MySQL 8.0.39
Source Code Documentation
graph_simplification.h
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23
24#ifndef SQL_JOIN_OPTIMIZER_GRAPH_SIMPLIFICATION_H_
25#define SQL_JOIN_OPTIMIZER_GRAPH_SIMPLIFICATION_H_
26
27/**
28 @file
29
30 Heuristic simplification of query graphs to make them execute faster,
31 largely a direct implementation of [Neu09] (any references to just
32 “the paper” will generally be to that). This is needed for when
33 query hypergraphs have too many possible (connected) subgraphs to
34 evaluate all of them, and we need to resort to heuristics.
35
36 The algorithm works by evaluating pairs of neighboring joins
37 (largely, those that touch some of the same tables), finding obviously _bad_
38 pairwise orderings and then disallowing them. I.e., if join A must
39 very likely happen before join B (as measured by cost heuristics),
40 we disallow the B-before-A join by extending the hyperedge of
41 B to include A's nodes. This makes the graph more visually complicated
42 (thus making “simplification” a bit of a misnomer), but reduces the search
43 space, so that the query generally is faster to plan.
44
45 Obviously, as the algorithm is greedy, it will sometimes make mistakes
46 and make for a more expensive (or at least higher-cost) query.
47 This isn't necessarily an optimal or even particularly good algorithm;
48 e.g. LinDP++ [Rad19] claims significantly better results, especially
49 on joins that are 40 tables or more. However, using graph simplification
50 allows us to handle large queries reasonably well, while still reusing nearly
51 all of our query planning machinery (i.e., we don't have to implement a
52 separate query planner and cost model for large queries).
53
54 Also note that graph simplification only addresses the problem of subgraph
55 pair explosion. If each subgraph pair generates large amounts of candidate
56 access paths (e.g. through parameterized paths), each subgraph pair will in
57 itself be expensive, and graph simplification does not concern itself with
58 this at all. Thus, to get a complete solution, we must _also_ have heuristic
59 pruning of access paths within a subgraph, which we're currently missing.
60
61
62 [Neu09] Neumann: “Query Simplification: Graceful Degradation for Join-Order
63 Optimization”.
64 [Rad19] Radke and Neumann: “LinDP++: Generalizing Linearized DP to
65 Crossproducts and Non-Inner Joins”.
66 */
67
68#include <stddef.h>
69
70#include <string>
71#include <vector>
72
73#include "my_compiler.h"
74#include "priority_queue.h"
77#include "sql/mem_root_array.h"
78#include "sql/sql_array.h"
79
80class THD;
81struct JoinHypergraph;
82struct MEM_ROOT;
83template <class T>
85
86// Exposed for unit testing.
88 public:
90
91 // Do a single simplification step. The return enum is mostly for unit tests;
92 // general code only needs to care about whether it returned
93 // NO_SIMPLIFICATION_POSSIBLE or not.
95 // No (more) simplifications are possible on this hypergraph.
97
98 // We applied a simplification of the graph (forcing one join ahead of
99 // another).
101
102 // We applied a simplification, but it was one that was forced upon us;
103 // we intended to apply the opposite, but discovered it would leave the
104 // graph
105 // in an impossible state. Thus, the graph has been changed, but the actual
106 // available join orderings are exactly as they were.
108
109 // We applied a step that was earlier undone using UndoSimplificationStep().
110 // (We do not know whether it was originally APPLIED_SIMPLIFICATION or
111 // APPLIED_NOOP.)
113 };
115
116 // Undo the last applied simplification step (by DoSimplificationStep()).
117 // Note that this does not reset the internal state, i.e., it only puts
118 // the graph back into the state before the last DoSimplificationStep()
119 // call. This means that the internal happens-before graph and cardinalities
120 // remain as if the step was still done. This is because if calling
121 // DoSimplificationStep() after an UndoSimplificationStep() call,
122 // no new work is done; the change is simply replayed again, with no
123 // new computation done. We only need to search for more simplifications
124 // once we've replayed all undone steps. This also means that we make
125 // the assumption that nobody else is changing the graph during the
126 // lifetime of GraphSimplifier.
127 //
128 // You can call UndoSimplificationStep() several times, as long as there
129 // is at least one simplification step to undo; undo/redo works essentially
130 // as a stack.
132
133 // How many steps we've (successfully) done and not undone.
134 int num_steps_done() const { return m_done_steps.size(); }
135
136 private:
137 // Update the given join's cache in the priority queue (or take it in
138 // or out of the queue), presumably after best_step.benefit has changed
139 // for that join.
140 //
141 // After this operation, m_pq should be in a consistent state.
142 void UpdatePQ(size_t edge_idx);
143
144 // Recalculate the benefit of all orderings involving the given edge,
145 // i.e., the advantage of ordering any other neighboring join before
146 // or after it. (These are stored in m_cache; see NeighborCache for
147 // more information on the scheme.) You will typically need to call this
148 // after having modified the given join (hyperedge endpoint). Note that
149 // if a given ordering has become less advantageous, this may entail
150 // recalculating other nodes recursively as well, but this should be rare
151 // (again, see the comments on NeighborCache).
