1 /* 2 * Copyright (C) 2015 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 android.util; 18 19 import com.android.ide.common.rendering.api.ILayoutLog; 20 import com.android.layoutlib.bridge.Bridge; 21 import com.android.layoutlib.bridge.impl.DelegateManager; 22 import com.android.tools.layoutlib.annotations.LayoutlibDelegate; 23 24 import android.annotation.NonNull; 25 import android.graphics.Path_Delegate; 26 27 import java.util.ArrayList; 28 import java.util.Arrays; 29 import java.util.logging.Level; 30 import java.util.logging.Logger; 31 32 /** 33 * Delegate that provides implementation for native methods in {@link android.util.PathParser} 34 * <p/> 35 * Through the layoutlib_create tool, selected methods of PathParser have been replaced by calls to 36 * methods of the same name in this delegate class. 37 * 38 * Most of the code has been taken from the implementation in 39 * {@code tools/base/sdk-common/src/main/java/com/android/ide/common/vectordrawable/PathParser.java} 40 * revision be6fe89a3b686db5a75e7e692a148699973957f3 41 */ 42 public class PathParser_Delegate { 43 44 private static final Logger LOGGER = Logger.getLogger("PathParser"); 45 46 // ---- Builder delegate manager ---- 47 private static final DelegateManager<PathParser_Delegate> sManager = 48 new DelegateManager<PathParser_Delegate>(PathParser_Delegate.class); 49 50 // ---- delegate data ---- 51 @NonNull 52 private PathDataNode[] mPathDataNodes; 53 getDelegate(long nativePtr)54 public static PathParser_Delegate getDelegate(long nativePtr) { 55 return sManager.getDelegate(nativePtr); 56 } 57 PathParser_Delegate(@onNull PathDataNode[] nodes)58 private PathParser_Delegate(@NonNull PathDataNode[] nodes) { 59 mPathDataNodes = nodes; 60 } 61 getPathDataNodes()62 public PathDataNode[] getPathDataNodes() { 63 return mPathDataNodes; 64 } 65 66 @LayoutlibDelegate nParseStringForPath(long pathPtr, @NonNull String pathString, int stringLength)67 /*package*/ static void nParseStringForPath(long pathPtr, @NonNull String pathString, int 68 stringLength) { 69 Path_Delegate path_delegate = Path_Delegate.getDelegate(pathPtr); 70 if (path_delegate == null) { 71 return; 72 } 73 assert pathString.length() == stringLength; 74 PathDataNode.nodesToPath(createNodesFromPathData(pathString), path_delegate); 75 } 76 77 @LayoutlibDelegate nCreatePathFromPathData(long outPathPtr, long pathData)78 /*package*/ static void nCreatePathFromPathData(long outPathPtr, long pathData) { 79 Path_Delegate path_delegate = Path_Delegate.getDelegate(outPathPtr); 80 PathParser_Delegate source = sManager.getDelegate(outPathPtr); 81 if (source == null || path_delegate == null) { 82 return; 83 } 84 PathDataNode.nodesToPath(source.mPathDataNodes, path_delegate); 85 } 86 87 @LayoutlibDelegate nCreateEmptyPathData()88 /*package*/ static long nCreateEmptyPathData() { 89 PathParser_Delegate newDelegate = new PathParser_Delegate(new PathDataNode[0]); 90 return sManager.addNewDelegate(newDelegate); 91 } 92 93 @LayoutlibDelegate nCreatePathData(long nativePtr)94 /*package*/ static long nCreatePathData(long nativePtr) { 95 PathParser_Delegate source = sManager.getDelegate(nativePtr); 96 if (source == null) { 97 return 0; 98 } 99 PathParser_Delegate dest = new PathParser_Delegate(deepCopyNodes(source.mPathDataNodes)); 100 return sManager.addNewDelegate(dest); 101 } 102 103 @LayoutlibDelegate nCreatePathDataFromString(@onNull String pathString, int stringLength)104 /*package*/ static long nCreatePathDataFromString(@NonNull String pathString, 105 int stringLength) { 106 assert pathString.length() == stringLength : "Inconsistent path string