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1 \chapter{Finding and fixing your mistakes}
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2 \label{chap:undo}
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3
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4 To err might be human, but to really handle the consequences well
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5 takes a top-notch revision control system. In this chapter, we'll
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6 discuss some of the techniques you can use when you find that a
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7 problem has crept into your project. Mercurial has some highly
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8 capable features that will help you to isolate the sources of
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9 problems, and to handle them appropriately.
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10
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11 \section{Erasing local history}
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12
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13 \subsection{The accidental commit}
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14
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15 I have the occasional but persistent problem of typing rather more
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16 quickly than I can think, which sometimes results in me committing a
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17 changeset that is either incomplete or plain wrong. In my case, the
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18 usual kind of incomplete changeset is one in which I've created a new
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19 source file, but forgotten to \hgcmd{add} it. A ``plain wrong''
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20 changeset is not as common, but no less annoying.
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21
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22 \subsection{Rolling back a transaction}
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23 \label{sec:undo:rollback}
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24
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25 In section~\ref{sec:concepts:txn}, I mentioned that Mercurial treats
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26 each modification of a repository as a \emph{transaction}. Every time
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27 you commit a changeset or pull changes from another repository,
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28 Mercurial remembers what you did. You can undo, or \emph{roll back},
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29 exactly one of these actions using the \hgcmd{rollback} command. (See
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30 section~\ref{sec:undo:rollback-after-push} for an important caveat
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31 about the use of this command.)
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32
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33 Here's a mistake that I often find myself making: committing a change
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34 in which I've created a new file, but forgotten to \hgcmd{add} it.
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35 \interaction{rollback.commit}
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36 Looking at the output of \hgcmd{status} after the commit immediately
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37 confirms the error.
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38 \interaction{rollback.status}
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39 The commit captured the changes to the file \filename{a}, but not the
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40 new file \filename{b}. If I were to push this changeset to a
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41 repository that I shared with a colleague, the chances are high that
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42 something in \filename{a} would refer to \filename{b}, which would not
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43 be present in their repository when they pulled my changes. I would
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44 thus become the object of some indignation.
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45
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46 However, luck is with me---I've caught my error before I pushed the
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47 changeset. I use the \hgcmd{rollback} command, and Mercurial makes
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48 that last changeset vanish.
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49 \interaction{rollback.rollback}
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50 Notice that the changeset is no longer present in the repository's
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51 history, and the working directory once again thinks that the file
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52 \filename{a} is modified. The commit and rollback have left the
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53 working directory exactly as it was prior to the commit; the changeset
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54 has been completely erased. I can now safely \hgcmd{add} the file
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55 \filename{b}, and rerun my commit.
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56 \interaction{rollback.add}
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57
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58 \subsection{The erroneous pull}
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59
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60 It's common practice with Mercurial to maintain separate development
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61 branches of a project in different repositories. Your development
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62 team might have one shared repository for your project's ``0.9''
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63 release, and another, containing different changes, for the ``1.0''
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64 release.
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65
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66 Given this, you can imagine that the consequences could be messy if
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67 you had a local ``0.9'' repository, and accidentally pulled changes
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68 from the shared ``1.0'' repository into it. At worst, you could be
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69 paying insufficient attention, and push those changes into the shared
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70 ``0.9'' tree, confusing your entire team (but don't worry, we'll
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71 return to this horror scenario later). However, it's more likely that
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72 you'll notice immediately, because Mercurial will display the URL it's
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73 pulling from, or you will see it pull a suspiciously large number of
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74 changes into the repository.
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75
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76 The \hgcmd{rollback} command will work nicely to expunge all of the
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77 changesets that you just pulled. Mercurial groups all changes from
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78 one \hgcmd{pull} into a single transaction, so one \hgcmd{rollback} is
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79 all you need to undo this mistake.
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80
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81 \subsection{Rolling back is useless once you've pushed}
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82 \label{sec:undo:rollback-after-push}
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83
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84 The value of the \hgcmd{rollback} command drops to zero once you've
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85 pushed your changes to another repository. Rolling back a change
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86 makes it disappear entirely, but \emph{only} in the repository in
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87 which you perform the \hgcmd{rollback}. Because a rollback eliminates
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88 history, there's no way for the disappearance of a change to propagate
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89 between repositories.
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90
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91 If you've pushed a change to another repository---particularly if it's
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92 a shared repository---it has essentially ``escaped into the wild,''
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93 and you'll have to recover from your mistake in a different way. What
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94 will happen if you push a changeset somewhere, then roll it back, then
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95 pull from the repository you pushed to, is that the changeset will
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96 reappear in your repository.
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97
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98 (If you absolutely know for sure that the change you want to roll back
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99 is the most recent change in the repository that you pushed to,
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100 \emph{and} you know that nobody else could have pulled it from that
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101 repository, you can roll back the changeset there, too, but you really
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102 should really not rely on this working reliably. If you do this,
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103 sooner or later a change really will make it into a repository that
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104 you don't directly control (or have forgotten about), and come back to
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105 bite you.)
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106
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107 \subsection{You can only roll back once}
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108
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109 Mercurial stores exactly one transaction in its transaction log; that
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110 transaction is the most recent one that occurred in the repository.
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111 This means that you can only roll back one transaction. If you expect
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112 to be able to roll back one transaction, then its predecessor, this is
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113 not the behaviour you will get.
