Mercurial > jhg
comparison src/org/tmatesoft/hg/internal/Patch.java @ 330:9747a786a34d
Patch merging algorithm complete trial
author | Artem Tikhomirov <tikhomirov.artem@gmail.com> |
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date | Tue, 25 Oct 2011 03:30:02 +0200 |
parents | 694ebabb5cb3 |
children | 7f136a3fa671 |
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329:694ebabb5cb3 | 330:9747a786a34d |
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16 */ | 16 */ |
17 package org.tmatesoft.hg.internal; | 17 package org.tmatesoft.hg.internal; |
18 | 18 |
19 import java.io.IOException; | 19 import java.io.IOException; |
20 import java.util.ArrayList; | 20 import java.util.ArrayList; |
21 import java.util.Formatter; | |
21 | 22 |
22 /** | 23 /** |
23 * @see http://mercurial.selenic.com/wiki/BundleFormat, in Changelog group description | 24 * @see http://mercurial.selenic.com/wiki/BundleFormat, in Changelog group description |
24 * | 25 * |
25 * range [start..end] in original source gets replaced with data of length (do not keep, use data.length instead) | 26 * range [start..end] in original source gets replaced with data of length (do not keep, use data.length instead) |
29 * @author TMate Software Ltd. | 30 * @author TMate Software Ltd. |
30 */ | 31 */ |
31 public final class Patch { | 32 public final class Patch { |
32 private final IntVector starts, ends; | 33 private final IntVector starts, ends; |
33 private final ArrayList<byte[]> data; | 34 private final ArrayList<byte[]> data; |
34 | 35 |
36 private static byte[] generate(int c) { | |
37 byte[] rv = new byte[c]; | |
38 for (int i = 0; i < c; i++) { | |
39 byte x = (byte) ('a' + i); | |
40 rv[i] = x; | |
41 } | |
42 return rv; | |
43 } | |
44 | |
45 public static void main(String[] args) { | |
46 Patch p1 = new Patch(), p2 = new Patch(); | |
47 // simple cases (one element in either patch) | |
48 // III: (1,10 20) & (5,15,15) p2End from [p1End..p1AppliedEnd] (i.e. within p1 range but index is past p2 end index) | |
49 // II: (1,10,7) & (3,15,15) insideP2 = true and no more p1 entries | |
50 // II: (1,1,10) & (3,11,15) | |
51 // independent: (1,10,10) & (15,25,10); (15, 25, 10) & (1, 10, 10) | |
52 // I: (15, 25, 10) & (10, 20, 10). result: [10, 20, 10] [20, 25, 5] | |
53 // IV: (15, 25, 10) & (10, 30, 20) | |
54 // | |
55 // cycle with insideP2 | |
56 // | |
57 // cycle with insideP1 | |
58 // | |
59 // multiple elements in patches (offsets) | |
60 p1.add(15, 25, generate(10)); | |
61 p2.add(10, 30, generate(20)); | |
62 System.out.println("p1: " + p1); | |
63 System.out.println("p2: " + p2); | |
64 Patch r = p1.apply(p2); | |
65 System.out.println("r: " + r); | |
66 } | |
67 | |
35 public Patch() { | 68 public Patch() { |
36 starts = new IntVector(); | 69 starts = new IntVector(); |
37 ends = new IntVector(); | 70 ends = new IntVector(); |
38 data = new ArrayList<byte[]>(); | 71 data = new ArrayList<byte[]>(); |
72 } | |
73 | |
74 public String toString() { | |
75 StringBuilder sb = new StringBuilder(); | |
76 Formatter f = new Formatter(sb); | |
77 for (int i = 0; i < count(); i++) { | |
78 f.format("[%d, %d, %d] ", starts.get(i), ends.get(i), data.get(i).length); | |
79 } | |
80 return sb.toString(); | |
39 } | 81 } |
40 | 82 |
41 public int count() { | 83 public int count() { |
42 return data.size(); | 84 return data.size(); |
43 } | 85 } |
110 starts.add(s); | 152 starts.add(s); |
111 ends.add(e); | 153 ends.add(e); |
112 data.add(src); | 154 data.add(src); |
113 } | 155 } |
114 | 156 |
115 /* | 157 private void add(Patch p, int i) { |
