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author	Guy Brand <gb@isis.u-strasbg.fr>
date	Mon Aug 07 05:20:07 2006 -0700 (2006-08-07)
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children	32bf9a5f22c0

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1 \chapter{Managing change with Mercurial Queues}

2 \label{chap:mq}

4 \section{The patch management problem}

5 \label{sec:mq:patch-mgmt}

7 Here is a common scenario: you need to install a software package from

8 source, but you find a bug that you must fix in the source before you

9 can start using the package. You make your changes, forget about the

10 package for a while, and a few months later you need to upgrade to a

11 newer version of the package. If the newer version of the package

12 still has the bug, you must extract your fix from the older source

13 tree and apply it against the newer version. This is a tedious task,

14 and it's easy to make mistakes.

16 This is a simple case of the ``patch management'' problem. You have

17 an ``upstream'' source tree that you can't change; you need to make

18 some local changes on top of the upstream tree; and you'd like to be

19 able to keep those changes separate, so that you can apply them to

20 newer versions of the upstream source.

22 The patch management problem arises in many situations. Probably the

23 most visible is that a user of an open source software project will

24 contribute a bug fix or new feature to the project's maintainers in the

25 form of a patch.

27 Distributors of operating systems that include open source software

28 often need to make changes to the packages they distribute so that

29 they will build properly in their environments.

31 When you have few changes to maintain, it is easy to manage a single

32 patch using the standard \texttt{diff} and \texttt{patch} programs

33 (see section~\ref{sec:mq:patch} for a discussion of these tools).

34 Once the number of changes grows, it starts to makes sense to maintain

35 patches as discrete ``chunks of work,'' so that for example a single

36 patch will contain only one bug fix (the patch might modify several

37 files, but it's doing ``only one thing''), and you may have a number

38 of such patches for different bugs you need fixed and local changes

39 you require. In this situation, if you submit a bug fix patch to the

40 upstream maintainers of a package and they include your fix in a

41 subsequent release, you can simply drop that single patch when you're

42 updating to the newer release.

44 Maintaining a single patch against an upstream tree is a little

45 tedious and error-prone, but not difficult. However, the complexity

46 of the problem grows rapidly as the number of patches you have to

47 maintain increases. With more than a tiny number of patches in hand,

48 understanding which ones you have applied and maintaining them moves

49 from messy to overwhelming.

51 Fortunately, Mercurial includes a powerful extension, Mercurial Queues

52 (or simply ``MQ''), that massively simplifies the patch management

53 problem.

55 \section{The prehistory of Mercurial Queues}

56 \label{sec:mq:history}

58 During the late 1990s, several Linux kernel developers started to

59 maintain ``patch series'' that modified the behaviour of the Linux

60 kernel. Some of these series were focused on stability, some on

61 feature coverage, and others were more speculative.

63 The sizes of these patch series grew rapidly. In 2002, Andrew Morton

64 published some shell scripts he had been using to automate the task of

65 managing his patch queues. Andrew was successfully using these

66 scripts to manage hundreds (sometimes thousands) of patches on top of

67 the Linux kernel.

69 \subsection{A patchwork quilt}

70 \label{sec:mq:quilt}

72 In early 2003, Andreas Gruenbacher and Martin Quinson borrowed the

73 approach of Andrew's scripts and published a tool called ``patchwork

74 quilt''~\cite{web:quilt}, or simply ``quilt''

75 (see~\cite{gruenbacher:2005} for a paper describing it). Because

76 quilt substantially automated patch management, it rapidly gained a

77 large following among open source software developers.

79 Quilt manages a \emph{stack of patches} on top of a directory tree.

80 To begin, you tell quilt to manage a directory tree, and tell it which

81 files you want to manage; it stores away the names and contents of

82 those files. To fix a bug, you create a new patch (using a single

83 command), edit the files you need to fix, then ``refresh'' the patch.

85 The refresh step causes quilt to scan the directory tree; it updates

86 the patch with all of the changes you have made. You can create

87 another patch on top of the first, which will track the changes

88 required to modify the tree from ``tree with one patch applied'' to

89 ``tree with two patches applied''.

91 You can \emph{change} which patches are applied to the tree. If you

92 ``pop'' a patch, the changes made by that patch will vanish from the

93 directory tree. Quilt remembers which patches you have popped,

94 though, so you can ``push'' a popped patch again, and the directory

95 tree will be restored to contain the modifications in the patch. Most

96 importantly, you can run the ``refresh'' command at any time, and the

97 topmost applied patch will be updated. This means that you can, at

98 any time, change both which patches are applied and what

99 modifications those patches make.

100

101 Quilt knows nothing about revision control tools, so it works equally

102 well on top of an unpacked tarball or a Subversion repository.

103

104 \subsection{From patchwork quilt to Mercurial Queues}

105 \label{sec:mq:quilt-mq}

106

107 In mid-2005, Chris Mason took the features of quilt and wrote an

108 extension that he called Mercurial Queues, which added quilt-like

109 behaviour to Mercurial.

110

111 The key difference between quilt and MQ is that quilt knows nothing

112 about revision control systems, while MQ is \emph{integrated} into

113 Mercurial. Each patch that you push is represented as a Mercurial

114 changeset. Pop a patch, and the changeset goes away.

115

116 Because quilt does not care about revision control tools, it is still

117 a tremendously useful piece of software to know about for situations

118 where you cannot use Mercurial and MQ.

119

120 \section{The huge advantage of MQ}

121

122 I cannot overstate the value that MQ offers through the unification of

123 patches and revision control.

124

125 A major reason that patches have persisted in the free software and

126 open source world---in spite of the availability of increasingly

127 capable revision control tools over the years---is the \emph{agility}

128 they offer.

129

130 Traditional revision control tools make a permanent, irreversible

131 record of everything that you do. While this has great value, it's

132 also somewhat stifling. If you want to perform a wild-eyed

133 experiment, you have to be careful in how you go about it, or you risk

134 leaving unneeded---or worse, misleading or destabilising---traces of

135 your missteps and errors in the permanent revision record.

136

137 By contrast, MQ's marriage of distributed revision control with

138 patches makes it much easier to isolate your work. Your patches live

139 on top of normal revision history, and you can make them disappear or

140 reappear at will. If you don't like a patch, you can drop it. If a

141 patch isn't quite as you want it to be, simply fix it---as many times

142 as you need to, until you have refined it into the form you desire.

143

144 As an example, the integration of patches with revision control makes

145 understanding patches and debugging their effects---and their

146 interplay with the code they're based on---\emph{enormously} easier.

147 Since every applied patch has an associated changeset, you can use

148 \hgcmdargs{log}{\emph{filename}} to see which changesets and patches

149 affected a file. You can use the \hgext{bisect} extension to

150 binary-search through all changesets and applied patches to see where

151 a bug got introduced or fixed. You can use the \hgcmd{annotate}

152 command to see which changeset or patch modified a particular line of

153 a source file. And so on.

154

155 \section{Understanding patches}

156 \label{sec:mq:patch}

157

158 Because MQ doesn't hide its patch-oriented nature, it is helpful to

159 understand what patches are, and a little about the tools that work

160 with them.

161

162 The traditional Unix \command{diff} command compares two files, and

163 prints a list of differences between them. The \command{patch} command

164 understands these differences as \emph{modifications} to make to a

165 file. Take a look at figure~\ref{ex:mq:diff} for a simple example of

166 these commands in action.

167

168 \begin{figure}[ht]

169 \interaction{mq.dodiff.diff}

170 \caption{Simple uses of the \command{diff} and \command{patch} commands}

171 \label{ex:mq:diff}

172 \end{figure}

173

174 The type of file that \command{diff} generates (and \command{patch}

175 takes as input) is called a ``patch'' or a ``diff''; there is no

176 difference between a patch and a diff. (We'll use the term ``patch'',

177 since it's more commonly used.)