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114 \interaction{rollback.twice}
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115 Once you've rolled back one transaction in a repository, you can't
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116 roll back again in that repository until you perform another commit or
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117 pull.
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118
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119 \section{Reverting the mistaken change}
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120
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121 If you make a modification to a file, and decide that you really
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122 didn't want to change the file at all, and you haven't yet committed
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123 your changes, the \hgcmd{revert} command is the one you'll need. It
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124 looks at the changeset that's the parent of the working directory, and
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125 restores the contents of the file to their state as of that changeset.
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126 (That's a long-winded way of saying that, in the normal case, it
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127 undoes your modifications.)
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128
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129 Let's illustrate how the \hgcmd{revert} command works with yet another
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130 small example. We'll begin by modifying a file that Mercurial is
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131 already tracking.
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132 \interaction{daily.revert.modify}
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133 If we don't want that change, we can simply \hgcmd{revert} the file.
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134 \interaction{daily.revert.unmodify}
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135 The \hgcmd{revert} command provides us with an extra degree of safety
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136 by saving our modified file with a \filename{.orig} extension.
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137 \interaction{daily.revert.status}
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138
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139 Here is a summary of the cases that the \hgcmd{revert} command can
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140 deal with. We will describe each of these in more detail in the
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141 section that follows.
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142 \begin{itemize}
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143 \item If you modify a file, it will restore the file to its unmodified
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144 state.
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145 \item If you \hgcmd{add} a file, it will undo the ``added'' state of
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146 the file, but leave the file itself untouched.
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147 \item If you delete a file without telling Mercurial, it will restore
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148 the file to its unmodified contents.
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149 \item If you use the \hgcmd{remove} command to remove a file, it will
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150 undo the ``removed'' state of the file, and restore the file to its
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151 unmodified contents.
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152 \end{itemize}
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153
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154 \subsection{File management errors}
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155 \label{sec:undo:mgmt}
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156
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157 The \hgcmd{revert} command is useful for more than just modified
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158 files. It lets you reverse the results of all of Mercurial's file
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159 management commands---\hgcmd{add}, \hgcmd{remove}, and so on.
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160
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161 If you \hgcmd{add} a file, then decide that in fact you don't want
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162 Mercurial to track it, use \hgcmd{revert} to undo the add. Don't
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163 worry; Mercurial will not modify the file in any way. It will just
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164 ``unmark'' the file.
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165 \interaction{daily.revert.add}
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166
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167 Similarly, if you ask Mercurial to \hgcmd{remove} a file, you can use
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168 \hgcmd{revert} to restore it to the contents it had as of the parent
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169 of the working directory.
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170 \interaction{daily.revert.remove}
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171 This works just as well for a file that you deleted by hand, without
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172 telling Mercurial (recall that in Mercurial terminology, this kind of
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173 file is called ``missing'').
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174 \interaction{daily.revert.missing}
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175
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176 If you revert a \hgcmd{copy}, the copied-to file remains in your
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177 working directory afterwards, untracked. Since a copy doesn't affect
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178 the copied-from file in any way, Mercurial doesn't do anything with
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179 the copied-from file.
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180 \interaction{daily.revert.copy}
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181
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182 \subsubsection{A slightly special case: reverting a rename}
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183
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184 If you \hgcmd{rename} a file, there is one small detail that
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185 you should remember. When you \hgcmd{revert} a rename, it's not
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186 enough to provide the name of the renamed-to file, as you can see
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187 here.
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188 \interaction{daily.revert.rename}
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189 As you can see from the output of \hgcmd{status}, the renamed-to file
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190 is no longer identified as added, but the renamed-\emph{from} file is
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191 still removed! This is counter-intuitive (at least to me), but at
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192 least it's easy to deal with.
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193 \interaction{daily.revert.rename-orig}
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194 So remember, to revert a \hgcmd{rename}, you must provide \emph{both}
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195 the source and destination names.
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196
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197 (By the way, if you rename a file, then modify the renamed-to file,
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198 then revert both components of the rename, when Mercurial restores the
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199 file that was removed as part of the rename, it will be unmodified.
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200 If you need the modifications in the renamed-to file to show up in the
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201 renamed-from file, don't forget to copy them over.)
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202
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203 These fiddly aspects of reverting a rename arguably constitute a small
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204 bug in Mercurial.
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205
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206 \section{Dealing with committed changes}
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207
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208 Consider a case where you have committed a change $a$, and another
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209 change $b$ on top of it; you then realise that change $a$ was
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210 incorrect. Mercurial lets you ``back out'' an entire changeset
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211 automatically, and building blocks that let you reverse part of a
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212 changeset by hand.
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213
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214 Before you read this section, here's something to keep in mind: the
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215 \hgcmd{backout} command undoes changes by \emph{adding} history, not
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216 by modifying or erasing it. It's the right tool to use if you're
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217 fixing bugs, but not if you're trying to undo some change that has
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218 catastrophic consequences. To deal with those, see
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219 section~\ref{sec:undo:aaaiiieee}.
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220
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221 \subsection{Backing out a changeset}
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222
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223 The \hgcmd{backout} command lets you ``undo'' the effects of an entire
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224 changeset in an automated fashion. Because Mercurial's history is
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225 immutable, this command \emph{does not} get rid of the changeset you
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226 want to undo. Instead, it creates a new changeset that
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227 \emph{reverses} the effect of the to-be-undone changeset.