length."; 107 PathDataNode[] nodes = createNodesFromPathData(pathString); 108 PathParser_Delegate delegate = new PathParser_Delegate(nodes); 109 return sManager.addNewDelegate(delegate); 110 111 } 112 113 @LayoutlibDelegate nInterpolatePathData(long outDataPtr, long fromDataPtr, long toDataPtr, float fraction)114 /*package*/ static boolean nInterpolatePathData(long outDataPtr, long fromDataPtr, 115 long toDataPtr, float fraction) { 116 PathParser_Delegate out = sManager.getDelegate(outDataPtr); 117 PathParser_Delegate from = sManager.getDelegate(fromDataPtr); 118 PathParser_Delegate to = sManager.getDelegate(toDataPtr); 119 if (out == null || from == null || to == null) { 120 return false; 121 } 122 int length = from.mPathDataNodes.length; 123 if (length != to.mPathDataNodes.length) { 124 Bridge.getLog().error(ILayoutLog.TAG_BROKEN, 125 "Cannot interpolate path data with different lengths (from " + length + " to " + 126 to.mPathDataNodes.length + ").", null, null); 127 return false; 128 } 129 if (out.mPathDataNodes.length != length) { 130 out.mPathDataNodes = new PathDataNode[length]; 131 } 132 for (int i = 0; i < length; i++) { 133 if (out.mPathDataNodes[i] == null) { 134 out.mPathDataNodes[i] = new PathDataNode(from.mPathDataNodes[i]); 135 } 136 out.mPathDataNodes[i].interpolatePathDataNode(from.mPathDataNodes[i], 137 to.mPathDataNodes[i], fraction); 138 } 139 return true; 140 } 141 142 @LayoutlibDelegate nFinalize(long nativePtr)143 /*package*/ static void nFinalize(long nativePtr) { 144 sManager.removeJavaReferenceFor(nativePtr); 145 } 146 147 @LayoutlibDelegate nCanMorph(long fromDataPtr, long toDataPtr)148 /*package*/ static boolean nCanMorph(long fromDataPtr, long toDataPtr) { 149 PathParser_Delegate fromPath = PathParser_Delegate.getDelegate(fromDataPtr); 150 PathParser_Delegate toPath = PathParser_Delegate.getDelegate(toDataPtr); 151 if (fromPath == null || toPath == null || fromPath.getPathDataNodes() == null || toPath 152 .getPathDataNodes() == null) { 153 return true; 154 } 155 return PathParser_Delegate.canMorph(fromPath.getPathDataNodes(), toPath.getPathDataNodes()); 156 } 157 158 @LayoutlibDelegate nSetPathData(long outDataPtr, long fromDataPtr)159 /*package*/ static void nSetPathData(long outDataPtr, long fromDataPtr) { 160 PathParser_Delegate out = sManager.getDelegate(outDataPtr); 161 PathParser_Delegate from = sManager.getDelegate(fromDataPtr); 162 if (from == null || out == null) { 163 return; 164 } 165 out.mPathDataNodes = deepCopyNodes(from.mPathDataNodes); 166 } 167 168 /** 169 * @param pathData The string representing a path, the same as "d" string in svg file. 170 * 171 * @return an array of the PathDataNode. 172 */ 173 @NonNull createNodesFromPathData(@onNull String pathData)174 public static PathDataNode[] createNodesFromPathData(@NonNull String pathData) { 175 int start = 0; 176 int end = 1; 177 178 ArrayList<PathDataNode> list = new ArrayList<PathDataNode>(); 179 while (end < pathData.length()) { 180 end = nextStart(pathData, end); 181 String s = pathData.substring(start, end).trim(); 182 if (s.length() > 0) { 183 float[] val = getFloats(s); 184 addNode(list, s.charAt(0), val); 185 } 186 187 start = end; 188 end++; 189 } 190 if ((end - start) == 1 && start < pathData.length()) { 191 addNode(list, pathData.charAt(start), new float[0]); 192 } 193 return list.toArray(new PathDataNode[list.size()]); 194 } 195 196 /** 197 * @param source The array of PathDataNode to be duplicated. 198 * 199 * @return a deep copy of the <code>source</code>. 