aCh && /* has a matching char */ GetPairedBracketType(aCh) == PAIRED_BRACKET_TYPE_OPEN) { /* opening bracket */ if (!AddOpening(match, aPosition)) { return false; } } } if (level & NSBIDI_LEVEL_OVERRIDE) { /* X4, X5 */ newProp = GET_LR_FROM_LEVEL(level); if (dirProp != S && dirProp != WS && dirProp != O_N) { aDirProps[aPosition] = newProp; } lastIsoRun.lastBase = newProp; lastIsoRun.lastStrong = newProp; lastIsoRun.contextDir = newProp; lastIsoRun.contextPos = aPosition; } else if (IS_STRONG_TYPE(dirProp)) { newProp = DirFromStrong(dirProp); lastIsoRun.lastBase = dirProp; lastIsoRun.lastStrong = dirProp; lastIsoRun.contextDir = newProp; lastIsoRun.contextPos = aPosition; } else if (dirProp == EN) { lastIsoRun.lastBase = EN; if (lastIsoRun.lastStrong == L) { newProp = L; /* W7 */ aDirProps[aPosition] = ENL; lastIsoRun.contextDir = L; lastIsoRun.contextPos = aPosition; } else { newProp = R; /* N0 */ if (lastIsoRun.lastStrong == AL) { aDirProps[aPosition] = AN; /* W2 */ } else { aDirProps[aPosition] = ENR; } lastIsoRun.contextDir = R; lastIsoRun.contextPos = aPosition; } } else if (dirProp == AN) { newProp = R; /* N0 */ lastIsoRun.lastBase = AN; lastIsoRun.contextDir = R; lastIsoRun.contextPos = aPosition; } else if (dirProp == NSM) { /* if the last real char was ON, change NSM to ON so that it will stay ON even if the last real char is a bracket which may be changed to L or R */ newProp = lastIsoRun.lastBase; if (newProp == O_N) { aDirProps[aPosition] = newProp; } } else { newProp = dirProp; lastIsoRun.lastBase = dirProp; } if (IS_STRONG_TYPE(newProp)) { uint16_t flag = DIRPROP_FLAG(DirFromStrong(newProp)); for (int32_t i = lastIsoRun.start; i < lastIsoRun.limit; i++) { if (aPosition > mOpenings[i].position) { mOpenings[i].flags |= flag; } } } return true; } /* perform (X1)..(X9) ------------------------------------------------------- */ /* * Resolve the explicit levels as specified by explicit embedding codes. * Recalculate the flags to have them reflect the real properties * after taking the explicit embeddings into account. * * The Bidi algorithm is designed to result in the same behavior whether embedding * levels are externally specified (from "styled text", supposedly the preferred * method) or set by explicit embedding codes (LRx, RLx, PDF, FSI, PDI) in the plain text. * That is why (X9) instructs to remove all not-isolate explicit codes (and BN). * However, in a real implementation, this removal of these codes and their index * positions in the plain text is undesirable since it would result in * reallocated, reindexed text. * Instead, this implementation leaves the codes in there and just ignores them * in the subsequent processing. * In order to get the same reordering behavior, positions with a BN or a not-isolate * explicit embedding code just get the same level assigned as the last "real" * character. * * Some implementations, not this one, then overwrite some of these * directionality properties at "real" same-level-run boundaries by * L or R codes so that the resolution of weak types can be performed on the * entire paragraph at once instead of having to parse it once more and * perform that resolution on same-level-runs. * This limits the scope of the implicit rules in effectively * the same way as the run limits. * * Instead, this implementation does not modify these codes. * On one hand, the paragraph has to be scanned for same-level-runs, but * on the other hand, this saves another loop to reset these codes, * or saves making and modifying a copy of dirProps[]. * * * Note that (Pn) and (Xn) changed significantly from version 4 of the Bidi algorithm. * * * Handling the stack of explicit levels (Xn): * * With the Bidi stack of explicit levels, as pushed with each * LRE, RLE, LRO, and RLO, LRI, RLI, and FSI and popped with each PDF and PDI, * the explicit level must never exceed NSBIDI_MAX_EXPLICIT_LEVEL. * * In order to have a correct push-pop semantics even in the case of overflows, * overflow counters and a valid isolate counter are used as