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228
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229 The operation of the \hgcmd{backout} command is a little intricate, so
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230 let's illustrate it with some examples. First, we'll create a
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231 repository with some simple changes.
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232 \interaction{backout.init}
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233
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234 The \hgcmd{backout} command takes a single changeset ID as its
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235 argument; this is the changeset to back out. Normally,
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236 \hgcmd{backout} will drop you into a text editor to write a commit
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237 message, so you can record why you're backing the change out. In this
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238 example, we provide a commit message on the command line using the
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239 \hgopt{backout}{-m} option.
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240
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241 \subsection{Backing out the tip changeset}
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242
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243 We're going to start by backing out the last changeset we committed.
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244 \interaction{backout.simple}
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245 You can see that the second line from \filename{myfile} is no longer
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246 present. Taking a look at the output of \hgcmd{log} gives us an idea
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247 of what the \hgcmd{backout} command has done.
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248 \interaction{backout.simple.log}
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249 Notice that the new changeset that \hgcmd{backout} has created is a
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250 child of the changeset we backed out. It's easier to see this in
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251 figure~\ref{fig:undo:backout}, which presents a graphical view of the
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252 change history. As you can see, the history is nice and linear.
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253
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254 \begin{figure}[htb]
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255 \centering
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256 \grafix{undo-simple}
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257 \caption{Backing out a change using the \hgcmd{backout} command}
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258 \label{fig:undo:backout}
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259 \end{figure}
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260
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261 \subsection{Backing out a non-tip change}
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262
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263 If you want to back out a change other than the last one you
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264 committed, pass the \hgopt{backout}{--merge} option to the
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265 \hgcmd{backout} command.
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266 \interaction{backout.non-tip.clone}
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267 This makes backing out any changeset a ``one-shot'' operation that's
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268 usually simple and fast.
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269 \interaction{backout.non-tip.backout}
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270
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271 If you take a look at the contents of \filename{myfile} after the
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272 backout finishes, you'll see that the first and third changes are
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273 present, but not the second.
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274 \interaction{backout.non-tip.cat}
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275
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276 As the graphical history in figure~\ref{fig:undo:backout-non-tip}
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277 illustrates, Mercurial actually commits \emph{two} changes in this
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278 kind of situation (the box-shaped nodes are the ones that Mercurial
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279 commits automatically). Before Mercurial begins the backout process,
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280 it first remembers what the current parent of the working directory
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281 is. It then backs out the target changeset, and commits that as a
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282 changeset. Finally, it merges back to the previous parent of the
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283 working directory, and commits the result of the merge.
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284
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285 \begin{figure}[htb]
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286 \centering
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287 \grafix{undo-non-tip}
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288 \caption{Automated backout of a non-tip change using the \hgcmd{backout} command}
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289 \label{fig:undo:backout-non-tip}
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290 \end{figure}
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291
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292 The result is that you end up ``back where you were'', only with some
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293 extra history that undoes the effect of the changeset you wanted to
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294 back out.
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295
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296 \subsubsection{Always use the \hgopt{backout}{--merge} option}
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297
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298 In fact, since the \hgopt{backout}{--merge} option will do the ``right
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299 thing'' whether or not the changeset you're backing out is the tip
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300 (i.e.~it won't try to merge if it's backing out the tip, since there's
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301 no need), you should \emph{always} use this option when you run the
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302 \hgcmd{backout} command.
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303
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304 \subsection{Gaining more control of the backout process}
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305
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306 While I've recommended that you always use the
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307 \hgopt{backout}{--merge} option when backing out a change, the
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308 \hgcmd{backout} command lets you decide how to merge a backout
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309 changeset. Taking control of the backout process by hand is something
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310 you will rarely need to do, but it can be useful to understand what
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311 the \hgcmd{backout} command is doing for you automatically. To
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312 illustrate this, let's clone our first repository, but omit the
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313 backout change that it contains.
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314
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315 \interaction{backout.manual.clone}
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316 As with our earlier example, We'll commit a third changeset, then back
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317 out its parent, and see what happens.
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318 \interaction{backout.manual.backout}
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319 Our new changeset is again a descendant of the changeset we backout
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320 out; it's thus a new head, \emph{not} a descendant of the changeset
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321 that was the tip. The \hgcmd{backout} command was quite explicit in
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322 telling us this.
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323 \interaction{backout.manual.log}
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324
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325 Again, it's easier to see what has happened by looking at a graph of
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326 the revision history, in figure~\ref{fig:undo:backout-manual}. This
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327 makes it clear that when we use \hgcmd{backout} to back out a change
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328 other than the tip, Mercurial adds a new head to the repository (the
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329 change it committed is box-shaped).
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330
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331 \begin{figure}[htb]
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332 \centering
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333 \grafix{undo-manual}
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334 \caption{Backing out a change using the \hgcmd{backout} command}
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335 \label{fig:undo:backout-manual}
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336 \end{figure}
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337
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338 After the \hgcmd{backout} command has completed, it leaves the new
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339 ``backout'' changeset as the parent of the working directory.
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340 \interaction{backout.manual.parents}
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341 Now we have two isolated sets of changes.
|
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342 \interaction{backout.manual.heads}
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343
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344 Let's think about what we expect to see as the contents of
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345 \filename{myfile} now. The first change should be present, because
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346 we've never backed it out. The second change should be missing, as
|
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347 that's the change we backed out. Since the history graph shows the
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348 third change as a separate head, we \emph{don't} expect to see the
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349 third change present in \filename{myfile}.
