1 /* 2 * Copyright (C) 2013 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 package com.android.inputmethod.latin.makedict; 18 19 import com.android.inputmethod.latin.makedict.BinaryDictDecoderUtils.CharEncoding; 20 import com.android.inputmethod.latin.makedict.FormatSpec.FormatOptions; 21 import com.android.inputmethod.latin.makedict.FusionDictionary.PtNode; 22 import com.android.inputmethod.latin.makedict.FusionDictionary.PtNodeArray; 23 24 import java.io.ByteArrayOutputStream; 25 import java.io.IOException; 26 import java.io.OutputStream; 27 import java.util.ArrayList; 28 import java.util.HashMap; 29 import java.util.Map.Entry; 30 31 /** 32 * Encodes binary files for a FusionDictionary. 33 * 34 * All the methods in this class are static. 35 * 36 * TODO: Rename this class to DictEncoderUtils. 37 */ 38 public class BinaryDictEncoderUtils { 39 40 private static final boolean DBG = MakedictLog.DBG; 41 BinaryDictEncoderUtils()42 private BinaryDictEncoderUtils() { 43 // This utility class is not publicly instantiable. 44 } 45 46 // Arbitrary limit to how much passes we consider address size compression should 47 // terminate in. At the time of this writing, our largest dictionary completes 48 // compression in five passes. 49 // If the number of passes exceeds this number, makedict bails with an exception on 50 // suspicion that a bug might be causing an infinite loop. 51 private static final int MAX_PASSES = 24; 52 53 /** 54 * Compute the binary size of the character array. 55 * 56 * If only one character, this is the size of this character. If many, it's the sum of their 57 * sizes + 1 byte for the terminator. 58 * 59 * @param characters the character array 60 * @return the size of the char array, including the terminator if any 61 */ getPtNodeCharactersSize(final int[] characters, final HashMap<Integer, Integer> codePointToOneByteCodeMap)62 static int getPtNodeCharactersSize(final int[] characters, 63 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 64 int size = CharEncoding.getCharArraySize(characters, codePointToOneByteCodeMap); 65 if (characters.length > 1) size += FormatSpec.PTNODE_TERMINATOR_SIZE; 66 return size; 67 } 68 69 /** 70 * Compute the binary size of the character array in a PtNode 71 * 72 * If only one character, this is the size of this character. If many, it's the sum of their 73 * sizes + 1 byte for the terminator. 74 * 75 * @param ptNode the PtNode 76 * @return the size of the char array, including the terminator if any 77 */ getPtNodeCharactersSize(final PtNode ptNode, final HashMap<Integer, Integer> codePointToOneByteCodeMap)78 private static int getPtNodeCharactersSize(final PtNode ptNode, 79 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 80 return getPtNodeCharactersSize(ptNode.mChars, codePointToOneByteCodeMap); 81 } 82 83 /** 84 * Compute the binary size of the PtNode count for a node array. 85 * @param nodeArray the nodeArray 86 * @return the size of the PtNode count, either 1 or 2 bytes. 87 */ getPtNodeCountSize(final PtNodeArray nodeArray)88 private static int getPtNodeCountSize(final PtNodeArray nodeArray) { 89 return BinaryDictIOUtils.getPtNodeCountSize(nodeArray.mData.size()); 90 } 91 92 /** 93 * Compute the maximum size of a PtNode, assuming 3-byte addresses for everything. 94 * 95 * @param ptNode the PtNode to compute the size of. 96 * @return the maximum size of the PtNode. 97 */ getPtNodeMaximumSize(final PtNode ptNode, final HashMap<Integer, Integer> codePointToOneByteCodeMap)98 private static int getPtNodeMaximumSize(final PtNode ptNode, 99 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 100 int size = getNodeHeaderSize(ptNode, codePointToOneByteCodeMap); 101 if (ptNode.isTerminal()) { 102 // If terminal, one byte for the frequency. 103 size += FormatSpec.PTNODE_FREQUENCY_SIZE; 104 } 105 size += FormatSpec.PTNODE_MAX_ADDRESS_SIZE; // For children address 106 if (null != ptNode.mBigrams) { 107 size += (FormatSpec.PTNODE_ATTRIBUTE_FLAGS_SIZE 108 + FormatSpec.PTNODE_ATTRIBUTE_MAX_ADDRESS_SIZE) 109 * ptNode.mBigrams.size(); 110 } 111 return size; 112 } 113 114 /** 115 * Compute the maximum size of each PtNode of a PtNode array, assuming 3-byte addresses for 116 * everything, and caches it in the `mCachedSize' member of the nodes; deduce the size of 117 * the containing node array, and cache it it its 'mCachedSize' member. 118 * 119 * @param ptNodeArray the node array to compute the maximum size of. 120 */ calculatePtNodeArrayMaximumSize(final PtNodeArray ptNodeArray, final HashMap<Integer, Integer> codePointToOneByteCodeMap)121 private static void calculatePtNodeArrayMaximumSize(final PtNodeArray ptNodeArray, 122 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 123 int size = getPtNodeCountSize(ptNodeArray); 124 for (PtNode node : ptNodeArray.mData) { 125 final int nodeSize = getPtNodeMaximumSize(node, codePointToOneByteCodeMap); 126 node.mCachedSize = nodeSize; 127 size += nodeSize; 128 } 129 ptNodeArray.mCachedSize = size; 130 } 131 132 /** 133 * Compute the size of the header (flag + [parent address] + characters size) of a PtNode. 