116 private void add(Patch another, int index) { | 158 add(p.starts.get(i), p.ends.get(i), p.data.get(i)); |
117 starts.add(another.starts.get(index)); | 159 } |
118 ends.add(another.ends.get(index)); | 160 |
119 data.add(another.data.get(index)); | 161 private void add(int start, int end, byte[] d) { |
162 starts.add(start); | |
163 ends.add(end); | |
164 data.add(d); | |
165 } | |
166 | |
167 private static byte[] subarray(byte[] d, int start, int end) { | |
168 byte[] r = new byte[end-start+1]; | |
169 System.arraycopy(d, start, r, 0, r.length); | |
170 return r; | |
120 } | 171 } |
121 | 172 |
122 /** | 173 /** |
123 * Modify this patch with subsequent patch | 174 * Modify this patch with subsequent patch |
124 * / | 175 */ |
125 public void apply(Patch another) { | 176 private /*SHALL BE PUBLIC ONCE TESTING ENDS*/ Patch apply(Patch another) { |
126 Patch r = new Patch(); | 177 Patch r = new Patch(); |
127 int p1AppliedPos = 0; | 178 int p1TotalAppliedDelta = 0; // value to add to start and end indexes of the older patch to get their values as if |
128 int p1PrevEnd = 0; | 179 // in the patched text, iow, directly comparable with respective indexes from the newer patch. |
129 for (int i = 0, j = 0, iMax = another.count(), jMax = this.count(); i < iMax; i++) { | 180 int p1EntryStart = 0, p1EntryEnd = 0, p1EntryLen = 0; |
130 int newerPatchEntryStart = another.starts.get(i); | 181 byte[] p1Data = null; |
131 int olderPatchEntryEnd; | 182 boolean insideP1entry = false; |
183 int p2 = 0, p1 = 0; | |
184 final int p2Max = another.count(), p1Max = this.count(); | |
185 L0: for (; p2 < p2Max; p2++) { | |
186 int p2EntryStart = another.starts.get(p2); | |
187 int p2EntryEnd = another.ends.get(p2); | |
188 final int p2EntryRange = p2EntryEnd - p2EntryStart; | |
189 final byte[] p2Data = another.data.get(p2); | |
190 boolean insideP2entry = false; | |
191 int p2EntryStartOffset = -1; | |
192 /// | |
193 p1EntryStart = p1EntryEnd = p1EntryLen = 0; | |
194 p1Data = null; | |
132 | 195 |
133 while (j < jMax) { | 196 L1: while (p1 < p1Max) { |
134 if (starts.get(j) < newerPatchEntryStart) { | 197 if (!insideP1entry) { |
135 if (starts.get(j)+data.get(j).length <= newerPatchEntryStart) { | 198 p1EntryStart = starts.get(p1); |
136 r.add(this, j); | 199 p1EntryEnd = ends.get(p1); |
200 p1Data = data.get(p1); | |
201 p1EntryLen = p1Data.length; | |
202 }// else keep values | |
203 | |
204 final int p1EntryDelta = p1EntryLen - (p1EntryEnd - p1EntryStart); // number of actually inserted(+) or deleted(-) chars | |
205 final int p1EntryAppliedStart = p1TotalAppliedDelta + p1EntryStart; | |
206 final int p1EntryAppliedEnd = p1EntryAppliedStart + p1EntryLen; // end of j'th patch entry in the text which is source for p2 | |
207 | |
208 if (insideP2entry) { | |
209 if (p2EntryEnd < p1EntryAppliedStart) { | |
210 r.add(p2EntryStart - p2EntryStartOffset, p2EntryEnd - p1TotalAppliedDelta, p2Data); | |
211 insideP2entry = false; | |
212 continue L0; | |
213 } | |
214 if (p2EntryEnd >= p1EntryAppliedEnd) { | |
215 // when p2EntryEnd == p1EntryAppliedEnd, I assume p1TotalAppliedDelta can't be used for p2EntryEnd to get it to p1 range, but rather shall be | |
216 // augmented with current p1 entry and at the next p1 entry (likely to hit p1EntryAppliedStart > p2EntryEnd above) would do the rest | |
217 insideP1entry = false; | |
218 p1++; | |
219 p1TotalAppliedDelta += p1EntryDelta; | |
220 continue L1; | |
221 } | |
222 // p1EntryAppliedStart <= p2EntryEnd < p1EntryAppliedEnd | |
223 r.add(p2EntryStart - p2EntryStartOffset, p2EntryEnd - p1TotalAppliedDelta, p2Data); | |
