Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
The estimation functions assume the inner relation join column is unique. But it freezes (flushes back to the main hash table) one skew bucket at a time in order of least importance so if 100 inner tuples can fit in the skew buckets then the skew buckets are only fully blown out if the best tuple (the single most common value) occurs more than 100 times in the inner relation. And up until that point you still have the tuples in memory that are the best "per tuple worth of memory". But yes, after that point (more than 100 tuples of that best MCV) the entire effort was wasted. The skew buckets are dynamically flushed just like buckets in a dynamic hash join would be. - Bryce Cutt On Fri, Mar 20, 2009 at 5:51 PM, Robert Haas wrote: > On Fri, Mar 20, 2009 at 8:45 PM, Bryce Cutt wrote: >> On Fri, Mar 20, 2009 at 5:35 PM, Robert Haas wrote: >>> If the inner relation isn't fairly close to unique you shouldn't be >>> using this optimization in the first place. >> Not necessarily true. Seeing as (when the statistics are correct) we >> know each of these inner tuples will match with the largest amount of >> outer tuples it is just as much of a win per inner tuple as when they >> are unique. There is just a chance you will have to give up on the >> optimization part way through if too many inner tuples fall into the >> new "skew buckets" (formerly IM buckets) and dump the tuples back into >> the main buckets. The potential win is still pretty high though. >> >> - Bryce Cutt > > Maybe I'm remembering wrong, but I thought the estimating functions > assuemd that the inner relation was unique. So if there turn out to > be 2, 3, 4, or more copies of each value, the chances of blowing out > the skew hash table are almost 100%, I would think... am I wrong? > > ...Robert > -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Not necessarily true. Seeing as (when the statistics are correct) we know each of these inner tuples will match with the largest amount of outer tuples it is just as much of a win per inner tuple as when they are unique. There is just a chance you will have to give up on the optimization part way through if too many inner tuples fall into the new "skew buckets" (formerly IM buckets) and dump the tuples back into the main buckets. The potential win is still pretty high though. - Bryce Cutt On Fri, Mar 20, 2009 at 5:35 PM, Robert Haas wrote: > On Fri, Mar 20, 2009 at 8:14 PM, Tom Lane wrote: >> Bryce Cutt writes: >>> Here is the new patch. >> >> Applied with revisions. I undid some of the "optimizations" that >> cluttered the code in order to save a cycle or two per tuple --- as per >> previous discussion, that's not what the performance questions were >> about. Also, I did not like the terminology "in-memory"/"IM"; it seemed >> confusing since the main hash table is in-memory too. I revised the >> code to consistently refer to the additional hash table as a "skew" >> hashtable and the optimization in general as skew optimization. Hope >> that seems reasonable to you --- we could search-and-replace it to >> something else if you'd prefer. >> >> For the moment, I didn't really do anything about teaching the planner >> to account for this optimization in its cost estimates. The initial >> estimate of the number of MCVs that will be specially treated seems to >> me to be too high (it's only accurate if the inner relation is unique), >> but getting a more accurate estimate seems pretty hard, and it's not >> clear it's worth the trouble. Without that, though, you can't tell >> what fraction of outer tuples will get the short-circuit treatment. > > If the inner relation isn't fairly close to unique you shouldn't be > using this optimization in the first place. > > ...Robert > -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Fri, Mar 20, 2009 at 8:45 PM, Bryce Cutt wrote: > On Fri, Mar 20, 2009 at 5:35 PM, Robert Haas wrote: >> If the inner relation isn't fairly close to unique you shouldn't be >> using this optimization in the first place. > Not necessarily true. Seeing as (when the statistics are correct) we > know each of these inner tuples will match with the largest amount of > outer tuples it is just as much of a win per inner tuple as when they > are unique. There is just a chance you will have to give up on the > optimization part way through if too many inner tuples fall into the > new "skew buckets" (formerly IM buckets) and dump the tuples back into > the main buckets. The potential win is still pretty high though. > > - Bryce Cutt Maybe I'm remembering wrong, but I thought the estimating functions assuemd that the inner relation was unique. So if there turn out to be 2, 3, 4, or more copies of each value, the chances of blowing out the skew hash table are almost 100%, I would think... am I wrong? ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Fri, Mar 20, 2009 at 8:45 PM, Bryce Cutt wrote: > On Fri, Mar 20, 2009 at 5:35 PM, Robert Haas wrote: >> If the inner relation isn't fairly close to unique you shouldn't be >> using this optimization in the first place. > Not necessarily true. Seeing as (when the statistics are correct) we > know each of these inner tuples will match with the largest amount of > outer tuples it is just as much of a win per inner tuple as when they > are unique. There is just a chance you will have to give up on the > optimization part way through if too many inner tuples fall into the > new "skew buckets" (formerly IM buckets) and dump the tuples back into > the main buckets. The potential win is still pretty high though. > > - Bryce Cutt Maybe I'm remembering wrong, but I thought the estimating functions assuemd that the inner relation was unique. So if there turn out to be 2, 3, 4, or more copies of each value, the chances of blowing out the skew hash table are almost 100%, I would think... am I wrong? ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Fri, Mar 20, 2009 at 8:14 PM, Tom Lane wrote: > Bryce Cutt writes: >> Here is the new patch. > > Applied with revisions. I undid some of the "optimizations" that > cluttered the code in order to save a cycle or two per tuple --- as per > previous discussion, that's not what the performance questions were > about. Also, I did not like the terminology "in-memory"/"IM"; it seemed > confusing since the main hash table is in-memory too. I revised the > code to consistently refer to the additional hash table as a "skew" > hashtable and the optimization in general as skew optimization. Hope > that seems reasonable to you --- we could search-and-replace it to > something else if you'd prefer. > > For the moment, I didn't really do anything about teaching the planner > to account for this optimization in its cost estimates. The initial > estimate of the number of MCVs that will be specially treated seems to > me to be too high (it's only accurate if the inner relation is unique), > but getting a more accurate estimate seems pretty hard, and it's not > clear it's worth the trouble. Without that, though, you can't tell > what fraction of outer tuples will get the short-circuit treatment. If the inner relation isn't fairly close to unique you shouldn't be using this optimization in the first place. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Bryce Cutt writes: > Here is the new patch. Applied with revisions. I undid some of the "optimizations" that cluttered the code in order to save a cycle or two per tuple --- as per previous discussion, that's not what the performance questions were about. Also, I did not like the terminology "in-memory"/"IM"; it seemed confusing since the main hash table is in-memory too. I revised the code to consistently refer to the additional hash table as a "skew" hashtable and the optimization in general as skew optimization. Hope that seems reasonable to you --- we could search-and-replace it to something else if you'd prefer. For the moment, I didn't really do anything about teaching the planner to account for this optimization in its cost estimates. The initial estimate of the number of MCVs that will be specially treated seems to me to be too high (it's only accurate if the inner relation is unique), but getting a more accurate estimate seems pretty hard, and it's not clear it's worth the trouble. Without that, though, you can't tell what fraction of outer tuples will get the short-circuit treatment. regards, tom lane -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> > I think you missed the point of the performance questions. It wasn't > > about avoiding extra simple if-tests in the per-tuple loops; a few of > > those are certainly not going to add measurable cost given how complex > > the code is already. (I really don't think you should be duplicating > > hunks of code to avoid adding such tests.) Rather, the concern was that > > if we are dedicating a fraction of available work_mem to this purpose, > > that reduces the overall efficiency of the regular non-IM code path, > > principally by forcing the creation of more batches than would otherwise > > be needed. It's not clear whether the savings for IM tuples always > > exceeds this additional cost. I misunderstood the concern. So, there is no issue with the patch when it is disabled (single batch case or multi-batch with no skew)? There is no memory allocated when the optimization is off, so these cases will not affect the number of batches or re-partitioning. > > * The IM hashtable is only needed during the first-batch processing; > > once we've completed the first pass over the outer relation there is > > no longer any need for it, unless I'm misunderstanding things > > completely. Therefore it really only competes for space with the > > regular first batch. However the damage to nbatches will already have > > been done; in effect, we can expect that each subsequent batch will > > probably only use (100 - IM_WORK_MEM_PERCENT)% of work_mem. The patch > > seems to try to deal with this by keeping IM_WORK_MEM_PERCENT negligibly > > small, but surely that's mostly equivalent to fighting with one hand > > tied behind your back. I wonder if it'd be better to dedicate all of > > work_mem to the MCV hash values during the first pass, rather than > > allowing them to compete with the first regular batch. > > The IM