200 */ 201 @NonNull deepCopyNodes(@onNull PathDataNode[] source)202 public static PathDataNode[] deepCopyNodes(@NonNull PathDataNode[] source) { 203 PathDataNode[] copy = new PathDataNode[source.length]; 204 for (int i = 0; i < source.length; i++) { 205 copy[i] = new PathDataNode(source[i]); 206 } 207 return copy; 208 } 209 210 /** 211 * @param nodesFrom The source path represented in an array of PathDataNode 212 * @param nodesTo The target path represented in an array of PathDataNode 213 * @return whether the <code>nodesFrom</code> can morph into <code>nodesTo</code> 214 */ canMorph(PathDataNode[] nodesFrom, PathDataNode[] nodesTo)215 public static boolean canMorph(PathDataNode[] nodesFrom, PathDataNode[] nodesTo) { 216 if (nodesFrom == null || nodesTo == null) { 217 return false; 218 } 219 220 if (nodesFrom.length != nodesTo.length) { 221 return false; 222 } 223 224 for (int i = 0; i < nodesFrom.length; i ++) { 225 if (nodesFrom[i].mType != nodesTo[i].mType 226 || nodesFrom[i].mParams.length != nodesTo[i].mParams.length) { 227 return false; 228 } 229 } 230 return true; 231 } 232 233 /** 234 * Update the target's data to match the source. 235 * Before calling this, make sure canMorph(target, source) is true. 236 * 237 * @param target The target path represented in an array of PathDataNode 238 * @param source The source path represented in an array of PathDataNode 239 */ updateNodes(PathDataNode[] target, PathDataNode[] source)240 public static void updateNodes(PathDataNode[] target, PathDataNode[] source) { 241 for (int i = 0; i < source.length; i ++) { 242 target[i].mType = source[i].mType; 243 for (int j = 0; j < source[i].mParams.length; j ++) { 244 target[i].mParams[j] = source[i].mParams[j]; 245 } 246 } 247 } 248 nextStart(@onNull String s, int end)249 private static int nextStart(@NonNull String s, int end) { 250 char c; 251 252 while (end < s.length()) { 253 c = s.charAt(end); 254 // Note that 'e' or 'E' are not valid path commands, but could be 255 // used for floating point numbers' scientific notation. 256 // Therefore, when searching for next command, we should ignore 'e' 257 // and 'E'. 258 if ((((c - 'A') * (c - 'Z') <= 0) || ((c - 'a') * (c - 'z') <= 0)) 259 && c != 'e' && c != 'E') { 260 return end; 261 } 262 end++; 263 } 264 return end; 265 } 266 267 /** 268 * Calculate the position of the next comma or space or negative sign 269 * 270 * @param s the string to search 271 * @param start the position to start searching 272 * @param result the result of the extraction, including the position of the the starting 273 * position of next number, whether it is ending with a '-'. 274 */ extract(@onNull String s, int start, @NonNull ExtractFloatResult result)275 private static void extract(@NonNull String s, int start, @NonNull ExtractFloatResult result) { 276 // Now looking for ' ', ',', '.' or '-' from the start. 277 int currentIndex = start; 278 boolean foundSeparator = false; 279 result.mEndWithNegOrDot = false; 280 boolean secondDot = false; 281 boolean isExponential = false; 282 for (; currentIndex < s.length(); currentIndex++) { 283 boolean isPrevExponential = isExponential; 284 isExponential = false; 285 char currentChar = s.charAt(currentIndex); 286 switch (currentChar) { 287 case ' ': 288 case ',': 289 case '\t': 290 case '\n': 291 foundSeparator = true; 292 break; 293 case '-': 294 // The negative sign following a 'e' or 'E' is not a separator. 295 if (currentIndex != start && !isPrevExponential) { 296 foundSeparator = true; 297 result.mEndWithNegOrDot = true; 298 } 299 break; 300 case '.': 301 if (!secondDot) { 302 secondDot = true; 303 } else { 304 // This is the second dot, and it is considered as a separator. 