178

179 A patch file can start with arbitrary text; the \command{patch}

180 command ignores this text, but MQ uses it as the commit message when

181 creating changesets. To find the beginning of the patch content,

182 \command{patch} searches for the first line that starts with the

183 string ``\texttt{diff~-}''.

184

185 MQ works with \emph{unified} diffs (\command{patch} can accept several

186 other diff formats, but MQ doesn't). A unified diff contains two

187 kinds of header. The \emph{file header} describes the file being

188 modified; it contains the name of the file to modify. When

189 \command{patch} sees a new file header, it looks for a file with that

190 name to start modifying.

191

192 After the file header comes a series of \emph{hunks}. Each hunk

193 starts with a header; this identifies the range of line numbers within

194 the file that the hunk should modify. Following the header, a hunk

195 starts and ends with a few (usually three) lines of text from the

196 unmodified file; these are called the \emph{context} for the hunk. If

197 there's only a small amount of context between successive hunks,

198 \command{diff} doesn't print a new hunk header; it just runs the hunks

199 together, with a few lines of context between modifications.

200

201 Each line of context begins with a space character. Within the hunk,

202 a line that begins with ``\texttt{-}'' means ``remove this line,''

203 while a line that begins with ``\texttt{+}'' means ``insert this

204 line.'' For example, a line that is modified is represented by one

205 deletion and one insertion.

206

207 We will return to some of the more subtle aspects of patches later (in

208 section~\ref{sec:mq:adv-patch}), but you should have enough information

209 now to use MQ.

210

211 \section{Getting started with Mercurial Queues}

212 \label{sec:mq:start}

213

214 Because MQ is implemented as an extension, you must explicitly enable

215 before you can use it. (You don't need to download anything; MQ ships

216 with the standard Mercurial distribution.) To enable MQ, edit your

217 \tildefile{.hgrc} file, and add the lines in figure~\ref{ex:mq:config}.

218

219 \begin{figure}[ht]

220 \begin{codesample4}

221 [extensions]

222 hgext.mq =

223 \end{codesample4}

224 \label{ex:mq:config}

225 \caption{Contents to add to \tildefile{.hgrc} to enable the MQ extension}

226 \end{figure}

227

228 Once the extension is enabled, it will make a number of new commands

229 available. To verify that the extension is working, you can use

230 \hgcmd{help} to see if the \hgcmd{qinit} command is now available; see

231 the example in figure~\ref{ex:mq:enabled}.

232

233 \begin{figure}[ht]

234 \interaction{mq.qinit-help.help}

235 \caption{How to verify that MQ is enabled}

236 \label{ex:mq:enabled}

237 \end{figure}

238

239 You can use MQ with \emph{any} Mercurial repository, and its commands

240 only operate within that repository. To get started, simply prepare

241 the repository using the \hgcmd{qinit} command (see

242 figure~\ref{ex:mq:qinit}). This command creates an empty directory

243 called \sdirname{.hg/patches}, where MQ will keep its metadata. As

244 with many Mercurial commands, the \hgcmd{qinit} command prints nothing

245 if it succeeds.

246

247 \begin{figure}[ht]

248 \interaction{mq.tutorial.qinit}

249 \caption{Preparing a repository for use with MQ}

250 \label{ex:mq:qinit}

251 \end{figure}

252

253 \begin{figure}[ht]

254 \interaction{mq.tutorial.qnew}

255 \caption{Creating a new patch}

256 \label{ex:mq:qnew}

257 \end{figure}

258

259 \subsection{Creating a new patch}

260

261 To begin work on a new patch, use the \hgcmd{qnew} command. This

262 command takes one argument, the name of the patch to create. MQ will

263 use this as the name of an actual file in the \sdirname{.hg/patches}

264 directory, as you can see in figure~\ref{ex:mq:qnew}.

265

266 Also newly present in the \sdirname{.hg/patches} directory are two

267 other files, \sfilename{series} and \sfilename{status}. The

268 \sfilename{series} file lists all of the patches that MQ knows about

269 for this repository, with one patch per line. Mercurial uses the

270 \sfilename{status} file for internal book-keeping; it tracks all of the

271 patches that MQ has \emph{applied} in this repository.

272

273 \begin{note}

274 You may sometimes want to edit the \sfilename{series} file by hand;

275 for example, to change the sequence in which some patches are

276 applied. However, manually editing the \sfilename{status} file is

277 almost always a bad idea, as it's easy to corrupt MQ's idea of what

278 is happening.

279 \end{note}

280

281 Once you have created your new patch, you can edit files in the

282 working directory as you usually would. All of the normal Mercurial

283 commands, such as \hgcmd{diff} and \hgcmd{annotate}, work exactly as

284 they did before.

285

286 \subsection{Refreshing a patch}

287

288 When you reach a point where you want to save your work, use the

289 \hgcmd{qrefresh} command (figure~\ref{ex:mq:qnew}) to update the patch

290 you are working on. This command folds the changes you have made in

291 the working directory into your patch, and updates its corresponding

292 changeset to contain those changes.

293

294 \begin{figure}[ht]

295 \interaction{mq.tutorial.qrefresh}

296 \caption{Refreshing a patch}

297 \label{ex:mq:qrefresh}

298 \end{figure}

299

300 You can run \hgcmd{qrefresh} as often as you like, so it's a good way

301 to ``checkpoint'' your work. Refresh your patch at an opportune

302 time; try an experiment; and if the experiment doesn't work out,

303 \hgcmd{revert} your modifications back to the last time you refreshed.

304

305 \begin{figure}[ht]

306 \interaction{mq.tutorial.qrefresh2}

307 \caption{Refresh a patch many times to accumulate changes}

308 \label{ex:mq:qrefresh2}

309 \end{figure}

310

311 \subsection{Stacking and tracking patches}

312

313 Once you have finished working on a patch, or need to work on another,

314 you can use the \hgcmd{qnew} command again to create a new patch.

315 Mercurial will apply this patch on top of your existing patch. See

316 figure~\ref{ex:mq:qnew2} for an example. Notice that the patch

317 contains the changes in our prior patch as part of its context (you

318 can see this more clearly in the output of \hgcmd{annotate}).

319

320 \begin{figure}[ht]

321 \interaction{mq.tutorial.qnew2}

322 \caption{Stacking a second patch on top of the first}

323 \label{ex:mq:qnew2}

324 \end{figure}

325

326 So far, with the exception of \hgcmd{qnew} and \hgcmd{qrefresh}, we've

327 been careful to only use regular Mercurial commands. However, MQ

328 provides many commands that are easier to use when you are thinking

329 about patches, as illustrated in figure~\ref{ex:mq:qseries}:

330

331 \begin{itemize}

332 \item The \hgcmd{qseries} command lists every patch that MQ knows

333 about in this repository, from oldest to newest (most recently

334 \emph{created}).

335 \item The \hgcmd{qapplied} command lists every patch that MQ has

336 \emph{applied} in this repository, again from oldest to newest (most

337 recently applied).

338 \end{itemize}

339

340 \begin{figure}[ht]

341 \interaction{mq.tutorial.qseries}

342 \caption{Understanding the patch stack with \hgcmd{qseries} and

343 \hgcmd{qapplied}}

344 \label{ex:mq:qseries}

345 \end{figure}

346

347 \subsection{Manipulating the patch stack}

348

349 The previous discussion implied that there must be a difference

350 between ``known'' and ``applied'' patches, and there is. MQ can

351 manage a patch without it being applied in the repository.

352

353 An \emph{applied} patch has a corresponding changeset in the

354 repository, and the effects of the patch and changeset are visible in

355 the working directory. You can undo the application of a patch using

356 the \hgcmd{qpop} command. MQ still \emph{knows about}, or manages, a

357 popped patch, but the patch no longer has a corresponding changeset in

358 the repository, and the working directory does not contain the changes

359 made by the patch. Figure~\ref{fig:mq:stack} illustrates the

360 difference between applied and tracked patches.