hash table doesn't need to be very large in order to produce a > substantial benefit, because there are only going to be ~100 MCVs in > the probe table and each of those may well be unique in the build > table. But no matter what size you choose for it, there's some danger > that it will push us over the edge into more batches, and if the skew > doesn't turn out to be enough to make up for that, you lose. I'm not > sure there's any way to completely eliminate that unpleasant > possibility. Correct - The IM table only competes with the first-batch during processing and is removed after the first pass. Also, it tends to be VERY small as the default of 100 MCVs usually results in 100 tuples being in the IM table which is normally much less than 2% of work_mem. We get almost all the benefit with 100-1 MCVs with little downside risk. Making the IM table larger (size of work_mem) is both not possible (not that many MCVs) and has a bigger downside risk if we get it wrong. > > * The IM hashtable creates an additional reason why nbatch might > > increase during the initial scan of the inner relation; in fact, since > > it's an effect not modeled in the initial choice of nbatch, it's > > probably going to be a major reason for that to happen. Increasing > > nbatch on the fly isn't good because it results in extra I/O for tuples > > that were previously assigned to what is now the wrong batch. Again, > > the only answer the patch has for this is to try not to use enough > > of work_mem for it to make a difference. Seems like instead the initial > > nbatch estimate needs to account for that. The possibility of the 1-2% IM_WORK_MEM_PERCENT causing a re-batch exists but is very small. The number of batches is calculated in ExecChooseHashTableSize (costsize.c) as ceil(inner_rel_bytes/work_mem) rounded up to the next power of 2. Thus, hash join already "wastes" some of its work_mem allocation due to rounding. For instance, if nbatch is calculated as 3 then rounded up to 4, only 75% of work_mem is used for each batch. This leaves 25% of work_mem "unaccounted for" which may be used by the IM table (and also to compensate for build skew). Clearly, if nbatch is exactly 4, then this unaccounted space is not present and if the optimizer is exact in its estimates, the extra 1-2% may force a re-partition. A solution may be to re-calculate nbatch factoring in the extra 1-2% during ExecHashTableCreate (nodeHashjoin.c) which calls ExecChooseHashTableSize again before execution. The decision is whether to modify ExecChooseHashTableSize itself (which is used during costing) or to make a modified ExecChooseHashTableSize function that is only used once in ExecHashTableCreate. We have tried to change the original code as little as possible, but it is possible to modify ExecChooseHashTableSize and the hash join cost function to be skew optimization aware. -- Ramon Lawrence -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Fri, Mar 6, 2009 at 1:57 PM, Tom Lane wrote: > Bryce Cutt writes: >> Here is the new patch. >> Our experiments show no noticeable performance issue when using the >> patch for cases where the optimization is not used because the number >> of extra statements executed when the optimization is disabled is >> insignificant. > >> We have updated the patch to remove a couple of if statements, but >> this is really minor. The biggest change was to MultiExecHash that >> avoids an if check per tuple by duplicating the hashing loop. > > I think you missed the point of the performance questions. It wasn't > about avoiding extra simple if-tests in the per-tuple loops; a few of > those are certainly not going to add measurable cost given how complex > the code is already. (I really don't think you should be duplicating > hunks of code to avoid adding such tests.) Rather, the concern was that Well, at one point we were still trying to verify that (1) the patch actually had a benefit and (2) blowing out the IM hashtable wasn't too horribly nasty. A great deal of improvement has been made in those areas since this was first reviewed. But your questions are completely valid, too. (I don't think anyone ever expressed a concern about the simple if-tests, either.) > if we are dedicating a fraction of available work_mem to this purpose, > that reduces the overall efficiency of the regular non-IM code path, > principally by forcing the creation of more batches than would otherwise > be needed. It's not clear whether the savings for IM tuples always > exceeds this additional cost. > > After looking over the code a bit, there are two points that > particularly concern me in this connection: > > * The IM hashtable is only needed during the first-batch processing; > once we've completed the first pass over the outer relation there is > no longer any need for it, unless I'm misunderstanding things > completely. Therefore it really only competes for space with the > regular first batch. However the damage to nbatches will already have > been done; in effect, we can expect that each subsequent batch will > probably only use (100 - IM_WORK_MEM_PERCENT)% of work_mem. The patch > seems to try to deal with this by