224 p1EntryStart = p2EntryEnd - p1TotalAppliedDelta; | |
225 final int p1DataPartShift = p2EntryEnd - p1EntryAppliedStart + 1; | |
226 if (p1DataPartShift >= p1EntryLen) { | |
227 p1EntryLen = 0; | |
228 p1Data = new byte[0]; | |
137 } else { | 229 } else { |
138 int newLen = newerPatchEntryStart - starts.get(j); | 230 p1EntryLen -= p1DataPartShift; |
139 int newEnd = ends.get(j) <= newerPatchEntryStart ? ends.get(j) : newerPatchEntryStart; | 231 p1Data = subarray(p1Data, p1DataPartShift, p1Data.length); |
140 r.add(starts.get(j), newEnd, data.get(j), newLen); | 232 } |
141 break; | 233 insideP1entry = true; |
142 } | 234 insideP2entry = false; |
235 continue L0; | |
143 } | 236 } |
144 p1AppliedPos += starts.get(j) - p1PrevEnd; | 237 |
145 p1AppliedPos += data.get(j).length; | 238 if (p1EntryAppliedStart < p2EntryStart) { |
146 p1PrevEnd = ends.get(j); | 239 if (p1EntryAppliedEnd <= p2EntryStart) { // p1EntryAppliedEnd in fact index of the first char *after* patch |
147 j++; | 240 // completely independent, copy and continue |
241 r.add(p1EntryStart, p1EntryEnd, p1Data); | |
242 insideP1entry = false; | |
243 p1++; | |
244 // fall-through to get p1TotalAppliedDelta incremented | |
245 } else { // SKETCH: II or III | |
246 // remember, p1EntryDelta may be negative | |
247 // shall break j'th entry into few | |
248 // fix p1's end/length | |
249 // p1EntryAppliedStart < p2EntryStart < p1EntryAppliedEnd | |
250 int s = p2EntryStart - p1TotalAppliedDelta; // p2EntryStart in p1 scale. Is within p1 range | |
251 if (s > p1EntryEnd) { | |
252 s = p1EntryEnd; | |
253 } | |
254 int p1DataPartEnd = p2EntryStart - p1EntryAppliedStart; // index, not count. <= (p1EntryEnd-p1EntryStart). | |
255 // add what left from p1 | |
256 if (p1DataPartEnd < p1EntryLen) { | |
257 r.add(p1EntryStart, s, subarray(p1Data, 0, p1DataPartEnd)); | |
258 } else { | |
259 p1DataPartEnd = p1EntryLen-1; // record factual number of p1 bytes we consumed. | |
260 r.add(p1EntryStart, s, p1Data); | |
261 } | |
262 p1TotalAppliedDelta += p1DataPartEnd - (s - p1EntryStart); // (s2 - (s1+delta)) - (s2 - delta - s1) = s2-s1-delta-s2+delta+s1 = 0, unless p1DataPartEnd >= p1Data.length | |
263 p1EntryLen -= (p1DataPartEnd+1); | |
264 if (p2EntryEnd < p1EntryAppliedEnd) { | |
265 // SKETCH: III | |
266 insideP1entry = true; | |
267 // p2 completely fits into changes of p1 | |
268 int e = p2EntryEnd - p1TotalAppliedDelta; // p2EntryEnd in p1 scale | |
269 if (e > p1EntryEnd) { | |
270 // any index past p1 end shall be calculated with respect to p1 end, thus it's unsafe to go past p1 end (there may be more p1 entries there) | |
271 e = p1EntryEnd; | |
272 } | |
273 r.add(s, e, p2Data); // add p2 | |
274 // modify p1 leftover | |
275 p1EntryStart = e; | |
276 if (p2EntryRange >= p1EntryLen) { | |
277 p1EntryLen = 0; | |
278 p1Data = new byte[0]; | |
279 } else { | |
280 p1Data = subarray(p1Data, p1DataPartEnd + p2EntryRange, p1Data.length-1 /*up to the last one*/); | |
281 p1EntryLen -= p2EntryRange; | |
282 } | |
283 // p2 is handled, but there are leftovers of p1 | |
284 continue L0; | |
285 } else { // p2EntryEnd >= p1EntryAppliedEnd | |
286 // SKETCH: II | |
287 insideP1entry = false; | |
288 p1++; | |
289 if (p1EntryAppliedStart + p1EntryDelta >= p2EntryEnd) { | |
290 // here we know next p1 entry would be past p2 entry and thus can put p2 right away | |
291 r.add(p2EntryStart - p1TotalAppliedDelta, p1EntryEnd, p2Data); | |
292 p1TotalAppliedDelta += p1EntryDelta; | |
293 continue L0; | |
294 } else { | |
295 // there are chances there are more p1 entries till p2 ends | |