134 * 135 * @param ptNode the PtNode of which to compute the size of the header 136 */ getNodeHeaderSize(final PtNode ptNode, final HashMap<Integer, Integer> codePointToOneByteCodeMap)137 private static int getNodeHeaderSize(final PtNode ptNode, 138 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 139 return FormatSpec.PTNODE_FLAGS_SIZE + getPtNodeCharactersSize(ptNode, 140 codePointToOneByteCodeMap); 141 } 142 143 /** 144 * Compute the size, in bytes, that an address will occupy. 145 * 146 * This can be used either for children addresses (which are always positive) or for 147 * attribute, which may be positive or negative but 148 * store their sign bit separately. 149 * 150 * @param address the address 151 * @return the byte size. 152 */ getByteSize(final int address)153 static int getByteSize(final int address) { 154 assert(address <= FormatSpec.UINT24_MAX); 155 if (!BinaryDictIOUtils.hasChildrenAddress(address)) { 156 return 0; 157 } else if (Math.abs(address) <= FormatSpec.UINT8_MAX) { 158 return 1; 159 } else if (Math.abs(address) <= FormatSpec.UINT16_MAX) { 160 return 2; 161 } else { 162 return 3; 163 } 164 } 165 writeUIntToBuffer(final byte[] buffer, final int fromPosition, final int value, final int size)166 static int writeUIntToBuffer(final byte[] buffer, final int fromPosition, final int value, 167 final int size) { 168 int position = fromPosition; 169 switch(size) { 170 case 4: 171 buffer[position++] = (byte) ((value >> 24) & 0xFF); 172 /* fall through */ 173 case 3: 174 buffer[position++] = (byte) ((value >> 16) & 0xFF); 175 /* fall through */ 176 case 2: 177 buffer[position++] = (byte) ((value >> 8) & 0xFF); 178 /* fall through */ 179 case 1: 180 buffer[position++] = (byte) (value & 0xFF); 181 break; 182 default: 183 /* nop */ 184 } 185 return position; 186 } 187 writeUIntToStream(final OutputStream stream, final int value, final int size)188 static void writeUIntToStream(final OutputStream stream, final int value, final int size) 189 throws IOException { 190 switch(size) { 191 case 4: 192 stream.write((value >> 24) & 0xFF); 193 /* fall through */ 194 case 3: 195 stream.write((value >> 16) & 0xFF); 196 /* fall through */ 197 case 2: 198 stream.write((value >> 8) & 0xFF); 199 /* fall through */ 200 case 1: 201 stream.write(value & 0xFF); 202 break; 203 default: 204 /* nop */ 205 } 206 } 207 208 // End utility methods 209 210 // This method is responsible for finding a nice ordering of the nodes that favors run-time 211 // cache performance and dictionary size. flattenTree( final PtNodeArray rootNodeArray)212 /* package for tests */ static ArrayList<PtNodeArray> flattenTree( 213 final PtNodeArray rootNodeArray) { 214 final int treeSize = FusionDictionary.countPtNodes(rootNodeArray); 215 MakedictLog.i("Counted nodes : " + treeSize); 216 final ArrayList<PtNodeArray> flatTree = new ArrayList<>(treeSize); 217 return flattenTreeInner(flatTree, rootNodeArray); 218 } 219 flattenTreeInner(final ArrayList<PtNodeArray> list, final PtNodeArray ptNodeArray)220 private static ArrayList<PtNodeArray> flattenTreeInner(final ArrayList<PtNodeArray> list, 221 final PtNodeArray ptNodeArray) { 222 // Removing the node is necessary if the tails are merged, because we would then 223 // add the same node several times when we only want it once. A number of places in 224 // the code also depends on any node being only once in the list. 225 // Merging tails can only be done if there are no attributes. Searching for attributes 226 // in LatinIME code depends on a total breadth-first ordering, which merging tails 227 // breaks. If there are no attributes, it should be fine (and reduce the file size) 228 // to merge tails, and removing the node from the list would be necessary. However, 229 // we don't merge tails because breaking the breadth-first ordering would result in 230 // extreme overhead at bigram lookup time (it would make the search function O(n) instead 231 // of the current O(log(n)), where n=number of nodes in the dictionary which is pretty 232 // high). 233 // If no nodes are ever merged, we can't have the same node twice in the list, hence 234 // searching for duplicates in unnecessary. It is also very performance consuming, 235 // since `list' is an ArrayList so it's an O(n) operation that runs on all nodes, making 236 // this simple list.remove operation O(n*n) overall. On Android this overhead is very 237 // high. 238 // For future reference, the code to remove duplicate is a simple : list.remove(node); 239 list.add(ptNodeArray); 240 final ArrayList<PtNode> branches = ptNodeArray.mData; 241 for (PtNode ptNode : branches) { 242 if (null != ptNode.mChildren) flattenTreeInner(list, ptNode.mChildren); 243 } 244 return list; 245 } 246 247 /** 248 * Get the offset from a position inside a current node array to a target node array, during 249 * update. 