keeping IM_WORK_MEM_PERCENT negligibly > small, but surely that's mostly equivalent to fighting with one hand > tied behind your back. I wonder if it'd be better to dedicate all of > work_mem to the MCV hash values during the first pass, rather than > allowing them to compete with the first regular batch. The IM hash table doesn't need to be very large in order to produce a substantial benefit, because there are only going to be ~100 MCVs in the probe table and each of those may well be unique in the build table. But no matter what size you choose for it, there's some danger that it will push us over the edge into more batches, and if the skew doesn't turn out to be enough to make up for that, you lose. I'm not sure there's any way to completely eliminate that unpleasant possibility. > * The IM hashtable creates an additional reason why nbatch might > increase during the initial scan of the inner relation; in fact, since > it's an effect not modeled in the initial choice of nbatch, it's > probably going to be a major reason for that to happen. Increasing > nbatch on the fly isn't good because it results in extra I/O for tuples > that were previously assigned to what is now the wrong batch. Again, > the only answer the patch has for this is to try not to use enough > of work_mem for it to make a difference. Seems like instead the initial > nbatch estimate needs to account for that. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Bryce Cutt writes: > Here is the new patch. > Our experiments show no noticeable performance issue when using the > patch for cases where the optimization is not used because the number > of extra statements executed when the optimization is disabled is > insignificant. > We have updated the patch to remove a couple of if statements, but > this is really minor. The biggest change was to MultiExecHash that > avoids an if check per tuple by duplicating the hashing loop. I think you missed the point of the performance questions. It wasn't about avoiding extra simple if-tests in the per-tuple loops; a few of those are certainly not going to add measurable cost given how complex the code is already. (I really don't think you should be duplicating hunks of code to avoid adding such tests.) Rather, the concern was that if we are dedicating a fraction of available work_mem to this purpose, that reduces the overall efficiency of the regular non-IM code path, principally by forcing the creation of more batches than would otherwise be needed. It's not clear whether the savings for IM tuples always exceeds this additional cost. After looking over the code a bit, there are two points that particularly concern me in this connection: * The IM hashtable is only needed during the first-batch processing; once we've completed the first pass over the outer relation there is no longer any need for it, unless I'm misunderstanding things completely. Therefore it really only competes for space with the regular first batch. However the damage to nbatches will already have been done; in effect, we can expect that each subsequent batch will probably only use (100 - IM_WORK_MEM_PERCENT)% of work_mem. The patch seems to try to deal with this by keeping IM_WORK_MEM_PERCENT negligibly small, but surely that's mostly equivalent to fighting with one hand tied behind your back. I wonder if it'd be better to dedicate all of work_mem to the MCV hash values during the first pass, rather than allowing them to compete with the first regular batch. * The IM hashtable creates an additional reason why nbatch might increase during the initial scan of the inner relation; in fact, since it's an effect not modeled in the initial choice of nbatch, it's probably going to be a major reason for that to happen. Increasing nbatch on the fly isn't good because it results in extra I/O for tuples that were previously assigned to what is now the wrong batch. Again, the only answer the patch has for this is to try not to use enough of work_mem for it to make a difference. Seems like instead the initial nbatch estimate needs to account for that. regards, tom lane -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Here is the new patch. Our experiments show no noticeable performance issue when using the patch for cases where the optimization is not used because the number of extra statements executed when the optimization is disabled is insignificant. We have updated the patch to remove a couple of if statements, but this is really minor. The biggest change was to MultiExecHash that avoids an if check per tuple by duplicating the hashing loop. To demonstrate the differences, here is an analysis of the code changes and their impact. Three cases: 1) One batch hash join - Optimization is disabled. Extra statements executed are: - One if (hashtable->nbatch > 1) in ExecHashJoin (line 356 of nodeHashjoin.c) - One if optimization_on in MultiExecHash (line 259 of nodeHash.c) - One if optimization_on in MultiExecHash per probe tuple (line 431 of nodeHashjoin.c) - One if statement in ExecScanHashBucket per probe tuple (line 1071 of nodeHash.c) 2) Multi-batch hash join with limited skew - Optimization is