X-Git-Url: http://www.chiark.greenend.org.uk/ucgi/~ian/git?p=topbloke-formulae.git;a=blobdiff_plain;f=article.tex;h=01297a8fb0681c79d7ffc1933fe941f02f77adb5;hp=b71bb326c09fcf3eb8387c075b3f7ded903087b6;hb=e02ac317b82e521bccdbfadda3ff9c11d6a1533d;hpb=d69833629e848b5da6cd00bca1986ffe84abd510 diff --git a/article.tex b/article.tex index b71bb32..01297a8 100644 --- a/article.tex +++ b/article.tex @@ -10,6 +10,8 @@ \renewcommand{\ge}{\geqslant} \renewcommand{\le}{\leqslant} +\newcommand{\nge}{\ngeqslant} +\newcommand{\nle}{\nleqslant} \newcommand{\has}{\sqsupseteq} \newcommand{\isin}{\sqsubseteq} @@ -53,7 +55,8 @@ \newcommand{\pancsof}[2]{\pancs ( #1 , #2 ) } \newcommand{\pendsof}[2]{\pends ( #1 , #2 ) } -\newcommand{\merge}[4]{{\mathcal M}(#1,#2,#3,#4)} +\newcommand{\merge}{{\mathcal M}} +\newcommand{\mergeof}[4]{\merge(#1,#2,#3,#4)} %\newcommand{\merge}[4]{{#2 {{\frac{ #1 }{ #3 } #4}}}} \newcommand{\patch}{{\mathcal P}} @@ -62,8 +65,8 @@ \newcommand{\patchof}[1]{\patch ( #1 ) } \newcommand{\baseof}[1]{\base ( #1 ) } +\newcommand{\eqntag}[2]{ #2 \tag*{\mbox{#1}} } \newcommand{\eqn}[2]{ #2 \tag*{\mbox{\bf #1}} } -\newcommand{\corrolary}[1]{ #1 \tag*{\mbox{\it Corrolary.}} } %\newcommand{\bigforall}{\mathop{\hbox{\huge$\forall$}}} \newcommand{\bigforall}{% @@ -78,7 +81,8 @@ \newcommand{\Largenexists}{\mathop{\hbox{\Large$\nexists$}}} \newcommand{\qed}{\square} -\newcommand{\proof}[1]{{\it Proof.} #1 $\qed$} +\newcommand{\proofstarts}{{\it Proof:}} +\newcommand{\proof}[1]{\proofstarts #1 $\qed$} \newcommand{\gathbegin}{\begin{gather} \tag*{}} \newcommand{\gathnext}{\\ \tag*{}} @@ -152,7 +156,7 @@ patch is applied to a non-Topbloke branch and then bubbles back to the Topbloke patch itself, we hope that git's merge algorithm will DTRT or that the user will no longer care about the Topbloke patch. -\item[ $\displaystyle \merge{C}{L}{M}{R} $ ] +\item[ $\displaystyle \mergeof{C}{L}{M}{R} $ ] The contents of a git merge result: $\displaystyle D \isin C \equiv @@ -202,7 +206,7 @@ Ie, the two limbs of the RHS of Tip Contents are mutually exclusive. Let $B = \baseof{C}$ in $D \isin \baseof{C}$. Now $B \in \pn$. So by Base Acyclic $D \isin B \implies D \notin \py$. } -\[ \corrolary{ +\[ \eqntag{{\it Corollary - equivalent to Tip Contents}}{ \bigforall_{C \in \py} D \isin C \equiv \begin{cases} D \in \py : & D \le C \\ @@ -259,15 +263,15 @@ XXX proof TBD. \subsection{No Replay for Merge Results} -If we are constructing $C$, given +If we are constructing $C$, with, \gathbegin - \merge{C}{L}{M}{R} + \mergeof{C}{L}{M}{R} \gathnext L \le C \gathnext R \le C \end{gather} -No Replay is preserved. {\it Proof:} +No Replay is preserved. \proofstarts \subsubsection{For $D=C$:} $D \isin C, D \le C$. OK. @@ -397,7 +401,7 @@ Used for removing a branch dependency. \gathnext \patchof{C} = \patchof{L} \gathnext - \merge{C}{L}{R^+}{R^-} + \mergeof{C}{L}{R^+}{R^-} \end{gather} \subsection{Conditions} @@ -420,19 +424,37 @@ Merge Results applies. $\qed$ \subsection{Desired Contents} -\[ $D \isin C \equiv [ D \not\in \pry \land D \isin L$ ] \lor D = C \] -{\it Proof.} +\[ D \isin C \equiv [ D \notin \pry \land D \isin L ] \lor D = C \] +\proofstarts \subsubsection{For $D = C$:} Trivially $D \isin C$. OK. -\subsubsection{For $D \not\le C$:} +\subsubsection{For $D \neq C, D \not\le L$:} +By No Replay $D \not\isin L$. Also $D \not\le R^-$ hence +$D \not\isin R^-$. Thus $D \not\isin C$. OK. +\subsubsection{For $D \neq C, D \le L, D \in \pry$:} -\subsubsection{For $D \in R^+$:} -By Currently Included, +By Currently Included, $D \isin L$. + +By Tip Self Inpatch, $D \isin R^+ \equiv D \le R^+$, but by +by Unique Tip, $D \le R^+ \equiv D \le L$. +So $D \isin R^+$. + +By Base Acyclic, $D \not\isin R^-$. + +Apply $\merge$: $D \not\isin C$. OK. + +\subsubsection{For $D \neq C, D \le L, D \notin \pry$:} + +By Tip Contents for $R^+$, $D \isin R^+ \equiv D \isin R^-$. + +Apply $\merge$: $D \isin C \equiv D \isin L$. OK. + +$\qed$ \subsection{Unique Base} @@ -440,6 +462,8 @@ Need to consider only $C \in \py$, ie $L \in \py$. xxx tbd +xxx need to finish anticommit + \section{Merge} Merge commits $L$ and $R$ using merge base $M$ ($M < L, M < R$): @@ -448,8 +472,9 @@ Merge commits $L$ and $R$ using merge base $M$ ($M < L, M < R$): \gathnext \patchof{C} = \patchof{L} \gathnext - \merge{C}{L}{M}{R} + \mergeof{C}{L}{M}{R} \end{gather} +We will occasionally use $X,Y$ s.t. $\{X,Y\} = \{L,R\}$. \subsection{Conditions} @@ -463,6 +488,21 @@ Merge commits $L$ and $R$ using merge base $M$ ($M < L, M < R$): \text{otherwise} : & \false \end{cases} }\] +\[ \eqn{ Removal Merge Ends }{ + X \not\haspatch \p \land + Y \haspatch \p \land + M \haspatch \p + \implies + \pendsof{Y}{\py} = \pendsof{M}{\py} +}\] +\[ \eqn{ Addition Merge Ends }{ + X \not\haspatch \p \land + Y \haspatch \p \land + M \nothaspatch \p + \implies \left[ + \bigforall_{E \in \pendsof{X}{\py}} E \le Y + \right] +}\] \subsection{No Replay} @@ -502,4 +542,78 @@ That is, $\baseof{C} = R$. $\qed$ +\subsection{Coherence and patch inclusion} + +Need to determine $C \haspatch \p$ based on $L,M,R \haspatch \p$. +This involves considering $D \in \py$. + +\subsubsection{For $L \nothaspatch \p, R \nothaspatch \p$:} +$D \not\isin L \land D \not\isin R$. $C \not\in \py$ (otherwise $L +\in \py$ ie $L \haspatch \p$ by Tip Self Inpatch). So $D \neq C$. +Applying $\merge$ gives $D \not\isin C$ i.e. $C \nothaspatch \p$. + +\subsubsection{For $L \haspatch \p, R \haspatch \p$:} +$D \isin L \equiv D \le L$ and $D \isin R \equiv D \le R$. +(Likewise $D \isin X \equiv D \le X$ and $D \isin Y \equiv D \le Y$.) + +Consider $D = C$: $D \isin C$, $D \le C$, OK for $C \haspatch \p$. + +For $D \neq C$: $D \le C \equiv D \le L \lor D \le R + \equiv D \isin L \lor D \isin R$. +(Likewise $D \le C \equiv D \le X \lor D \le Y$.) + +Consider $D \neq C, D \isin X \land D \isin Y$: +By $\merge$, $D \isin C$. Also $D \le X$ +so $D \le C$. OK for $C \haspatch \p$. + +Consider $D \neq C, D \not\isin X \land D \not\isin Y$: +By $\merge$, $D \not\isin C$. +And $D \not\le X \land D \not\le Y$ so $D \not\le C$. +OK for $C \haspatch \p$. + +Remaining case, wlog, is $D \not\isin X \land D \isin Y$. +$D \not\le X$ so $D \not\le M$ so $D \not\isin M$. +Thus by $\merge$, $D \isin C$. And $D \le Y$ so $D \le C$. +OK for $C \haspatch \p$. + +So indeed $L \haspatch \p \land R \haspatch \p \implies C \haspatch \p$. + +\subsubsection{For (wlog) $X \not\haspatch \p, Y \haspatch \p$:} + +$C \haspatch \p \equiv M \nothaspatch \p$. + +\proofstarts + +One of the Merge Ends conditions applies. +Recall that we are considering $D \in \py$. +$D \isin Y \equiv D \le Y$. $D \not\isin X$. +We will show for each of +various cases that $D \isin C \equiv M \nothaspatch \p \land D \le C$ +(which suffices by definition of $\haspatch$ and $\nothaspatch$). + +Consider $D = C$: Thus $C \in \py, L \in \py$, and by Tip +Self Inpatch $L \haspatch \p$, so $L=Y, R=X$. By Tip Merge, +$M=\baseof{L}$. So by Base Acyclic $D \not\isin M$, i.e. +$M \nothaspatch \p$. And indeed $D \isin C$ and $D \le C$. OK. + +Consider $D \neq C, M \nothaspatch P, D \isin Y$: +$D \le Y$ so $D \le C$. +$D \not\isin M$ so by $\merge$, $D \isin C$. OK. + +Consider $D \neq C, M \nothaspatch P, D \not\isin Y$: +$D \not\le Y$. If $D \le X$ then +$D \in \pancsof{X}{\py}$, so by Addition Merge Ends and +Transitive Ancestors $D \le Y$ --- a contradiction, so $D \not\le X$. +Thus $D \not\le C$. By $\merge$, $D \not\isin C$. OK. + +Consider $D \neq C, M \haspatch P, D \isin Y$: +$D \le Y$ so $D \in \pancsof{Y}{\py}$ so by Removal Merge Ends +and Transitive Ancestors $D \in \pancsof{M}{\py}$ so $D \le M$. +Thus $D \isin M$. By $\merge$, $D \not\isin C$. OK. + +Consider $D \neq C, M \haspatch P, D \not\isin Y$: +By $\merge$, $D \not\isin C$. OK. + +$\qed$ + \end{document}