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author | Carlo Zancanaro <carlo@pc-4w14-0.cs.usyd.edu.au> | 2012-10-30 21:29:35 +1100 |
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committer | Carlo Zancanaro <carlo@pc-4w14-0.cs.usyd.edu.au> | 2012-10-30 21:29:35 +1100 |
commit | 093a35f07986ecfac8c43d053445e8417c7c2139 (patch) | |
tree | f53a11027dbf85db8e05e71c47fabe9863bc0ad3 /tex/thesis/contribution | |
parent | 95b82ea3830c3a34455323167894647e3aa773a6 (diff) |
Commit some stuff to move between computers.
Diffstat (limited to 'tex/thesis/contribution')
-rw-r--r-- | tex/thesis/contribution/contribution.tex | 329 |
1 files changed, 218 insertions, 111 deletions
diff --git a/tex/thesis/contribution/contribution.tex b/tex/thesis/contribution/contribution.tex index 6d4aeca..7d12299 100644 --- a/tex/thesis/contribution/contribution.tex +++ b/tex/thesis/contribution/contribution.tex @@ -2,8 +2,12 @@ \newcommand\stable{\mathsf{stable}} \newcommand\eval{\mathsf{\textsc{eval}}} +\newcommand\stabilise{\mathsf{\textsc{stabilise}}} \newcommand\solve{\mathsf{\textsc{solve}}} \newcommand\system{\mathsf{system}} +\newcommand\invalidate{\mathsf{\textsc{invalidate}}} +\newcommand\fixpoint{\mathsf{\textsc{fixpoint}}} +\newcommand\strategy{\mathsf{\textsc{strategy}}} \algblockx[Globals]{Globals}{EndGlobals}{\textbf{Globals:\\}}{} \algblockx[Assume]{Assumptions}{EndAssumptions}{\textbf{Assume:\\}}{} @@ -16,7 +20,8 @@ over the integers with monotonic operators\cite{Gawlitza:2007:PFC:1762174.1762203}. The original algorithm is presented in Section \ref{section:basic-algorithm}. We employ the ideas of Seidl, et al. to design an algorithm which runs in -considerably less time than the existing solver. +considerably less time (in the best case, and in most practical cases) +than the existing solver. In this chapter we will begin by presenting the Work-list Depth First Search (W-DFS) fixpoint algorithm developed by Seidl, et @@ -62,18 +67,32 @@ and all values from the set $\D$. consider expressions, $e \in E$, as $e : (X \to \D) \to \D$, a mapping from a variable assignment to the expression's value in that assignment. + + The subset of expressions of the form $\max(e_1, e_2, + ... e_n)$, with $e_1, e_2, ..., e_n \in E$ are referred to as + \emph{$\max$-expressions}, denoted by $E_{\max} \subset E$. \end{definition} \begin{definition} - \textbf{Equation System:} $\{ x = e_x \mid x \in X, e_x \in E \}$. An - equation system can also be considered as a function $\varepsilon : - (X \to D) \to (X \to D)$; $\varepsilon[\rho](x) = e_x(\rho)$. + \textbf{Equation System:} $\{ x = e_x \mid x \in X, e_x \in E + \}$. The values $x \in X$ are called ``variables'' while the values + $e_x \in E$ are called ``right-hand-sides''. + + An equation system can also be considered as a function $\varepsilon + : (X \to D) \to (X \to D)$; $\varepsilon[\rho](x) = e_x(\rho)$. +\end{definition} + +\begin{definition} + \textbf{Dependencies:} A variable or expression $x$ is said to + \emph{depend on} $y$ if a change to the value of $y$ induces a + change in the value of $x$. If $x$ depends on $y$ then $y$ is said + to \emph{influence} $x$. \end{definition} \begin{definition} - \textbf{Dependencies:} A variable $x$ is said to \emph{depend on} - $y$ if a change to the value of $y$ induces a change in the value of - $x$. + \textbf{Local:} A solver is said be local if, for some $e_x \in E$, + the evaluation of $e_x$ only requires the evaluation of other + variables which $e_x$ may depend on. \end{definition} \section{Fixpoint Iteration} @@ -86,7 +105,7 @@ reach the least/greatest solution if there is one to be found, but it will often perform many