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350 \interaction{backout.manual.cat}
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351 To get the third change back into the file, we just do a normal merge
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352 of our two heads.
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353 \interaction{backout.manual.merge}
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354 Afterwards, the graphical history of our repository looks like
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355 figure~\ref{fig:undo:backout-manual-merge}.
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356
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357 \begin{figure}[htb]
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358 \centering
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359 \grafix{undo-manual-merge}
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360 \caption{Manually merging a backout change}
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361 \label{fig:undo:backout-manual-merge}
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362 \end{figure}
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363
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364 \subsection{Why \hgcmd{backout} works as it does}
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365
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366 Here's a brief description of how the \hgcmd{backout} command works.
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367 \begin{enumerate}
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368 \item It ensures that the working directory is ``clean'', i.e.~that
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369 the output of \hgcmd{status} would be empty.
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370 \item It remembers the current parent of the working directory. Let's
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371 call this changeset \texttt{orig}
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372 \item It does the equivalent of a \hgcmd{update} to sync the working
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373 directory to the changeset you want to back out. Let's call this
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374 changeset \texttt{backout}
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375 \item It finds the parent of that changeset. Let's call that
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376 changeset \texttt{parent}.
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377 \item For each file that the \texttt{backout} changeset affected, it
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378 does the equivalent of a \hgcmdargs{revert}{-r parent} on that file,
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379 to restore it to the contents it had before that changeset was
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380 committed.
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381 \item It commits the result as a new changeset. This changeset has
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382 \texttt{backout} as its parent.
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383 \item If you specify \hgopt{backout}{--merge} on the command line, it
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384 merges with \texttt{orig}, and commits the result of the merge.
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385 \end{enumerate}
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386
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387 An alternative way to implement the \hgcmd{backout} command would be
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388 to \hgcmd{export} the to-be-backed-out changeset as a diff, then use
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389 the \cmdopt{patch}{--reverse} option to the \command{patch} command to
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390 reverse the effect of the change without fiddling with the working
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391 directory. This sounds much simpler, but it would not work nearly as
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392 well.
|
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393
|
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394 The reason that \hgcmd{backout} does an update, a commit, a merge, and
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395 another commit is to give the merge machinery the best chance to do a
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396 good job when dealing with all the changes \emph{between} the change
|
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397 you're backing out and the current tip.
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398
|
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399 If you're backing out a changeset that's~100 revisions back in your
|
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400 project's history, the chances that the \command{patch} command will
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401 be able to apply a reverse diff cleanly are not good, because
|
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402 intervening changes are likely to have ``broken the context'' that
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403 \command{patch} uses to determine whether it can apply a patch (if
|
bos@125
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404 this sounds like gibberish, see \ref{sec:mq:patch} for a
|
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405 discussion of the \command{patch} command). Also, Mercurial's merge
|
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406 machinery will handle files and directories being renamed, permission
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407 changes, and modifications to binary files, none of which
|
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408 \command{patch} can deal with.
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409
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410 \section{Changes that should never have been}
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411 \label{sec:undo:aaaiiieee}
|
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412
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413 Most of the time, the \hgcmd{backout} command is exactly what you need
|
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414 if you want to undo the effects of a change. It leaves a permanent
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415 record of exactly what you did, both when committing the original
|
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416 changeset and when you cleaned up after it.
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417
|
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418 On rare occasions, though, you may find that you've committed a change
|
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419 that really should not be present in the repository at all. For
|
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420 example, it would be very unusual, and usually considered a mistake,
|
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421 to commit a software project's object files as well as its source
|
bos@126
|
422 files. Object files have almost no intrinsic value, and they're
|
bos@126
|
423 \emph{big}, so they increase the size of the repository and the amount
|
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|
424 of time it takes to clone or pull changes.
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425
|
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|
426 Before I discuss the options that you have if you commit a ``brown
|
bos@126
|
427 paper bag'' change (the kind that's so bad that you want to pull a
|
bos@126
|
428 brown paper bag over your head), let me first discuss some approaches
|
bos@126
|
429 that probably won't work.
|
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|
430
|
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431 Since Mercurial treats history as accumulative---every change builds
|
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|
432 on top of all changes that preceded it---you generally can't just make
|
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|
433 disastrous changes disappear. The one exception is when you've just
|
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|
434 committed a change, and it hasn't been pushed or pulled into another
|
bos@126
|
435 repository. That's when you can safely use the \hgcmd{rollback}
|
bos@126
|
436 command, as I detailed in section~\ref{sec:undo:rollback}.
|
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|
437
|
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|
438 After you've pushed a bad change to another repository, you
|
bos@126
|
439 \emph{could} still use \hgcmd{rollback} to make your local copy of the
|
bos@126
|
440 change disappear, but it won't have the consequences you want. The
|
bos@126
|
441 change will still be present in the remote repository, so it will
|
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|
442 reappear in your local repository the next time you pull.
|
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|
443
|
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|
444 If a situation like this arises, and you know which repositories your
|
bos@126
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445 bad change has propagated into, you can \emph{try} to get rid of the
|
bos@126
|
446 changeefrom \emph{every} one of those repositories. This is, of
|
bos@126
|
447 course, not a satisfactory solution: if you miss even a single
|
bos@126
|
448 repository while you're expunging, the change is still ``in the
|
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|
449 wild'', and could propagate further.