250 * 251 * If the current node array is before the target node array, the target node array has not 252 * been updated yet, so we should return the offset from the old position of the current node 253 * array to the old position of the target node array. If on the other hand the target is 254 * before the current node array, it already has been updated, so we should return the offset 255 * from the new position in the current node array to the new position in the target node 256 * array. 257 * 258 * @param currentNodeArray node array containing the PtNode where the offset will be written 259 * @param offsetFromStartOfCurrentNodeArray offset, in bytes, from the start of currentNodeArray 260 * @param targetNodeArray the target node array to get the offset to 261 * @return the offset to the target node array 262 */ getOffsetToTargetNodeArrayDuringUpdate(final PtNodeArray currentNodeArray, final int offsetFromStartOfCurrentNodeArray, final PtNodeArray targetNodeArray)263 private static int getOffsetToTargetNodeArrayDuringUpdate(final PtNodeArray currentNodeArray, 264 final int offsetFromStartOfCurrentNodeArray, final PtNodeArray targetNodeArray) { 265 final boolean isTargetBeforeCurrent = (targetNodeArray.mCachedAddressBeforeUpdate 266 < currentNodeArray.mCachedAddressBeforeUpdate); 267 if (isTargetBeforeCurrent) { 268 return targetNodeArray.mCachedAddressAfterUpdate 269 - (currentNodeArray.mCachedAddressAfterUpdate 270 + offsetFromStartOfCurrentNodeArray); 271 } 272 return targetNodeArray.mCachedAddressBeforeUpdate 273 - (currentNodeArray.mCachedAddressBeforeUpdate + offsetFromStartOfCurrentNodeArray); 274 } 275 276 /** 277 * Get the offset from a position inside a current node array to a target PtNode, during 278 * update. 279 * 280 * @param currentNodeArray node array containing the PtNode where the offset will be written 281 * @param offsetFromStartOfCurrentNodeArray offset, in bytes, from the start of currentNodeArray 282 * @param targetPtNode the target PtNode to get the offset to 283 * @return the offset to the target PtNode 284 */ 285 // TODO: is there any way to factorize this method with the one above? getOffsetToTargetPtNodeDuringUpdate(final PtNodeArray currentNodeArray, final int offsetFromStartOfCurrentNodeArray, final PtNode targetPtNode)286 private static int getOffsetToTargetPtNodeDuringUpdate(final PtNodeArray currentNodeArray, 287 final int offsetFromStartOfCurrentNodeArray, final PtNode targetPtNode) { 288 final int oldOffsetBasePoint = currentNodeArray.mCachedAddressBeforeUpdate 289 + offsetFromStartOfCurrentNodeArray; 290 final boolean isTargetBeforeCurrent = (targetPtNode.mCachedAddressBeforeUpdate 291 < oldOffsetBasePoint); 292 // If the target is before the current node array, then its address has already been 293 // updated. We can use the AfterUpdate member, and compare it to our own member after 294 // update. Otherwise, the AfterUpdate member is not updated yet, so we need to use the 295 // BeforeUpdate member, and of course we have to compare this to our own address before 296 // update. 297 if (isTargetBeforeCurrent) { 298 final int newOffsetBasePoint = currentNodeArray.mCachedAddressAfterUpdate 299 + offsetFromStartOfCurrentNodeArray; 300 return targetPtNode.mCachedAddressAfterUpdate - newOffsetBasePoint; 301 } 302 return targetPtNode.mCachedAddressBeforeUpdate - oldOffsetBasePoint; 303 } 304 305 /** 306 * Computes the actual node array size, based on the cached addresses of the children nodes. 307 * 308 * Each node array stores its tentative address. During dictionary address computing, these 309 * are not final, but they can be used to compute the node array size (the node array size 310 * depends on the address of the children because the number of bytes necessary to store an 311 * address depends on its numeric value. The return value indicates whether the node array 312 * contents (as in, any of the addresses stored in the cache fields) have changed with 313 * respect to their previous value. 314 * 315 * @param ptNodeArray the node array to compute the size of. 316 * @param dict the dictionary in which the word/attributes are to be found. 317 * @return false if none of the cached addresses inside the node array changed, true otherwise. 