305 foundSeparator = true; 306 result.mEndWithNegOrDot = true; 307 } 308 break; 309 case 'e': 310 case 'E': 311 isExponential = true; 312 break; 313 } 314 if (foundSeparator) { 315 break; 316 } 317 } 318 // When there is nothing found, then we put the end position to the end 319 // of the string. 320 result.mEndPosition = currentIndex; 321 } 322 323 /** 324 * Parse the floats in the string. This is an optimized version of 325 * parseFloat(s.split(",|\\s")); 326 * 327 * @param s the string containing a command and list of floats 328 * 329 * @return array of floats 330 */ 331 @NonNull getFloats(@onNull String s)332 private static float[] getFloats(@NonNull String s) { 333 if (s.charAt(0) == 'z' || s.charAt(0) == 'Z') { 334 return new float[0]; 335 } 336 try { 337 float[] results = new float[s.length()]; 338 int count = 0; 339 int startPosition = 1; 340 int endPosition; 341 342 ExtractFloatResult result = new ExtractFloatResult(); 343 int totalLength = s.length(); 344 345 // The startPosition should always be the first character of the 346 // current number, and endPosition is the character after the current 347 // number. 348 while (startPosition < totalLength) { 349 extract(s, startPosition, result); 350 endPosition = result.mEndPosition; 351 352 if (startPosition < endPosition) { 353 results[count++] = Float.parseFloat( 354 s.substring(startPosition, endPosition)); 355 } 356 357 if (result.mEndWithNegOrDot) { 358 // Keep the '-' or '.' sign with next number. 359 startPosition = endPosition; 360 } else { 361 startPosition = endPosition + 1; 362 } 363 } 364 return Arrays.copyOf(results, count); 365 } catch (NumberFormatException e) { 366 assert false : "error in parsing \"" + s + "\"" + e; 367 return new float[0]; 368 } 369 } 370 371 addNode(@onNull ArrayList<PathDataNode> list, char cmd, @NonNull float[] val)372 private static void addNode(@NonNull ArrayList<PathDataNode> list, char cmd, 373 @NonNull float[] val) { 374 list.add(new PathDataNode(cmd, val)); 375 } 376 377 private static class ExtractFloatResult { 378 // We need to return the position of the next separator and whether the 379 // next float starts with a '-' or a '.'. 380 private int mEndPosition; 381 private boolean mEndWithNegOrDot; 382 } 383 384 /** 385 * Each PathDataNode represents one command in the "d" attribute of the svg file. An array of 386 * PathDataNode can represent the whole "d" attribute. 387 */ 388 public static class PathDataNode { 389 private char mType; 390 @NonNull 391 private float[] mParams; 392 PathDataNode(char type, @NonNull float[] params)393 private PathDataNode(char type, @NonNull float[] params) { 394 mType = type; 395 mParams = params; 396 } 397 getType()398 public char getType() { 399 return mType; 400 } 401 402 @NonNull getParams()403 public float[] getParams() { 404 return mParams; 405 } 406 PathDataNode(@onNull PathDataNode n)407 private PathDataNode(@NonNull PathDataNode n) { 408 mType = n.mType; 409 mParams = Arrays.copyOf(n.mParams, n.mParams.length); 410 } 411 412 /** 413 * Convert an array of PathDataNode to Path. Reset the passed path as needed before 414 * calling this method. 415 * 416 * @param node The source array of PathDataNode. 417 * @param path The target Path object. 418 */ nodesToPath(@onNull PathDataNode[] node, @NonNull Path_Delegate path)419 public static void nodesToPath(@NonNull PathDataNode[] node, @NonNull Path_Delegate path) { 420 float[] current = new float[6]; 421 char previousCommand = 'm'; 422 //noinspection ForLoopReplaceableByForEach 423 for (int i = 0; i < node.length; i++) { 424 addCommand(path, current, previousCommand, node[i].mType, node[i].mParams); 425 previousCommand = node[i].mType; 426 } 427 } 428 429 /** 430 * The current PathDataNode will be interpolated between the <code>nodeFrom</code> and 431 * <code>nodeTo</code> according to the <code>fraction</code>. 