361

362 \begin{figure}[ht]

363 \centering

364 \grafix{mq-stack}

365 \caption{Applied and unapplied patches in the MQ patch stack}

366 \label{fig:mq:stack}

367 \end{figure}

368

369 You can reapply an unapplied, or popped, patch using the \hgcmd{qpush}

370 command. This creates a new changeset to correspond to the patch, and

371 the patch's changes once again become present in the working

372 directory. See figure~\ref{ex:mq:qpop} for examples of \hgcmd{qpop}

373 and \hgcmd{qpush} in action. Notice that once we have popped a patch

374 or two patches, the output of \hgcmd{qseries} remains the same, while

375 that of \hgcmd{qapplied} has changed.

376

377 \begin{figure}[ht]

378 \interaction{mq.tutorial.qpop}

379 \caption{Modifying the stack of applied patches}

380 \label{ex:mq:qpop}

381 \end{figure}

382

383 \subsection{Pushing and popping many patches}

384

385 While \hgcmd{qpush} and \hgcmd{qpop} each operate on a single patch at

386 a time by default, you can push and pop many patches in one go. The

387 \hgopt{qpush}{-a} option to \hgcmd{qpush} causes it to push all

388 unapplied patches, while the \hgopt{qpop}{-a} option to \hgcmd{qpop}

389 causes it to pop all applied patches. (For some more ways to push and

390 pop many patches, see section~\ref{sec:mq:perf} below.)

391

392 \begin{figure}[ht]

393 \interaction{mq.tutorial.qpush-a}

394 \caption{Pushing all unapplied patches}

395 \label{ex:mq:qpush-a}

396 \end{figure}

397

398 \subsection{Safety checks, and overriding them}

399

400 Several MQ commands check the working directory before they do

401 anything, and fail if they find any modifications. They do this to

402 ensure that you won't lose any changes that you have made, but not yet

403 incorporated into a patch. Figure~\ref{ex:mq:add} illustrates this;

404 the \hgcmd{qnew} command will not create a new patch if there are

405 outstanding changes, caused in this case by the \hgcmd{add} of

406 \filename{file3}.

407

408 \begin{figure}[ht]

409 \interaction{mq.tutorial.add}

410 \caption{Forcibly creating a patch}

411 \label{ex:mq:add}

412 \end{figure}

413

414 Commands that check the working directory all take an ``I know what

415 I'm doing'' option, which is always named \option{-f}. The exact

416 meaning of \option{-f} depends on the command. For example,

417 \hgcmdargs{qnew}{\hgopt{qnew}{-f}} will incorporate any outstanding

418 changes into the new patch it creates, but

419 \hgcmdargs{qpop}{\hgopt{qpop}{-f}} will revert modifications to any

420 files affected by the patch that it is popping. Be sure to read the

421 documentation for a command's \option{-f} option before you use it!

422

423 \subsection{Working on several patches at once}

424

425 The \hgcmd{qrefresh} command always refreshes the \emph{topmost}

426 applied patch. This means that you can suspend work on one patch (by

427 refreshing it), pop or push to make a different patch the top, and

428 work on \emph{that} patch for a while.

429

430 Here's an example that illustrates how you can use this ability.

431 Let's say you're developing a new feature as two patches. The first

432 is a change to the core of your software, and the second---layered on

433 top of the first---changes the user interface to use the code you just

434 added to the core. If you notice a bug in the core while you're

435 working on the UI patch, it's easy to fix the core. Simply

436 \hgcmd{qrefresh} the UI patch to save your in-progress changes, and

437 \hgcmd{qpop} down to the core patch. Fix the core bug,

438 \hgcmd{qrefresh} the core patch, and \hgcmd{qpush} back to the UI

439 patch to continue where you left off.

440

441 \section{More about patches}

442 \label{sec:mq:adv-patch}

443

444 MQ uses the GNU \command{patch} command to apply patches, so it's

445 helpful to know a few more detailed aspects of how \command{patch}

446 works, and about patches themselves.

447

448 \subsection{The strip count}

449

450 If you look at the file headers in a patch, you will notice that the

451 pathnames usually have an extra component on the front that isn't

452 present in the actual path name. This is a holdover from the way that

453 people used to generate patches (people still do this, but it's

454 somewhat rare with modern revision control tools).

455

456 Alice would unpack a tarball, edit her files, then decide that she

457 wanted to create a patch. So she'd rename her working directory,

458 unpack the tarball again (hence the need for the rename), and use the

459 \cmdopt{diff}{-r} and \cmdopt{diff}{-N} options to \command{diff} to

460 recursively generate a patch between the unmodified directory and the

461 modified one. The result would be that the name of the unmodified

462 directory would be at the front of the left-hand path in every file

463 header, and the name of the modified directory would be at the front

464 of the right-hand path.

465

466 Since someone receiving a patch from the Alices of the net would be

467 unlikely to have unmodified and modified directories with exactly the

468 same names, the \command{patch} command has a \cmdopt{patch}{-p}

469 option that indicates the number of leading path name components to

470 strip when trying to apply a patch. This number is called the

471 \emph{strip count}.

472

473 An option of ``\texttt{-p1}'' means ``use a strip count of one''. If

474 \command{patch} sees a file name \filename{foo/bar/baz} in a file

475 header, it will strip \filename{foo} and try to patch a file named

476 \filename{bar/baz}. (Strictly speaking, the strip count refers to the

477 number of \emph{path separators} (and the components that go with them

478 ) to strip. A strip count of one will turn \filename{foo/bar} into

479 \filename{bar}, but \filename{/foo/bar} (notice the extra leading

480 slash) into \filename{foo/bar}.)

481

482 The ``standard'' strip count for patches is one; almost all patches

483 contain one leading path name component that needs to be stripped.

484 Mercurial's \hgcmd{diff} command generates path names in this form,

485 and the \hgcmd{import} command and MQ expect patches to have a strip

486 count of one.

487

488 If you receive a patch from someone that you want to add to your patch

489 queue, and the patch needs a strip count other than one, you cannot

490 just \hgcmd{qimport} the patch, because \hgcmd{qimport} does not yet

491 have a \texttt{-p} option (see~\bug{311}). Your best bet is to

492 \hgcmd{qnew} a patch of your own, then use \cmdargs{patch}{-p\emph{N}}

493 to apply their patch, followed by \hgcmd{addremove} to pick up any

494 files added or removed by the patch, followed by \hgcmd{qrefresh}.

495 This complexity may become unnecessary; see~\bug{311} for details.

496 \subsection{Strategies for applying a patch}

497

498 When \command{patch} applies a hunk, it tries a handful of

499 successively less accurate strategies to try to make the hunk apply.

500 This falling-back technique often makes it possible to take a patch

501 that was generated against an old version of a file, and apply it

502 against a newer version of that file.

503

504 First, \command{patch} tries an exact match, where the line numbers,

505 the context, and the text to be modified must apply exactly. If it

506 cannot make an exact match, it tries to find an exact match for the

507 context, without honouring the line numbering information. If this

508 succeeds, it prints a line of output saying that the hunk was applied,

509 but at some \emph{offset} from the original line number.

510

511 If a context-only match fails, \command{patch} removes the first and

512 last lines of the context, and tries a \emph{reduced} context-only

513 match. If the hunk with reduced context succeeds, it prints a message

514 saying that it applied the hunk with a \emph{fuzz factor} (the number

515 after the fuzz factor indicates how many lines of context

516 \command{patch} had to trim before the patch applied).