more evaluations than are necessary. This algorithm is presented in Listing \ref{algo:kleene}. -\begin{algorithm} +\begin{algorithm}[H] \begin{algorithmic} \Assumptions \begin{tabularx}{0.9\textwidth}{rX} @@ -110,9 +129,10 @@ algorithm is presented in Listing \ref{algo:kleene}. For each iteration the entire system is evaluated, irrespective of whether it could possibly have changed value. This results in a -considerable inefficiency in practice and thus an approach which can -evaluate smaller portions of the system in each iteration would be a -sensible improvement. +considerable inefficiency in practice, requiring the evaluation of +$O(n^3)$ right-hand-sides, and thus an approach which can evaluate +smaller portions of the system in each iteration would be a +significant improvement. \subsection{W-DFS algorithm} @@ -121,20 +141,24 @@ form of data-dependencies as it solves the system. This gives it the ability to leave portions of the system unevaluated when it is certain that those values have not changed. -\begin{algorithm} +\begin{algorithm}[H] \begin{algorithmic} \Globals \begin{tabularx}{0.9\textwidth}{rX} - $D : X \to \D$ & a mapping from variables to their current values, starting - at $\{ x \mapsto \infty | \forall x \in X \}$ \\ - I & A mapping from a variable to the variables which depend on - it in their evaluation \\ - stable & The set of all variables whose values have stabilised \\ + $D : X \to \D$ & a mapping from variables to their current + values, starting at $\{ x \mapsto \infty | \forall x \in X \}$ + \\ + + I & A mapping from a variable to the variables which \emph{may} + depend on it in their evaluation \\ + + stable & The set of all variables whose values have stabilised + \\ + system & The equation system, a mapping from a variable to its associated function \\ \end{tabularx} \EndGlobals - something something \end{algorithmic} \begin{algorithmic} @@ -155,8 +179,7 @@ that those values have not changed. \State $\stable = \stable \cup \{x\}$ \State $v = f( \lambda y . \eval(x, y) )$ \If {$v \ne D[x]$} - \State $D = \{ x \mapsto v, \alpha \mapsto D[\alpha] \} - \forall \alpha \ne x$ + \State $D = \{ x \mapsto v \} \oplus D$ \State $W = I[x]$ \State $I(x) = \emptyset$ \State $\stable = \stable \backslash W$ @@ -174,27 +197,71 @@ that those values have not changed. \label{algo:w-dfs} \end{algorithm} +The W-DFS algorithm over-approximates the dependencies for each +variable, keeping a map of which variables \emph{may} depend on other +variables. + +The particular variation of W-DFS presented here is designed to return +the \emph{greatest} fixpoint of an equation system consisting of only +\emph{monotonic} expressions. + \section{$\max$-strategy Iteration} + +The $\max$-strategy iteration can be viewed as an accelerated fixpoint +problem. We are attempting to find a strategy, $\sigma: E_{\max} \to +E$ that will result in the greatest value for each $e \in +E_{\max}$. Therefore if we consider our ``variables'' to be +$\max$-expressions and our ``values'' to be their subexpressions then we +can solve for the best $\max$-strategy using a similar approach + and our +``comparison'' + +Because $\max$-strategy iteration is so similar to a standard fixpoint +problem it is possible + \subsection{Naive approach} -TODO: Explanation of the naive approach +\begin{algorithm}[H] + \begin{algorithmic} + \Assumptions + \begin{tabularx}{0.9\textwidth}{rX} + $\sigma $:&$ E_{\max} \to E$, a $\max$ strategy \\ + + $\varepsilon $:&$ (X \to \D) \to (X \to \D)$, an equation + system \\ + + $\rho $:&$ (X \to D)$, a variable assignment \\ + + $P_{\max} $:&$ ((E_{\max} \to E_{\max}), (X \to \D)) \to + (E_{\max} \to