432 * 433 * @param nodeFrom The start value as a PathDataNode. 434 * @param nodeTo The end value as a PathDataNode 435 * @param fraction The fraction to interpolate. 436 */ interpolatePathDataNode(@onNull PathDataNode nodeFrom, @NonNull PathDataNode nodeTo, float fraction)437 private void interpolatePathDataNode(@NonNull PathDataNode nodeFrom, 438 @NonNull PathDataNode nodeTo, float fraction) { 439 for (int i = 0; i < nodeFrom.mParams.length; i++) { 440 mParams[i] = nodeFrom.mParams[i] * (1 - fraction) 441 + nodeTo.mParams[i] * fraction; 442 } 443 } 444 445 @SuppressWarnings("PointlessArithmeticExpression") addCommand(@onNull Path_Delegate path, float[] current, char previousCmd, char cmd, @NonNull float[] val)446 private static void addCommand(@NonNull Path_Delegate path, float[] current, 447 char previousCmd, char cmd, @NonNull float[] val) { 448 449 int incr = 2; 450 float currentX = current[0]; 451 float currentY = current[1]; 452 float ctrlPointX = current[2]; 453 float ctrlPointY = current[3]; 454 float currentSegmentStartX = current[4]; 455 float currentSegmentStartY = current[5]; 456 float reflectiveCtrlPointX; 457 float reflectiveCtrlPointY; 458 459 switch (cmd) { 460 case 'z': 461 case 'Z': 462 path.close(); 463 // Path is closed here, but we need to move the pen to the 464 // closed position. So we cache the segment's starting position, 465 // and restore it here. 466 currentX = currentSegmentStartX; 467 currentY = currentSegmentStartY; 468 ctrlPointX = currentSegmentStartX; 469 ctrlPointY = currentSegmentStartY; 470 path.moveTo(currentX, currentY); 471 break; 472 case 'm': 473 case 'M': 474 case 'l': 475 case 'L': 476 case 't': 477 case 'T': 478 incr = 2; 479 break; 480 case 'h': 481 case 'H': 482 case 'v': 483 case 'V': 484 incr = 1; 485 break; 486 case 'c': 487 case 'C': 488 incr = 6; 489 break; 490 case 's': 491 case 'S': 492 case 'q': 493 case 'Q': 494 incr = 4; 495 break; 496 case 'a': 497 case 'A': 498 incr = 7; 499 break; 500 } 501 502 for (int k = 0; k < val.length; k += incr) { 503 switch (cmd) { 504 case 'm': // moveto - Start a new sub-path (relative) 505 currentX += val[k + 0]; 506 currentY += val[k + 1]; 507 508 if (k > 0) { 509 // According to the spec, if a moveto is followed by multiple 510 // pairs of coordinates, the subsequent pairs are treated as 511 // implicit lineto commands. 512 path.rLineTo(val[k + 0], val[k + 1]); 513 } else { 514 path.rMoveTo(val[k + 0], val[k + 1]); 515 currentSegmentStartX = currentX; 516 currentSegmentStartY = currentY; 517 } 518 break; 519 case 'M': // moveto - Start a new sub-path 520 currentX = val[k + 0]; 521 currentY = val[k + 1]; 522 523 if (k > 0) { 524 // According to the spec, if a moveto is followed by multiple 525 // pairs of coordinates, the subsequent pairs are treated as 526 // implicit lineto commands. 527 path.lineTo(val[k + 0], val[k + 1]); 528 } else { 529 path.moveTo(val[k + 0], val[k + 1]); 530 currentSegmentStartX = currentX; 531 currentSegmentStartY = currentY; 532 } 533 break; 534 case 'l': // lineto - Draw a line from the current point (relative) 535 path.rLineTo(val[k + 0], val[k + 1]); 536 currentX += val[k + 0]; 537 currentY += val[k + 1]; 538 break; 539 case 'L': // lineto - Draw a line from the current point 540 path.lineTo(val[k + 0], val[k + 1]); 541 currentX = val[k + 0]; 542 currentY = val[k + 1]; 543 break; 544 case 'h': // horizontal