private bool GetCEsFromContractionCE32(CollationData data, int ce32)
        {
            int trieIndex = Collation.IndexFromCE32(ce32);

            ce32 = data.GetCE32FromContexts(trieIndex);  // Default if no suffix match.
                                                         // Since the original ce32 is not a prefix mapping,
                                                         // the default ce32 must not be another contraction.
            Debug.Assert(!Collation.IsContractionCE32(ce32));
            int contractionIndex = contractionCEs.Count;

            if (GetCEsFromCE32(data, Collation.SentinelCodePoint, ce32))
            {
                AddContractionEntry(CollationFastLatin.CONTR_CHAR_MASK, ce0, ce1);
            }
            else
            {
                // Bail out for c-without-contraction.
                AddContractionEntry(CollationFastLatin.CONTR_CHAR_MASK, Collation.NoCE, 0);
            }
            // Handle an encodable contraction unless the next contraction is too long
            // and starts with the same character.
            int  prevX          = -1;
            bool addContraction = false;

            using (CharsTrieEnumerator suffixes = CharsTrie.GetEnumerator(data.contexts, trieIndex + 2, 0))
            {
                while (suffixes.MoveNext())
                {
                    CharsTrieEntry entry  = suffixes.Current;
                    ICharSequence  suffix = entry.Chars;
                    int            x      = CollationFastLatin.GetCharIndex(suffix[0]);
                    if (x < 0)
                    {
                        continue;
                    }                         // ignore anything but fast Latin text
                    if (x == prevX)
                    {
                        if (addContraction)
                        {
                            // Bail out for all contractions starting with this character.
                            AddContractionEntry(x, Collation.NoCE, 0);
                            addContraction = false;
                        }
                        continue;
                    }
                    if (addContraction)
                    {
                        AddContractionEntry(prevX, ce0, ce1);
                    }
                    ce32 = entry.Value;
                    if (suffix.Length == 1 && GetCEsFromCE32(data, Collation.SentinelCodePoint, ce32))
                    {
                        addContraction = true;
                    }
                    else
                    {
                        AddContractionEntry(x, Collation.NoCE, 0);
                        addContraction = false;
                    }
                    prevX = x;
                }
            }
            if (addContraction)
            {
                AddContractionEntry(prevX, ce0, ce1);
            }
            // Note: There might not be any fast Latin contractions, but
            // we need to enter contraction handling anyway so that we can bail out
            // when there is a non-fast-Latin character following.
            // For example: Danish &Y<<u+umlaut, when we compare Y vs. u\u0308 we need to see the
            // following umlaut and bail out, rather than return the difference of Y vs. u.
            ce0 = (Collation.NO_CE_PRIMARY << 32) | CONTRACTION_FLAG | (uint)contractionIndex;
            ce1 = 0;
            return(true);
        }
Esempio n. 2
0
        internal static void Read(CollationTailoring @base, ByteBuffer inBytes,
                                  CollationTailoring tailoring)
        {
            tailoring.Version = ICUBinary.ReadHeader(inBytes, DATA_FORMAT, IS_ACCEPTABLE);
            if (@base != null && @base.GetUCAVersion() != tailoring.GetUCAVersion())
            {
                throw new ICUException("Tailoring UCA version differs from base data UCA version");
            }

            int inLength = inBytes.Remaining;

            if (inLength < 8)
            {
                throw new ICUException("not enough bytes");
            }
            int indexesLength = inBytes.GetInt32();  // inIndexes[IX_INDEXES_LENGTH]

            if (indexesLength < 2 || inLength < indexesLength * 4)
            {
                throw new ICUException("not enough indexes");
            }
            int[] inIndexes = new int[IX_TOTAL_SIZE + 1];
            inIndexes[0] = indexesLength;
            for (int i = 1; i < indexesLength && i < inIndexes.Length; ++i)
            {
                inIndexes[i] = inBytes.GetInt32();
            }
            for (int i = indexesLength; i < inIndexes.Length; ++i)
            {
                inIndexes[i] = -1;
            }
            if (indexesLength > inIndexes.Length)
            {
                ICUBinary.SkipBytes(inBytes, (indexesLength - inIndexes.Length) * 4);
            }

            // Assume that the tailoring data is in initial state,
            // with null pointers and 0 lengths.