|
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|
450
|
bos@126
|
451 If you've committed one or more changes \emph{after} the change that
|
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|
452 you'd like to see disappear, your options are further reduced.
|
bos@126
|
453 Mercurial doesn't provide a way to ``punch a hole'' in history,
|
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|
454 leaving changesets intact.
|
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|
455
|
bos@129
|
456 XXX This needs filling out. The \texttt{hg-replay} script in the
|
bos@129
|
457 \texttt{examples} directory works, but doesn't handle merge
|
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|
458 changesets. Kind of an important omission.
|
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459
|
bos@201
|
460 \subsection{Protect yourself from ``escaped'' changes}
|
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461
|
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462 If you've committed some changes to your local repository and they've
|
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|
463 been pushed or pulled somewhere else, this isn't necessarily a
|
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|
464 disaster. You can protect yourself ahead of time against some classes
|
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|
465 of bad changeset. This is particularly easy if your team usually
|
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|
466 pulls changes from a central repository.
|
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|
467
|
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|
468 By configuring some hooks on that repository to validate incoming
|
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|
469 changesets (see chapter~\ref{chap:hook}), you can automatically
|
bos@201
|
470 prevent some kinds of bad changeset from being pushed to the central
|
bos@201
|
471 repository at all. With such a configuration in place, some kinds of
|
bos@201
|
472 bad changeset will naturally tend to ``die out'' because they can't
|
bos@201
|
473 propagate into the central repository. Better yet, this happens
|
bos@201
|
474 without any need for explicit intervention.
|
bos@201
|
475
|
bos@201
|
476 For instance, an incoming change hook that verifies that a changeset
|
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|
477 will actually compile can prevent people from inadvertantly ``breaking
|
bos@201
|
478 the build''.
|
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|
479
|
bos@130
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480 \section{Finding the source of a bug}
|
bos@200
|
481 \label{sec:undo:bisect}
|
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482
|
bos@130
|
483 While it's all very well to be able to back out a changeset that
|
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|
484 introduced a bug, this requires that you know which changeset to back
|
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|
485 out. Mercurial provides an invaluable extension, called
|
bos@130
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486 \hgext{bisect}, that helps you to automate this process and accomplish
|
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|
487 it very efficiently.
|
bos@130
|
488
|
bos@130
|
489 The idea behind the \hgext{bisect} extension is that a changeset has
|
bos@130
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490 introduced some change of behaviour that you can identify with a
|
bos@130
|
491 simple binary test. You don't know which piece of code introduced the
|
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|
492 change, but you know how to test for the presence of the bug. The
|
bos@130
|
493 \hgext{bisect} extension uses your test to direct its search for the
|
bos@130
|
494 changeset that introduced the code that caused the bug.
|
bos@130
|
495
|
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496 Here are a few scenarios to help you understand how you might apply this
|
bos@130
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497 extension.
|
bos@130
|
498 \begin{itemize}
|
bos@130
|
499 \item The most recent version of your software has a bug that you
|
bos@130
|
500 remember wasn't present a few weeks ago, but you don't know when it
|
bos@130
|
501 was introduced. Here, your binary test checks for the presence of
|
bos@130
|
502 that bug.
|
bos@130
|
503 \item You fixed a bug in a rush, and now it's time to close the entry
|
bos@130
|
504 in your team's bug database. The bug database requires a changeset
|
bos@130
|
505 ID when you close an entry, but you don't remember which changeset
|
bos@130
|
506 you fixed the bug in. Once again, your binary test checks for the
|
bos@130
|
507 presence of the bug.
|
bos@130
|
508 \item Your software works correctly, but runs~15\% slower than the
|
bos@130
|
509 last time you measured it. You want to know which changeset
|
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|
510 introduced the performance regression. In this case, your binary
|
bos@130
|
511 test measures the performance of your software, to see whether it's
|
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|
512 ``fast'' or ``slow''.
|
bos@130
|
513 \item The sizes of the components of your project that you ship
|
bos@130
|
514 exploded recently, and you suspect that something changed in the way
|
bos@130
|
515 you build your project.
|
bos@130
|
516 \end{itemize}
|
bos@130
|
517
|
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|
518 From these examples, it should be clear that the \hgext{bisect}
|
bos@130
|
519 extension is not useful only for finding the sources of bugs. You can
|
bos@130
|
520 use it to find any ``emergent property'' of a repository (anything
|
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|
521 that you can't find from a simple text search of the files in the
|
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|
522 tree) for which you can write a binary test.
|
bos@130
|
523
|
bos@130
|
524 We'll introduce a little bit of terminology here, just to make it
|
bos@130
|
525 clear which parts of the search process are your responsibility, and
|
bos@130
|
526 which are Mercurial's. A \emph{test} is something that \emph{you} run
|
bos@130
|
527 when \hgext{bisect} chooses a changeset. A \emph{probe} is what
|
bos@130
|
528 \hgext{bisect} runs to tell whether a revision is good. Finally,
|
bos@130
|
529 we'll use the word ``bisect'', as both a noun and a verb, to stand in
|
bos@130
|
530 for the phrase ``search using the \hgext{bisect} extension''.
