//--------------------------------------------------------------------- // // Copyright (c) Microsoft Corporation. All rights reserved. // // // @owner [....] // @backupOwner [....] //--------------------------------------------------------------------- using System; using System.Diagnostics; using System.Collections.Generic; using System.Text; using System.Linq; namespace System.Data.Mapping.ViewGeneration.QueryRewriting { internal class RewritingSimplifier where T_Tile : class { private readonly T_Tile m_originalRewriting; private readonly T_Tile m_toAvoid; private readonly RewritingProcessor m_qp; private readonly Dictionary m_usedViews = new Dictionary(); // used for join/antisemijoin simplification private RewritingSimplifier(T_Tile originalRewriting, T_Tile toAvoid, Dictionary usedViews, RewritingProcessor qp) { m_originalRewriting = originalRewriting; m_toAvoid = toAvoid; m_qp = qp; m_usedViews = usedViews; } // used for union simplification private RewritingSimplifier(T_Tile rewriting, T_Tile toFill, T_Tile toAvoid, RewritingProcessor qp) { m_originalRewriting = toFill; m_toAvoid = toAvoid; m_qp = qp; m_usedViews = new Dictionary(); GatherUnionedSubqueriesInUsedViews(rewriting); } // called for top query only internal static bool TrySimplifyUnionRewriting(ref T_Tile rewriting, T_Tile toFill, T_Tile toAvoid, RewritingProcessor qp) { RewritingSimplifier simplifier = new RewritingSimplifier(rewriting, toFill, toAvoid, qp); // gather all unioned subqueries T_Tile simplifiedRewriting; if (simplifier.SimplifyRewriting(out simplifiedRewriting)) { rewriting = simplifiedRewriting; return true; } return false; } // modifies usedViews - removes all redundant views from it internal static bool TrySimplifyJoinRewriting(ref T_Tile rewriting, T_Tile toAvoid, Dictionary usedViews, RewritingProcessor qp) { RewritingSimplifier simplifier = new RewritingSimplifier(rewriting, toAvoid, usedViews, qp); T_Tile simplifiedRewriting; if (simplifier.SimplifyRewriting(out simplifiedRewriting)) { rewriting = simplifiedRewriting; return true; } return false; } private void GatherUnionedSubqueriesInUsedViews(T_Tile query) { if (query != null) { if (m_qp.GetOpKind(query) != TileOpKind.Union) { m_usedViews[query] = TileOpKind.Union; } else { GatherUnionedSubqueriesInUsedViews(m_qp.GetArg1(query)); GatherUnionedSubqueriesInUsedViews(m_qp.GetArg2(query)); } } } // isExactAnswer: matters for Intersections/Differences only private bool SimplifyRewriting(out T_Tile simplifiedRewriting) { bool compacted = false; simplifiedRewriting = null; T_Tile simplifiedOnce; while (SimplifyRewritingOnce(out simplifiedOnce)) { compacted = true; simplifiedRewriting = simplifiedOnce; } return compacted; } // try removing one redundant view from intersected and subtracted views // This method uses a dynamic divide-and-conquer algorithm that avoids recomputing many intersections/differences private bool SimplifyRewritingOnce(out T_Tile simplifiedRewriting) { // check whether removing one or multiple views from intersected and subtracted views // still (a) reduces extra tuples, and (b) has no missing tuples // First, try removing a subtracted view HashSet remainingViews = new HashSet(m_usedViews.Keys); foreach (T_Tile usedView in m_usedViews.Keys) { // pick an intersected view, and nail it down switch (m_usedViews[usedView]) { case TileOpKind.Join: case TileOpKind.Union: remainingViews.Remove(usedView); if (SimplifyRewritingOnce(usedView, remainingViews, out simplifiedRewriting)) { return true; } remainingViews.Add(usedView); break; } } simplifiedRewriting = null; return false; } // remainingViews may contain either unions only or intersections + differences private bool SimplifyRewritingOnce(T_Tile newRewriting, HashSet remainingViews, out T_Tile simplifiedRewriting) { simplifiedRewriting = null; if (remainingViews.Count == 0) { return false; } if (remainingViews.Count == 1) { // determine the remaining view T_Tile remainingView = remainingViews.First(); // check whether rewriting obtained so far is good enough // try disposing of this remaining view bool isDisposable = false; switch (m_usedViews[remainingView]) { case TileOpKind.Union: // check whether rewriting still covers toFill isDisposable = m_qp.IsContainedIn(m_originalRewriting, newRewriting); break; default: // intersection isDisposable = m_qp.IsContainedIn(m_originalRewriting, newRewriting) && m_qp.IsDisjointFrom(m_toAvoid, newRewriting); break; } if (isDisposable) { // yes, the remaining view is disposable simplifiedRewriting = newRewriting; m_usedViews.Remove(remainingView); return true; } return false; // no, can't trash the remaining view } // split remainingViews into two halves // Compute rewriting for first half. Call recursively on second half. // Then, compute rewriting for second half. Call recursively on first half. int halfCount = remainingViews.Count / 2; int count = 0; T_Tile firstHalfRewriting = newRewriting; T_Tile secondHalfRewriting = newRewriting; HashSet firstHalf = new HashSet(); HashSet secondHalf = new HashSet(); foreach (T_Tile remainingView in remainingViews) { TileOpKind viewKind = m_usedViews[remainingView]; // add to first half if (count++ < halfCount) { firstHalf.Add(remainingView); firstHalfRewriting = GetRewritingHalf(firstHalfRewriting, remainingView, viewKind); } else // add to second half { secondHalf.Add(remainingView); secondHalfRewriting = GetRewritingHalf(secondHalfRewriting, remainingView, viewKind); } } // now, call recursively return SimplifyRewritingOnce(firstHalfRewriting, secondHalf, out simplifiedRewriting) || SimplifyRewritingOnce(secondHalfRewriting, firstHalf, out simplifiedRewriting); } private T_Tile GetRewritingHalf(T_Tile halfRewriting, T_Tile remainingView, TileOpKind viewKind) { switch (viewKind) { case TileOpKind.Join: halfRewriting = m_qp.Join(halfRewriting, remainingView); break; case TileOpKind.AntiSemiJoin: halfRewriting = m_qp.AntiSemiJoin(halfRewriting, remainingView); break; case TileOpKind.Union: halfRewriting = m_qp.Union(halfRewriting, remainingView); break; default: Debug.Fail("unexpected"); break; } return halfRewriting; } } }