318 */ computeActualPtNodeArraySize(final PtNodeArray ptNodeArray, final FusionDictionary dict, final HashMap<Integer, Integer> codePointToOneByteCodeMap)319 private static boolean computeActualPtNodeArraySize(final PtNodeArray ptNodeArray, 320 final FusionDictionary dict, 321 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 322 boolean changed = false; 323 int size = getPtNodeCountSize(ptNodeArray); 324 for (PtNode ptNode : ptNodeArray.mData) { 325 ptNode.mCachedAddressAfterUpdate = ptNodeArray.mCachedAddressAfterUpdate + size; 326 if (ptNode.mCachedAddressAfterUpdate != ptNode.mCachedAddressBeforeUpdate) { 327 changed = true; 328 } 329 int nodeSize = getNodeHeaderSize(ptNode, codePointToOneByteCodeMap); 330 if (ptNode.isTerminal()) { 331 nodeSize += FormatSpec.PTNODE_FREQUENCY_SIZE; 332 } 333 if (null != ptNode.mChildren) { 334 nodeSize += getByteSize(getOffsetToTargetNodeArrayDuringUpdate(ptNodeArray, 335 nodeSize + size, ptNode.mChildren)); 336 } 337 if (null != ptNode.mBigrams) { 338 for (WeightedString bigram : ptNode.mBigrams) { 339 final int offset = getOffsetToTargetPtNodeDuringUpdate(ptNodeArray, 340 nodeSize + size + FormatSpec.PTNODE_ATTRIBUTE_FLAGS_SIZE, 341 FusionDictionary.findWordInTree(dict.mRootNodeArray, bigram.mWord)); 342 nodeSize += getByteSize(offset) + FormatSpec.PTNODE_ATTRIBUTE_FLAGS_SIZE; 343 } 344 } 345 ptNode.mCachedSize = nodeSize; 346 size += nodeSize; 347 } 348 if (ptNodeArray.mCachedSize != size) { 349 ptNodeArray.mCachedSize = size; 350 changed = true; 351 } 352 return changed; 353 } 354 355 /** 356 * Initializes the cached addresses of node arrays and their containing nodes from their size. 357 * 358 * @param flatNodes the list of node arrays. 359 * @return the byte size of the entire stack. 360 */ initializePtNodeArraysCachedAddresses( final ArrayList<PtNodeArray> flatNodes)361 private static int initializePtNodeArraysCachedAddresses( 362 final ArrayList<PtNodeArray> flatNodes) { 363 int nodeArrayOffset = 0; 364 for (final PtNodeArray nodeArray : flatNodes) { 365 nodeArray.mCachedAddressBeforeUpdate = nodeArrayOffset; 366 int nodeCountSize = getPtNodeCountSize(nodeArray); 367 int nodeffset = 0; 368 for (final PtNode ptNode : nodeArray.mData) { 369 ptNode.mCachedAddressBeforeUpdate = ptNode.mCachedAddressAfterUpdate = 370 nodeCountSize + nodeArrayOffset + nodeffset; 371 nodeffset += ptNode.mCachedSize; 372 } 373 nodeArrayOffset += nodeArray.mCachedSize; 374 } 375 return nodeArrayOffset; 376 } 377 378 /** 379 * Updates the cached addresses of node arrays after recomputing their new positions. 380 * 381 * @param flatNodes the list of node arrays. 382 */ updatePtNodeArraysCachedAddresses(final ArrayList<PtNodeArray> flatNodes)383 private static void updatePtNodeArraysCachedAddresses(final ArrayList<PtNodeArray> flatNodes) { 384 for (final PtNodeArray nodeArray : flatNodes) { 385 nodeArray.mCachedAddressBeforeUpdate = nodeArray.mCachedAddressAfterUpdate; 386 for (final PtNode ptNode : nodeArray.mData) { 387 ptNode.mCachedAddressBeforeUpdate = ptNode.mCachedAddressAfterUpdate; 388 } 389 } 390 } 391 392 /** 393 * Compute the addresses and sizes of an ordered list of PtNode arrays. 394 * 395 * This method takes a list of PtNode arrays and will update their cached address and size 396 * values so that they can be written into a file. It determines the smallest size each of the 397 * PtNode arrays can be given the addresses of its children and attributes, and store that into 398 * each PtNode. 399 * The order of the PtNode is given by the order of the array. This method makes no effort 400 * to find a good order; it only mechanically computes the size this order results in. 401 * 402 * @param dict the dictionary 403 * @param flatNodes the ordered list of PtNode arrays 404 * @return the same array it was passed. The nodes have been updated for address and size. 405 */ computeAddresses(final FusionDictionary dict, final ArrayList<PtNodeArray> flatNodes, final HashMap<Integer, Integer> codePointToOneByteCodeMap)406 /* package */ static ArrayList<PtNodeArray> computeAddresses(final FusionDictionary dict, 407 final ArrayList<PtNodeArray> flatNodes, 408 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 409 // First get the worst possible sizes and offsets 410 for (final PtNodeArray n : flatNodes) { 411 calculatePtNodeArrayMaximumSize(n, codePointToOneByteCodeMap); 412 } 413 final int offset = initializePtNodeArraysCachedAddresses(flatNodes); 414 415 MakedictLog.i("Compressing the array addresses. Original size : " + offset); 416 MakedictLog.i("(Recursively seen size : " + offset + ")"); 417 418 int passes = 0; 419 boolean changesDone = false; 420 do { 421 changesDone = false; 422 int ptNodeArrayStartOffset = 0; 423 for (final PtNodeArray ptNodeArray : flatNodes) { 424 ptNodeArray.mCachedAddressAfterUpdate = ptNodeArrayStartOffset; 425 final int oldNodeArraySize = ptNodeArray.mCachedSize; 426 final boolean changed = computeActualPtNodeArraySize(ptNodeArray, dict, 427 codePointToOneByteCodeMap); 428 final int newNodeArraySize = ptNodeArray.mCachedSize; 429 if (oldNodeArraySize < newNodeArraySize) { 430 throw new RuntimeException("Increased size ?!"); 431 } 432 ptNodeArrayStartOffset += newNodeArraySize; 433 changesDone |= changed; 434 } 435 updatePtNodeArraysCachedAddresses(flatNodes); 436 ++passes; 437 if (passes > MAX_PASSES) throw new RuntimeException("Too many passes - probably a bug"); 438 } while (changesDone); 439 440 final PtNodeArray lastPtNodeArray = flatNodes.get(flatNodes.size() - 1); 441 MakedictLog.i("Compression complete in " + passes + " passes."); 442 MakedictLog.i("After address compression : " 443 + (lastPtNodeArray.mCachedAddressAfterUpdate + lastPtNodeArray.mCachedSize)); 444 445 return flatNodes; 446 } 447 448 /** 449 * Validity-checking method. 