517

518 When neither of these techniques works, \command{patch} prints a

519 message saying that the hunk in question was rejected. It saves

520 rejected hunks (also simply called ``rejects'') to a file with the

521 same name, and an added \sfilename{.rej} extension. It also saves an

522 unmodified copy of the file with a \sfilename{.orig} extension; the

523 copy of the file without any extensions will contain any changes made

524 by hunks that \emph{did} apply cleanly. If you have a patch that

525 modifies \filename{foo} with six hunks, and one of them fails to

526 apply, you will have: an unmodified \filename{foo.orig}, a

527 \filename{foo.rej} containing one hunk, and \filename{foo}, containing

528 the changes made by the five successful five hunks.

529

530 \subsection{Some quirks of patch representation}

531

532 There are a few useful things to know about how \command{patch} works

533 with files.

534 \begin{itemize}

535 \item This should already be obvious, but \command{patch} cannot

536 handle binary files.

537 \item Neither does it care about the executable bit; it creates new

538 files as readable, but not executable.

539 \item \command{patch} treats the removal of a file as a diff between

540 the file to be removed and the empty file. So your idea of ``I

541 deleted this file'' looks like ``every line of this file was

542 deleted'' in a patch.

543 \item It treats the addition of a file as a diff between the empty

544 file and the file to be added. So in a patch, your idea of ``I

545 added this file'' looks like ``every line of this file was added''.

546 \item It treats a renamed file as the removal of the old name, and the

547 addition of the new name. This means that renamed files have a big

548 footprint in patches. (Note also that Mercurial does not currently

549 try to infer when files have been renamed or copied in a patch.)

550 \item \command{patch} cannot represent empty files, so you cannot use

551 a patch to represent the notion ``I added this empty file to the

552 tree''.

553 \end{itemize}

554 \subsection{Beware the fuzz}

555

556 While applying a hunk at an offset, or with a fuzz factor, will often

557 be completely successful, these inexact techniques naturally leave

558 open the possibility of corrupting the patched file. The most common

559 cases typically involve applying a patch twice, or at an incorrect

560 location in the file. If \command{patch} or \hgcmd{qpush} ever

561 mentions an offset or fuzz factor, you should make sure that the

562 modified files are correct afterwards.

563

564 It's often a good idea to refresh a patch that has applied with an

565 offset or fuzz factor; refreshing the patch generates new context

566 information that will make it apply cleanly. I say ``often,'' not

567 ``always,'' because sometimes refreshing a patch will make it fail to

568 apply against a different revision of the underlying files. In some

569 cases, such as when you're maintaining a patch that must sit on top of

570 multiple versions of a source tree, it's acceptable to have a patch

571 apply with some fuzz, provided you've verified the results of the

572 patching process in such cases.

573

574 \subsection{Handling rejection}

575

576 If \hgcmd{qpush} fails to apply a patch, it will print an error

577 message and exit. If it has left \sfilename{.rej} files behind, it is

578 usually best to fix up the rejected hunks before you push more patches

579 or do any further work.

580

581 If your patch \emph{used to} apply cleanly, and no longer does because

582 you've changed the underlying code that your patches are based on,

583 Mercurial Queues can help; see section~\ref{sec:mq:merge} for details.

584

585 Unfortunately, there aren't any great techniques for dealing with

586 rejected hunks. Most often, you'll need to view the \sfilename{.rej}

587 file and edit the target file, applying the rejected hunks by hand.

588

589 If you're feeling adventurous, Neil Brown, a Linux kernel hacker,

590 wrote a tool called \command{wiggle}~\cite{web:wiggle}, which is more

591 vigorous than \command{patch} in its attempts to make a patch apply.

592

593 Another Linux kernel hacker, Chris Mason (the author of Mercurial

594 Queues), wrote a similar tool called \command{rej}~\cite{web:rej},

595 which takes a simple approach to automating the application of hunks

596 rejected by \command{patch}. \command{rej} can help with four common

597 reasons that a hunk may be rejected:

598

599 \begin{itemize}

600 \item The context in the middle of a hunk has changed.

601 \item A hunk is missing some context at the beginning or end.

602 \item A large hunk might apply better---either entirely or in

603 part---if it was broken up into smaller hunks.

604 \item A hunk removes lines with slightly different content than those

605 currently present in the file.

606 \end{itemize}

607

608 If you use \command{wiggle} or \command{rej}, you should be doubly

609 careful to check your results when you're done. In fact,

610 \command{rej} enforces this method of double-checking the tool's

611 output, by automatically dropping you into a merge program when it has

612 done its job, so that you can verify its work and finish off any

613 remaining merges.

614

615 \section{Getting the best performance out of MQ}

616 \label{sec:mq:perf}

617

618 MQ is very efficient at handling a large number of patches. I ran

619 some performance experiments in mid-2006 for a talk that I gave at the

620 2006 EuroPython conference~\cite{web:europython}. I used as my data

621 set the Linux 2.6.17-mm1 patch series, which consists of 1,738

622 patches. I applied these on top of a Linux kernel repository

623 containing all 27,472 revisions between Linux 2.6.12-rc2 and Linux

624 2.6.17.

625

626 On my old, slow laptop, I was able to

627 \hgcmdargs{qpush}{\hgopt{qpush}{-a}} all 1,738 patches in 3.5 minutes,

628 and \hgcmdargs{qpop}{\hgopt{qpop}{-a}} them all in 30 seconds. (On a

629 newer laptop, the time to push all patches dropped to two minutes.) I

630 could \hgcmd{qrefresh} one of the biggest patches (which made 22,779

631 lines of changes to 287 files) in 6.6 seconds.

632

633 Clearly, MQ is well suited to working in large trees, but there are a

634 few tricks you can use to get the best performance of it.

635

636 First of all, try to ``batch'' operations together. Every time you

637 run \hgcmd{qpush} or \hgcmd{qpop}, these commands scan the working

638 directory once to make sure you haven't made some changes and then

639 forgotten to run \hgcmd{qrefresh}. On a small tree, the time that

640 this scan takes is unnoticeable. However, on a medium-sized tree

641 (containing tens of thousands of files), it can take a second or more.

642

643 The \hgcmd{qpush} and \hgcmd{qpop} commands allow you to push and pop

644 multiple patches at a time. You can identify the ``destination

645 patch'' that you want to end up at. When you \hgcmd{qpush} with a

646 destination specified, it will push patches until that patch is at the

647 top of the applied stack. When you \hgcmd{qpop} to a destination, MQ

648 will pop patches until the destination patch is at the top.

649

650 You can identify a destination patch using either the name of the

651 patch, or by number. If you use numeric addressing, patches are

652 counted from zero; this means that the first patch is zero, the second

653 is one, and so on.

654

655 \section{Updating your patches when the underlying code changes}

656 \label{sec:mq:merge}

657

658 It's common to have a stack of patches on top of an underlying

659 repository that you don't modify directly. If you're working on

660 changes to third-party code, or on a feature that is taking longer to

661 develop than the rate of change of the code beneath, you will often

662 need to sync up with the underlying code, and fix up any hunks in your

663 patches that no longer apply. This is called \emph{rebasing} your

664 patch series.

665

666 The simplest way to do this is to \hgcmdargs{qpop}{\hgopt{qpop}{-a}}

667 your patches, then \hgcmd{pull} changes into the underlying

668 repository, and finally \hgcmdargs{qpush}{\hgopt{qpop}{-a}} your

669 patches again. MQ will stop pushing any time it runs across a patch

670 that fails to apply during conflicts, allowing you to fix your

671 conflicts, \hgcmd{qrefresh} the affected patch, and continue pushing

672 until you have fixed your entire stack.

673

674 This approach is easy to use and works well if you don't expect

675 changes to the underlying code to affect how well your patches apply.

676 If your patch stack touches code that is modified frequently or

677 invasively in the underlying repository, however, fixing up rejected

678 hunks by hand quickly becomes tiresome.

679

680 It's possible to partially automate the rebasing process. If your

681 patches apply cleanly against some revision of the underlying repo, MQ

682 can use this information to help you to resolve conflicts between your

683 patches and a different revision.