described in UAX#9 * section 3.3.2 "Explicit Levels and Direction". * * This implementation assumes that NSBIDI_MAX_EXPLICIT_LEVEL is odd. */ void nsBidi::ResolveExplicitLevels(nsBidiDirection *aDirection, const char16_t *aText) { DirProp *dirProps=mDirProps; nsBidiLevel *levels=mLevels; int32_t i=0, length=mLength; Flags flags=mFlags; /* collect all directionalities in the text */ DirProp dirProp; nsBidiLevel level=mParaLevel; nsBidiDirection direction; mIsolateCount = 0; /* determine if the text is mixed-directional or single-directional */ direction=DirectionFromFlags(flags); /* we may not need to resolve any explicit levels */ if(direction!=NSBIDI_MIXED) { /* not mixed directionality: levels don't matter - trailingWSStart will be 0 */ } else if(!(flags&(MASK_EXPLICIT|MASK_ISO))) { BracketData bracketData(this); /* no embeddings, set all levels to the paragraph level */ for(i=0; i=NSBIDI_MAX_EXPLICIT_LEVEL but we need one more entry as base */ int32_t stackLast = 0; int32_t overflowIsolateCount = 0; int32_t overflowEmbeddingCount = 0; int32_t validIsolateCount = 0; BracketData bracketData(this); stack[0] = level; /* recalculate the flags */ flags=0; /* since we assume that this is a single paragraph, we ignore (X8) */ for(i=0; i 0 && stack[stackLast] < ISOLATE) { /* not an isolate entry */ lastDirControlCharPos = i; stackLast--; embeddingLevel = stack[stackLast]; } break; case LRI: case RLI: flags |= DIRPROP_FLAG(O_N) | DIRPROP_FLAG_LR(embeddingLevel); levels[i] = NO_OVERRIDE(embeddingLevel); if (NO_OVERRIDE(embeddingLevel) != NO_OVERRIDE(previousLevel)) { bracketData.ProcessBoundary(lastDirControlCharPos, previousLevel, embeddingLevel, mDirProps); flags |= DIRPROP_FLAG_MULTI_RUNS; } previousLevel = embeddingLevel; /* (X5a, X5b) */ if (dirProp == LRI) { newLevel = (embeddingLevel + 2) & ~(NSBIDI_LEVEL_OVERRIDE | 1); /* least greater even level */ } else { newLevel = ((embeddingLevel & ~NSBIDI_LEVEL_OVERRIDE) + 1) | 1; /* least greater odd level */ } if (newLevel <= NSBIDI_MAX_EXPLICIT_LEVEL && overflowIsolateCount == 0 && overflowEmbeddingCount == 0) { flags |= DIRPROP_FLAG(dirProp); lastDirControlCharPos = i; previousLevel = embeddingLevel; validIsolateCount++; if (validIsolateCount > mIsolateCount) { mIsolateCount = validIsolateCount; } embeddingLevel = newLevel; stackLast++; stack[stackLast] = embeddingLevel + ISOLATE; bracketData.ProcessLRI_RLI(embeddingLevel); } else { /* make it so that it is handled by AdjustWSLevels() */ dirProps[i] = WS; overflowIsolateCount++; } break; case PDI: if (NO_OVERRIDE(embeddingLevel) != NO_OVERRIDE(previousLevel)) { bracketData.ProcessBoundary(lastDirControlCharPos, previousLevel, embeddingLevel, mDirProps); flags |= DIRPROP_FLAG_MULTI_RUNS; } /* (X6a) */ if (overflowIsolateCount) { overflowIsolateCount--; /* make it so that it is handled by AdjustWSLevels() */ dirProps[i] = WS; } else if (validIsolateCount) { flags |= DIRPROP_FLAG(PDI); lastDirControlCharPos = i; overflowEmbeddingCount = 0; while (stack[stackLast] < ISOLATE) { /* pop embedding entries */ /* until the last isolate entry */ stackLast--; // Since validIsolateCount is true, there must be an isolate entry // on the stack, so the stack is guaranteed to not be empty. // Still, to eliminate a warning from coverity, we use an assertion. MOZ_ASSERT(stackLast > 0); } stackLast--; /* pop also the last isolate entry */ MOZ_ASSERT(stackLast >= 0); // For coverity validIsolateCount--; bracketData.ProcessPDI(); } else { /* make it so that it is handled by AdjustWSLevels() */ dirProps[i] = WS; } embeddingLevel = stack[stackLast] & ~ISOLATE; flags |= DIRPROP_FLAG(O_N) | DIRPROP_FLAG_LR(embeddingLevel); previousLevel = embeddingLevel; levels[i] = NO_OVERRIDE(embeddingLevel); break; case B: /* * We do not expect to see a paragraph separator (B), */ NS_NOTREACHED("Unexpected paragraph separator"); break; case BN: /* BN, LRE, RLE, and PDF are supposed to be removed (X9) */ /* they will get their levels set correctly in AdjustWSLevels() */ levels[i] = previousLevel; flags |= DIRPROP_FLAG(BN); break; default: /* all other types get the "real" level */ if (NO_OVERRIDE(embeddingLevel) != NO_OVERRIDE(previousLevel)) { bracketData.ProcessBoundary(lastDirControlCharPos, previousLevel, embeddingLevel, mDirProps); flags |= DIRPROP_FLAG_MULTI_RUNS; if (embeddingLevel & NSBIDI_LEVEL_OVERRIDE) { flags |= DIRPROP_FLAG_O(embeddingLevel); } else { flags |= DIRPROP_FLAG_E(embeddingLevel); } } previousLevel = embeddingLevel; levels[i] = embeddingLevel; if (!bracketData.ProcessChar(i, aText[i], mDirProps, mLevels)) { NS_WARNING("BracketData::ProcessChar failed, out of memory?"); *aDirection = NSBIDI_LTR; return; } flags |= DIRPROP_FLAG(dirProps[i]); break; } } if(flags&MASK_EMBEDDING) { flags|=DIRPROP_FLAG_LR(mParaLevel); } /* subsequently, ignore the explicit codes and BN (X9) */ /* again, determine if the text is mixed-directional or single-directional */ mFlags=flags; direction=DirectionFromFlags(flags); } *aDirection = direction; } /* determine if the text is mixed-directional or single-directional */ nsBidiDirection nsBidi::DirectionFromFlags(Flags aFlags) { /* if the text contains AN and neutrals, then some neutrals may become RTL */ if(!(aFlags&MASK_RTL || (aFlags&DIRPROP_FLAG(AN) && aFlags&MASK_POSSIBLE_N))) { return NSBIDI_LTR; } else if(!(aFlags&MASK_LTR)) { return NSBIDI_RTL; } else { return NSBIDI_MIXED; } } /****************************************************************** The Properties state machine table ******************************************************************* All table cells are 8 bits: bits 0..4: next state bits 5..7: action to perform (if > 0) Cells may be of format "n" where n represents the next state (except for the rightmost column). Cells may also be of format "s(x,y)" where x represents an action to perform and y represents the next state. ******************************************************************* Definitions and type for properties state table ******************************************************************* */ #define IMPTABPROPS_COLUMNS 16 #define IMPTABPROPS_RES (IMPTABPROPS_COLUMNS - 1) #define GET_STATEPROPS(cell) ((cell)&0x1f) #define GET_ACTIONPROPS(cell) ((cell)>>5) #undef s #define s(action, newState) ((uint8_t)(newState+(action<<5))) static const uint8_t groupProp[] = /* dirProp regrouped */ { /* L R EN ES ET AN CS B S WS ON LRE LRO AL RLE RLO PDF NSM BN FSI LRI RLI PDI ENL ENR */ 0, 1, 2, 7, 8, 3, 9, 6, 5, 4, 4, 10, 10, 12, 10, 10, 10, 11, 10, 4, 4, 4, 4, 13, 14 }; /****************************************************************** PROPERTIES STATE TABLE In table impTabProps, - the ON column regroups ON and WS, FSI, RLI, LRI and PDI - the BN column regroups BN, LRE, RLE, LRO, RLO, PDF - the Res column is the reduced property assigned to a run Action 1: process current run1, init new run1 2: init new run2 3: process run1, process run2, init new run1 4: process run1, set run1=run2, init new run2 Notes: 1) This table is used in ResolveImplicitLevels(). 2) This table triggers actions when there is a change in the Bidi property of incoming characters (action 1). 3) Most such property sequences are processed immediately (in fact, passed to ProcessPropertySeq(). 4) However, numbers are assembled as one sequence. This means that undefined situations (like CS following digits, until it is known if the next char will be a digit) are held until following chars define them. Example: digits followed by CS, then comes another CS or ON; the digits will be processed, then the CS assigned as the start of an ON sequence (action 3). 