450 * 451 * This method checks a list of PtNode arrays for juxtaposition, that is, it will do 452 * nothing if each node array's cached address is actually the previous node array's address 453 * plus the previous node's size. 454 * If this is not the case, it will throw an exception. 455 * 456 * @param arrays the list of node arrays to check 457 */ checkFlatPtNodeArrayList(final ArrayList<PtNodeArray> arrays)458 /* package */ static void checkFlatPtNodeArrayList(final ArrayList<PtNodeArray> arrays) { 459 int offset = 0; 460 int index = 0; 461 for (final PtNodeArray ptNodeArray : arrays) { 462 // BeforeUpdate and AfterUpdate addresses are the same here, so it does not matter 463 // which we use. 464 if (ptNodeArray.mCachedAddressAfterUpdate != offset) { 465 throw new RuntimeException("Wrong address for node " + index 466 + " : expected " + offset + ", got " + 467 ptNodeArray.mCachedAddressAfterUpdate); 468 } 469 ++index; 470 offset += ptNodeArray.mCachedSize; 471 } 472 } 473 474 /** 475 * Helper method to write a children position to a file. 476 * 477 * @param buffer the buffer to write to. 478 * @param fromIndex the index in the buffer to write the address to. 479 * @param position the position to write. 480 * @return the size in bytes the address actually took. 481 */ writeChildrenPosition(final byte[] buffer, final int fromIndex, final int position)482 /* package */ static int writeChildrenPosition(final byte[] buffer, final int fromIndex, 483 final int position) { 484 int index = fromIndex; 485 switch (getByteSize(position)) { 486 case 1: 487 buffer[index++] = (byte)position; 488 return 1; 489 case 2: 490 buffer[index++] = (byte)(0xFF & (position >> 8)); 491 buffer[index++] = (byte)(0xFF & position); 492 return 2; 493 case 3: 494 buffer[index++] = (byte)(0xFF & (position >> 16)); 495 buffer[index++] = (byte)(0xFF & (position >> 8)); 496 buffer[index++] = (byte)(0xFF & position); 497 return 3; 498 case 0: 499 return 0; 500 default: 501 throw new RuntimeException("Position " + position + " has a strange size"); 502 } 503 } 504 505 /** 506 * Makes the flag value for a PtNode. 507 * 508 * @param hasMultipleChars whether the PtNode has multiple chars. 509 * @param isTerminal whether the PtNode is terminal. 510 * @param childrenAddressSize the size of a children address. 511 * @param hasBigrams whether the PtNode has bigrams. 512 * @param isNotAWord whether the PtNode is not a word. 513 * @param isPossiblyOffensive whether the PtNode is a possibly offensive entry. 514 * @return the flags 515 */ makePtNodeFlags(final boolean hasMultipleChars, final boolean isTerminal, final int childrenAddressSize, final boolean hasBigrams, final boolean isNotAWord, final boolean isPossiblyOffensive)516 static int makePtNodeFlags(final boolean hasMultipleChars, final boolean isTerminal, 517 final int childrenAddressSize, final boolean hasBigrams, 518 final boolean isNotAWord, final boolean isPossiblyOffensive) { 519 byte flags = 0; 520 if (hasMultipleChars) flags |= FormatSpec.FLAG_HAS_MULTIPLE_CHARS; 521 if (isTerminal) flags |= FormatSpec.FLAG_IS_TERMINAL; 522 switch (childrenAddressSize) { 523 case 1: 524 flags |= FormatSpec.FLAG_CHILDREN_ADDRESS_TYPE_ONEBYTE; 525 break; 526 case 2: 527 flags |= FormatSpec.FLAG_CHILDREN_ADDRESS_TYPE_TWOBYTES; 528 break; 529 case 3: 530 flags |= FormatSpec.FLAG_CHILDREN_ADDRESS_TYPE_THREEBYTES; 531 break; 532 case 0: 533 flags |= FormatSpec.FLAG_CHILDREN_ADDRESS_TYPE_NOADDRESS; 534 break; 535 default: 536 throw new RuntimeException("Node with a strange address"); 537 } 538 if (hasBigrams) flags |= FormatSpec.FLAG_HAS_BIGRAMS; 539 if (isNotAWord) flags |= FormatSpec.FLAG_IS_NOT_A_WORD; 540 if (isPossiblyOffensive) flags |= FormatSpec.FLAG_IS_POSSIBLY_OFFENSIVE; 541 return flags; 542 } 543 makePtNodeFlags(final PtNode node, final int childrenOffset)544 /* package */ static byte makePtNodeFlags(final PtNode node, final int childrenOffset) { 545 return (byte) makePtNodeFlags(node.mChars.length > 1, node.isTerminal(), 546 getByteSize(childrenOffset), 547 node.mBigrams != null && !node.mBigrams.isEmpty(), 548 node.mIsNotAWord, node.mIsPossiblyOffensive); 549 } 550 551 /** 552 * Makes the flag value for a bigram. 