            // Set pointers to non-empty data parts.
            // Do this in order of their byte offsets. (Should help porting to Java.)

            int index;  // one of the indexes[] slots
            int offset; // byte offset for the index part
            int length; // number of bytes in the index part

            if (indexesLength > IX_TOTAL_SIZE)
            {
                length = inIndexes[IX_TOTAL_SIZE];
            }
            else if (indexesLength > IX_REORDER_CODES_OFFSET)
            {
                length = inIndexes[indexesLength - 1];
            }
            else
            {
                length = 0;  // only indexes, and inLength was already checked for them
            }
            if (inLength < length)
            {
                throw new ICUException("not enough bytes");
            }

            CollationData baseData = @base == null ? null : @base.Data;

            int[] reorderCodes;
            int   reorderCodesLength;

            index  = IX_REORDER_CODES_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 4)
            {
                if (baseData == null)
                {
                    // We assume for collation settings that
                    // the base data does not have a reordering.
                    throw new ICUException("Collation base data must not reorder scripts");
                }
                reorderCodesLength = length / 4;
                reorderCodes       = ICUBinary.GetInts(inBytes, reorderCodesLength, length & 3);

                // The reorderRanges (if any) are the trailing reorderCodes entries.
                // Split the array at the boundary.
                // Script or reorder codes do not exceed 16-bit values.
                // Range limits are stored in the upper 16 bits, and are never 0.
                int reorderRangesLength = 0;
                while (reorderRangesLength < reorderCodesLength &&
                       (reorderCodes[reorderCodesLength - reorderRangesLength - 1] & 0xffff0000) != 0)
                {
                    ++reorderRangesLength;
                }
                Debug.Assert(reorderRangesLength < reorderCodesLength);
                reorderCodesLength -= reorderRangesLength;
            }
            else
            {
                reorderCodes       = new int[0];
                reorderCodesLength = 0;
                ICUBinary.SkipBytes(inBytes, length);
            }

            // There should be a reorder table only if there are reorder codes.
            // However, when there are reorder codes the reorder table may be omitted to reduce
            // the data size.
            byte[] reorderTable = null;
            index  = IX_REORDER_TABLE_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 256)
            {
                if (reorderCodesLength == 0)
                {
                    throw new ICUException("Reordering table without reordering codes");
                }
                reorderTable = new byte[256];
                inBytes.Get(reorderTable);
                length -= 256;
            }
            else
            {
                // If we have reorder codes, then build the reorderTable at the end,
                // when the CollationData is otherwise complete.
            }
            ICUBinary.SkipBytes(inBytes, length);

            if (baseData != null && baseData.numericPrimary != (inIndexes[IX_OPTIONS] & 0xff000000L))
            {
                throw new ICUException("Tailoring numeric primary weight differs from base data");
            }
            CollationData data = null;  // Remains null if there are no mappings.

            index  = IX_TRIE_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 8)
            {
                tailoring.EnsureOwnedData();
                data                = tailoring.OwnedData;
                data.Base           = baseData;
                data.numericPrimary = inIndexes[IX_OPTIONS] & 0xff000000L;
                data.trie           = tailoring.Trie = Trie2_32.CreateFromSerialized(inBytes);
                int trieLength = data.trie.GetSerializedLength();
                if (trieLength > length)
                {
                    throw new ICUException("Not enough bytes for the mappings trie");  // No mappings.
                }
                length -= trieLength;
            }
            else if (baseData != null)
            {
                // Use the base data. Only the settings are tailored.
                tailoring.Data = baseData;
            }
            else
            {
                throw new ICUException("Missing collation data mappings");  // No mappings.
            }
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_RESERVED8_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_CES_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 8)
            {
                if (data == null)
                {
                    throw new ICUException("Tailored ces without tailored trie");
                }
                data.ces = ICUBinary.GetLongs(inBytes, length / 8, length & 7);
            }
            else
            {
                ICUBinary.SkipBytes(inBytes, length);
            }

            index  = IX_RESERVED10_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_CE32S_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 4)
            {
                if (data == null)
                {
                    throw new ICUException("Tailored ce32s without tailored trie");
                }
                data.ce32s = ICUBinary.GetInts(inBytes, length / 4, length & 3);
            }
            else
            {
                ICUBinary.SkipBytes(inBytes, length);
            }

            int jamoCE32sStart = inIndexes[IX_JAMO_CE32S_START];

            if (jamoCE32sStart >= 0)
            {
                if (data == null || data.ce32s == null)
                {
                    throw new ICUException("JamoCE32sStart index into non-existent ce32s[]");
                }
                data.jamoCE32s = new int[CollationData.JAMO_CE32S_LENGTH];
                // ICU4N specific - added extension method to IList<T> to handle "copy to"
                data.ce32s.CopyTo(jamoCE32sStart, data.jamoCE32s, 0, CollationData.JAMO_CE32S_LENGTH);
            }
            else if (data == null)
            {
                // Nothing to do.
            }
            else if (baseData != null)
            {
                data.jamoCE32s = baseData.jamoCE32s;
            }
            else
            {
                throw new ICUException("Missing Jamo CE32s for Hangul processing");
            }