684

685 The process is a little involved.

686 \begin{enumerate}

687 \item To begin, \hgcmdargs{qpush}{-a} all of your patches on top of

688 the revision where you know that they apply cleanly.

689 \item Save a backup copy of your patch directory using

690 \hgcmdargs{qsave}{\hgopt{qsave}{-e} \hgopt{qsave}{-c}}. This prints

691 the name of the directory that it has saved the patches in. It will

692 save the patches to a directory called

693 \sdirname{.hg/patches.\emph{N}}, where \texttt{\emph{N}} is a small

694 integer. It also commits a ``save changeset'' on top of your

695 applied patches; this is for internal book-keeping, and records the

696 states of the \sfilename{series} and \sfilename{status} files.

697 \item Use \hgcmd{pull} to bring new changes into the underlying

698 repository. (Don't run \hgcmdargs{pull}{-u}; see below for why.)

699 \item Update to the new tip revision, using

700 \hgcmdargs{update}{\hgopt{update}{-C}} to override the patches you

701 have pushed.

702 \item Merge all patches using \hgcmdargs{qpush}{\hgopt{qpush}{-m}

703 \hgopt{qpush}{-a}}. The \hgopt{qpush}{-m} option to \hgcmd{qpush}

704 tells MQ to perform a three-way merge if the patch fails to apply.

705 \end{enumerate}

706

707 During the \hgcmdargs{qpush}{\hgopt{qpush}{-m}}, each patch in the

708 \sfilename{series} file is applied normally. If a patch applies with

709 fuzz or rejects, MQ looks at the queue you \hgcmd{qsave}d, and

710 performs a three-way merge with the corresponding changeset. This

711 merge uses Mercurial's normal merge machinery, so it may pop up a GUI

712 merge tool to help you to resolve problems.

713

714 When you finish resolving the effects of a patch, MQ refreshes your

715 patch based on the result of the merge.

716

717 At the end of this process, your repository will have one extra head

718 from the old patch queue, and a copy of the old patch queue will be in

719 \sdirname{.hg/patches.\emph{N}}. You can remove the extra head using

720 \hgcmdargs{qpop}{\hgopt{qpop}{-a} \hgopt{qpop}{-n} patches.\emph{N}}

721 or \hgcmd{strip}. You can delete \sdirname{.hg/patches.\emph{N}} once

722 you are sure that you no longer need it as a backup.

723

724 \section{Identifying patches}

725

726 MQ commands that work with patches let you refer to a patch either by

727 using its name or by a number. By name is obvious enough; pass the

728 name \filename{foo.patch} to \hgcmd{qpush}, for example, and it will

729 push patches until \filename{foo.patch} is applied.

730

731 As a shortcut, you can refer to a patch using both a name and a

732 numeric offset; \texttt{foo.patch-2} means ``two patches before

733 \texttt{foo.patch}'', while \texttt{bar.patch+4} means ``four patches

734 after \texttt{bar.patch}''.

735

736 Referring to a patch by index isn't much different. The first patch

737 printed in the output of \hgcmd{qseries} is patch zero (yes, it's one

738 of those start-at-zero counting systems); the second is patch one; and

739 so on

740

741 MQ also makes it easy to work with patches when you are using normal

742 Mercurial commands. Every command that accepts a changeset ID will

743 also accept the name of an applied patch. MQ augments the tags

744 normally in the repository with an eponymous one for each applied

745 patch. In addition, the special tags \index{tags!special tag

746 names!\texttt{qbase}}\texttt{qbase} and \index{tags!special tag

747 names!\texttt{qtip}}\texttt{qtip} identify the ``bottom-most'' and

748 topmost applied patches, respectively.

749

750 These additions to Mercurial's normal tagging capabilities make

751 dealing with patches even more of a breeze.

752 \begin{itemize}

753 \item Want to patchbomb a mailing list with your latest series of

754 changes?

755 \begin{codesample4}

756 hg email qbase:qtip

757 \end{codesample4}

758 \item Need to see all of the patches since \texttt{foo.patch} that

759 have touched files in a subdirectory of your tree?

760 \begin{codesample4}

761 hg log -r foo.patch:qtip \emph{subdir}

762 \end{codesample4}

763 \end{itemize}

764

765 Because MQ makes the names of patches available to the rest of

766 Mercurial through its normal internal tag machinery, you don't need to

767 type in the entire name of a patch when you want to identify it by

768 name.

769

770 \begin{figure}[ht]

771 \interaction{mq.id.out}

772 \caption{Using MQ's tag features to work with patches}

773 \label{ex:mq:id}

774 \end{figure}

775

776 Another nice consequence of representing patch names as tags is that

777 when you run the \hgcmd{log} command, it will display a patch's name

778 as a tag, simply as part of its normal output. This makes it easy to

779 visually distinguish applied patches from underlying ``normal''

780 revisions. Figure~\ref{ex:mq:id} shows a few normal Mercurial

781 commands in use with applied patches.

782

783 \section{Useful things to know about}

784

785 There are a number of aspects of MQ usage that don't fit tidily into

786 sections of their own, but that are good to know. Here they are, in

787 one place.

788

789 \begin{itemize}

790 \item Normally, when you \hgcmd{qpop} a patch and \hgcmd{qpush} it

791 again, the changeset that represents the patch after the pop/push

792 will have a \emph{different identity} than the changeset that

793 represented the hash beforehand. See section~\ref{sec:mq:cmd:qpush}

794 for information as to why this is.

795 \item It's not a good idea to \hgcmd{merge} changes from another

796 branch with a patch changeset, at least if you want to maintain the

797 ``patchiness'' of that changeset and changesets below it on the

798 patch stack. If you try to do this, it will appear to succeed, but

799 MQ will become confused.

800 \end{itemize}

801

802 \section{Managing patches in a repository}

803

804 Because MQ's \sdirname{.hg/patches} directory resides outside a

805 Mercurial repository's working directory, the ``underlying'' Mercurial

806 repository knows nothing about the management or presence of patches.

807

808 This presents the interesting possibility of managing the contents of

809 the patch directory as a Mercurial repository in its own right. This

810 can be a useful way to work. For example, you can work on a patch for

811 a while, \hgcmd{qrefresh} it, then \hgcmd{commit} the current state of

812 the patch. This lets you ``roll back'' to that version of the patch

813 later on.

814

815 You can then share different versions of the same patch stack among

816 multiple underlying repositories. I use this when I am developing a

817 Linux kernel feature. I have a pristine copy of my kernel sources for

818 each of several CPU architectures, and a cloned repository under each

819 that contains the patches I am working on. When I want to test a

820 change on a different architecture, I push my current patches to the

821 patch repository associated with that kernel tree, pop and push all of

822 my patches, and build and test that kernel.

823

824 Managing patches in a repository makes it possible for multiple

825 developers to work on the same patch series without colliding with

826 each other, all on top of an underlying source base that they may or

827 may not control.

828

829 \subsection{MQ support for patch repositories}

830

831 MQ helps you to work with the \sdirname{.hg/patches} directory as a

832 repository; when you prepare a repository for working with patches

833 using \hgcmd{qinit}, you can pass the \hgopt{qinit}{-c} option to

834 create the \sdirname{.hg/patches} directory as a Mercurial repository.

835

836 \begin{note}

837 If you forget to use the \hgopt{qinit}{-c} option, you can simply go

838 into the \sdirname{.hg/patches} directory at any time and run

839 \hgcmd{init}. Don't forget to add an entry for the

840 \sfilename{status} file to the \sfilename{.hgignore} file, though

841 (\hgcmdargs{qinit}{\hgopt{qinit}{-c}} does this for you

842 automatically); you \emph{really} don't want to manage the

843 \sfilename{status} file.

844 \end{note}

845

846 As a convenience, if MQ notices that the \dirname{.hg/patches}

847 directory is a repository, it will automatically \hgcmd{add} every

848 patch that you create and import.