5) There are cases where more than one sequence must be processed, for instance digits followed by CS followed by L: the digits must be processed as one sequence, and the CS must be processed as an ON sequence, all this before starting assembling chars for the opening L sequence. */ static const uint8_t impTabProps[][IMPTABPROPS_COLUMNS] = { /* L , R , EN , AN , ON , S , B , ES , ET , CS , BN , NSM , AL , ENL , ENR , Res */ /* 0 Init */ { 1 , 2 , 4 , 5 , 7 , 15 , 17 , 7 , 9 , 7 , 0 , 7 , 3 , 18 , 21 , DirProp_ON }, /* 1 L */ { 1 , s(1,2), s(1,4), s(1,5), s(1,7),s(1,15),s(1,17), s(1,7), s(1,9), s(1,7), 1 , 1 , s(1,3),s(1,18),s(1,21), DirProp_L }, /* 2 R */ { s(1,1), 2 , s(1,4), s(1,5), s(1,7),s(1,15),s(1,17), s(1,7), s(1,9), s(1,7), 2 , 2 , s(1,3),s(1,18),s(1,21), DirProp_R }, /* 3 AL */ { s(1,1), s(1,2), s(1,6), s(1,6), s(1,8),s(1,16),s(1,17), s(1,8), s(1,8), s(1,8), 3 , 3 , 3 ,s(1,18),s(1,21), DirProp_R }, /* 4 EN */ { s(1,1), s(1,2), 4 , s(1,5), s(1,7),s(1,15),s(1,17),s(2,10), 11 ,s(2,10), 4 , 4 , s(1,3), 18 , 21 , DirProp_EN }, /* 5 AN */ { s(1,1), s(1,2), s(1,4), 5 , s(1,7),s(1,15),s(1,17), s(1,7), s(1,9),s(2,12), 5 , 5 , s(1,3),s(1,18),s(1,21), DirProp_AN }, /* 6 AL:EN/AN */ { s(1,1), s(1,2), 6 , 6 , s(1,8),s(1,16),s(1,17), s(1,8), s(1,8),s(2,13), 6 , 6 , s(1,3), 18 , 21 , DirProp_AN }, /* 7 ON */ { s(1,1), s(1,2), s(1,4), s(1,5), 7 ,s(1,15),s(1,17), 7 ,s(2,14), 7 , 7 , 7 , s(1,3),s(1,18),s(1,21), DirProp_ON }, /* 8 AL:ON */ { s(1,1), s(1,2), s(1,6), s(1,6), 8 ,s(1,16),s(1,17), 8 , 8 , 8 , 8 , 8 , s(1,3),s(1,18),s(1,21), DirProp_ON }, /* 9 ET */ { s(1,1), s(1,2), 4 , s(1,5), 7 ,s(1,15),s(1,17), 7 , 9 , 7 , 9 , 9 , s(1,3), 18 , 21 , DirProp_ON }, /*10 EN+ES/CS */ { s(3,1), s(3,2), 4 , s(3,5), s(4,7),s(3,15),s(3,17), s(4,7),s(4,14), s(4,7), 10 , s(4,7), s(3,3), 18 , 21 , DirProp_EN }, /*11 EN+ET */ { s(1,1), s(1,2), 4 , s(1,5), s(1,7),s(1,15),s(1,17), s(1,7), 11 , s(1,7), 11 , 11 , s(1,3), 18 , 21 , DirProp_EN }, /*12 AN+CS */ { s(3,1), s(3,2), s(3,4), 5 , s(4,7),s(3,15),s(3,17), s(4,7),s(4,14), s(4,7), 12 , s(4,7), s(3,3),s(3,18),s(3,21), DirProp_AN }, /*13 AL:EN/AN+CS */ { s(3,1), s(3,2), 6 , 6 , s(4,8),s(3,16),s(3,17), s(4,8), s(4,8), s(4,8), 13 , s(4,8), s(3,3), 18 , 21 , DirProp_AN }, /*14 ON+ET */ { s(1,1), s(1,2), s(4,4), s(1,5), 7 ,s(1,15),s(1,17), 7 , 14 , 7 , 14 , 14 , s(1,3),s(4,18),s(4,21), DirProp_ON }, /*15 S */ { s(1,1), s(1,2), s(1,4), s(1,5), s(1,7), 15 ,s(1,17), s(1,7), s(1,9), s(1,7), 15 , s(1,7), s(1,3),s(1,18),s(1,21), DirProp_S }, /*16 AL:S */ { s(1,1), s(1,2), s(1,6), s(1,6), s(1,8), 16 ,s(1,17), s(1,8), s(1,8), s(1,8), 16 , s(1,8), s(1,3),s(1,18),s(1,21), DirProp_S }, /*17 B */ { s(1,1), s(1,2), s(1,4), s(1,5), s(1,7),s(1,15), 17 , s(1,7), s(1,9), s(1,7), 17 , s(1,7), s(1,3),s(1,18),s(1,21), DirProp_B }, /*18 ENL */ { s(1,1), s(1,2), 18 , s(1,5), s(1,7),s(1,15),s(1,17),s(2,19), 20 ,s(2,19), 18 , 18 , s(1,3), 18 , 21 , DirProp_L }, /*19 ENL+ES/CS */ { s(3,1), s(3,2), 18 , s(3,5), s(4,7),s(3,15),s(3,17), s(4,7),s(4,14), s(4,7), 19 , s(4,7), s(3,3), 18 , 21 , DirProp_L }, /*20 ENL+ET */ { s(1,1), s(1,2), 18 , s(1,5), s(1,7),s(1,15),s(1,17), s(1,7), 20 , s(1,7), 20 , 20 , s(1,3), 18 , 21 , DirProp_L }, /*21 ENR */ { s(1,1), s(1,2), 21 , s(1,5), s(1,7),s(1,15),s(1,17),s(2,22), 23 ,s(2,22), 21 , 21 , s(1,3), 18 , 21 , DirProp_AN }, /*22 ENR+ES/CS */ { s(3,1), s(3,2), 21 , s(3,5), s(4,7),s(3,15),s(3,17), s(4,7),s(4,14), s(4,7), 22 , s(4,7), s(3,3), 18 , 21 , DirProp_AN }, /*23 ENR+ET */ { s(1,1), s(1,2), 21 , s(1,5), s(1,7),s(1,15),s(1,17), s(1,7), 23 , s(1,7), 23 , 23 , s(1,3), 18 , 21 , DirProp_AN } }; /* we must undef macro s because the levels table have a different * structure (4 bits for action and 4 bits for next state. */ #undef s /****************************************************************** The levels state machine tables ******************************************************************* All table cells are 8 bits: bits 0..3: next state bits 4..7: action to perform (if > 0) Cells may be of format "n" where n represents the next state (except for the rightmost column). Cells may also be of format "s(x,y)" where x represents an action to perform and y represents the next state. This format limits each table to 16 states each and to 15 actions. ******************************************************************* Definitions and type for levels state tables ******************************************************************* */ #define IMPTABLEVELS_RES (IMPTABLEVELS_COLUMNS - 1) #define