            index  = IX_ROOT_ELEMENTS_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 4)
            {
                int rootElementsLength = length / 4;
                if (data == null)
                {
                    throw new ICUException("Root elements but no mappings");
                }
                if (rootElementsLength <= CollationRootElements.IX_SEC_TER_BOUNDARIES)
                {
                    throw new ICUException("Root elements array too short");
                }
                data.rootElements = new long[rootElementsLength];
                for (int i = 0; i < rootElementsLength; ++i)
                {
                    data.rootElements[i] = inBytes.GetInt32() & 0xffffffffL;  // unsigned int -> long
                }
                long commonSecTer = data.rootElements[CollationRootElements.IX_COMMON_SEC_AND_TER_CE];
                if (commonSecTer != Collation.COMMON_SEC_AND_TER_CE)
                {
                    throw new ICUException("Common sec/ter weights in base data differ from the hardcoded value");
                }
                long secTerBoundaries = data.rootElements[CollationRootElements.IX_SEC_TER_BOUNDARIES];
                if ((secTerBoundaries.TripleShift(24)) < CollationKeys.SEC_COMMON_HIGH)
                {
                    // [fixed last secondary common byte] is too low,
                    // and secondary weights would collide with compressed common secondaries.
                    throw new ICUException("[fixed last secondary common byte] is too low");
                }
                length &= 3;
            }
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_CONTEXTS_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 2)
            {
                if (data == null)
                {
                    throw new ICUException("Tailored contexts without tailored trie");
                }
                data.contexts = ICUBinary.GetString(inBytes, length / 2, length & 1);
            }
            else
            {
                ICUBinary.SkipBytes(inBytes, length);
            }

            index  = IX_UNSAFE_BWD_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 2)
            {
                if (data == null)
                {
                    throw new ICUException("Unsafe-backward-set but no mappings");
                }
                if (baseData == null)
                {
                    // Create the unsafe-backward set for the root collator.
                    // Include all non-zero combining marks and trail surrogates.
                    // We do this at load time, rather than at build time,
                    // to simplify Unicode version bootstrapping:
                    // The root data builder only needs the new FractionalUCA.txt data,
                    // but it need not be built with a version of ICU already updated to
                    // the corresponding new Unicode Character Database.
                    //
                    // The following is an optimized version of
                    // new UnicodeSet("[[:^lccc=0:][\\udc00-\\udfff]]").
                    // It is faster and requires fewer code dependencies.
                    tailoring.UnsafeBackwardSet = new UnicodeSet(0xdc00, 0xdfff);  // trail surrogates
                    data.nfcImpl.AddLcccChars(tailoring.UnsafeBackwardSet);
                }
                else
                {
                    // Clone the root collator's set contents.
                    tailoring.UnsafeBackwardSet = baseData.unsafeBackwardSet.CloneAsThawed();
                }
                // Add the ranges from the data file to the unsafe-backward set.
                USerializedSet sset       = new USerializedSet();
                char[]         unsafeData = ICUBinary.GetChars(inBytes, length / 2, length & 1);
                length = 0;
                sset.GetSet(unsafeData, 0);
                int   count = sset.CountRanges();
                int[] range = new int[2];
                for (int i = 0; i < count; ++i)
                {
                    sset.GetRange(i, range);
                    tailoring.UnsafeBackwardSet.Add(range[0], range[1]);
                }
                // Mark each lead surrogate as "unsafe"
                // if any of its 1024 associated supplementary code points is "unsafe".
                int c = 0x10000;
                for (int lead = 0xd800; lead < 0xdc00; ++lead, c += 0x400)
                {
                    if (!tailoring.UnsafeBackwardSet.ContainsNone(c, c + 0x3ff))
                    {
                        tailoring.UnsafeBackwardSet.Add(lead);
                    }
                }
                tailoring.UnsafeBackwardSet.Freeze();
                data.unsafeBackwardSet = tailoring.UnsafeBackwardSet;
            }
            else if (data == null)
            {
                // Nothing to do.
            }
            else if (baseData != null)
            {
                // No tailoring-specific data: Alias the root collator's set.
                data.unsafeBackwardSet = baseData.unsafeBackwardSet;
            }
            else
            {
                throw new ICUException("Missing unsafe-backward-set");
            }
            ICUBinary.SkipBytes(inBytes, length);

