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1 \chapter{Managing change with Mercurial Queues}
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2 \label{chap:mq}
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3
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4 \section{The patch management problem}
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5 \label{sec:mq:patch-mgmt}
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6
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7 Here is a common scenario: you need to install a software package from
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8 source, but you find a bug that you must fix in the source before you
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9 can start using the package. You make your changes, forget about the
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10 package for a while, and a few months later you need to upgrade to a
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11 newer version of the package. If the newer version of the package
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12 still has the bug, you must extract your fix from the older source
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13 tree and apply it against the newer version. This is a tedious task,
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14 and it's easy to make mistakes.
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15
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16 This is a simple case of the ``patch management'' problem. You have
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17 an ``upstream'' source tree that you can't change; you need to make
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18 some local changes on top of the upstream tree; and you'd like to be
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19 able to keep those changes separate, so that you can apply them to
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20 newer versions of the upstream source.
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21
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22 The patch management problem arises in many situations. Probably the
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23 most visible is that a user of an open source software project will
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24 contribute a bug fix or new feature to the project's maintainers in the
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25 form of a patch.
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26
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27 Distributors of operating systems that include open source software
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28 often need to make changes to the packages they distribute so that
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29 they will build properly in their environments.
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30
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31 When you have few changes to maintain, it is easy to manage a single
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32 patch using the standard \texttt{diff} and \texttt{patch} programs.
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33 Once the number of changes grows, it starts to makes sense to maintain
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34 patches as discrete ``chunks of work,'' so that for example a single
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35 patch will contain only one bug fix (the patch might modify several
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36 files, but it's doing ``only one thing''), and you may have a number
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37 of such patches for different bugs you need fixed and local changes
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38 you require. In this situation, if you submit a bug fix patch to the
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39 upstream maintainers of a package and they include your fix in a
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40 subsequent release, you can simply drop that single patch when you're
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41 updating to the newer release.
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42
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43 Maintaining a single patch against an upstream tree is a little
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44 tedious and error-prone, but not difficult. However, the complexity
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45 of the problem grows rapidly as the number of patches you have to
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46 maintain increases. With more than a tiny number of patches in hand,
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47 understanding which ones you have applied and maintaining them moves
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48 from messy to overwhelming.
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49
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50 Fortunately, Mercurial includes a powerful extension, Mercurial Queues
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51 (or simply ``MQ''), that massively simplifies the patch management
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52 problem.
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53
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54 \section{The prehistory of Mercurial Queues}
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55 \label{sec:mq:history}
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56
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57 During the late 1990s, several Linux kernel developers started to
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58 maintain ``patch series'' that modified the behaviour of the Linux
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59 kernel. Some of these series were focused on stability, some on
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60 feature coverage, and others were more speculative.
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61
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62 The sizes of these patch series grew rapidly. In 2002, Andrew Morton
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63 published some shell scripts he had been using to automate the task of
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64 managing his patch queues. Andrew was successfully using these
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65 scripts to manage hundreds (sometimes thousands) of patches on top of
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66 the Linux kernel.
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67
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68 \subsection{A patchwork quilt}
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69 \label{sec:mq:quilt}
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70
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71
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72 In early 2003, Andreas Gruenbacher and Martin Quinson borrowed the
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73 approach of Andrew's scripts and published a tool called ``patchwork
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74 quilt''~\cite{web:quilt}, or simply ``quilt''
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75 (see~\cite{gruenbacher:2005} for a paper describing it). Because
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76 quilt substantially automated patch management, it rapidly gained a
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77 large following among open source software developers.
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78
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79 Quilt manages a \emph{stack of patches} on top of a directory tree.
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80 To begin, you tell quilt to manage a directory tree; it stores away
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81 the names and contents of all files in the tree. To fix a bug, you
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82 create a new patch (using a single command), edit the files you need
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83 to fix, then ``refresh'' the patch.
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84
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85 The refresh step causes quilt to scan the directory tree; it updates
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86 the patch with all of the changes you have made. You can create
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87 another patch on top of the first, which will track the changes
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88 required to modify the tree from ``tree with one patch applied'' to
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89 ``tree with two patches applied''.
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90
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91 You can \emph{change} which patches are applied to the tree. If you
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92 ``pop'' a patch, the changes made by that patch will vanish from the
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93 directory tree. Quilt remembers which patches you have popped,
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94 though, so you can ``push'' a popped patch again, and the directory
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95 tree will be restored to contain the modifications in the patch. Most
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96 importantly, you can run the ``refresh'' command at any time, and the
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97 topmost applied patch will be updated. This means that you can, at
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98 any time, change both which patches are applied and what
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99 modifications those patches make.
