hgbook
annotate en/mq.tex @ 4:33a2e7b9978d
Make it possible to include example input and output from real programs.
Instead of having to cut and paste example text, the task is automated.
Instead of having to cut and paste example text, the task is automated.
author | Bryan O'Sullivan <bos@serpentine.com> |
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date | Sun Jun 25 22:04:50 2006 -0700 (2006-06-25) |
parents | 906d9021f9e5 |
children | 339e75288632 |
rev | line source |
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bos@1 | 1 \chapter{Managing change with Mercurial Queues} |
bos@1 | 2 \label{chap:mq} |
bos@1 | 3 |
bos@1 | 4 \section{The patch management problem} |
bos@1 | 5 \label{sec:mq:patch-mgmt} |
bos@1 | 6 |
bos@1 | 7 Here is a common scenario: you need to install a software package from |
bos@1 | 8 source, but you find a bug that you must fix in the source before you |
bos@1 | 9 can start using the package. You make your changes, forget about the |
bos@1 | 10 package for a while, and a few months later you need to upgrade to a |
bos@1 | 11 newer version of the package. If the newer version of the package |
bos@1 | 12 still has the bug, you must extract your fix from the older source |
bos@1 | 13 tree and apply it against the newer version. This is a tedious task, |
bos@1 | 14 and it's easy to make mistakes. |
bos@1 | 15 |
bos@1 | 16 This is a simple case of the ``patch management'' problem. You have |
bos@1 | 17 an ``upstream'' source tree that you can't change; you need to make |
bos@1 | 18 some local changes on top of the upstream tree; and you'd like to be |
bos@1 | 19 able to keep those changes separate, so that you can apply them to |
bos@1 | 20 newer versions of the upstream source. |
bos@1 | 21 |
bos@1 | 22 The patch management problem arises in many situations. Probably the |
bos@1 | 23 most visible is that a user of an open source software project will |
bos@3 | 24 contribute a bug fix or new feature to the project's maintainers in the |
bos@1 | 25 form of a patch. |
bos@1 | 26 |
bos@1 | 27 Distributors of operating systems that include open source software |
bos@1 | 28 often need to make changes to the packages they distribute so that |
bos@1 | 29 they will build properly in their environments. |
bos@1 | 30 |
bos@1 | 31 When you have few changes to maintain, it is easy to manage a single |
bos@1 | 32 patch using the standard \texttt{diff} and \texttt{patch} programs. |
bos@1 | 33 Once the number of changes grows, it starts to makes sense to maintain |
bos@1 | 34 patches as discrete ``chunks of work,'' so that for example a single |
bos@1 | 35 patch will contain only one bug fix (the patch might modify several |
bos@1 | 36 files, but it's doing ``only one thing''), and you may have a number |
bos@1 | 37 of such patches for different bugs you need fixed and local changes |
bos@3 | 38 you require. In this situation, if you submit a bug fix patch to the |
bos@1 | 39 upstream maintainers of a package and they include your fix in a |
bos@1 | 40 subsequent release, you can simply drop that single patch when you're |
bos@1 | 41 updating to the newer release. |
bos@1 | 42 |
bos@1 | 43 Maintaining a single patch against an upstream tree is a little |
bos@1 | 44 tedious and error-prone, but not difficult. However, the complexity |
bos@1 | 45 of the problem grows rapidly as the number of patches you have to |
bos@1 | 46 maintain increases. With more than a tiny number of patches in hand, |
bos@1 | 47 understanding which ones you have applied and maintaining them moves |
bos@1 | 48 from messy to overwhelming. |
bos@1 | 49 |
bos@1 | 50 Fortunately, Mercurial includes a powerful extension, Mercurial Queues |
bos@1 | 51 (or simply ``MQ''), that massively simplifies the patch management |
bos@1 | 52 problem. |
bos@1 | 53 |
bos@1 | 54 \section{The prehistory of Mercurial Queues} |
bos@1 | 55 \label{sec:mq:history} |
bos@1 | 56 |
bos@1 | 57 During the late 1990s, several Linux kernel developers started to |
bos@1 | 58 maintain ``patch series'' that modified the behaviour of the Linux |
bos@1 | 59 kernel. Some of these series were focused on stability, some on |
bos@1 | 60 feature coverage, and others were more speculative. |
bos@1 | 61 |
bos@1 | 62 The sizes of these patch series grew rapidly. In 2002, Andrew Morton |
bos@1 | 63 published some shell scripts he had been using to automate the task of |
bos@1 | 64 managing his patch queues. Andrew was successfully using these |
bos@1 | 65 scripts to manage hundreds (sometimes thousands) of patches on top of |
bos@1 | 66 the Linux kernel. |
bos@1 | 67 |
bos@1 | 68 \subsection{A patchwork quilt} |
bos@1 | 69 \label{sec:mq:quilt} |
bos@1 | 70 |
bos@1 | 71 |
bos@1 | 72 In early 2003, Andreas Gruenbacher and Martin Quinson borrowed the |
bos@2 | 73 approach of Andrew's scripts and published a tool called ``patchwork |