GET_STATE(cell) ((cell)&0x0f) #define GET_ACTION(cell) ((cell)>>4) #define s(action, newState) ((uint8_t)(newState+(action<<4))) /****************************************************************** LEVELS STATE TABLES In all levels state tables, - state 0 is the initial state - the Res column is the increment to add to the text level for this property sequence. The impAct arrays for each table of a pair map the local action numbers of the table to the total list of actions. For instance, action 2 in a given table corresponds to the action number which appears in entry [2] of the impAct array for that table. The first entry of all impAct arrays must be 0. Action 1: init conditional sequence 2: prepend conditional sequence to current sequence 3: set ON sequence to new level - 1 4: init EN/AN/ON sequence 5: fix EN/AN/ON sequence followed by R 6: set previous level sequence to level 2 Notes: 1) These tables are used in ProcessPropertySeq(). The input is property sequences as determined by ResolveImplicitLevels. 2) Most such property sequences are processed immediately (levels are assigned). 3) However, some sequences cannot be assigned a final level till one or more following sequences are received. For instance, ON following an R sequence within an even-level paragraph. If the following sequence is R, the ON sequence will be assigned basic run level+1, and so will the R sequence. 4) S is generally handled like ON, since its level will be fixed to paragraph level in AdjustWSLevels(). */ static const ImpTab impTabL = /* Even paragraph level */ /* In this table, conditional sequences receive the higher possible level until proven otherwise. */ { /* L , R , EN , AN , ON , S , B , Res */ /* 0 : init */ { 0 , 1 , 0 , 2 , 0 , 0 , 0 , 0 }, /* 1 : R */ { 0 , 1 , 3 , 3 , s(1,4), s(1,4), 0 , 1 }, /* 2 : AN */ { 0 , 1 , 0 , 2 , s(1,5), s(1,5), 0 , 2 }, /* 3 : R+EN/AN */ { 0 , 1 , 3 , 3 , s(1,4), s(1,4), 0 , 2 }, /* 4 : R+ON */ { s(2,0), 1 , 3 , 3 , 4 , 4 , s(2,0), 1 }, /* 5 : AN+ON */ { s(2,0), 1 , s(2,0), 2 , 5 , 5 , s(2,0), 1 } }; static const ImpTab impTabR = /* Odd paragraph level */ /* In this table, conditional sequences receive the lower possible level until proven otherwise. */ { /* L , R , EN , AN , ON , S , B , Res */ /* 0 : init */ { 1 , 0 , 2 , 2 , 0 , 0 , 0 , 0 }, /* 1 : L */ { 1 , 0 , 1 , 3 , s(1,4), s(1,4), 0 , 1 }, /* 2 : EN/AN */ { 1 , 0 , 2 , 2 , 0 , 0 , 0 , 1 }, /* 3 : L+AN */ { 1 , 0 , 1 , 3 , 5 , 5 , 0 , 1 }, /* 4 : L+ON */ { s(2,1), 0 , s(2,1), 3 , 4 , 4 , 0 , 0 }, /* 5 : L+AN+ON */ { 1 , 0 , 1 , 3 , 5 , 5 , 0 , 0 } }; #undef s static ImpAct impAct0 = {0,1,2,3,4,5,6}; static PImpTab impTab[2] = {impTabL, impTabR}; /*------------------------------------------------------------------------*/ /* perform rules (Wn), (Nn), and (In) on a run of the text ------------------ */ /* * This implementation of the (Wn) rules applies all rules in one pass. * In order to do so, it needs a look-ahead of typically 1 character * (except for W5: sequences of ET) and keeps track of changes * in a rule Wp that affect a later Wq (ppImpTab; PImpAct pImpAct = pLevState->pImpAct; nsBidiLevel* levels = mLevels; nsBidiLevel level, addLevel; int32_t start0, k; start0 = start; /* save original start position */ oldStateSeq = (uint8_t)pLevState->state; cell = pImpTab[oldStateSeq][_prop]; pLevState->state = GET_STATE(cell); /* isolate the new state */ actionSeq = pImpAct[GET_ACTION(cell)]; /* isolate the action */ addLevel = pImpTab[pLevState->state][IMPTABLEVELS_RES]; if(actionSeq) { switch(actionSeq) { case 1: /* init ON seq */ pLevState->startON = start0; break; case 2: /* prepend ON seq to current seq */ MOZ_ASSERT(pLevState->startON >= 0, "no valid ON sequence start!"); start = pLevState->startON; break; default: /* we should never get here */ MOZ_ASSERT(false); break; } } if(addLevel || (start < start0)) { level = pLevState->runLevel + addLevel; if (start >= pLevState->runStart) { for (k = start; k < limit; k++) { levels[k] = level; } } else { DirProp *dirProps = mDirProps, dirProp; int32_t