disabled. Extra statements executed are: - One if (hashtable->nbatch > 1) in ExecHashJoin (line 356 of nodeHashjoin.c) - Executes ExecHashJoinDetectSkew method (at line 357 of nodeHashjoin.c) that reads stats tuple for probe relation attribute and determines if skew is above cut-off. In this case, skew is not above cutoff and no extra memory is used. - One if optimization_on in MultiExecHash (line 259 of nodeHash.c) - One if optimization_on in MultiExecHash per probe tuple (line 431 of nodeHashjoin.c) - One if statement in ExecScanHashBucket per probe tuple (line 1071 of nodeHash.c) 3) Multi-batch hash join with skew - Optimization is enabled. Extra statements executed are: - One if (hashtable->nbatch > 1) in ExecHashJoin (line 356 of nodeHashjoin.c) - Executes ExecHashJoinDetectSkew method (at line 357 of nodeHashjoin.c) that reads stats tuple for probe relation attribute and determines there is skew. Allocates space for XXX which is 2% of work_mem. - One if optimization_on in MultiExecHash (line 259 of nodeHash.c) - In MultiExecHash after each tuple is hashed determines if its join attribute value matches one of the MCVs. If it does, it is put in the MCV structure. Cost is the hash and search for each build tuple. - If all IM buckets end up frozen in the build phase (MultiExecHash) because they grow larger than the memory allowed for IM buckets then skew optimization is turned off and the probe phase reverts to Case 2 - For each probe tuple, determines if its value is a MCV by performing hash and quick table lookup. If yes, probes MCV bucket otherwise does regular hash algorithm as usual. - One if statement in ExecScanHashBucket per probe tuple (line 1071 of nodeHash.c) - Additional cost is determining if a tuple is a common tuple (both on build and probe side). This additional cost is dramatically outweighed by avoiding disk I/Os (even if they never hit the disk due to caching). The if statement on line 440 of nodeHashjoin.c (in ExecHashJoin) has been rearranged so that in the single batch case short circuit evaluation requires only the first test in the IF to be checked. The "limited skew" check mentioned in Case 2 above is a simple check in the ExecHashJoinDetectSkew function. - Bryce Cutt On Thu, Feb 26, 2009 at 12:16 PM, Bryce Cutt wrote: > The patch originally modified the cost function but I removed that > part before we submitted it to be a bit conservative about our > proposed changes. I didn't like that for large plans the statistics > were retrieved and calculated many times when finding the optimal > query plan. > > The overhead of the algorithm when the skew optimization is not used > ends up being roughly a function call and an if statement per tuple. > It would be easy to remove the function call per tuple. Dr. Lawrence > has come up with some changes so that when the optimization is turned > off, the function call does not happen at all and instead of the if > statement happening per tuple it is run just once per join. We have > to test this a bit more but it should further reduce the overhead. > > Hopefully we will have the new patch ready to go this weekend. > > - Bryce Cutt > > > On Thu, Feb 26, 2009 at 7:45 AM, Tom Lane wrote: >> Heikki's got a point here: the planner is aware that hashjoin doesn't >> like skewed distributions, and it assigns extra cost accordingly if it >> can determine that the join key is skewed. (See the "bucketsize" stuff >> in cost_hashjoin.) If this patch is accepted we'll want to tweak that >> code. >> >> Still, that has little to do with the current gating issue, which is >> whether we've convinced ourselves that the patch doesn't cause a >> performance decrease for cases in which it's unable to help. >> >> regards, tom lane >> > histojoin_v6.patch Description: Binary data -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mail
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
The patch originally modified the cost function but I removed that part before we submitted it to be a bit conservative about our proposed changes. I didn't like that for large plans the statistics were retrieved and calculated many times when finding the optimal query plan. The overhead of the algorithm when the skew optimization is not used ends up being roughly a function call and an if statement per tuple. It would be easy to remove the function call per tuple. Dr. Lawrence has come up with some changes so that when the optimization is turned off, the function call does not happen at all and instead of the if statement happening per tuple it is run just once per join. We have to test this a bit more but it should further reduce the overhead. Hopefully we will have the new patch ready to go this weekend. - Bryce Cutt On Thu, Feb 26, 2009 at 7:45 AM, Tom Lane wrote: > Heikki's got a point here: the planner is aware that hashjoin doesn't > like skewed distributions, and it assigns extra cost accordingly if it > can determine that the join key is skewed. (See the "bucketsize" stuff > in cost_hashjoin.) If this patch is accepted we'll want to tweak that > code. > > Still, that has little to do with the current gating issue, which is > whether we've convinced