            // If the fast Latin format version is different,
            // or the version is set to 0 for "no fast Latin table",
            // then just always use the normal string comparison path.
            index  = IX_FAST_LATIN_TABLE_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (data != null)
            {
                data.fastLatinTable       = null;
                data.fastLatinTableHeader = null;
                if (((inIndexes[IX_OPTIONS] >> 16) & 0xff) == CollationFastLatin.VERSION)
                {
                    if (length >= 2)
                    {
                        char header0      = inBytes.GetChar();
                        int  headerLength = header0 & 0xff;
                        data.fastLatinTableHeader    = new char[headerLength];
                        data.fastLatinTableHeader[0] = header0;
                        for (int i = 1; i < headerLength; ++i)
                        {
                            data.fastLatinTableHeader[i] = inBytes.GetChar();
                        }
                        int tableLength = length / 2 - headerLength;
                        data.fastLatinTable = ICUBinary.GetChars(inBytes, tableLength, length & 1);
                        length = 0;
                        if ((header0 >> 8) != CollationFastLatin.VERSION)
                        {
                            throw new ICUException("Fast-Latin table version differs from version in data header");
                        }
                    }
                    else if (baseData != null)
                    {
                        data.fastLatinTable       = baseData.fastLatinTable;
                        data.fastLatinTableHeader = baseData.fastLatinTableHeader;
                    }
                }
            }
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_SCRIPTS_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 2)
            {
                if (data == null)
                {
                    throw new ICUException("Script order data but no mappings");
                }
                int        scriptsLength = length / 2;
                CharBuffer inChars       = inBytes.AsCharBuffer();
                data.numScripts = inChars.Get();
                // There must be enough entries for both arrays, including more than two range starts.
                int scriptStartsLength = scriptsLength - (1 + data.numScripts + 16);
                if (scriptStartsLength <= 2)
                {
                    throw new ICUException("Script order data too short");
                }
                inChars.Get(data.scriptsIndex = new char[data.numScripts + 16]);
                inChars.Get(data.scriptStarts = new char[scriptStartsLength]);
                if (!(data.scriptStarts[0] == 0 &&
                      data.scriptStarts[1] == ((Collation.MERGE_SEPARATOR_BYTE + 1) << 8) &&
                      data.scriptStarts[scriptStartsLength - 1] ==
                      (Collation.TRAIL_WEIGHT_BYTE << 8)))
                {
                    throw new ICUException("Script order data not valid");
                }
            }
            else if (data == null)
            {
                // Nothing to do.
            }
            else if (baseData != null)
            {
                data.numScripts   = baseData.numScripts;
                data.scriptsIndex = baseData.scriptsIndex;
                data.scriptStarts = baseData.scriptStarts;
            }
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_COMPRESSIBLE_BYTES_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            if (length >= 256)
            {
                if (data == null)
                {
                    throw new ICUException("Data for compressible primary lead bytes but no mappings");
                }
                data.compressibleBytes = new bool[256];
                for (int i = 0; i < 256; ++i)
                {
                    data.compressibleBytes[i] = inBytes.Get() != 0;
                }
                length -= 256;
            }
            else if (data == null)
            {
                // Nothing to do.
            }
            else if (baseData != null)
            {
                data.compressibleBytes = baseData.compressibleBytes;
            }
            else
            {
                throw new ICUException("Missing data for compressible primary lead bytes");
            }
            ICUBinary.SkipBytes(inBytes, length);

            index  = IX_RESERVED18_OFFSET;
            offset = inIndexes[index];
            length = inIndexes[index + 1] - offset;
            ICUBinary.SkipBytes(inBytes, length);

            CollationSettings ts = tailoring.Settings.ReadOnly;
            int options          = inIndexes[IX_OPTIONS] & 0xffff;

            char[] fastLatinPrimaries = new char[CollationFastLatin.LATIN_LIMIT];
            int    fastLatinOptions   = CollationFastLatin.GetOptions(
                tailoring.Data, ts, fastLatinPrimaries);

            if (options == ts.Options && ts.VariableTop != 0 &&
                Arrays.Equals(reorderCodes, ts.ReorderCodes) &&
                fastLatinOptions == ts.FastLatinOptions &&
                (fastLatinOptions < 0 ||
                 Arrays.Equals(fastLatinPrimaries, ts.FastLatinPrimaries)))
            {
                return;
            }

            CollationSettings settings = tailoring.Settings.CopyOnWrite();

            settings.Options = options;
            // Set variableTop from options and scripts data.
            settings.VariableTop = tailoring.Data.GetLastPrimaryForGroup(
                ReorderCodes.First + settings.MaxVariable);
            if (settings.VariableTop == 0)
            {
                throw new ICUException("The maxVariable could not be mapped to a variableTop");
            }

            if (reorderCodesLength != 0)
            {
                settings.AliasReordering(baseData, reorderCodes, reorderCodesLength, reorderTable);
            }

            settings.FastLatinOptions = CollationFastLatin.GetOptions(
                tailoring.Data, settings,
                settings.FastLatinPrimaries);
        }