isolateCount = 0; for (k = start; k < limit; k++) { dirProp = dirProps[k]; if (dirProp == PDI) { isolateCount--; } if (isolateCount == 0) { levels[k]=level; } if (dirProp == LRI || dirProp == RLI) { isolateCount++; } } } } } void nsBidi::ResolveImplicitLevels(int32_t aStart, int32_t aLimit, DirProp aSOR, DirProp aEOR) { const DirProp *dirProps = mDirProps; DirProp dirProp; LevState levState; int32_t i, start1, start2; uint16_t oldStateImp, stateImp, actionImp; uint8_t gprop, resProp, cell; /* initialize for property and levels state tables */ levState.runStart = aStart; levState.runLevel = mLevels[aStart]; levState.pImpTab = impTab[levState.runLevel & 1]; levState.pImpAct = impAct0; levState.startON = -1; /* initialize to invalid start position */ /* The isolates[] entries contain enough information to resume the bidi algorithm in the same state as it was when it was interrupted by an isolate sequence. */ if (dirProps[aStart] == PDI && mIsolateCount >= 0) { start1 = mIsolates[mIsolateCount].start1; stateImp = mIsolates[mIsolateCount].stateImp; levState.state = mIsolates[mIsolateCount].state; mIsolateCount--; } else { levState.startON = -1; start1 = aStart; if (dirProps[aStart] == NSM) { stateImp = 1 + aSOR; } else { stateImp = 0; } levState.state = 0; ProcessPropertySeq(&levState, aSOR, aStart, aStart); } start2 = aStart; for (i = aStart; i <= aLimit; i++) { if (i >= aLimit) { int32_t k; for (k = aLimit - 1; k > aStart && (DIRPROP_FLAG(dirProps[k]) & MASK_BN_EXPLICIT); k--) { // empty loop body } dirProp = mDirProps[k]; if (dirProp == LRI || dirProp == RLI) { break; /* no forced closing for sequence ending with LRI/RLI */ } gprop = aEOR; } else { DirProp prop; prop = dirProps[i]; gprop = groupProp[prop]; } oldStateImp = stateImp; cell = impTabProps[oldStateImp][gprop]; stateImp = GET_STATEPROPS(cell); /* isolate the new state */ actionImp = GET_ACTIONPROPS(cell); /* isolate the action */ if ((i == aLimit) && (actionImp == 0)) { /* there is an unprocessed sequence if its property == eor */ actionImp = 1; /* process the last sequence */ } if (actionImp) { resProp = impTabProps[oldStateImp][IMPTABPROPS_RES]; switch (actionImp) { case 1: /* process current seq1, init new seq1 */ ProcessPropertySeq(&levState, resProp, start1, i); start1 = i; break; case 2: /* init new seq2 */ start2 = i; break; case 3: /* process seq1, process seq2, init new seq1 */ ProcessPropertySeq(&levState, resProp, start1, start2); ProcessPropertySeq(&levState, DirProp_ON, start2, i); start1 = i; break; case 4: /* process seq1, set seq1=seq2, init new seq2 */ ProcessPropertySeq(&levState, resProp, start1, start2); start1 = start2; start2 = i; break; default: /* we should never get here */ MOZ_ASSERT(false); break; } } } for (i = aLimit - 1; i > aStart && (DIRPROP_FLAG(dirProps[i]) & MASK_BN_EXPLICIT); i--) { // empty loop body } dirProp = dirProps[i]; if ((dirProp == LRI || dirProp == RLI) && aLimit < mLength) { mIsolateCount++; mIsolates[mIsolateCount].stateImp = stateImp; mIsolates[mIsolateCount].state = levState.state; mIsolates[mIsolateCount].start1 = start1; } else { ProcessPropertySeq(&levState, aEOR, aLimit, aLimit); } } /* perform (L1) and (X9) ---------------------------------------------------- */ /* * Reset the embedding levels for some non-graphic characters (L1). * This function also sets appropriate levels for BN, and * explicit embedding types that are supposed to have been removed * from the paragraph in (X9). */ void nsBidi::AdjustWSLevels() { const DirProp *dirProps=mDirProps; nsBidiLevel *levels=mLevels; int32_t i; if(mFlags&MASK_WS) { nsBidiLevel paraLevel=mParaLevel; Flags flag; i=mTrailingWSStart; while(i>0) { /* reset a sequence of WS/BN before eop and B/S to the paragraph paraLevel */ while (i > 0 && DIRPROP_FLAG(dirProps[--i]) & MASK_WS) { levels[i]=paraLevel; } /* reset BN to the next character's paraLevel until B/S, which restarts above loop */ /* here, i+1 is guaranteed to be 0) { flag = DIRPROP_FLAG(dirProps[--i]); if(flag&MASK_BN_EXPLICIT) { levels[i]=levels[i+1]; } else