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100
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101 Quilt knows nothing about revision control tools, so it works equally
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102 well on top of an unpacked tarball or a Subversion repository.
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103
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104 \subsection{From patchwork quilt to Mercurial Queues}
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105 \label{sec:mq:quilt-mq}
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106
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107 In mid-2005, Chris Mason took the features of quilt and wrote an
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108 extension that he called Mercurial Queues, which added quilt-like
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109 behaviour to Mercurial.
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110
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111 The key difference between quilt and MQ is that quilt knows nothing
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112 about revision control systems, while MQ is \emph{integrated} into
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113 Mercurial. Each patch that you push is represented as a Mercurial
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114 changeset. Pop a patch, and the changeset goes away.
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115
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116 This integration makes understanding patches and debugging their
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117 effects \emph{enormously} easier. Since every applied patch has an
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118 associated changeset, you can use \hgcmdargs{log}{\emph{filename}} to
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119 see which changesets and patches affected a file. You can use the
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120 \hgext{bisect} extension to binary-search through all changesets and
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121 applied patches to see where a bug got introduced or fixed. You can
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122 use the \hgcmd{annotate} command to see which changeset or patch
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123 modified a particular line of a source file. And so on.
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124
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125 Because quilt does not care about revision control tools, it is still
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126 a tremendously useful piece of software to know about for situations
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127 where you cannot use Mercurial and MQ.
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128 \section{Getting started with Mercurial Queues}
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129 \label{sec:mq:start}
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130
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131 Because MQ is implemented as an extension, you must explicitly enable
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132 before you can use it. (You don't need to download anything; MQ ships
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133 with the standard Mercurial distribution.) To enable MQ, edit your
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134 \tildefile{.hgrc} file, and add the lines in figure~\ref{ex:mq:config}.
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135
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136 \begin{figure}[h]
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137 \begin{codesample4}
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138 [extensions]
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139 hgext.mq =
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140 \end{codesample4}
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141 \label{ex:mq:config}
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142 \caption{Contents to add to \tildefile{.hgrc} to enable the MQ extension}
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143 \end{figure}
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144
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145 Once the extension is enabled, it will make a number of new commands
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146 available. To verify that the extension is working, you can use
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147 \hgcmd{help} to see if the \hgcmd{qinit} command is now available; see
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148 the example in figure~\ref{ex:mq:enabled}.
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149
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150 \begin{figure}[h]
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151 \interaction{mq.qinit-help.help}
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152 \caption{How to verify that MQ is enabled}
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153 \label{ex:mq:enabled}
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154 \end{figure}
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155
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156 You can use MQ with \emph{any} Mercurial repository, and its commands
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157 only operate within that repository. To get started, simply prepare
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158 the repository using the \hgcmd{qinit} command (see
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159 figure~\ref{ex:mq:qinit}). This command creates an empty directory
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160 called \filename{.hg/patches}, where MQ will keep its metadata. As
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161 with many Mercurial commands, the \hgcmd{qinit} command prints nothing
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162 if it succeeds.
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163
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164 \begin{figure}[h]
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165 \interaction{mq.tutorial.qinit}
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166 \caption{Preparing a repository for use with MQ}
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167 \label{ex:mq:qinit}
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168 \end{figure}
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169
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170 \begin{figure}[h]
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171 \interaction{mq.tutorial.qnew}
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172 \caption{Creating a new patch}
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173 \label{ex:mq:qnew}
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174 \end{figure}
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175
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176 \subsection{Creating a new patch}
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177
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178 To begin work on a new patch, use the \hgcmd{qnew} command. This
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179 command takes one argument, the name of the patch to create. MQ will
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180 use this as the name of an actual file in the \filename{.hg/patches}
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181 directory, as you can see in figure~\ref{ex:mq:qnew}.
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182
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183 Also newly present in the \filename{.hg/patches} directory are two
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184 other files, \filename{series} and \filename{status}. The
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185 \filename{series} file lists all of the patches that MQ knows about
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186 for this repository, with one patch per line. Mercurial uses the
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187 \filename{status} file for internal book-keeping; it tracks all of the
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188 patches that MQ has \emph{applied} in this repository.
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189
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190 \begin{note}
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191 You may sometimes want to edit the \filename{series} file by hand;
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192 for example, to change the sequence in which some patches are
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193 applied. However, manually editing the \filename{status} file is
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194 almost always a bad idea, as it's easy to corrupt MQ's idea of what
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195 is happening.
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196 \end{note}
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197
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198 Once you have created your new patch, you can edit files in the
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199 working directory as you usually would. All of the normal Mercurial
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200 commands, such as \hgcmd{diff} and \hgcmd{annotate}, work exactly as
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201 they did before.