296 insideP2entry = true; | |
297 p2EntryStartOffset = p1TotalAppliedDelta; | |
298 // p2EntryEnd is past delta, no chances for p1Data leftovers to be in use | |
299 // p2 processing is not over, need to fix end, depending on what else fits into p2 range (if nothing, can put p2.end right away) | |
300 // fall-through to get p1TotalAppliedDelta incremented; | |
301 } | |
302 } | |
303 } | |
304 } else { // p1EntryAppliedStart >= p2EntryStart | |
305 if (p2EntryEnd < p1EntryAppliedStart) { | |
306 // newer patch completely fits between two older patches | |
307 r.add(p2EntryStart - p1TotalAppliedDelta, p2EntryEnd - p1TotalAppliedDelta, p2Data); | |
308 // SHALL NOT increment p1TotalAppliedDelta as we didn't use any of p1 | |
309 continue L0; // next p2 | |
310 } else { // p2EntryEnd >= p1EntryAppliedStart | |
311 // SKETCH: I or IV | |
312 // p2EntryEnd is either < p1EntryAppliedEnd or past it | |
313 if (p2EntryEnd <= p1EntryAppliedEnd) { | |
314 // SKETCH: I: copy p2, strip p1 to start from p2EntryEnd, next i (p2) | |
315 insideP1entry = true; | |
316 int e = p2EntryEnd - p1TotalAppliedDelta; | |
317 if (e > p1EntryEnd) { | |
318 e = p1EntryEnd; // added by analogy with above. Is needed? | |
319 } | |
320 r.add(p2EntryStart - p1TotalAppliedDelta, e, p2Data); | |
321 p1EntryStart = e; | |
322 int p1DataShift = p2EntryEnd - p1EntryAppliedStart; | |
323 if (p1DataShift >= p1EntryLen) { | |
324 p1EntryLen = 0; | |
325 p1Data = new byte[0]; | |
326 } else { | |
327 p1EntryLen -= p1DataShift; | |
328 p1Data = subarray(p1Data, p1DataShift, p1Data.length - 1); | |
329 } | |
330 // p1TotalAppliedDelta would get incremented once this modified p1 is handled | |
331 continue L0; // next p2; | |
332 } else { | |
333 // p2EntryEnd > p1EntryAppliedEnd | |
334 // SKETCH IV: skip (rest of) p1 completely, continue the same unless found p1 with start or end past p2EntryEnd. | |
335 insideP1entry = false; | |
336 p1++; | |
337 insideP2entry = true; | |
338 p2EntryStartOffset = p1TotalAppliedDelta; | |
339 // fall-through to get p1TotalAppliedDelta incremented | |
340 } | |
341 } | |
342 } | |
343 p1TotalAppliedDelta += p1EntryDelta; | |
344 } // while (p1 < p1Max) | |
345 { | |
346 // no more p1 entries, shall close p2 (if it's handled, code above jumps directly to L0) | |
347 // regardless of whether insideP2 is .t | |
348 int s = p2EntryStart; | |
349 // p2EntryStartOffset != -1 when we started p2 entry processing, but not completed | |
350 // if we handled last p1 entry but didn't start with p2 entry processing, it's -1 and regular p1 delta shall be used | |
351 s -= p2EntryStartOffset == -1 ? p1TotalAppliedDelta : p2EntryStartOffset; | |
352 r.add(s, p2EntryEnd - p1TotalAppliedDelta, p2Data); | |
148 } | 353 } |
149 r.add(newerPatchEntryStart, another.ends.get(i), another.data.get(i)); | 354 } |
150 p1AppliedPos += newerPatchEntryStart + p1PrevEnd - another.data.get(i).length; | 355 if (p1 < p1Max && insideP1entry) { |
151 // either j == jMax and another(i, i+1, ..., iMax) need to be just copied | 356 r.add(p1EntryStart, p1EntryEnd, p1Data); |
152 // or new patch entry starts before end of one of original patch entries | 357 p1++; |
153 if (olderPatchEntryEnd > (destPosition + newerPatchEntryStart)) { | 358 } |
154 destPosition += starts.get(j) - prevEnd; // count those in the original stream up to old patch start | 359 while (p1 < p1Max) { |
155 int newLen = newerPatchEntryStart - destPosition; | 360 r.add(this, p1); |
156 } | 361 p1++; |
157 } | 362 }; |
158 } | 363 return r; |
159 */ | 364 } |
160 } | 365 } |