E_{\max})$, a $\max$-strategy improvement + operator + \end{tabularx} + \EndAssumptions + + \State $n = 0$ + \State $\sigma_0 = \lambda x . -\infty$ + \State $\rho_0 = \underline{-\infty}$ + \Repeat + \State $\sigma_{n+1} = P_{\max}(\sigma, \rho)$ + \State $\rho_{n+1} = \sigma(\varepsilon)[ \rho_{n} ]$ + \State $n = n + 1$ + \Until {$\sigma_{n-1} = \sigma_n$} + \State \Return $\sigma_n$ + \end{algorithmic} + \caption{The naive approach to strategy iteration} + \label{algo:naive-strategy} +\end{algorithm} -\subsection{Adapted W-DFS algorithm} -The $\max$-strategy iteration can be viewed as a fixpoint problem. We -are attempting to find a strategy, $\sigma: E_{\max} \to E$ that will -result in the greatest value for each $e \in E_{\max}$. Therefore if -we consider our ``variables'' to be $\max$-expressions, our ``values'' -to be their subexpressions and our ``comparison'' to be carried out -using the result of evaluating the system with that strategy. +\subsection{Adapted W-DFS algorithm} This, then, allows us to use the W-DFS algorithm to re-evaluate only those parts of the strategy which have changed. Listing \ref{algo:w-dfs-max} presents this variation on W-DFS. -\begin{algorithm} +\begin{algorithm}[H] \begin{algorithmic} \Globals \begin{tabularx}{0.9\textwidth}{rX} @@ -226,10 +293,9 @@ those parts of the strategy which have changed. Listing \If {$x \not \in \stable$} \State $f = \system[x]$ \State $\stable = \stable \cup \{x\}$ - \State $v = bestStrategy(x, \lambda y . \eval(x, y))$ + \State $v = bestStrategy(f, \lambda y . \eval(x, y))$ \If {$v \ne \sigma[x]$} - \State $\sigma = \{ x \mapsto v, \alpha \mapsto \sigma[\alpha] - \} \forall \alpha \ne x $ + \State $\sigma = \{ x \mapsto v\} \oplus \sigma$ \State $W = I[x]$ \State $I(x) = \emptyset$ \State $\stable = \stable \backslash W$ @@ -246,7 +312,7 @@ those parts of the strategy which have changed. Listing \end{algorithm} -\section{Combined W-DFS} +\section{Local Demand-driven Strategy Improvement (LDSI)} W-DFS can be used to speed up both the $\max$-strategy iteration and the fixpoint iteration as two independent processes, but each @@ -258,103 +324,143 @@ provide some information to each other about what values have changed so that at each step only a subset of the entire system would have to be evaluated. -The new algorithm, \emph{Combined W-DFS} seeks to do this. By adding -an ``invalidate'' method to both W-DFS instances we provide an -interface for the two sides of the algorithm to indicate which values -have changed. This gives the other side enough information to avoid -evaluating irrelevant portions of the equation system. - -This algorithm is presented in two parts. Listing -\ref{algo:combined-fixpoint} presents the fixpoint-iteration portion -of the algorithm, while Listing \ref{algo:combined-max} presents the -$\max$-strategy portion. The correctness of this new algorithm is -argued in \ref{sec:combined-correctness}. - - -\begin{algorithm} +The new \emph{Local Demand-driven Strategy Improvement} algorithm, +\emph{LDSI}, seeks to do this. By adding an ``invalidate'' +function to both W-DFS instances we provide an interface for the two +sides of the algorithm to indicate which values have changed. The +fixpoint-iteration operation can then be provided with a ``stabilise'' +function to solve a partially-unstable system. + +This essentially results in a $\max$-strategy iteration which, at each +strategy-improvement step, invalidates a portion of the current +fixpoint iteration. The fixpoint iteration then re-stabilises itself +by evaluating what values have been changed before returning control +to the $\max$-strategy iteration to change the