bos@2 | 74 quilt''~\cite{web:quilt}, or simply ``quilt'' |
bos@2 | 75 (see~\cite{gruenbacher:2005} for a paper describing it). Because |
bos@2 | 76 quilt substantially automated patch management, it rapidly gained a |
bos@2 | 77 large following among open source software developers. |
bos@1 | 78 |
bos@1 | 79 Quilt manages a \emph{stack of patches} on top of a directory tree. |
bos@1 | 80 To begin, you tell quilt to manage a directory tree; it stores away |
bos@1 | 81 the names and contents of all files in the tree. To fix a bug, you |
bos@1 | 82 create a new patch (using a single command), edit the files you need |
bos@1 | 83 to fix, then ``refresh'' the patch. |
bos@1 | 84 |
bos@1 | 85 The refresh step causes quilt to scan the directory tree; it updates |
bos@1 | 86 the patch with all of the changes you have made. You can create |
bos@1 | 87 another patch on top of the first, which will track the changes |
bos@1 | 88 required to modify the tree from ``tree with one patch applied'' to |
bos@1 | 89 ``tree with two patches applied''. |
bos@1 | 90 |
bos@1 | 91 You can \emph{change} which patches are applied to the tree. If you |
bos@1 | 92 ``pop'' a patch, the changes made by that patch will vanish from the |
bos@1 | 93 directory tree. Quilt remembers which patches you have popped, |
bos@1 | 94 though, so you can ``push'' a popped patch again, and the directory |
bos@1 | 95 tree will be restored to contain the modifications in the patch. Most |
bos@1 | 96 importantly, you can run the ``refresh'' command at any time, and the |
bos@1 | 97 topmost applied patch will be updated. This means that you can, at |
bos@1 | 98 any time, change both which patches are applied and what |
bos@1 | 99 modifications those patches make. |
bos@1 | 100 |
bos@1 | 101 Quilt knows nothing about revision control tools, so it works equally |
bos@3 | 102 well on top of an unpacked tarball or a Subversion repository. |
bos@1 | 103 |
bos@1 | 104 \subsection{From patchwork quilt to Mercurial Queues} |
bos@1 | 105 \label{sec:mq:quilt-mq} |
bos@1 | 106 |
bos@1 | 107 In mid-2005, Chris Mason took the features of quilt and wrote an |
bos@1 | 108 extension that he called Mercurial Queues, which added quilt-like |
bos@1 | 109 behaviour to Mercurial. |
bos@1 | 110 |
bos@1 | 111 The key difference between quilt and MQ is that quilt knows nothing |
bos@1 | 112 about revision control systems, while MQ is \emph{integrated} into |
bos@1 | 113 Mercurial. Each patch that you push is represented as a Mercurial |
bos@1 | 114 changeset. Pop a patch, and the changeset goes away. |
bos@1 | 115 |
bos@1 | 116 This integration makes understanding patches and debugging their |
bos@1 | 117 effects \emph{enormously} easier. Since every applied patch has an |
bos@1 | 118 associated changeset, you can use \hgcmdargs{log}{\emph{filename}} to |
bos@1 | 119 see which changesets and patches affected a file. You can use the |
bos@1 | 120 \hgext{bisect} extension to binary-search through all changesets and |
bos@1 | 121 applied patches to see where a bug got introduced or fixed. You can |
bos@1 | 122 use the \hgcmd{annotate} command to see which changeset or patch |
bos@1 | 123 modified a particular line of a source file. And so on. |
bos@1 | 124 |
bos@1 | 125 Because quilt does not care about revision control tools, it is still |
bos@1 | 126 a tremendously useful piece of software to know about for situations |
bos@1 | 127 where you cannot use Mercurial and MQ. |
bos@2 | 128 \section{Getting started with Mercurial Queues} |
bos@2 | 129 \label{sec:mq:start} |
bos@1 | 130 |
bos@3 | 131 Because MQ is implemented as an extension, you must explicitly enable |
bos@3 | 132 before you can use it. (You don't need to download anything; MQ ships |
bos@3 | 133 with the standard Mercurial distribution.) To enable MQ, edit your |
bos@4 | 134 \tildefile{.hgrc} file, and add the lines in figure~\ref{ex:mq:config}. |
bos@2 | 135 |
bos@4 | 136 \begin{figure} |
bos@4 | 137 \begin{codesample4} |
bos@4 | 138 [extensions] |
bos@4 | 139 hgext.mq = |
bos@4 | 140 \end{codesample4} |
bos@4 | 141 \label{ex:mq:config} |
bos@4 | 142 \caption{Contents to add to \tildefile{.hgrc} to enable the MQ extension} |
bos@4 | 143 \end{figure} |
bos@3 | 144 |
bos@3 | 145 Once the extension is enabled, it will make a number of new commands |
bos@4 | 146 available. To verify that the extension is working, follow the |
bos@4 | 147 example in figure~\ref{ex:mq:enabled}. |
bos@3 | 148 |
bos@4 | 149 \begin{figure} |
bos@4 | 150 \interaction{mq.qinit-help.help} |
bos@4 | 151 \caption{How to verify that MQ is enabled} |
bos@4 | 152 \label{ex:mq:enabled} |
bos@4 | 153 \end{figure} |
bos@1 | 154 |
bos@1 | 155 %%% Local Variables: |
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bos@1 | 157 %%% TeX-master: "00book" |
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