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202 \subsection{Refreshing a patch}
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203
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204 When you reach a point where you want to save your work, use the
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205 \hgcmd{qrefresh} command (figure~\ref{ex:mq:qnew}) to update the patch
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206 you are working on. This command folds the changes you have made in
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207 the working directory into your patch, and updates its corresponding
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208 changeset to contain those changes.
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209
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210 \begin{figure}[h]
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211 \interaction{mq.tutorial.qrefresh}
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212 \caption{Refreshing a patch}
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213 \label{ex:mq:qrefresh}
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214 \end{figure}
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215
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216 You can run \hgcmd{qrefresh} as often as you like, so it's a good way
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217 to ``checkpoint'' your work. Reefresh your patch at an opportune
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218 time; try an experiment; and if the experiment doesn't work out,
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219 \hgcmd{revert} your modifications back to the last time you refreshed.
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220
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221 \begin{figure}[h]
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222 \interaction{mq.tutorial.qrefresh2}
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223 \caption{Refresh a patch many times to accumulate changes}
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224 \label{ex:mq:qrefresh2}
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225 \end{figure}
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226
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227 \subsection{Stacking and tracking patches}
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228
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229 Once you have finished working on a patch, or need to work on another,
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230 you can use the \hgcmd{qnew} command again to create a new patch.
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231 Mercurial will apply this patch on top of your existing patch. See
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232 figure~\ref{ex:mq:qnew2} for an example. Notice that the patch
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233 contains the changes in our prior patch as part of its context (you
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234 can see this more clearly in the output of \hgcmd{annotate}).
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235
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236 \begin{figure}[h]
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237 \interaction{mq.tutorial.qnew2}
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238 \caption{Stacking a second patch on top of the first}
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239 \label{ex:mq:qnew2}
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240 \end{figure}
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241
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242 So far, with the exception of \hgcmd{qnew} and \hgcmd{qrefresh}, we've
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243 been careful to only use regular Mercurial commands. However, there
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244 are more ``natural'' commands you can use when thinking about patches
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245 with MQ, as illustrated in figure~\ref{ex:mq:qseries}:
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246
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247 \begin{itemize}
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248 \item The \hgcmd{qseries} command lists every patch that MQ knows
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249 about in this repository, from oldest to newest (most recently
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250 \emph{created}).
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251 \item The \hgcmd{qapplied} command lists every patch that MQ has
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252 \emph{applied} in this repository, again from oldest to newest (most
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253 recently applied).
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254 \end{itemize}
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255
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256 \begin{figure}[h]
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257 \interaction{mq.tutorial.qseries}
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258 \caption{Understanding the patch stack with \hgcmd{qseries} and
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259 \hgcmd{qapplied}}
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260 \label{ex:mq:qseries}
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261 \end{figure}
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262
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263 \subsection{Manipulating the patch stack}
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264
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265 The previous discussion implied that there must be a difference
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266 between ``known'' and ``applied'' patches, and there is. MQ can
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267 manage a patch without it being applied in the repository.
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268
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269 An \emph{applied} patch has a corresponding changeset in the
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270 repository, and the effects of the patch and changeset are visible in
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271 the working directory. You can undo the application of a patch using
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272 the \hgcmd{qpop} command. MQ still \emph{knows about} a popped patch,
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273 but it no longer has a corresponding changeset in the repository, and
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274 the working directory does not contain the changes made by the patch.
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275
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276 \begin{figure}[h]
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277 \interaction{mq.tutorial.qpop}
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278 \caption{Modifying the stack of applied patches}
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279 \label{ex:mq:qpop}
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280 \end{figure}
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281
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282 You can reapply an unapplied, or popped, patch using the \hgcmd{qpush}
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283 command. This creates a new changeset to correspond to the patch, and
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284 the patch's changes once again become present in the working
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285 directory. See figure~\ref{ex:mq:qpop} for examples of \hgcmd{qpop}
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286 and \hgcmd{qpush} in action. Notice that once we have popped a patch
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287 or two patches, the output of \hgcmd{qseries} remains the same, while
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288 that of \hgcmd{qapplied} has changed.
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289
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290 \begin{figure}
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291 \centering
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292 \grafix{mq-stack}
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293 \caption{Applied and unapplied patches in the MQ patch stack}
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294 \label{fig:mq:stack}
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295 \end{figure}
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296
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297 MQ does not limit you to pushing or popping one patch. You can have
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298 no patches, all of them, or any number in between applied at some
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299 point in time.
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300
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301 %%% Local Variables:
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302 %%% mode: latex
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303 %%% TeX-master: "00book"
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304 %%% End:
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