|
bos@130
|
531
|
bos@130
|
532 One simple way to automate the searching process would be simply to
|
bos@130
|
533 probe every changeset. However, this scales poorly. If it took ten
|
bos@130
|
534 minutes to test a single changeset, and you had 10,000 changesets in
|
bos@130
|
535 your repository, the exhaustive approach would take on average~35
|
bos@130
|
536 \emph{days} to find the changeset that introduced a bug. Even if you
|
bos@130
|
537 knew that the bug was introduced by one of the last 500 changesets,
|
bos@130
|
538 and limited your search to those, you'd still be looking at over 40
|
bos@130
|
539 hours to find the changeset that introduced your bug.
|
bos@130
|
540
|
bos@130
|
541 What the \emph{bisect} extension does is use its knowledge of the
|
bos@130
|
542 ``shape'' of your project's revision history to perform a search in
|
bos@130
|
543 time proportional to the \emph{logarithm} of the number of changesets
|
bos@130
|
544 to check (the kind of search it performs is called a dichotomic
|
bos@130
|
545 search). With this approach, searching through 10,000 changesets will
|
bos@130
|
546 take less than two hours, even at ten minutes per test. Limit your
|
bos@130
|
547 search to the last 500 changesets, and it will take less than an hour.
|
bos@130
|
548
|
bos@130
|
549 The \hgext{bisect} extension is aware of the ``branchy'' nature of a
|
bos@130
|
550 Mercurial project's revision history, so it has no problems dealing
|
bos@130
|
551 with branches, merges, or multiple heads in a repoository. It can
|
bos@130
|
552 prune entire branches of history with a single probe, which is how it
|
bos@130
|
553 operates so efficiently.
|
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|
554
|
bos@130
|
555 \subsection{Using the \hgext{bisect} extension}
|
bos@130
|
556
|
bos@130
|
557 Here's an example of \hgext{bisect} in action. To keep the core of
|
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|
558 Mercurial simple, \hgext{bisect} is packaged as an extension; this
|
bos@130
|
559 means that it won't be present unless you explicitly enable it. To do
|
bos@130
|
560 this, edit your \hgrc\ and add the following section header (if it's
|
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|
561 not already present):
|
bos@130
|
562 \begin{codesample2}
|
bos@130
|
563 [extensions]
|
bos@130
|
564 \end{codesample2}
|
bos@130
|
565 Then add a line to this section to enable the extension:
|
bos@130
|
566 \begin{codesample2}
|
bos@130
|
567 hbisect =
|
bos@130
|
568 \end{codesample2}
|
bos@130
|
569 \begin{note}
|
bos@130
|
570 That's right, there's a ``\texttt{h}'' at the front of the name of
|
bos@130
|
571 the \hgext{bisect} extension. The reason is that Mercurial is
|
bos@130
|
572 written in Python, and uses a standard Python package called
|
bos@130
|
573 \texttt{bisect}. If you omit the ``\texttt{h}'' from the name
|
bos@130
|
574 ``\texttt{hbisect}'', Mercurial will erroneously find the standard
|
bos@130
|
575 Python \texttt{bisect} package, and try to use it as a Mercurial
|
bos@130
|
576 extension. This won't work, and Mercurial will crash repeatedly
|
bos@130
|
577 until you fix the spelling in your \hgrc. Ugh.
|
bos@130
|
578 \end{note}
|
bos@130
|
579
|
bos@130
|
580 Now let's create a repository, so that we can try out the
|
bos@130
|
581 \hgext{bisect} extension in isolation.
|
bos@130
|
582 \interaction{bisect.init}
|
bos@130
|
583 We'll simulate a project that has a bug in it in a simple-minded way:
|
bos@130
|
584 create trivial changes in a loop, and nominate one specific change
|
bab@267
|
585 that will have the ``bug''. This loop creates 35 changesets, each
|
bos@130
|
586 adding a single file to the repository. We'll represent our ``bug''
|
bos@130
|
587 with a file that contains the text ``i have a gub''.
|
bos@130
|
588 \interaction{bisect.commits}
|
bos@130
|
589
|
bos@130
|
590 The next thing that we'd like to do is figure out how to use the
|
bos@130
|
591 \hgext{bisect} extension. We can use Mercurial's normal built-in help
|
bos@130
|
592 mechanism for this.
|
bos@130
|
593 \interaction{bisect.help}
|
bos@130
|
594
|
bos@130
|
595 The \hgext{bisect} extension works in steps. Each step proceeds as follows.
|
bos@130
|
596 \begin{enumerate}
|
bos@130
|
597 \item You run your binary test.
|
bos@130
|
598 \begin{itemize}
|
bos@130
|
599 \item If the test succeeded, you tell \hgext{bisect} by running the
|
bos@130
|
600 \hgcmdargs{bisect}{good} command.
|
bos@130
|
601 \item If it failed, use the \hgcmdargs{bisect}{bad} command to let
|
bos@130
|
602 the \hgext{bisect} extension know.
|
bos@130
|
603 \end{itemize}
|
bos@130
|
604 \item The extension uses your information to decide which changeset to
|
bos@130
|
605 test next.
|
bos@130
|
606 \item It updates the working directory to that changeset, and the
|
bos@130
|
607 process begins again.
|
bos@130
|
608 \end{enumerate}
|
bos@130
|
609 The process ends when \hgext{bisect} identifies a unique changeset
|
bos@130
|
610 that marks the point where your test transitioned from ``succeeding''
|
bos@130
|
611 to ``failing''.