553 * 554 * @param more whether there are more bigrams after this one. 555 * @param offset the offset of the bigram. 556 * @param bigramFrequency the frequency of the bigram, 0..255. 557 * @param unigramFrequency the unigram frequency of the same word, 0..255. 558 * @param word the second bigram, for debugging purposes 559 * @return the flags 560 */ makeBigramFlags(final boolean more, final int offset, final int bigramFrequency, final int unigramFrequency, final String word)561 /* package */ static int makeBigramFlags(final boolean more, final int offset, 562 final int bigramFrequency, final int unigramFrequency, final String word) { 563 int bigramFlags = (more ? FormatSpec.FLAG_BIGRAM_SHORTCUT_ATTR_HAS_NEXT : 0) 564 + (offset < 0 ? FormatSpec.FLAG_BIGRAM_ATTR_OFFSET_NEGATIVE : 0); 565 switch (getByteSize(offset)) { 566 case 1: 567 bigramFlags |= FormatSpec.FLAG_BIGRAM_ATTR_ADDRESS_TYPE_ONEBYTE; 568 break; 569 case 2: 570 bigramFlags |= FormatSpec.FLAG_BIGRAM_ATTR_ADDRESS_TYPE_TWOBYTES; 571 break; 572 case 3: 573 bigramFlags |= FormatSpec.FLAG_BIGRAM_ATTR_ADDRESS_TYPE_THREEBYTES; 574 break; 575 default: 576 throw new RuntimeException("Strange offset size"); 577 } 578 final int frequency; 579 if (unigramFrequency > bigramFrequency) { 580 MakedictLog.e("Unigram freq is superior to bigram freq for \"" + word 581 + "\". Bigram freq is " + bigramFrequency + ", unigram freq for " 582 + word + " is " + unigramFrequency); 583 frequency = unigramFrequency; 584 } else { 585 frequency = bigramFrequency; 586 } 587 bigramFlags += getBigramFrequencyDiff(unigramFrequency, frequency) 588 & FormatSpec.FLAG_BIGRAM_SHORTCUT_ATTR_FREQUENCY; 589 return bigramFlags; 590 } 591 getBigramFrequencyDiff(final int unigramFrequency, final int bigramFrequency)592 public static int getBigramFrequencyDiff(final int unigramFrequency, 593 final int bigramFrequency) { 594 // We compute the difference between 255 (which means probability = 1) and the 595 // unigram score. We split this into a number of discrete steps. 596 // Now, the steps are numbered 0~15; 0 represents an increase of 1 step while 15 597 // represents an increase of 16 steps: a value of 15 will be interpreted as the median 598 // value of the 16th step. In all justice, if the bigram frequency is low enough to be 599 // rounded below the first step (which means it is less than half a step higher than the 600 // unigram frequency) then the unigram frequency itself is the best approximation of the 601 // bigram freq that we could possibly supply, hence we should *not* include this bigram 602 // in the file at all. 603 // until this is done, we'll write 0 and slightly overestimate this case. 604 // In other words, 0 means "between 0.5 step and 1.5 step", 1 means "between 1.5 step 605 // and 2.5 steps", and 15 means "between 15.5 steps and 16.5 steps". So we want to 606 // divide our range [unigramFreq..MAX_TERMINAL_FREQUENCY] in 16.5 steps to get the 607 // step size. Then we compute the start of the first step (the one where value 0 starts) 608 // by adding half-a-step to the unigramFrequency. From there, we compute the integer 609 // number of steps to the bigramFrequency. One last thing: we want our steps to include 610 // their lower bound and exclude their higher bound so we need to have the first step 611 // start at exactly 1 unit higher than floor(unigramFreq + half a step). 612 // Note : to reconstruct the score, the dictionary reader will need to divide 613 // MAX_TERMINAL_FREQUENCY - unigramFreq by 16.5 likewise to get the value of the step, 614 // and add (discretizedFrequency + 0.5 + 0.5) times this value to get the best 615 // approximation. (0.5 to get the first step start, and 0.5 to get the middle of the 616 // step pointed by the discretized frequency. 617 final float stepSize = 618 (FormatSpec.MAX_TERMINAL_FREQUENCY - unigramFrequency) 619 / (1.5f + FormatSpec.MAX_BIGRAM_FREQUENCY); 620 final float firstStepStart = 1 + unigramFrequency + (stepSize / 2.0f); 621 final int discretizedFrequency = (int)((bigramFrequency - firstStepStart) / stepSize); 622 // If the bigram freq is less than half-a-step higher than the unigram freq, we get -1 623 // here. The best approximation would be the unigram freq itself, so we should not 624 // include this bigram in the dictionary. For now, register as 0, and live with the 625 // small over-estimation that we get in this case. TODO: actually remove this bigram 626 // if discretizedFrequency < 0. 627 return discretizedFrequency > 0 ? discretizedFrequency : 0; 628 } 629 getChildrenPosition(final PtNode ptNode, final HashMap<Integer, Integer> codePointToOneByteCodeMap)630 /* package */ static int getChildrenPosition(final PtNode ptNode, 631 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 632 int positionOfChildrenPosField = ptNode.mCachedAddressAfterUpdate 633 + getNodeHeaderSize(ptNode, codePointToOneByteCodeMap); 634 if (ptNode.isTerminal()) { 635 // A terminal node has the frequency. 