152 //
153 // “begin” and “end” are the range of other joins to compare against
154 // (edge1_idx itself is always excluded). It should normally be set to
155 // 0 and N (the number of edges) to compare against all, but during the
156 // initial population in the constructor, where every pair is considered,
157 // it is be used to avoid redundant computation.
158 //
159 // It would have been nice to somehow be able to use neighbor-of-neighbor
160 // information to avoid rescanning all candidates for neighbors
161 // (and the paper mentions “materializing all neighbors of a join”),
162 // but given how hyperedges work, there doesn't seem to be a trivial way
163 // of doing that (after A has absorbed B's into one of its hyperedges,
164 // it seems it could gain new neighbors that were neither neighbors of
165 // A nor B).
166 void RecalculateNeighbors(size_t edge1_idx, size_t begin, size_t end);
167
169 double benefit;
172 };
173
174 // Returns whether two joins are neighboring (share edges),
175 // and if so, estimates the benefit of joining one before the other
176 // (including which one should be first) and writes into “step”.
177 ALWAYS_INLINE bool EdgesAreNeighboring(size_t edge1_idx, size_t edge2_idx,
179
183
184 // Old and new versions of after_edge_idx.
187 };
188
189 // Convert a simplification step (join A before join B) to an actual
190 // idea of how to modify the given edge (new values for join B's
191 // hyperedge endpoints).
194
195 // Steps that we have applied so far, in chronological order.
196 // Used so that we can undo them easily on UndoSimplificationStep().
198
199 // Steps that we used to have applied, but have undone, in chronological
200 // order of the undo (ie., latest undone step last).
201 // DoSimplificationStep() will use these to quickly reapply an undone
202 // step if needed (and then move it to the end of done_steps again).
204
205 // Cache the cardinalities of (a join of) the nodes on each side of each
206 // hyperedge, corresponding 1:1 index-wise to m_graph->edges. So if
207 // e.g. m_graph->graph.edges[0].left contains {t1,t2,t4}, then
208 // m_edge_cardinalities[0].left will contain the cardinality of joining
209 // t1, t2 and t4 together.
210 //
211 // This cache is so that we don't need to make repeated calls to
212 // GetCardinality(), which is fairly expensive. It is updated when we
213 // apply simplification steps (which change the hyperedges).
215 double left;
216 double right;
217 };
219
220 // The graph we are simplifying.
222
223 // Stores must-happen-before relationships between the joins (edges),
224 // so that we don't end up with impossibilities. See OnlineCycleFinder
225 // for more information.
227
228 // Used for storing which neighbors are possible to simplify,
229 // and how attractive they are. This speeds up repeated application of
230 // DoSimplificationStep() significantly, as we don't have to recompute
231 // the same information over and over again. This is keyed on the numerically
232 // lowest join of the join pair, i.e., information about the benefit of
233 // ordering join A before or after join B is stored on m_cache[min(A,B)].
234 // These take part in a priority queue (see m_pq below), so that we always
235 // know cheaply which one is the most attractive.
236 //
237 // There is a maybe surprising twist here; for any given cache node (join),
238 // we only store the most beneficial ordering, and throw away all others.
239 // This is because our benefit values keep changing all the time; once we've
240 // chosen to put A before B, it means we've changed B, and that means every
241 // single join pair involving B now needs to be recalculated anyway
242 // (the costs, and thus ordering benefits, are highly dependent on the
243 // hyperedge of B). Thus, storing only the best one (and by extension,
244 // not having information about the other ones in the priority queue)
245 // allows us to very quickly and easily throw away half of the invalidated
246 // ones. We still need to check the other half (the ones that may be the best
247 // for other nodes) to see if we need to invalidate them, but actual
248 // invalidation is rare, as it only happens for the best simplification
249 // involving that node (i.e., 1/N).
250 //
251 // It's unclear if this is the same scheme that the paper alludes to;
252 // it mentions a priority queue and ordering by neighbor-involving joins,
253 // but very little detail.
255 // The best simplification involving this join and a higher-indexed join,
256 // and the index of that other node. (best_neighbor could be inferred
257 // from the indexes in best_step and this index, but we keep it around
258 // for simplicity.) best_neighbor == -1 indicates that there are no
259 // possible reorderings involving this join and a higher-indexed one
260 // (so it should not take part in the priority queue).
263
264 // Where we are in the priority queue (heap index);
265 // Priority_queue will update this for us (through MarkNeighborCache)
266 // whenever we are insert into or moved around in the queue.
267 // This is so that we can easily tell the PQ to recalculate our position
268 // whenever best_step.benefit changes. -1 means that we are
269 // currently not in the priority queue.
270 int index_in_pq = -1;
271 };
273
274 // A priority queue of which simplifications are the most attractive,
275 // containing pointers into m_cache. See the documentation on NeighborCache
276 // for more information.