849

850 Finally, MQ provides a shortcut command, \hgcmd{qcommit}, that runs

851 \hgcmd{commit} in the \sdirname{.hg/patches} directory. This saves

852 some cumbersome typing.

853

854 \subsection{A few things to watch out for}

855

856 MQ's support for working with a repository full of patches is limited

857 in a few small respects.

858

859 MQ cannot automatically detect changes that you make to the patch

860 directory. If you \hgcmd{pull}, manually edit, or \hgcmd{update}

861 changes to patches or the \sfilename{series} file, you will have to

862 \hgcmdargs{qpop}{\hgopt{qpop}{-a}} and then

863 \hgcmdargs{qpush}{\hgopt{qpush}{-a}} in the underlying repository to

864 see those changes show up there. If you forget to do this, you can

865 confuse MQ's idea of which patches are applied.

866

867 \section{Third party tools for working with patches}

868 \label{sec:mq:tools}

869

870 Once you've been working with patches for a while, you'll find

871 yourself hungry for tools that will help you to understand and

872 manipulate the patches you're dealing with.

873

874 The \command{diffstat} command~\cite{web:diffstat} generates a

875 histogram of the modifications made to each file in a patch. It

876 provides a good way to ``get a sense of'' a patch---which files it

877 affects, and how much change it introduces to each file and as a

878 whole. (I find that it's a good idea to use \command{diffstat}'s

879 \texttt{-p} option as a matter of course, as otherwise it will try to

880 do clever things with prefixes of file names that inevitably confuse

881 at least me.)

882

883 \begin{figure}[ht]

884 \interaction{mq.tools.tools}

885 \caption{The \command{diffstat}, \command{filterdiff}, and \command{lsdiff} commands}

886 \label{ex:mq:tools}

887 \end{figure}

888

889 The \package{patchutils} package~\cite{web:patchutils} is invaluable.

890 It provides a set of small utilities that follow the ``Unix

891 philosophy;'' each does one useful thing with a patch. The

892 \package{patchutils} command I use most is \command{filterdiff}, which

893 extracts subsets from a patch file. For example, given a patch that

894 modifies hundreds of files across dozens of directories, a single

895 invocation of \command{filterdiff} can generate a smaller patch that

896 only touches files whose names match a particular glob pattern.

897

898 \section{Good ways to work with patches}

899

900 Whether you are working on a patch series to submit to a free software

901 or open source project, or a series that you intend to treat as a

902 sequence of regular changesets when you're done, you can use some

903 simple techniques to keep your work well organised.

904

905 Give your patches descriptive names. A good name for a patch might be

906 \filename{rework-device-alloc.patch}, because it will immediately give

907 you a hint what the purpose of the patch is. Long names shouldn't be

908 a problem; you won't be typing the names often, but you \emph{will} be

909 running commands like \hgcmd{qapplied} and \hgcmd{qtop} over and over.

910 Good naming becomes especially important when you have a number of

911 patches to work with, or if you are juggling a number of different

912 tasks and your patches only get a fraction of your attention.

913

914 Be aware of what patch you're working on. Use the \hgcmd{qtop}

915 command and skim over the text of your patches frequently---for

916 example, using \hgcmdargs{tip}{\hgopt{tip}{-p}})---to be sure of where

917 you stand. I have several times worked on and \hgcmd{qrefresh}ed a

918 patch other than the one I intended, and it's often tricky to migrate

919 changes into the right patch after making them in the wrong one.

920

921 For this reason, it is very much worth investing a little time to

922 learn how to use some of the third-party tools I described in

923 section~\ref{sec:mq:tools}, particularly \command{diffstat} and

924 \command{filterdiff}. The former will give you a quick idea of what

925 changes your patch is making, while the latter makes it easy to splice

926 hunks selectively out of one patch and into another.

927

928 \section{MQ cookbook}

929

930 \subsection{Manage ``trivial'' patches}

931

932 Because the overhead of dropping files into a new Mercurial repository

933 is so low, it makes a lot of sense to manage patches this way even if

934 you simply want to make a few changes to a source tarball that you

935 downloaded.

936

937 Begin by downloading and unpacking the source tarball,

938 and turning it into a Mercurial repository.

939 \interaction{mq.tarball.download}

940

941 Continue by creating a patch stack and making your changes.

942 \interaction{mq.tarball.qinit}

943

944 Let's say a few weeks or months pass, and your package author releases

945 a new version. First, bring their changes into the repository.

946 \interaction{mq.tarball.newsource}

947 The pipeline starting with \hgcmd{locate} above deletes all files in

948 the working directory, so that \hgcmd{commit}'s

949 \hgopt{commit}{--addremove} option can actually tell which files have

950 really been removed in the newer version of the source.

951

952 Finally, you can apply your patches on top of the new tree.

953 \interaction{mq.tarball.repush}

954

955 \subsection{Combining entire patches}

956 \label{sec:mq:combine}

957

958 MQ provides a command, \hgcmd{qfold} that lets you combine entire

959 patches. This ``folds'' the patches you name, in the order you name

960 them, into the topmost applied patch, and concatenates their

961 descriptions onto the end of its description. The patches that you

962 fold must be unapplied before you fold them.

963

964 The order in which you fold patches matters. If your topmost applied

965 patch is \texttt{foo}, and you \hgcmd{qfold} \texttt{bar} and

966 \texttt{quux} into it, you will end up with a patch that has the same

967 effect as if you applied first \texttt{foo}, then \texttt{bar},

968 followed by \texttt{quux}.

969

970 \subsection{Merging part of one patch into another}

971

972 Merging \emph{part} of one patch into another is more difficult than

973 combining entire patches.

974

975 If you want to move changes to entire files, you can use

976 \command{filterdiff}'s \cmdopt{filterdiff}{-i} and

977 \cmdopt{filterdiff}{-x} options to choose the modifications to snip

978 out of one patch, concatenating its output onto the end of the patch

979 you want to merge into. You usually won't need to modify the patch

980 you've merged the changes from. Instead, MQ will report some rejected

981 hunks when you \hgcmd{qpush} it (from the hunks you moved into the

982 other patch), and you can simply \hgcmd{qrefresh} the patch to drop

983 the duplicate hunks.

984

985 If you have a patch that has multiple hunks modifying a file, and you

986 only want to move a few of those hunks, the job becomes more messy,

987 but you can still partly automate it. Use \cmdargs{lsdiff}{-nvv} to

988 print some metadata about the patch.

989 \interaction{mq.tools.lsdiff}

990

991 This command prints three different kinds of number:

992 \begin{itemize}

993 \item (in the first column) a \emph{file number} to identify each file

994 modified in the patch;

995 \item (on the next line, indented) the line number within a modified

996 file where a hunk starts; and

997 \item (on the same line) a \emph{hunk number} to identify that hunk.

998 \end{itemize}

999

1000 You'll have to use some visual inspection, and reading of the patch,

1001 to identify the file and hunk numbers you'll want, but you can then

1002 pass them to to \command{filterdiff}'s \cmdopt{filterdiff}{--files}

1003 and \cmdopt{filterdiff}{--hunks} options, to select exactly the file

1004 and hunk you want to extract.

1005

1006 Once you have this hunk, you can concatenate it onto the end of your

1007 destination patch and continue with the remainder of

1008 section~\ref{sec:mq:combine}.

1009

1010 \section{Differences between quilt and MQ}

1011

1012 If you are already familiar with quilt, MQ provides a similar command

1013 set. There are a few differences in the way that it works.

1014

1015 You will already have noticed that most quilt commands have MQ

1016 counterparts that simply begin with a ``\texttt{q}''. The exceptions

1017 are quilt's \texttt{add} and \texttt{remove} commands, the

1018 counterparts for which are the normal Mercurial \hgcmd{add} and

1019 \hgcmd{remove} commands. There is no MQ equivalent of the quilt

1020 \texttt{edit} command.