636 // If positionOfChildrenPosField is incorrect, we may crash when jumping to the children 637 // position. 638 positionOfChildrenPosField += FormatSpec.PTNODE_FREQUENCY_SIZE; 639 } 640 return null == ptNode.mChildren ? FormatSpec.NO_CHILDREN_ADDRESS 641 : ptNode.mChildren.mCachedAddressAfterUpdate - positionOfChildrenPosField; 642 } 643 644 /** 645 * Write a PtNodeArray. The PtNodeArray is expected to have its final position cached. 646 * 647 * @param dict the dictionary the node array is a part of (for relative offsets). 648 * @param dictEncoder the dictionary encoder. 649 * @param ptNodeArray the node array to write. 650 * @param codePointToOneByteCodeMap the map to convert the code points. 651 */ writePlacedPtNodeArray(final FusionDictionary dict, final DictEncoder dictEncoder, final PtNodeArray ptNodeArray, final HashMap<Integer, Integer> codePointToOneByteCodeMap)652 /* package */ static void writePlacedPtNodeArray(final FusionDictionary dict, 653 final DictEncoder dictEncoder, final PtNodeArray ptNodeArray, 654 final HashMap<Integer, Integer> codePointToOneByteCodeMap) { 655 // TODO: Make the code in common with BinaryDictIOUtils#writePtNode 656 dictEncoder.setPosition(ptNodeArray.mCachedAddressAfterUpdate); 657 658 final int ptNodeCount = ptNodeArray.mData.size(); 659 dictEncoder.writePtNodeCount(ptNodeCount); 660 for (int i = 0; i < ptNodeCount; ++i) { 661 final PtNode ptNode = ptNodeArray.mData.get(i); 662 if (dictEncoder.getPosition() != ptNode.mCachedAddressAfterUpdate) { 663 throw new RuntimeException("Bug: write index is not the same as the cached address " 664 + "of the node : " + dictEncoder.getPosition() + " <> " 665 + ptNode.mCachedAddressAfterUpdate); 666 } 667 // Validity checks. 668 if (DBG && ptNode.getProbability() > FormatSpec.MAX_TERMINAL_FREQUENCY) { 669 throw new RuntimeException("A node has a frequency > " 670 + FormatSpec.MAX_TERMINAL_FREQUENCY 671 + " : " + ptNode.mProbabilityInfo.toString()); 672 } 673 dictEncoder.writePtNode(ptNode, dict, codePointToOneByteCodeMap); 674 } 675 if (dictEncoder.getPosition() != ptNodeArray.mCachedAddressAfterUpdate 676 + ptNodeArray.mCachedSize) { 677 throw new RuntimeException("Not the same size : written " 678 + (dictEncoder.getPosition() - ptNodeArray.mCachedAddressAfterUpdate) 679 + " bytes from a node that should have " + ptNodeArray.mCachedSize + " bytes"); 680 } 681 } 682 683 /** 684 * Dumps a collection of useful statistics about a list of PtNode arrays. 685 * 686 * This prints purely informative stuff, like the total estimated file size, the 687 * number of PtNode arrays, of PtNodes, the repartition of each address size, etc 688 * 689 * @param ptNodeArrays the list of PtNode arrays. 690 */ showStatistics(ArrayList<PtNodeArray> ptNodeArrays)691 /* package */ static void showStatistics(ArrayList<PtNodeArray> ptNodeArrays) { 692 int firstTerminalAddress = Integer.MAX_VALUE; 693 int lastTerminalAddress = Integer.MIN_VALUE; 694 int size = 0; 695 int ptNodes = 0; 696 int maxNodes = 0; 697 int maxRuns = 0; 698 for (final PtNodeArray ptNodeArray : ptNodeArrays) { 699 if (maxNodes < ptNodeArray.mData.size()) maxNodes = ptNodeArray.mData.size(); 700 for (final PtNode ptNode : ptNodeArray.mData) { 701 ++ptNodes; 702 if (ptNode.mChars.length > maxRuns) maxRuns = ptNode.mChars.length; 703 if (ptNode.isTerminal()) { 704 if (ptNodeArray.mCachedAddressAfterUpdate < firstTerminalAddress) 705 firstTerminalAddress = ptNodeArray.mCachedAddressAfterUpdate; 706 if (ptNodeArray.mCachedAddressAfterUpdate > lastTerminalAddress) 707 lastTerminalAddress = ptNodeArray.mCachedAddressAfterUpdate; 708 } 709 } 710 if (ptNodeArray.mCachedAddressAfterUpdate + ptNodeArray.mCachedSize > size) { 711 size = ptNodeArray.mCachedAddressAfterUpdate + ptNodeArray.mCachedSize; 712 } 713 } 714 final int[] ptNodeCounts = new int[maxNodes + 1]; 715 final int[] runCounts = new int[maxRuns + 1]; 716 for (final PtNodeArray ptNodeArray : ptNodeArrays) { 717 ++ptNodeCounts[ptNodeArray.mData.size()]; 718 for (final PtNode ptNode : ptNodeArray.mData) { 719 ++runCounts[ptNode.mChars.length]; 720 } 721 } 722 723 MakedictLog.i("Statistics:\n" 724 + " Total file size " + size + "\n" 725 + " " + ptNodeArrays.size() + " node arrays\n" 726 + " " + ptNodes + " PtNodes (" + ((float)ptNodes / ptNodeArrays.size()) 727 + " PtNodes per node)\n" 728 + " First terminal at " + firstTerminalAddress + "\n" 729 + " Last terminal at " + lastTerminalAddress + "\n" 730 + " PtNode stats : max = " + maxNodes); 731 } 732 733 /** 734 * Writes a file header to an output stream. 735 * 736 * @param destination the stream to write the file header to. 737 * @param dict the dictionary to write. 738 * @param formatOptions file format options. 739 * @param codePointOccurrenceArray code points ordered by occurrence count. 