lineto - Draws a horizontal line (relative) 545 path.rLineTo(val[k + 0], 0); 546 currentX += val[k + 0]; 547 break; 548 case 'H': // horizontal lineto - Draws a horizontal line 549 path.lineTo(val[k + 0], currentY); 550 currentX = val[k + 0]; 551 break; 552 case 'v': // vertical lineto - Draws a vertical line from the current point (r) 553 path.rLineTo(0, val[k + 0]); 554 currentY += val[k + 0]; 555 break; 556 case 'V': // vertical lineto - Draws a vertical line from the current point 557 path.lineTo(currentX, val[k + 0]); 558 currentY = val[k + 0]; 559 break; 560 case 'c': // curveto - Draws a cubic Bézier curve (relative) 561 path.rCubicTo(val[k + 0], val[k + 1], val[k + 2], val[k + 3], 562 val[k + 4], val[k + 5]); 563 564 ctrlPointX = currentX + val[k + 2]; 565 ctrlPointY = currentY + val[k + 3]; 566 currentX += val[k + 4]; 567 currentY += val[k + 5]; 568 569 break; 570 case 'C': // curveto - Draws a cubic Bézier curve 571 path.cubicTo(val[k + 0], val[k + 1], val[k + 2], val[k + 3], 572 val[k + 4], val[k + 5]); 573 currentX = val[k + 4]; 574 currentY = val[k + 5]; 575 ctrlPointX = val[k + 2]; 576 ctrlPointY = val[k + 3]; 577 break; 578 case 's': // smooth curveto - Draws a cubic Bézier curve (reflective cp) 579 reflectiveCtrlPointX = 0; 580 reflectiveCtrlPointY = 0; 581 if (previousCmd == 'c' || previousCmd == 's' 582 || previousCmd == 'C' || previousCmd == 'S') { 583 reflectiveCtrlPointX = currentX - ctrlPointX; 584 reflectiveCtrlPointY = currentY - ctrlPointY; 585 } 586 path.rCubicTo(reflectiveCtrlPointX, reflectiveCtrlPointY, 587 val[k + 0], val[k + 1], 588 val[k + 2], val[k + 3]); 589 590 ctrlPointX = currentX + val[k + 0]; 591 ctrlPointY = currentY + val[k + 1]; 592 currentX += val[k + 2]; 593 currentY += val[k + 3]; 594 break; 595 case 'S': // shorthand/smooth curveto Draws a cubic Bézier curve(reflective cp) 596 reflectiveCtrlPointX = currentX; 597 reflectiveCtrlPointY = currentY; 598 if (previousCmd == 'c' || previousCmd == 's' 599 || previousCmd == 'C' || previousCmd == 'S') { 600 reflectiveCtrlPointX = 2 * currentX - ctrlPointX; 601 reflectiveCtrlPointY = 2 * currentY - ctrlPointY; 602 } 603 path.cubicTo(reflectiveCtrlPointX, reflectiveCtrlPointY, 604 val[k + 0], val[k + 1], val[k + 2], val[k + 3]); 605 ctrlPointX = val[k + 0]; 606 ctrlPointY = val[k + 1]; 607 currentX = val[k + 2]; 608 currentY = val[k + 3]; 609 break; 610 case 'q': // Draws a quadratic Bézier (relative) 611 path.rQuadTo(val[k + 0], val[k + 1], val[k + 2], val[k + 3]); 612 ctrlPointX = currentX + val[k + 0]; 613 ctrlPointY = currentY + val[k + 1]; 614 currentX += val[k + 2]; 615 currentY += val[k + 3]; 616 break; 617 case 'Q': // Draws a quadratic Bézier 618 path.quadTo(val[k + 0], val[k + 1], val[k + 2], val[k + 3]); 619 ctrlPointX = val[k + 0]; 620 ctrlPointY = val[k + 1]; 621 currentX = val[k + 2]; 622 currentY = val[k + 3]; 623 break; 624 case 't': // Draws a quadratic Bézier curve(reflective control point)(relative) 625 reflectiveCtrlPointX = 0; 626 reflectiveCtrlPointY = 0; 627 if (previousCmd == 'q' || previousCmd == 't' 628 || previousCmd == 'Q' || previousCmd == 'T') { 629 reflectiveCtrlPointX = currentX - ctrlPointX; 630 reflectiveCtrlPointY = currentY - ctrlPointY; 631 } 632 path.rQuadTo(reflectiveCtrlPointX, reflectiveCtrlPointY, 633 val[k + 0], val[k + 1]); 634 ctrlPointX = currentX + reflectiveCtrlPointX; 635 ctrlPointY = currentY + reflectiveCtrlPointY; 636 currentX += val[k + 0]; 637 currentY += val[k + 1]; 638 break; 639 case 'T': // Draws a quadratic Bézier curve (reflective control point) 640 reflectiveCtrlPointX = currentX; 641 reflectiveCtrlPointY = currentY; 