system again. The back +and forth continues in this way until the $\max$-strategy can not +improve the strategy any further. + + + +This algorithm is presented in two parts. Listings +\ref{algo:ldsi:fixpoint:globals}, +\ref{algo:ldsi:fixpoint:eval}, +\ref{algo:ldsi:fixpoint:invalidate}, +\ref{algo:ldsi:fixpoint:solve} and +\ref{algo:ldsi:fixpoint:stabilise} present the +fixpoint-iteration portion of the algorithm, while Listing +\ref{algo:combined-max} presents the $\max$-strategy portion. The +correctness of this new algorithm is argued in +\ref{sec:ldsi-correctness}. + +\begin{algorithm}[H] \begin{algorithmic} \Globals \begin{tabularx}{0.9\textwidth}{rX} - D & A mapping from variables to their current values, starting - at $\{ x \mapsto \infty \}$ \\ - I & A mapping from a variable to the variables which depend on - it in their evaluation \\ - stable & The set of all variables whose values have stabilised \\ - system & The equation system, a mapping from a variable to its - associated function \\ + $V$ & $\{X \to \D\}$ - a mapping from variables to values, + starting at $\{ x \mapsto \infty \}$ \\ + + $I_{X,X}$ & $\{X \to X\}$ - a mapping from a variable to the + variables it influences \\ + + $I_{\max,\max}$ & $\{E_{\max} \to E_{\max}\}$ - a mapping from a + $\max$-expression to the $\max$-expressions it influences \\ + + $I_{X,\max}$ & $\{X \to E_{\max}\}$ - a mapping from a variable + to the $\max$-expressions it influences \\ + + $U_{X}$ & The set of all variables whose values have not + stabilised to a final fixpoint value (unstable variables) \\ + + $U_{\max}$ & The set of all $\max$ expressions whose strategies + have not yet stabilised to their final strategy (unstable + $\max$-expressions) \\ + + $\varepsilon$ & The equation system, a mapping from a variable + to its associated function \\ \end{tabularx} \EndGlobals + \end{algorithmic} + \caption{Global variables used by the LDSI algorithm} + \label{algo:ldsi:fixpoint:globals} +\end{algorithm} - \Function {eval} {$x$, $y$} - \Comment{Evaluate $y$ for its value and note that when $y$ - changes, $x$ must be re-evaluated} - \State $\solve(y)$ - \State $I[y] = I[y] \cup \{x\}$ + + + +\begin{algorithm}[H] + \begin{algorithmic} + \Function {evalfixpoint} {$x$, $y$} + \State $\solve \fixpoint(y)$ + \State $I_{X,X}[y] = I_{X,X}[y] \cup \{x\}$ \State \Return $D[y]$ \EndFunction + \end{algorithmic} + \caption{Utility function used to track fixpoint variable dependencies.} + \label{algo:ldsi:fixpoint:eval} +\end{algorithm} - \Function {invalidate} {$x$} - \If {$x \in \stable$} - \State $\stable = \stable \backslash \{x\}$ +\begin{algorithm}[H] + \begin{algorithmic} + \Function {invalidatefixpoint} {$x$} + \If {$x \not \in U_X$} + \State $U_X = U_X \cup \{x\}$ \State $D[x] = \infty$ \State $W = I[x]$ \State $I[x] = \emptyset$ \For {$v \in W$} - invalidate(v) + \State $\invalidate \fixpoint(v)$ \EndFor \EndIf \EndFunction + \end{algorithmic} + \caption{Fixpoint subroutine called from the $\max$-strategy + iteration portion to invalidate fixpoint variables} + \label{algo:ldsi:fixpoint:invalidate} +\end{algorithm} - \Function {solve} {$x$} +\begin{algorithm}[H] + \begin{algorithmic} + \Function {solvefixpoint} {$x$} \Comment{Solve a specific expression and place its value in $D$} - \If {$x \not \in \stable$} + \If {$x \in U_X$} \State $f = \system[x]$ - \State $\stable = \stable \cup \{x\}$ + \State $U_X = U_X \backslash \{x\}$ \State $v = f( \lambda y . \eval(x, y) )$ \If {$v \ne D[x]$} - \State $D = \{ x \mapsto v, \alpha \mapsto D[\alpha] \} - \forall \alpha \ne x$ - \State $W = I[x]$ - \State $I(x) = \emptyset$ - \State strategy::invalidate($x$) + \State $D = \{ x \mapsto v \} \oplus D$ + \State $W = I_{X,X}[x]$ + \State $I_{X,X}[x] = \emptyset$ + \State $\invalidate \strategy(x)$ \State $\stable = \stable \backslash W$ \For {$v \in W$} - \State $\solve(v)$ + \State $\solve \fixpoint(v)$ \EndFor \EndIf \EndIf \EndFunction \end{algorithmic} - - \caption{The fixpoint portion of the Combined W-DFS.