if(flag&MASK_B_S) { levels[i]=paraLevel; break; } } } } } nsresult nsBidi::GetDirection(nsBidiDirection* aDirection) { *aDirection = mDirection; return NS_OK; } nsresult nsBidi::GetParaLevel(nsBidiLevel* aParaLevel) { *aParaLevel = mParaLevel; return NS_OK; } nsresult nsBidi::GetCharTypeAt(int32_t aCharIndex, nsCharType* pType) { if(aCharIndex<0 || mLength<=aCharIndex) { return NS_ERROR_INVALID_ARG; } *pType = (nsCharType)mDirProps[aCharIndex]; return NS_OK; } nsresult nsBidi::GetLogicalRun(int32_t aLogicalStart, int32_t *aLogicalLimit, nsBidiLevel *aLevel) { int32_t length = mLength; if(aLogicalStart<0 || length<=aLogicalStart) { return NS_ERROR_INVALID_ARG; } int32_t runCount, visualStart, logicalLimit, logicalFirst, i; Run iRun; /* CountRuns will check VALID_PARA_OR_LINE */ nsresult rv = CountRuns(&runCount); if (NS_FAILED(rv)) { return rv; } visualStart = logicalLimit = 0; iRun = mRuns[0]; for (i = 0; i < runCount; i++) { iRun = mRuns[i]; logicalFirst = GET_INDEX(iRun.logicalStart); logicalLimit = logicalFirst + iRun.visualLimit - visualStart; if ((aLogicalStart >= logicalFirst) && (aLogicalStart < logicalLimit)) { break; } visualStart = iRun.visualLimit; } if (aLogicalLimit) { *aLogicalLimit = logicalLimit; } if (aLevel) { if (mDirection != NSBIDI_MIXED || aLogicalStart >= mTrailingWSStart) { *aLevel = mParaLevel; } else { *aLevel = mLevels[aLogicalStart]; } } return NS_OK; } /* runs API functions ------------------------------------------------------- */ nsresult nsBidi::CountRuns(int32_t* aRunCount) { if(mRunCount<0 && !GetRuns()) { return NS_ERROR_OUT_OF_MEMORY; } else { if (aRunCount) *aRunCount = mRunCount; return NS_OK; } } nsresult nsBidi::GetVisualRun(int32_t aRunIndex, int32_t *aLogicalStart, int32_t *aLength, nsBidiDirection *aDirection) { if( aRunIndex<0 || (mRunCount==-1 && !GetRuns()) || aRunIndex>=mRunCount ) { *aDirection = NSBIDI_LTR; return NS_OK; } else { int32_t start=mRuns[aRunIndex].logicalStart; if(aLogicalStart!=nullptr) { *aLogicalStart=GET_INDEX(start); } if(aLength!=nullptr) { if(aRunIndex>0) { *aLength=mRuns[aRunIndex].visualLimit- mRuns[aRunIndex-1].visualLimit; } else { *aLength=mRuns[0].visualLimit; } } *aDirection = (nsBidiDirection)GET_ODD_BIT(start); return NS_OK; } } /* compute the runs array --------------------------------------------------- */ /* * Compute the runs array from the levels array. * After GetRuns() returns true, runCount is guaranteed to be >0 * and the runs are reordered. * Odd-level runs have visualStart on their visual right edge and * they progress visually to the left. */ bool nsBidi::GetRuns() { /* * This method returns immediately if the runs are already set. This * includes the case of length==0 (handled in setPara).. */ if (mRunCount >= 0) { return true; } if(mDirection!=NSBIDI_MIXED) { /* simple, single-run case - this covers length==0 */ GetSingleRun(mParaLevel); } else /* NSBIDI_MIXED, length>0 */ { /* mixed directionality */ int32_t length=mLength, limit=mTrailingWSStart; /* * If there are WS characters at the end of the line * and the run preceding them has a level different from * paraLevel, then they will form their own run at paraLevel (L1). * Count them separately. * We need some special treatment for this in order to not * modify the levels array which a line nsBidi object shares * with its paragraph parent and its other line siblings. * In other words, for the trailing WS, it may be * levels[]!