ourselves that the patch doesn't cause a > performance decrease for cases in which it's unable to help. > > regards, tom lane > -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> From: Tom Lane > Heikki's got a point here: the planner is aware that hashjoin doesn't > like skewed distributions, and it assigns extra cost accordingly if it > can determine that the join key is skewed. (See the "bucketsize" stuff > in cost_hashjoin.) If this patch is accepted we'll want to tweak that > code. Those modifications would make the optimizer more likely to select hash join, even with skewed distributions. For the TPC-H data set that we are using the optimizer always picks hash join over merge join (single or multi-batch). Since the current patch does not change the cost function, there is no change in the planning cost. It may or may not be useful to modify the cost function depending on the effect on planning cost. > Still, that has little to do with the current gating issue, which is > whether we've convinced ourselves that the patch doesn't cause a > performance decrease for cases in which it's unable to help. Although we have not seen an overhead when the optimization is by-passed, we are looking at some small code changes that would guarantee that no extra statements are executed for the single batch case. Currently, an if optimization_on check is performed on each probe tuple which, although minor, should be able to be avoided. The patch's author, Bryce Cutt, is defending his Master's thesis Friday morning (on this work), so we will provide some updated code right after that. Since these code changes are small, they should not affect people trying to test the performance of the current patch. -- Ramon Lawrence -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Heikki's got a point here: the planner is aware that hashjoin doesn't like skewed distributions, and it assigns extra cost accordingly if it can determine that the join key is skewed. (See the "bucketsize" stuff in cost_hashjoin.) If this patch is accepted we'll want to tweak that code. Still, that has little to do with the current gating issue, which is whether we've convinced ourselves that the patch doesn't cause a performance decrease for cases in which it's unable to help. regards, tom lane -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Thu, Feb 26, 2009 at 08:22:52AM -0500, Robert Haas wrote: > On Thu, Feb 26, 2009 at 4:22 AM, Heikki Linnakangas > wrote: > > Joshua, in the tests that you've been running, did you have to rig the > > planner with "enable_mergjoin=off" or similar, to get the queries to use > > hash joins? > > I didn't have to fiddle anything, but Josh's tests were more exhaustive. The planner chose hash joins for the queries I was running, regardless of whether the patch was applied. I didn't have to mess with any settings to get hash joins. - Josh signature.asc Description: Digital signature
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Wed, Feb 25, 2009 at 10:24:21PM -0500, Robert Haas wrote: > I don't think we're really doing this the right way. EXPLAIN ANALYZE > has a measurable effect on the results, and we probably ought to stop > the database and drop the VM caches after each query. Are the Z1-Z7 > datasets on line someplace? I might be able to rig up a script here. > > ...Robert They're automatically generated by the dbgen utility, a link to which was originally published somewhere in this thread. That tool creates a few text files suitable (with some tweaking) for a COPY command. I've got the original files... the .tbz I just made is 1.8 GB :) Anyone have someplace they'd like me to drop it? - Josh signature.asc Description: Digital signature
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Thu, Feb 26, 2009 at 4:22 AM, Heikki Linnakangas wrote: > I haven't been following this thread closely, so pardon if this has been > discussed already. > > The patch doesn't seem to change the cost estimates in the planner at all. > Without that, I'd imagine that the planner rarely chooses a multi-batch hash > join to begin with. AFAICS, a multi-batch hash join happens when you are joining two big, unsorted paths. The planner essentially compares the cost of sorting the two paths and then merge-joining them versus the cost of a hash join. It doesn't seem to be unusual for the hash join to come out the winner, although admittedly I haven't played with it a ton. You certainly could try to model it in the costing algorithm, but I'm not sure how much benefit you'd get out of it: if you're doing this a lot you're probably better off creating indices. > Joshua, in the tests that you've been running, did you have to rig the > planner with "enable_mergjoin=off" or similar, to get the queries to use > hash joins? I didn't have to fiddle anything, but Josh's tests were more exhaustive. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