|
bos@130
|
612
|
bos@130
|
613 To start the search, we must run the \hgcmdargs{bisect}{init} command.
|
bos@130
|
614 \interaction{bisect.search.init}
|
bos@130
|
615
|
bos@130
|
616 In our case, the binary test we use is simple: we check to see if any
|
bos@130
|
617 file in the repository contains the string ``i have a gub''. If it
|
bos@130
|
618 does, this changeset contains the change that ``caused the bug''. By
|
bos@130
|
619 convention, a changeset that has the property we're searching for is
|
bos@130
|
620 ``bad'', while one that doesn't is ``good''.
|
bos@130
|
621
|
bos@130
|
622 Most of the time, the revision to which the working directory is
|
bos@130
|
623 synced (usually the tip) already exhibits the problem introduced by
|
bos@130
|
624 the buggy change, so we'll mark it as ``bad''.
|
bos@130
|
625 \interaction{bisect.search.bad-init}
|
bos@130
|
626
|
bos@130
|
627 Our next task is to nominate a changeset that we know \emph{doesn't}
|
bos@130
|
628 have the bug; the \hgext{bisect} extension will ``bracket'' its search
|
bos@130
|
629 between the first pair of good and bad changesets. In our case, we
|
bos@130
|
630 know that revision~10 didn't have the bug. (I'll have more words
|
bos@130
|
631 about choosing the first ``good'' changeset later.)
|
bos@130
|
632 \interaction{bisect.search.good-init}
|
bos@130
|
633
|
bos@130
|
634 Notice that this command printed some output.
|
bos@130
|
635 \begin{itemize}
|
bos@130
|
636 \item It told us how many changesets it must consider before it can
|
bos@130
|
637 identify the one that introduced the bug, and how many tests that
|
bos@130
|
638 will require.
|
bos@130
|
639 \item It updated the working directory to the next changeset to test,
|
bos@130
|
640 and told us which changeset it's testing.
|
bos@130
|
641 \end{itemize}
|
bos@130
|
642
|
bos@130
|
643 We now run our test in the working directory. We use the
|
bos@130
|
644 \command{grep} command to see if our ``bad'' file is present in the
|
bos@130
|
645 working directory. If it is, this revision is bad; if not, this
|
bos@130
|
646 revision is good.
|
bos@131
|
647 \interaction{bisect.search.step1}
|
bos@130
|
648
|
bos@130
|
649 This test looks like a perfect candidate for automation, so let's turn
|
bos@130
|
650 it into a shell function.
|
bos@131
|
651 \interaction{bisect.search.mytest}
|
bos@130
|
652 We can now run an entire test step with a single command,
|
bos@130
|
653 \texttt{mytest}.
|
bos@131
|
654 \interaction{bisect.search.step2}
|
bos@130
|
655 A few more invocations of our canned test step command, and we're
|
bos@130
|
656 done.
|
bos@131
|
657 \interaction{bisect.search.rest}
|
bos@130
|
658
|
bos@130
|
659 Even though we had~40 changesets to search through, the \hgext{bisect}
|
bos@130
|
660 extension let us find the changeset that introduced our ``bug'' with
|
bos@130
|
661 only five tests. Because the number of tests that the \hgext{bisect}
|
bos@130
|
662 extension grows logarithmically with the number of changesets to
|
bos@130
|
663 search, the advantage that it has over the ``brute force'' search
|
bos@130
|
664 approach increases with every changeset you add.
|
bos@130
|
665
|
bos@130
|
666 \subsection{Cleaning up after your search}
|
bos@130
|
667
|
bos@130
|
668 When you're finished using the \hgext{bisect} extension in a
|
bos@130
|
669 repository, you can use the \hgcmdargs{bisect}{reset} command to drop
|
bos@130
|
670 the information it was using to drive your search. The extension
|
bos@130
|
671 doesn't use much space, so it doesn't matter if you forget to run this
|
bos@130
|
672 command. However, \hgext{bisect} won't let you start a new search in
|
bos@130
|
673 that repository until you do a \hgcmdargs{bisect}{reset}.
|
bos@131
|
674 \interaction{bisect.search.reset}
|
bos@130
|
675
|
bos@130
|
676 \section{Tips for finding bugs effectively}
|
bos@130
|
677
|
bos@130
|
678 \subsection{Give consistent input}
|
bos@130
|
679
|
bos@130
|
680 The \hgext{bisect} extension requires that you correctly report the
|
bos@130
|
681 result of every test you perform. If you tell it that a test failed
|
bos@130
|
682 when it really succeeded, it \emph{might} be able to detect the
|
bos@130
|
683 inconsistency. If it can identify an inconsistency in your reports,
|
bos@130
|
684 it will tell you that a particular changeset is both good and bad.
|
bos@130
|
685 However, it can't do this perfectly; it's about as likely to report
|
bos@130
|
686 the wrong changeset as the source of the bug.
|
bos@130
|
687
|
bos@130
|
688 \subsection{Automate as much as possible}
|
bos@130
|
689
|
bos@130
|
690 When I started using the \hgext{bisect} extension, I tried a few times
|
bos@130
|
691 to run my tests by hand, on the command line. This is an approach
|
bos@130
|
692 that I, at least, am not suited to. After a few tries, I found that I
|
bos@130
|
693 was making enough mistakes that I was having to restart my searches
|
bos@130
|
694 several times before finally getting correct results.