=paraLevel but we have to treat it like it were so. */ nsBidiLevel *levels=mLevels; int32_t i, runCount; nsBidiLevel level=NSBIDI_DEFAULT_LTR; /* initialize with no valid level */ /* count the runs, there is at least one non-WS run, and limit>0 */ runCount=0; for(i=0; i1 || limit1 */ if(GETRUNSMEMORY(runCount)) { runs=mRunsMemory; } else { return false; } /* set the runs */ /* this could be optimized, e.g.: 464->444, 484->444, 575->555, 595->555 */ /* however, that would take longer and make other functions more complicated */ runIndex=0; /* search for the run ends */ i = 0; do { /* prepare this run */ start = i; level = levels[i]; if(levelmaxLevel) { maxLevel=level; } /* look for the run limit */ while (++i < limit && levels[i] == level) { } /* i is another run limit */ runs[runIndex].logicalStart = start; runs[runIndex].visualLimit = i - start; ++runIndex; } while (i < limit); if(limit1 and maxLevel>=minLevel>=paraLevel. * All the visualStart fields=logical start before reordering. * The "odd" bits are not set yet. * * Reordering with this data structure lends itself to some handy shortcuts: * * Since each run is moved but not modified, and since at the initial maxLevel * each sequence of same-level runs consists of only one run each, we * don't need to do anything there and can predecrement maxLevel. * In many simple cases, the reordering is thus done entirely in the * index mapping. * Also, reordering occurs only down to the lowest odd level that occurs, * which is minLevel|1. However, if the lowest level itself is odd, then * in the last reordering the sequence of the runs at this level or higher * will be all runs, and we don't need the elaborate loop to search for them. * This is covered by ++minLevel instead of minLevel|=1 followed * by an extra reorder-all after the reorder-some loop. * About a trailing WS run: * Such a run would need special treatment because its level is not * reflected in levels[] if this is not a paragraph object. * Instead, all characters from trailingWSStart on are implicitly at * paraLevel. * However, for all maxLevel>paraLevel, this run will never be reordered * and does not need to be taken into account. maxLevel==paraLevel is only reordered * if minLevel==paraLevel is odd, which is done in the extra segment. * This means that for the main reordering loop we don't need to consider * this run and can --runCount. If it is later part of the all-runs * reordering, then runCount is adjusted accordingly. */ void nsBidi::ReorderLine(nsBidiLevel aMinLevel, nsBidiLevel aMaxLevel) { Run *runs, tempRun; nsBidiLevel *levels; int32_t firstRun, endRun, limitRun, runCount; /* nothing to do? */ if(aMaxLevel<=(aMinLevel|1)) { return; } /* * Reorder only down to the lowest odd level * and reorder at an odd aMinLevel in a separate, simpler loop. * See comments above for why aMinLevel is always incremented. */ ++aMinLevel; runs=mRuns; levels=mLevels; runCount=mRunCount; /* do not include the WS run at paraLevel<=old aMinLevel except in the simple loop */ if(mTrailingWSStart=aMinLevel) { firstRun=0; /* loop for all sequences of runs */ for(;;) { /* look for a sequence of runs that are all at >=aMaxLevel */ /* look for the first run of such a sequence */ while(firstRun=runCount) { break; /* no more such runs */ } /* look for the limit run of such a sequence (the run behind it) */ for(limitRun=firstRun; ++limitRun=aMaxLevel;) {} /* Swap the entire sequence of runs from firstRun to limitRun-1. */ endRun=limitRun-1; while(firstRun=maxLevel */ /* look for the first index of such a sequence */ while(start=aLength) { break; /* no more such runs */ } /* look for the limit of such a sequence (the index behind it) */ for(limit=start; ++limit=maxLevel;) {} /* * Swap the entire interval of indexes from start to limit-1. * We don't need to swap the levels for the purpose of this * algorithm: the sequence of levels that we look at does not * move anyway. */ end=limit-1; while(start=minLevel); return NS_OK; } bool nsBidi::PrepareReorder(const nsBidiLevel *aLevels, int32_t aLength, int32_t *aIndexMap, nsBidiLevel *aMinLevel, nsBidiLevel *aMaxLevel) { int32_t start; nsBidiLevel level, minLevel, maxLevel; if(aLevels==nullptr || aLength<=0) { return false; } /* determine minLevel and maxLevel */ minLevel=NSBIDI_MAX_EXPLICIT_LEVEL+1; maxLevel=0; for(start=aLength; start>0;) { level=aLevels[--start]; if(level>NSBIDI_MAX_EXPLICIT_LEVEL+1) { return false; } if(levelmaxLevel) { maxLevel=level; } } *aMinLevel=minLevel; *aMaxLevel=maxLevel; /* initialize the index map */ for(start=aLength; start>0;) { --start; aIndexMap[start]=start; } return true; }