278 bool operator()(const NeighborCache *a, const NeighborCache *b) const {
279 return a->best_step.benefit < b->best_step.benefit;
280 }
281 };
283 void operator()(size_t index, NeighborCache **cache) {
284 (*cache)->index_in_pq = index;
285 }
286 };
288 NeighborCache *,
289 std::vector<NeighborCache *, Mem_root_allocator<NeighborCache *>>,
290 CompareByBenefit, MarkNeighborCache>
292};
293
294// See comment in .cc file.
295void SimplifyQueryGraph(THD *thd, int subgraph_pair_limit,
296 JoinHypergraph *graph, std::string *trace);
297
298#endif // SQL_JOIN_OPTIMIZER_GRAPH_SIMPLIFICATION_H_
A wrapper class which provides array bounds checking.
Definition: sql_array.h:47
Definition: graph_simplification.h:87
ALWAYS_INLINE bool EdgesAreNeighboring(size_t edge1_idx, size_t edge2_idx, ProposedSimplificationStep *step)
Definition: graph_simplification.cc:648
Bounds_checked_array< NeighborCache > m_cache
Definition: graph_simplification.h:272
Bounds_checked_array< EdgeCardinalities > m_edge_cardinalities
Definition: graph_simplification.h:218
void RecalculateNeighbors(size_t edge1_idx, size_t begin, size_t end)
Definition: graph_simplification.cc:597
SimplificationStep ConcretizeSimplificationStep(GraphSimplifier::ProposedSimplificationStep step)
Definition: graph_simplification.cc:770
JoinHypergraph * m_graph
Definition: graph_simplification.h:221
SimplificationResult
Definition: graph_simplification.h:94
@ APPLIED_REDO_STEP
Definition: graph_simplification.h:112
@ NO_SIMPLIFICATION_POSSIBLE
Definition: graph_simplification.h:96
@ APPLIED_SIMPLIFICATION
Definition: graph_simplification.h:100
@ APPLIED_NOOP
Definition: graph_simplification.h:107
void UndoSimplificationStep()
Definition: graph_simplification.cc:899
SimplificationResult DoSimplificationStep()
Definition: graph_simplification.cc:825
Mem_root_array< SimplificationStep > m_undone_steps
Definition: graph_simplification.h:203
void UpdatePQ(size_t edge_idx)
Definition: graph_simplification.cc:577
int num_steps_done() const
Definition: graph_simplification.h:134
Priority_queue< NeighborCache *, std::vector< NeighborCache *, Mem_root_allocator< NeighborCache * > >, CompareByBenefit, MarkNeighborCache > m_pq
Definition: graph_simplification.h:291
OnlineCycleFinder m_cycles
Definition: graph_simplification.h:226
Mem_root_array< SimplificationStep > m_done_steps
Definition: graph_simplification.h:197
GraphSimplifier(JoinHypergraph *graph, MEM_ROOT *mem_root)
Definition: graph_simplification.cc:553
Mem_root_allocator is a C++ STL memory allocator based on MEM_ROOT.
Definition: mem_root_allocator.h:68
A typesafe replacement for DYNAMIC_ARRAY.
Definition: mem_root_array.h:426
A fast online cycle finder, based on [Pea03].
Definition: online_cycle_finder.h:54
Implements a priority queue using a vector-based max-heap.
Definition: priority_queue.h:104
For each client connection we create a separate thread with THD serving as a thread/connection descri...
Definition: sql_lexer_thd.h:34
static MEM_ROOT mem_root
Definition: client_plugin.cc:110
void SimplifyQueryGraph(THD *thd, int subgraph_pair_limit, JoinHypergraph *graph, std::string *trace)
Definition of an undirected (join) hypergraph.
Header for compiler-dependent features.
#define ALWAYS_INLINE
Definition: my_compiler.h:110
Cursor end()
A past-the-end Cursor.
Definition: rules_table_service.cc:192
Definition: graph_simplification.h:277
bool operator()(const NeighborCache *a, const NeighborCache *b) const
Definition: graph_simplification.h:278
Definition: graph_simplification.h:214
double left
Definition: graph_simplification.h:215
double right
Definition: graph_simplification.h:216
Definition: graph_simplification.h:282
void operator()(size_t index, NeighborCache **cache)
Definition: graph_simplification.h:283
Definition: graph_simplification.h:254
int best_neighbor
Definition: graph_simplification.h:261
ProposedSimplificationStep best_step
Definition: graph_simplification.h:262
int index_in_pq
Definition: graph_simplification.h:270
Definition: graph_simplification.h:168
int before_edge_idx
Definition: graph_simplification.h:170
int after_edge_idx
Definition: graph_simplification.h:171
double benefit
Definition: graph_simplification.h:169
Definition: graph_simplification.h:180
int after_edge_idx
Definition: graph_simplification.h:182
int before_edge_idx
Definition: graph_simplification.h:181
hypergraph::Hyperedge new_edge
Definition: graph_simplification.h:186
hypergraph::Hyperedge old_edge
Definition: graph_simplification.h:185
A struct containing a join hypergraph of a single query block, encapsulating the constraints given by...
Definition: make_join_hypergraph.h:77
The MEM_ROOT is a simple arena, where allocations are carved out of larger blocks.
Definition: my_alloc.h:83
Definition: hypergraph.h:80