I haven't been following this thread closely, so pardon if this has been discussed already. The patch doesn't seem to change the cost estimates in the planner at all. Without that, I'd imagine that the planner rarely chooses a multi-batch hash join to begin with. Joshua, in the tests that you've been running, did you have to rig the planner with "enable_mergjoin=off" or similar, to get the queries to use hash joins? -- Heikki Linnakangas EnterpriseDB http://www.enterprisedb.com -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Wed, Feb 25, 2009 at 12:38 AM, Lawrence, Ramon wrote: >> -Original Message- >> From: Robert Haas >> Sadly, there seem to be a number of cases in the Z7 database where the >> optimization makes things significantly worse (specifically, queries >> 2, 3, and 7, but especially query 3). Have you investigated what is >> going on there? I had thought that we had sufficient safeguards in >> place to prevent this optimization from kicking in in cases where it >> doesn't help, but it seems not. There will certainly be real-world >> databases that are more like Z7 than Z1. > > I agree that there should be no noticeable performance difference when > the optimization is not used (single batch case or no skew). I think > the patch achieves this. The optimization is not used in those cases, > but we will review to see if it is the code that by-passes the > optimization that is causing a difference. Yeah we need to understand what's going on there. > The query #3 timing difference is primarily due to a flaw in the > experimental setup. For some reason, query #3 got executed before #4 > with the optimization on, and executed after #4 with the optimization > off. This skewed the results for all runs (due to buffering issues), > but is especially noticeable for Z7. Note how query #4 is always faster > for the optimization on version even though the optimization is not > actually used for those queries (because they were one batch). I expect > that if you run query #3 on Z7 in isolation then the results should be > basically identical. > > I have attached the SQL script that Joshua sent me. The raw data I have > posted at: http://people.ok.ubc.ca/rlawrenc/test.output I don't think we're really doing this the right way. EXPLAIN ANALYZE has a measurable effect on the results, and we probably ought to stop the database and drop the VM caches after each query. Are the Z1-Z7 datasets on line someplace? I might be able to rig up a script here. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> -Original Message- > From: Robert Haas > Sadly, there seem to be a number of cases in the Z7 database where the > optimization makes things significantly worse (specifically, queries > 2, 3, and 7, but especially query 3). Have you investigated what is > going on there? I had thought that we had sufficient safeguards in > place to prevent this optimization from kicking in in cases where it > doesn't help, but it seems not. There will certainly be real-world > databases that are more like Z7 than Z1. I agree that there should be no noticeable performance difference when the optimization is not used (single batch case or no skew). I think the patch achieves this. The optimization is not used in those cases, but we will review to see if it is the code that by-passes the optimization that is causing a difference. The query #3 timing difference is primarily due to a flaw in the experimental setup. For some reason, query #3 got executed before #4 with the optimization on, and executed after #4 with the optimization off. This skewed the results for all runs (due to buffering issues), but is especially noticeable for Z7. Note how query #4 is always faster for the optimization on version even though the optimization is not actually used for those queries (because they were one batch). I expect that if you run query #3 on Z7 in isolation then the results should be basically identical. I have attached the SQL script that Joshua sent me. The raw data I have posted at: http://people.ok.ubc.ca/rlawrenc/test.output -- Ramon Lawrence test.sql Description: test.sql -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> Joshua sent us some preliminary data with this query and others and indicated > that we could post it. He wanted time to clean it up > and re-run some experiments, but the data is generally good and the algorithm > performs as expected. I have attached this data to the > post. Note that the last set of data (although labelled as Z7) is actually > an almost zero skew database and represents the worst-case > for the algorithm (for most queries the optimization is not even used). Sadly, there seem to be a number of cases in the Z7 database where the optimization makes things significantly worse (specifically, queries 2, 3, and 7, but especially query 3). Have you investigated what is going on there? I had thought that we had sufficient safeguards in place to prevent this optimization from kicking in in cases where it doesn't help, but it seems not. There will certainly be real-world databases that are more like Z7 than Z1. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Thu, Feb 19, 2009 at 01:50:55PM -0700, Josh Tolley wrote: > (my new daughter will be 24 hours old in a little bit, though, so it > might be a while!) Pics! Cheers, David. -- David Fetter http://fetter.org/ Phone: +1 415 235 3778 AIM: dfetter666 Yahoo!: dfetter Skype: davidfetter XMPP: david.fet...