|
bos@130
|
695
|
bos@130
|
696 My initial problems with driving the \hgext{bisect} extension by hand
|
bos@130
|
697 occurred even with simple searches on small repositories; if the
|
bos@130
|
698 problem you're looking for is more subtle, or the number of tests that
|
bos@130
|
699 \hgext{bisect} must perform increases, the likelihood of operator
|
bos@130
|
700 error ruining the search is much higher. Once I started automating my
|
bos@130
|
701 tests, I had much better results.
|
bos@130
|
702
|
bos@130
|
703 The key to automated testing is twofold:
|
bos@130
|
704 \begin{itemize}
|
bos@130
|
705 \item always test for the same symptom, and
|
bos@130
|
706 \item always feed consistent input to the \hgcmd{bisect} command.
|
bos@130
|
707 \end{itemize}
|
bos@130
|
708 In my tutorial example above, the \command{grep} command tests for the
|
bos@130
|
709 symptom, and the \texttt{if} statement takes the result of this check
|
bos@130
|
710 and ensures that we always feed the same input to the \hgcmd{bisect}
|
bos@130
|
711 command. The \texttt{mytest} function marries these together in a
|
bos@130
|
712 reproducible way, so that every test is uniform and consistent.
|
bos@130
|
713
|
bos@130
|
714 \subsection{Check your results}
|
bos@130
|
715
|
bos@130
|
716 Because the output of a \hgext{bisect} search is only as good as the
|
bos@130
|
717 input you give it, don't take the changeset it reports as the
|
bos@130
|
718 absolute truth. A simple way to cross-check its report is to manually
|
bos@130
|
719 run your test at each of the following changesets:
|
bos@130
|
720 \begin{itemize}
|
bos@130
|
721 \item The changeset that it reports as the first bad revision. Your
|
bos@130
|
722 test should still report this as bad.
|
bos@130
|
723 \item The parent of that changeset (either parent, if it's a merge).
|
bos@130
|
724 Your test should report this changeset as good.
|
bos@130
|
725 \item A child of that changeset. Your test should report this
|
bos@130
|
726 changeset as bad.
|
bos@130
|
727 \end{itemize}
|
bos@130
|
728
|
bos@130
|
729 \subsection{Beware interference between bugs}
|
bos@130
|
730
|
bos@130
|
731 It's possible that your search for one bug could be disrupted by the
|
bos@130
|
732 presence of another. For example, let's say your software crashes at
|
bos@130
|
733 revision 100, and worked correctly at revision 50. Unknown to you,
|
bos@130
|
734 someone else introduced a different crashing bug at revision 60, and
|
bos@130
|
735 fixed it at revision 80. This could distort your results in one of
|
bos@130
|
736 several ways.
|
bos@130
|
737
|
bos@130
|
738 It is possible that this other bug completely ``masks'' yours, which
|
bos@130
|
739 is to say that it occurs before your bug has a chance to manifest
|
bos@130
|
740 itself. If you can't avoid that other bug (for example, it prevents
|
bos@130
|
741 your project from building), and so can't tell whether your bug is
|
bos@130
|
742 present in a particular changeset, the \hgext{bisect} extension cannot
|
bos@130
|
743 help you directly. Instead, you'll need to manually avoid the
|
bos@130
|
744 changesets where that bug is present, and do separate searches
|
bos@130
|
745 ``around'' it.
|
bos@130
|
746
|
bos@130
|
747 A different problem could arise if your test for a bug's presence is
|
wbunaarfubss@248
|
748 not specific enough. If you check for ``my program crashes'', then
|
bos@130
|
749 both your crashing bug and an unrelated crashing bug that masks it
|
bos@130
|
750 will look like the same thing, and mislead \hgext{bisect}.
|
bos@130
|
751
|
bos@130
|
752 \subsection{Bracket your search lazily}
|
bos@130
|
753
|
bos@130
|
754 Choosing the first ``good'' and ``bad'' changesets that will mark the
|
bos@130
|
755 end points of your search is often easy, but it bears a little
|
mrowe@257
|
756 discussion nevertheless. From the perspective of \hgext{bisect}, the
|
bos@130
|
757 ``newest'' changeset is conventionally ``bad'', and the older
|
bos@130
|
758 changeset is ``good''.
|
bos@130
|
759
|
bos@130
|
760 If you're having trouble remembering when a suitable ``good'' change
|
bos@130
|
761 was, so that you can tell \hgext{bisect}, you could do worse than
|
bos@130
|
762 testing changesets at random. Just remember to eliminate contenders
|
bos@130
|
763 that can't possibly exhibit the bug (perhaps because the feature with
|
bos@130
|
764 the bug isn't present yet) and those where another problem masks the
|
bos@130
|
765 bug (as I discussed above).
|
bos@130
|
766
|
bos@130
|
767 Even if you end up ``early'' by thousands of changesets or months of
|
bos@130
|
768 history, you will only add a handful of tests to the total number that
|
bos@130
|
769 \hgext{bisect} must perform, thanks to its logarithmic behaviour.
|
bos@130
|
770
|
bos@121
|
771 %%% Local Variables:
|
bos@121
|
772 %%% mode: latex
|
bos@121
|
773 %%% TeX-master: "00book"
|
bos@121
|
774 %%% End:
|