} - \label{algo:combined-fixpoint} + \caption{The subroutine of the fixpoint iteration responsible for + solving for each variable} + \label{algo:ldsi:fixpoint:solve} \end{algorithm} +After an evaluation of the $\solve \fixpoint$ procedure, the variable +supplied as its argument will have been stabilised within the current +$\max$-strategy. -\begin{algorithm} - \begin{algorithmic} - \Globals - \begin{tabularx}{0.9\textwidth}{rX} - $\sigma$ & A mapping from $\max$-expressions to their current - sub-expressions, starting by \\& mapping to the first - sub-expression \\ - D & A \emph{dynamic} variable assignment which will stay updated - as $\sigma$ changes \\ - $I$ & A mapping from a $\max$-expression to the sub-expressions - which depend on it \\& in their evaluation \\ - $I_V$ & A mapping from a variable to the $\max-$ expressions which - depend on it in their \\& evaluation \\ - stable & The set of all $\max$-expressions whose strategies have - stabilised \\ - system & The equation system, a mapping from a variable to its - associated function \\ - bestStrategy & A function $(E_{\max}, (X \to D)) \to E$ mapping - from an expression and a variable \\& assignment to the greatest - subexpression in that context - \end{tabularx} - \EndGlobals +After an evaluation of the $\stabilise \fixpoint$ procedure all +currently ``unstable'' variables in the current fixpoint will be +solved. This correlates to performing an entire fixpoint-iteration for +the greatest-fixpoint of the unstable portion of the equation +system. This is meant to be used to perform a sufficient +fixpoint-iteration to allow for the next $\max$-strategy improvement +step, but this relies on the $\max$-strategy solver to correctly +invalidate the fixpoint-iteration portion of the algorithm. - \Function {eval} {$x$, $y$} + +\begin{algorithm}[H] + \begin{algorithmic} + \Function {evalstrategy} {$x$, $y$} \Comment{Evaluate $y$ for its value and note that when $y$ changes, $x$ must be re-evaluated} \State $\solve(y)$ @@ -362,28 +468,29 @@ argued in \ref{sec:combined-correctness}. \State \Return $\sigma[y]$ \EndFunction - \Function {invalidate} {$x \in X$} \Comment{X is vars} - \State $\stable = \stable \backslash I[x]$ - \State $W = I_v[x]$ - \State $I_V = \emptyset$ - \For {$v \in W$} - \State solve(v) - \EndFor + \Function {invalidatestrategy} {$x \in X$} \Comment{$x$ is a + \emph{variable}} + \If {$x \not \in U_X$} + \State $U_X = U_X \cup \{x\}$ + \State $W = I[x]$ + \State $I[x] = \emptyset$ + \For {$v \in W$} + \State $\invalidate \fixpoint(v)$ + \EndFor + \EndIf \EndFunction - \Function {solve} {$x$} + \Function {solvestrategy} {$x$} \Comment{Solve a specific variable and place its value in $\sigma$} \If {$x \not \in \stable$} \State $f = \system[x]$ \State $\stable = \stable \cup \{x\}$ - \State $v = bestStrategy(x, - \lambda y . \eval(x, y))$ + \State $v = bestStrategy(f, \sigma(), \lambda y . \eval(x, y))$ \If {$v \ne \sigma[x]$} - \State $\sigma = \{ x \mapsto v, \alpha \mapsto \sigma[\alpha] - \} \forall \alpha \ne x $ + \State $\sigma = \{ x \mapsto v \} \oplus \sigma$ \State $W = I[x]$ \State $I(x) = \emptyset$ - \State fixpoint::invalidate$(\mathsf{lookupVarFor}(x))$ + \State $\invalidate \fixpoint(\mathsf{lookupVarFor}(x))$ \State $\stable = \stable \backslash W$ \For {$v \in W$} \State $\solve(v)$ |