X-Git-Url: http://www.chiark.greenend.org.uk/ucgi/~ian/git?a=blobdiff_plain;f=article.tex;h=01800f96132a69fb7a89ab4e9e6ab9d0a82e9519;hb=d1afd16455a7de8e90e79610f5af798faad0bd44;hp=d85a022ff8fb8388f380325f4ffd4ed9e4330d5d;hpb=400772c417bd54383994df5a227df88adc769171;p=topbloke-formulae.git diff --git a/article.tex b/article.tex index d85a022..01800f9 100644 --- a/article.tex +++ b/article.tex @@ -1,4 +1,5 @@ \documentclass[a4paper,leqno]{strayman} +\errorcontextlines=50 \let\numberwithin=\notdef \usepackage{amsmath} \usepackage{mathabx} @@ -18,8 +19,12 @@ \newcommand{\haspatch}{\sqSupset} \newcommand{\patchisin}{\sqSubset} -\newcommand{\set}[1]{\mathbb #1} -\newcommand{\pa}[1]{\varmathbb #1} + \newif\ifhidehack\hidehackfalse + \DeclareRobustCommand\hidefromedef[2]{% + \hidehacktrue\ifhidehack#1\else#2\fi\hidehackfalse} + \newcommand{\pa}[1]{\hidefromedef{\varmathbb{#1}}{#1}} + +\newcommand{\set}[1]{\mathbb{#1}} \newcommand{\pay}[1]{\pa{#1}^+} \newcommand{\pan}[1]{\pa{#1}^-} @@ -27,6 +32,10 @@ \newcommand{\py}{\pay{P}} \newcommand{\pn}{\pan{P}} +\newcommand{\pr}{\pa{R}} +\newcommand{\pry}{\pay{R}} +\newcommand{\prn}{\pan{R}} + %\newcommand{\hasparents}{\underaccent{1}{>}} %\newcommand{\hasparents}{{% % \declareslashed{}{_{_1}}{0}{-0.8}{>}\slashed{>}}} @@ -59,6 +68,8 @@ {\hbox{\scriptsize$\forall$}}}% } +\newcommand{\Largeexists}{\mathop{\hbox{\Large$\exists$}}} +\newcommand{\Largenexists}{\mathop{\hbox{\Large$\nexists$}}} \newcommand{\qed}{\square} \newcommand{\proof}[1]{{\it Proof.} #1 $\qed$} @@ -114,7 +125,7 @@ which are in $\set P$. \item[ $ \pendsof{C}{\set P} $ ] $ \{ E \; | \; E \in \pancsof{C}{\set P} \land \mathop{\not\exists}_{A \in \pancsof{C}{\set P}} - A \neq E \land E \le A \} $ + E \neq A \land E \le A \} $ i.e. all $\le$-maximal commits in $\pancsof{C}{\set P}$. \item[ $ \baseof{C} $ ] @@ -217,6 +228,17 @@ in which case we repeat for $A'$. Since there are finitely many commits, this terminates with $A'' \in \pends()$, ie $A'' \le M$ by the LHS. And $A \le A''$. } +\[ \eqn{Calculation Of Ends:}{ + \bigforall_{C \hasparents \set A} + \pendsof{C}{\set P} = + \Bigl\{ E \Big| + \Bigl[ \Largeexists_{A \in \set A} + E \in \pendsof{A}{\set P} \Bigr] \land + \Bigl[ \Largenexists_{B \in \set A} + E \neq B \land E \le B \Bigr] + \Bigr\} +}\] +XXX proof TBD. \section{Commit annotation} @@ -316,6 +338,29 @@ $\qed$ If $D = C$, trivial. For $D \neq C$: $D \isin C \equiv D \isin A \equiv D \le A \equiv D \le C$. $\qed$ +\section{Anticommit} + +Given $L, R^+, R^-$ where +$\patchof{R^+} = \pry, \patchof{R^-} = \prn$. +Construct $C$ which has $\pr$ removed. +Used for removing a branch dependency. +\gathbegin + C \hasparents \{ L \} +\gathnext + \patchof{C} = \patchof{L} +\gathnext + D \isin C \equiv + \begin{cases} + R \in \py : & \baseof{R} \ge \baseof{L} + \land [\baseof{L} = M \lor \baseof{L} = \baseof{M}] \\ + R \in \pn : & R \ge \baseof{L} + \land M = \baseof{L} \\ + \text{otherwise} : & \false + \end{cases} +\end{gather} + +xxx want to prove $D \isin C \equiv D \not\in pry \land D \isin L$. + \section{Merge} Merge commits $L$ and $R$ using merge base $M$ ($M < L, M < R$): @@ -334,15 +379,74 @@ Merge commits $L$ and $R$ using merge base $M$ ($M < L, M < R$): \subsection{Conditions} -\[ \eqn{ Merges Exhaustive }{ - L \in \py => \Bigl[ R \in \py \lor R \in \pn \Bigr] -}\] \[ \eqn{ Tip Merge }{ - L \in \py \land R \in \py \implies \Bigl[ \text{TBD} \Bigr] -}\] -\[ \eqn{ Base Merge }{ - L \in \py \land R \in \pn \implies \Bigl[ R \ge \baseof{L} \land M = - \baseof{L} \Bigr] + L \in \py \implies + \begin{cases} + R \in \py : & \baseof{R} \ge \baseof{L} + \land [\baseof{L} = M \lor \baseof{L} = \baseof{M}] \\ + R \in \pn : & R \ge \baseof{L} + \land M = \baseof{L} \\ + \text{otherwise} : & \false + \end{cases} }\] +\subsection{No Replay} + +\subsubsection{For $D=C$:} $D \isin C, D \le C$. OK. + +\subsubsection{For $D \isin L \land D \isin R$:} +$D \isin C$. And $D \isin L \implies D \le L \implies D \le C$. OK. + +\subsubsection{For $D \neq C \land D \not\isin L \land D \not\isin R$:} +$D \not\isin C$. OK. + +\subsubsection{For $D \neq C \land D \not\isin L \land D \not\isin R$:} +$D \not\isin C$. OK. + +\subsubsection{For $D \neq C \land (D \isin L \equiv D \not\isin R) + \land D \not\isin M$:} +$D \isin C$. Also $D \isin L \lor D \isin R$ so $D \le L \lor D \le +R$ so $D \le C$. OK. + +\subsubsection{For $D \neq C \land (D \isin L \equiv D \not\isin R) + \land D \isin M$:} +$D \not\isin C$. Also $D \isin L \lor D \isin R$ so $D \le L \lor D \le +R$ so $D \le C$. OK. + +$\qed$ + +\subsection{Unique Base} + +Need to consider only $C \in \py$, ie $L \in \py$, +and calculate $\pendsof{C}{\pn}$. So we will consider some +putative ancestor $A \in \pn$ and see whether $A \le C$. + +By Exact Ancestors for C, $A \le C \equiv A \le L \lor A \le R \lor A = C$. +But $C \in py$ and $A \in \pn$ so $A \neq C$. +Thus $A \le C \equiv A \le L \lor A \le R$. + +By Unique Base of L and Transitive Ancestors, +$A \le L \equiv A \le \baseof{L}$. + +\subsubsection{For $R \in \py$:} + +By Unique Base of $R$ and Transitive Ancestors, +$A \le R \equiv A \le \baseof{R}$. + +But by Tip Merge condition on $\baseof{R}$, +$A \le \baseof{L} \implies A \le \baseof{R}$, so +$A \le \baseof{R} \lor A \le \baseof{L} \equiv A \le \baseof{R}$. +Thus $A \le C \equiv A \le \baseof{R}$. +That is, $\baseof{C} = \baseof{R}$. + +\subsubsection{For $R \in \pn$:} + +By Tip Merge condition on $R$, +$A \le \baseof{L} \implies A \le R$, so +$A \le R \lor A \le \baseof{L} \equiv A \le R$. +Thus $A \le C \equiv A \le R$. +That is, $\baseof{C} = R$. + +$\qed$ + \end{document}