1021

1022 \section{MQ command reference}

1023 \label{sec:mq:cmdref}

1024

1025 For an overview of the commands provided by MQ, use the command

1026 \hgcmdargs{help}{mq}.

1027

1028 \subsection{\hgcmd{qapplied}---print applied patches}

1029

1030 The \hgcmd{qapplied} command prints the current stack of applied

1031 patches. Patches are printed in oldest-to-newest order, so the last

1032 patch in the list is the ``top'' patch.

1033

1034 \subsection{\hgcmd{qcommit}---commit changes in the queue repository}

1035

1036 The \hgcmd{qcommit} command commits any outstanding changes in the

1037 \sdirname{.hg/patches} repository. This command only works if the

1038 \sdirname{.hg/patches} directory is a repository, i.e.~you created the

1039 directory using \hgcmdargs{qinit}{\hgopt{qinit}{-c}} or ran

1040 \hgcmd{init} in the directory after running \hgcmd{qinit}.

1041

1042 This command is shorthand for \hgcmdargs{commit}{--cwd .hg/patches}.

1043

1044 \subsection{\hgcmd{qdelete}---delete a patch from the

1045 \sfilename{series} file}

1046

1047 The \hgcmd{qdelete} command removes the entry for a patch from the

1048 \sfilename{series} file in the \sdirname{.hg/patches} directory. It

1049 does not pop the patch if the patch is already applied. By default,

1050 it does not delete the patch file; use the \hgopt{qdel}{-f} option to

1051 do that.

1052

1053 Options:

1054 \begin{itemize}

1055 \item[\hgopt{qdel}{-f}] Delete the patch file.

1056 \end{itemize}

1057

1058 \subsection{\hgcmd{qdiff}---print a diff of the topmost applied patch}

1059

1060 The \hgcmd{qdiff} command prints a diff of the topmost applied patch.

1061 It is equivalent to \hgcmdargs{diff}{-r-2:-1}.

1062

1063 \subsection{\hgcmd{qfold}---merge (``fold'') several patches into one}

1064

1065 The \hgcmd{qfold} command merges multiple patches into the topmost

1066 applied patch, so that the topmost applied patch makes the union of

1067 all of the changes in the patches in question.

1068

1069 The patches to fold must not be applied; \hgcmd{qfold} will exit with

1070 an error if any is. The order in which patches are folded is

1071 significant; \hgcmdargs{qfold}{a b} means ``apply the current topmost

1072 patch, followed by \texttt{a}, followed by \texttt{b}''.

1073

1074 The comments from the folded patches are appended to the comments of

1075 the destination patch, with each block of comments separated by three

1076 asterisk (``\texttt{*}'') characters. Use the \hgopt{qfold}{-e}

1077 option to edit the commit message for the combined patch/changeset

1078 after the folding has completed.

1079

1080 Options:

1081 \begin{itemize}

1082 \item[\hgopt{qfold}{-e}] Edit the commit message and patch description

1083 for the newly folded patch.

1084 \item[\hgopt{qfold}{-l}] Use the contents of the given file as the new

1085 commit message and patch description for the folded patch.

1086 \item[\hgopt{qfold}{-m}] Use the given text as the new commit message

1087 and patch description for the folded patch.

1088 \end{itemize}

1089

1090 \subsection{\hgcmd{qheader}---display the header/description of a patch}

1091

1092 The \hgcmd{qheader} command prints the header, or description, of a

1093 patch. By default, it prints the header of the topmost applied patch.

1094 Given an argument, it prints the header of the named patch.

1095

1096 \subsection{\hgcmd{qimport}---import a third-party patch into the queue}

1097

1098 The \hgcmd{qimport} command adds an entry for an external patch to the

1099 \sfilename{series} file, and copies the patch into the

1100 \sdirname{.hg/patches} directory. It adds the entry immediately after

1101 the topmost applied patch, but does not push the patch.

1102

1103 If the \sdirname{.hg/patches} directory is a repository,

1104 \hgcmd{qimport} automatically does an \hgcmd{add} of the imported

1105 patch.

1106

1107 \subsection{\hgcmd{qinit}---prepare a repository to work with MQ}

1108

1109 The \hgcmd{qinit} command prepares a repository to work with MQ. It

1110 creates a directory called \sdirname{.hg/patches}.

1111

1112 Options:

1113 \begin{itemize}

1114 \item[\hgopt{qinit}{-c}] Create \sdirname{.hg/patches} as a repository

1115 in its own right. Also creates a \sfilename{.hgignore} file that

1116 will ignore the \sfilename{status} file.

1117 \end{itemize}

1118

1119 When the \sdirname{.hg/patches} directory is a repository, the

1120 \hgcmd{qimport} and \hgcmd{qnew} commands automatically \hgcmd{add}

1121 new patches.

1122

1123 \subsection{\hgcmd{qnew}---create a new patch}

1124

1125 The \hgcmd{qnew} command creates a new patch. It takes one mandatory

1126 argument, the name to use for the patch file. The newly created patch

1127 is created empty by default. It is added to the \sfilename{series}

1128 file after the current topmost applied patch, and is immediately

1129 pushed on top of that patch.

1130

1131 If \hgcmd{qnew} finds modified files in the working directory, it will

1132 refuse to create a new patch unless the \hgopt{qnew}{-f} option is

1133 used (see below). This behaviour allows you to \hgcmd{qrefresh} your

1134 topmost applied patch before you apply a new patch on top of it.

1135

1136 Options:

1137 \begin{itemize}

1138 \item[\hgopt{qnew}{-f}] Create a new patch if the contents of the

1139 working directory are modified. Any outstanding modifications are

1140 added to the newly created patch, so after this command completes,

1141 the working directory will no longer be modified.

1142 \item[\hgopt{qnew}{-m}] Use the given text as the commit message.

1143 This text will be stored at the beginning of the patch file, before

1144 the patch data.

1145 \end{itemize}

1146

1147 \subsection{\hgcmd{qnext}---print the name of the next patch}

1148

1149 The \hgcmd{qnext} command prints the name name of the next patch in

1150 the \sfilename{series} file after the topmost applied patch. This

1151 patch will become the topmost applied patch if you run \hgcmd{qpush}.

1152

1153 \subsection{\hgcmd{qpop}---pop patches off the stack}

1154

1155 The \hgcmd{qpop} command removes applied patches from the top of the

1156 stack of applied patches. By default, it removes only one patch.

1157

1158 This command removes the changesets that represent the popped patches

1159 from the repository, and updates the working directory to undo the

1160 effects of the patches.

1161

1162 This command takes an optional argument, which it uses as the name or

1163 index of the patch to pop to. If given a name, it will pop patches

1164 until the named patch is the topmost applied patch. If given a

1165 number, \hgcmd{qpop} treats the number as an index into the entries in

1166 the series file, counting from zero (empty lines and lines containing

1167 only comments do not count). It pops patches until the patch

1168 identified by the given index is the topmost applied patch.

1169

1170 The \hgcmd{qpop} command does not read or write patches or the

1171 \sfilename{series} file. It is thus safe to \hgcmd{qpop} a patch that

1172 you have removed from the \sfilename{series} file, or a patch that you

1173 have renamed or deleted entirely. In the latter two cases, use the

1174 name of the patch as it was when you applied it.

1175

1176 By default, the \hgcmd{qpop} command will not pop any patches if the

1177 working directory has been modified. You can override this behaviour

1178 using the \hgopt{qpop}{-f} option, which reverts all modifications in

1179 the working directory.

1180

1181 Options:

1182 \begin{itemize}

1183 \item[\hgopt{qpop}{-a}] Pop all applied patches. This returns the

1184 repository to its state before you applied any patches.

1185 \item[\hgopt{qpop}{-f}] Forcibly revert any modifications to the

1186 working directory when popping.

1187 \item[\hgopt{qpop}{-n}] Pop a patch from the named queue.