642 if (previousCmd == 'q' || previousCmd == 't' 643 || previousCmd == 'Q' || previousCmd == 'T') { 644 reflectiveCtrlPointX = 2 * currentX - ctrlPointX; 645 reflectiveCtrlPointY = 2 * currentY - ctrlPointY; 646 } 647 path.quadTo(reflectiveCtrlPointX, reflectiveCtrlPointY, 648 val[k + 0], val[k + 1]); 649 ctrlPointX = reflectiveCtrlPointX; 650 ctrlPointY = reflectiveCtrlPointY; 651 currentX = val[k + 0]; 652 currentY = val[k + 1]; 653 break; 654 case 'a': // Draws an elliptical arc 655 // (rx ry x-axis-rotation large-arc-flag sweep-flag x y) 656 drawArc(path, 657 currentX, 658 currentY, 659 val[k + 5] + currentX, 660 val[k + 6] + currentY, 661 val[k + 0], 662 val[k + 1], 663 val[k + 2], 664 val[k + 3] != 0, 665 val[k + 4] != 0); 666 currentX += val[k + 5]; 667 currentY += val[k + 6]; 668 ctrlPointX = currentX; 669 ctrlPointY = currentY; 670 break; 671 case 'A': // Draws an elliptical arc 672 drawArc(path, 673 currentX, 674 currentY, 675 val[k + 5], 676 val[k + 6], 677 val[k + 0], 678 val[k + 1], 679 val[k + 2], 680 val[k + 3] != 0, 681 val[k + 4] != 0); 682 currentX = val[k + 5]; 683 currentY = val[k + 6]; 684 ctrlPointX = currentX; 685 ctrlPointY = currentY; 686 break; 687 } 688 previousCmd = cmd; 689 } 690 current[0] = currentX; 691 current[1] = currentY; 692 current[2] = ctrlPointX; 693 current[3] = ctrlPointY; 694 current[4] = currentSegmentStartX; 695 current[5] = currentSegmentStartY; 696 } 697 drawArc(@onNull Path_Delegate p, float x0, float y0, float x1, float y1, float a, float b, float theta, boolean isMoreThanHalf, boolean isPositiveArc)698 private static void drawArc(@NonNull Path_Delegate p, float x0, float y0, float x1, 699 float y1, float a, float b, float theta, boolean isMoreThanHalf, 700 boolean isPositiveArc) { 701 702 LOGGER.log(Level.FINE, "(" + x0 + "," + y0 + ")-(" + x1 + "," + y1 703 + ") {" + a + " " + b + "}"); 704 /* Convert rotation angle from degrees to radians */ 705 double thetaD = theta * Math.PI / 180.0f; 706 /* Pre-compute rotation matrix entries */ 707 double cosTheta = Math.cos(thetaD); 708 double sinTheta = Math.sin(thetaD); 709 /* Transform (x0, y0) and (x1, y1) into unit space */ 710 /* using (inverse) rotation, followed by (inverse) scale */ 711 double x0p = (x0 * cosTheta + y0 * sinTheta) / a; 712 double y0p = (-x0 * sinTheta + y0 * cosTheta) / b; 713 double x1p = (x1 * cosTheta + y1 * sinTheta) / a; 714 double y1p = (-x1 * sinTheta + y1 * cosTheta) / b; 715 LOGGER.log(Level.FINE, "unit space (" + x0p + "," + y0p + ")-(" + x1p 716 + "," + y1p + ")"); 717 /* Compute differences and averages */ 718 double dx = x0p - x1p; 719 double dy = y0p - y1p; 720 double xm = (x0p + x1p) / 2; 721 double ym = (y0p + y1p) / 2; 722 /* Solve for intersecting unit circles */ 723 double dsq = dx * dx + dy * dy; 724 if (dsq == 0.0) { 725 LOGGER.log(Level.FINE, " Points are coincident"); 726 return; /* Points are coincident */ 727 } 728 double disc = 1.0 / dsq - 1.0 / 4.0; 729 if (disc < 0.0) { 730 LOGGER.log(Level.FINE, "Points are too far apart " + dsq); 731 float adjust = (float) (Math.sqrt(dsq) / 1.99999); 732 drawArc(p, x0, y0, x1, y1, a * adjust, b * adjust, theta, 733 isMoreThanHalf, isPositiveArc); 734 return; /* Points are too far apart */ 735 } 736 double s = Math.sqrt(disc); 737 double sdx = s * dx; 738 double sdy = s * dy; 739 double cx; 740 double cy; 741 if (isMoreThanHalf == isPositiveArc) { 742 cx = xm - sdy; 743 cy = ym + sdx; 744 } else { 745 cx = xm + sdy; 746 cy = ym - sdx; 747 } 748 749 double eta0 = Math.atan2((y0p - cy), (x0p - cx)); 750 LOGGER.log(Level.FINE, "eta0 = Math.atan2( " + (y0p - cy) + " , " 751 + (x0p - cx) + ") = " + Math.toDegrees(eta0)); 752 753 double eta1 = Math.atan2((y1p - cy), (x1p - cx)); 754 LOGGER.log(Level.FINE, "eta1 = Math.atan2( " + (y1p - cy) + " , " 755 + (x1p - cx) + ") = " + Math.toDegrees(eta1)); 756 double sweep = (eta1 - eta0); 757 if (isPositiveArc != (sweep >= 0)) { 758 if (sweep > 0) { 759 sweep -= 2 * Math.PI; 760 } else { 761 sweep += 2 * Math.PI; 762 } 763 } 764 765 cx *= a; 766 cy *= b; 767 double tcx = cx; 768 cx = cx * cosTheta - cy * sinTheta; 769 cy = tcx * sinTheta + cy * cosTheta; 770 LOGGER.log( 771 Level.FINE, 772 "cx, cy, a, b, x0, y0, thetaD, eta0, sweep = " + cx + " , " 773 + cy + " , " + a + " , " + b + " , " + x0 + " , " + y0 774 + " , " + Math.toDegrees(thetaD) + " , " 775 + Math.toDegrees(eta0) + " , " + Math.toDegrees(sweep)); 776 777 arcToBezier(p, cx, cy, a, b, x0, y0, thetaD, eta0, sweep); 778 } 779 780 /** 781 * Converts an arc to cubic Bezier segments and records them in p. 782 * 783 * @param p The target for the cubic Bezier segments 784 * @param cx The x coordinate center of the ellipse 785 * @param cy The y coordinate center of the ellipse 786 * @param a The radius of the ellipse in the horizontal direction 787 * @param b The radius of the ellipse in the vertical direction 788 * @param e1x E(eta1) x coordinate of the starting point of the arc 789 * @param e1y E(eta2) y coordinate of the starting point of the arc 790 * @param theta The angle that the ellipse bounding rectangle makes with the horizontal 791 * plane 792 * @param start The start angle of the arc on the ellipse 793 * @param sweep The angle (positive or negative) of the sweep of the arc on the ellipse 794 */ arcToBezier(@onNull Path_Delegate p, double cx, double cy, double a, double b, double e1x, double e1y, double theta, double start, double sweep)795 private static void arcToBezier(@NonNull Path_Delegate p, double cx, double cy, double a, 796 double b, double e1x, double e1y, double theta, double start, 797 double sweep) { 798 // Taken from equations at: 799 // http://spaceroots.org/documents/ellipse/node8.html 800 // and http://www.spaceroots.org/documents/ellipse/node22.html 801 // Maximum of 45 degrees per cubic Bezier segment 802 int numSegments = (int) Math.ceil(Math.abs(sweep * 4 / Math.PI)); 803 804 805 double eta1 = start; 806 double cosTheta = Math.cos(theta); 807 double sinTheta = Math.sin(theta); 808 double cosEta1 = Math.cos(eta1); 809 double sinEta1 = Math.sin(eta1); 810 double ep1x = (-a * cosTheta * sinEta1) - (b * sinTheta * cosEta1); 811 double ep1y = (-a * sinTheta * sinEta1) + (b * cosTheta * cosEta1); 812 813 double anglePerSegment = sweep / numSegments; 814 for (int i = 0; i < numSegments; i++) { 815 double eta2 = eta1 + anglePerSegment; 816 double sinEta2 = Math.sin(eta2); 817 double cosEta2 = Math.cos(eta2); 818 double e2x = cx + (a * cosTheta * cosEta2) 819 - (b * sinTheta * sinEta2); 820 double e2y = cy + (a * sinTheta * cosEta2) 821 + (b * cosTheta * sinEta2); 822 double ep2x = -a * cosTheta * sinEta2 - b * sinTheta * cosEta2; 823 double ep2y = -a * sinTheta * sinEta2 + b * cosTheta * cosEta2; 824 double tanDiff2 = Math.tan((eta2 - eta1) / 2); 825 double alpha = Math.sin(eta2 - eta1) 826 * (Math.sqrt(4 + (3 * tanDiff2 * tanDiff2)) - 1) / 3; 827 double q1x = e1x + alpha * ep1x; 828 double q1y = e1y + alpha * ep1y; 829 double q2x = e2x - alpha * ep2x; 830 double q2y = e2y - alpha * ep2y; 831 832 p.cubicTo((float) q1x, 833 (float) q1y, 834 (float) q2x, 835 (float) q2y, 836 (float) e2x, 837 (float) e2y); 838 eta1 = eta2; 839 e1x = e2x; 840 e1y = e2y; 841 ep1x = ep2x; 842 ep1y = ep2y; 843 } 844 } 845 } 846 } 847