740 * @return the size of the header. 741 */ writeDictionaryHeader(final OutputStream destination, final FusionDictionary dict, final FormatOptions formatOptions, final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray)742 /* package */ static int writeDictionaryHeader(final OutputStream destination, 743 final FusionDictionary dict, final FormatOptions formatOptions, 744 final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray) 745 throws IOException, UnsupportedFormatException { 746 final int version = formatOptions.mVersion; 747 if ((version >= FormatSpec.MINIMUM_SUPPORTED_STATIC_VERSION && 748 version <= FormatSpec.MAXIMUM_SUPPORTED_STATIC_VERSION) || ( 749 version >= FormatSpec.MINIMUM_SUPPORTED_DYNAMIC_VERSION && 750 version <= FormatSpec.MAXIMUM_SUPPORTED_DYNAMIC_VERSION)) { 751 // Dictionary is valid 752 } else { 753 throw new UnsupportedFormatException("Requested file format version " + version 754 + ", but this implementation only supports static versions " 755 + FormatSpec.MINIMUM_SUPPORTED_STATIC_VERSION + " through " 756 + FormatSpec.MAXIMUM_SUPPORTED_STATIC_VERSION + " and dynamic versions " 757 + FormatSpec.MINIMUM_SUPPORTED_DYNAMIC_VERSION + " through " 758 + FormatSpec.MAXIMUM_SUPPORTED_DYNAMIC_VERSION); 759 } 760 761 ByteArrayOutputStream headerBuffer = new ByteArrayOutputStream(256); 762 763 // The magic number in big-endian order. 764 // Magic number for all versions. 765 headerBuffer.write((byte) (0xFF & (FormatSpec.MAGIC_NUMBER >> 24))); 766 headerBuffer.write((byte) (0xFF & (FormatSpec.MAGIC_NUMBER >> 16))); 767 headerBuffer.write((byte) (0xFF & (FormatSpec.MAGIC_NUMBER >> 8))); 768 headerBuffer.write((byte) (0xFF & FormatSpec.MAGIC_NUMBER)); 769 // Dictionary version. 770 headerBuffer.write((byte) (0xFF & (version >> 8))); 771 headerBuffer.write((byte) (0xFF & version)); 772 773 // Options flags 774 // TODO: Remove this field. 775 final int options = 0; 776 headerBuffer.write((byte) (0xFF & (options >> 8))); 777 headerBuffer.write((byte) (0xFF & options)); 778 final int headerSizeOffset = headerBuffer.size(); 779 // Placeholder to be written later with header size. 780 for (int i = 0; i < 4; ++i) { 781 headerBuffer.write(0); 782 } 783 // Write out the options. 784 for (final String key : dict.mOptions.mAttributes.keySet()) { 785 final String value = dict.mOptions.mAttributes.get(key); 786 CharEncoding.writeString(headerBuffer, key, null); 787 CharEncoding.writeString(headerBuffer, value, null); 788 } 789 // Write out the codePointTable if there is codePointOccurrenceArray. 790 if (codePointOccurrenceArray != null) { 791 final String codePointTableString = 792 encodeCodePointTable(codePointOccurrenceArray); 793 CharEncoding.writeString(headerBuffer, DictionaryHeader.CODE_POINT_TABLE_KEY, null); 794 CharEncoding.writeString(headerBuffer, codePointTableString, null); 795 } 796 final int size = headerBuffer.size(); 797 final byte[] bytes = headerBuffer.toByteArray(); 798 // Write out the header size. 799 bytes[headerSizeOffset] = (byte) (0xFF & (size >> 24)); 800 bytes[headerSizeOffset + 1] = (byte) (0xFF & (size >> 16)); 801 bytes[headerSizeOffset + 2] = (byte) (0xFF & (size >> 8)); 802 bytes[headerSizeOffset + 3] = (byte) (0xFF & (size >> 0)); 803 destination.write(bytes); 804 805 headerBuffer.close(); 806 return size; 807 } 808 809 static final class CodePointTable { 810 final HashMap<Integer, Integer> mCodePointToOneByteCodeMap; 811 final ArrayList<Entry<Integer, Integer>> mCodePointOccurrenceArray; 812 813 // Let code point table empty for version 200 dictionary which used in test CodePointTable()814 CodePointTable() { 815 mCodePointToOneByteCodeMap = null; 816 mCodePointOccurrenceArray = null; 817 } 818 CodePointTable(final HashMap<Integer, Integer> codePointToOneByteCodeMap, final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray)819 CodePointTable(final HashMap<Integer, Integer> codePointToOneByteCodeMap, 820 final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray) { 821 mCodePointToOneByteCodeMap = codePointToOneByteCodeMap; 822 mCodePointOccurrenceArray = codePointOccurrenceArray; 823 } 824 } 825 encodeCodePointTable( final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray)826 private static String encodeCodePointTable( 827 final ArrayList<Entry<Integer, Integer>> codePointOccurrenceArray) { 828 final StringBuilder codePointTableString = new StringBuilder(); 829 int currentCodePointTableIndex = FormatSpec.MINIMAL_ONE_BYTE_CHARACTER_VALUE; 830 for (final Entry<Integer, Integer> entry : codePointOccurrenceArray) { 831 // Native reads the table as a string 832 codePointTableString.appendCodePoint(entry.getKey()); 833 if (FormatSpec.MAXIMAL_ONE_BYTE_CHARACTER_VALUE < ++currentCodePointTableIndex) { 834 break; 835 } 836 } 837 return codePointTableString.toString(); 838 } 839 } 840