1188 \end{itemize}

1189

1190 The \hgcmd{qpop} command removes one line from the end of the

1191 \sfilename{status} file for each patch that it pops.

1192

1193 \subsection{\hgcmd{qprev}---print the name of the previous patch}

1194

1195 The \hgcmd{qprev} command prints the name of the patch in the

1196 \sfilename{series} file that comes before the topmost applied patch.

1197 This will become the topmost applied patch if you run \hgcmd{qpop}.

1198

1199 \subsection{\hgcmd{qpush}---push patches onto the stack}

1200 \label{sec:mq:cmd:qpush}

1201

1202 The \hgcmd{qpush} command adds patches onto the applied stack. By

1203 default, it adds only one patch.

1204

1205 This command creates a new changeset to represent each applied patch,

1206 and updates the working directory to apply the effects of the patches.

1207

1208 The default data used when creating a changeset are as follows:

1209 \begin{itemize}

1210 \item The commit date and time zone are the current date and time

1211 zone. Because these data are used to compute the identity of a

1212 changeset, this means that if you \hgcmd{qpop} a patch and

1213 \hgcmd{qpush} it again, the changeset that you push will have a

1214 different identity than the changeset you popped.

1215 \item The author is the same as the default used by the \hgcmd{commit}

1216 command.

1217 \item The commit message is any text from the patch file that comes

1218 before the first diff header. If there is no such text, a default

1219 commit message is used that identifies the name of the patch.

1220 \end{itemize}

1221 If a patch contains a Mercurial patch header (XXX add link), the

1222 information in the patch header overrides these defaults.

1223

1224 Options:

1225 \begin{itemize}

1226 \item[\hgopt{qpush}{-a}] Push all unapplied patches from the

1227 \sfilename{series} file until there are none left to push.

1228 \item[\hgopt{qpush}{-l}] Add the name of the patch to the end

1229 of the commit message.

1230 \item[\hgopt{qpush}{-m}] If a patch fails to apply cleanly, use the

1231 entry for the patch in another saved queue to compute the parameters

1232 for a three-way merge, and perform a three-way merge using the

1233 normal Mercurial merge machinery. Use the resolution of the merge

1234 as the new patch content.

1235 \item[\hgopt{qpush}{-n}] Use the named queue if merging while pushing.

1236 \end{itemize}

1237

1238 The \hgcmd{qpush} command reads, but does not modify, the

1239 \sfilename{series} file. It appends one line to the \hgcmd{status}

1240 file for each patch that it pushes.

1241

1242 \subsection{\hgcmd{qrefresh}---update the topmost applied patch}

1243

1244 The \hgcmd{qrefresh} command updates the topmost applied patch. It

1245 modifies the patch, removes the old changeset that represented the

1246 patch, and creates a new changeset to represent the modified patch.

1247

1248 The \hgcmd{qrefresh} command looks for the following modifications:

1249 \begin{itemize}

1250 \item Changes to the commit message, i.e.~the text before the first

1251 diff header in the patch file, are reflected in the new changeset

1252 that represents the patch.

1253 \item Modifications to tracked files in the working directory are

1254 added to the patch.

1255 \item Changes to the files tracked using \hgcmd{add}, \hgcmd{copy},

1256 \hgcmd{remove}, or \hgcmd{rename}. Added files and copy and rename

1257 destinations are added to the patch, while removed files and rename

1258 sources are removed.

1259 \end{itemize}

1260

1261 Even if \hgcmd{qrefresh} detects no changes, it still recreates the

1262 changeset that represents the patch. This causes the identity of the

1263 changeset to differ from the previous changeset that identified the

1264 patch.

1265

1266 Options:

1267 \begin{itemize}

1268 \item[\hgopt{qrefresh}{-e}] Modify the commit and patch description,

1269 using the preferred text editor.

1270 \item[\hgopt{qrefresh}{-m}] Modify the commit message and patch

1271 description, using the given text.

1272 \item[\hgopt{qrefresh}{-l}] Modify the commit message and patch

1273 description, using text from the given file.

1274 \end{itemize}

1275

1276 \subsection{\hgcmd{qrename}---rename a patch}

1277

1278 The \hgcmd{qrename} command renames a patch, and changes the entry for

1279 the patch in the \sfilename{series} file.

1280

1281 With a single argument, \hgcmd{qrename} renames the topmost applied

1282 patch. With two arguments, it renames its first argument to its

1283 second.

1284

1285 \subsection{\hgcmd{qrestore}---restore saved queue state}

1286

1287 XXX No idea what this does.

1288

1289 \subsection{\hgcmd{qsave}---save current queue state}

1290

1291 XXX Likewise.

1292

1293 \subsection{\hgcmd{qseries}---print the entire patch series}

1294

1295 The \hgcmd{qseries} command prints the entire patch series from the

1296 \sfilename{series} file. It prints only patch names, not empty lines

1297 or comments. It prints in order from first to be applied to last.

1298

1299 \subsection{\hgcmd{qtop}---print the name of the current patch}

1300

1301 The \hgcmd{qtop} prints the name of the topmost currently applied

1302 patch.

1303

1304 \subsection{\hgcmd{qunapplied}---print patches not yet applied}

1305

1306 The \hgcmd{qunapplied} command prints the names of patches from the

1307 \sfilename{series} file that are not yet applied. It prints them in

1308 order from the next patch that will be pushed to the last.

1309

1310 \subsection{\hgcmd{qversion}}

1311

1312 The \hgcmd{qversion} command prints the version of MQ that is in use.

1313

1314 \subsection{\hgcmd{strip}---remove a revision and descendants}

1315

1316 The \hgcmd{strip} command removes a revision, and all of its

1317 descendants, from the repository. It undoes the effects of the

1318 removed revisions from the repository, and updates the working

1319 directory to the first parent of the removed revision.

1320

1321 The \hgcmd{strip} command saves a backup of the removed changesets in

1322 a bundle, so that they can be reapplied if removed in error.

1323

1324 Options:

1325 \begin{itemize}

1326 \item[\hgopt{strip}{-b}] Save unrelated changesets that are intermixed

1327 with the stripped changesets in the backup bundle.

1328 \item[\hgopt{strip}{-f}] If a branch has multiple heads, remove all

1329 heads. XXX This should be renamed, and use \texttt{-f} to strip revs

1330 when there are pending changes.

1331 \item[\hgopt{strip}{-n}] Do not save a backup bundle.

1332 \end{itemize}

1333

1334 \section{MQ file reference}

1335

1336 \subsection{The \sfilename{series} file}

1337

1338 The \sfilename{series} file contains a list of the names of all

1339 patches that MQ can apply. It is represented as a list of names, with

1340 one name saved per line. Leading and trailing white space in each

1341 line are ignored.

1342

1343 Lines may contain comments. A comment begins with the ``\texttt{\#}''

1344 character, and extends to the end of the line. Empty lines, and lines

1345 that contain only comments, are ignored.

1346

1347 You will often need to edit the \sfilename{series} file by hand, hence

1348 the support for comments and empty lines noted above. For example,

1349 you can comment out a patch temporarily, and \hgcmd{qpush} will skip

1350 over that patch when applying patches. You can also change the order

1351 in which patches are applied by reordering their entries in the

1352 \sfilename{series} file.

1353

1354 Placing the \sfilename{series} file under revision control is also

1355 supported; it is a good idea to place all of the patches that it

1356 refers to under revision control, as well. If you create a patch

1357 directory using the \hgopt{qinit}{-c} option to \hgcmd{qinit}, this

1358 will be done for you automatically.

1359

1360 \subsection{The \sfilename{status} file}

1361

1362 The \sfilename{status} file contains the names and changeset hashes of

1363 all patches that MQ currently has applied. Unlike the

1364 \sfilename{series} file, this file is not intended for editing. You

1365 should not place this file under revision control, or modify it in any

1366 way. It is used by MQ strictly for internal book-keeping.

1367

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