@gmail.com Remember to vote! Consider donating to Postgres: http://www.postgresql.org/about/donate -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Wed, Feb 18, 2009 at 11:20:03PM -0500, Robert Haas wrote: > On Wed, Jan 7, 2009 at 9:14 AM, Joshua Tolley wrote: > > On Tue, Jan 06, 2009 at 11:49:57PM -0500, Robert Haas wrote: > >> Josh / eggyknap - > >> > >> Can you rerun your performance tests with this version of the patch? > >> > >> ...Robert > > > > Will do, as soon as I can. > > Josh, > > Have you been able to do anything further with this? > > I'm attaching a rebased version of this patch with a few further > whitespace cleanups. > > ...Robert I keep trying to do testing, but not getting too far, though I did return some test results to the original authors for their review. I'll try to get a more formal response put together (my new daughter will be 24 hours old in a little bit, though, so it might be a while!) - Josh signature.asc Description: Digital signature
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
From: pgsql-hackers-ow...@postgresql.org on behalf of Robert Haas I think what we need here is some very simple testing to demonstrate that this patch demonstrates a speed-up even when the inner side of the join is a joinrel rather than a baserel. Can you suggest a single query against the skewed TPCH dataset that will result in two or more multi-batch hash joins? If so, it should be a simple matter to run that query with and without the patch and verify that the former is faster than the latter. This query will have the outer relation be a joinrel rather than a baserel: select count(*) from supplier, part, lineitem where l_partkey = p_partkey and s_suppkey = l_suppkey; The approach collects statistics on the outer relation (not the inner relation) so the code had to have the ability to determine a stats tuple on a joinrel in addition to a baserel. Joshua sent us some preliminary data with this query and others and indicated that we could post it. He wanted time to clean it up and re-run some experiments, but the data is generally good and the algorithm performs as expected. I have attached this data to the post. Note that the last set of data (although labelled as Z7) is actually an almost zero skew database and represents the worst-case for the algorithm (for most queries the optimization is not even used). -- Ramon Lawrence JoshuaTolleyData.xls Description: JoshuaTolleyData.xls -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> At this point, we await further feedback on what is necessary to get > this patch accepted. We would also like to thank Josh and Robert again > for their review time. I think what we need here is some very simple testing to demonstrate that this patch demonstrates a speed-up even when the inner side of the join is a joinrel rather than a baserel. Can you suggest a single query against the skewed TPCH dataset that will result in two or more multi-batch hash joins? If so, it should be a simple matter to run that query with and without the patch and verify that the former is faster than the latter. Thanks, ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Wed, Jan 7, 2009 at 9:14 AM, Joshua Tolley wrote: > On Tue, Jan 06, 2009 at 11:49:57PM -0500, Robert Haas wrote: >> Josh / eggyknap - >> >> Can you rerun your performance tests with this version of the patch? >> >> ...Robert > > Will do, as soon as I can. Josh, Have you been able to do anything further with this? I'm attaching a rebased version of this patch with a few further whitespace cleanups. ...Robert *** a/src/backend/executor/nodeHash.c --- b/src/backend/executor/nodeHash.c *** *** 53,58 ExecHash(HashState *node) --- 53,222 return NULL; } + /* + * + * ExecHashGetIMBucket + * + * Returns the index of the in-memory bucket for this + * hashvalue, or IM_INVALID_BUCKET if the hashvalue is not + * associated with any unfrozen bucket (or if skew + * optimization is not being used). + * + * It is possible for a tuple whose join attribute value is + * not a MCV to hash to an in-memory bucket due to the limited + * number of hash values but it is unlikely and everything + * continues to work even if it does happen. We would + * accidentally cache some less optimal tuples in memory + * but the join result would still be accurate. + * + * hashtable->imBucket is an open addressing hashtable of + * in-memory buckets (HashJoinIMBucket). + * + */ + int + ExecHashGetIMBucket(HashJoinTable hashtable, uint32 hashvalue) + { + int bucket; + + if (!hashtable->enableSkewOptimization) + return IM_INVALID_BUCKET; + + /* Modulo the hashvalue (using bitmask) to find the IM bucket. */ + bucket = hashvalue & (hashtable->nIMBuckets - 1); + + /* + * While we have not hit a hole in the hashtable and have not hit the + * actual bucket we have collided in the hashtable so try the next + * bucket location. + */ + while (hashtable->imBucket[bucket] != NULL + && hashtable->imBucket[bucket]->hashvalue != hashvalue) + bucket = (bucket + 1) & (hashtable->nIMBuckets - 1); + + /* + * If the bucket exists and has been correctly determined return + * the bucket index. + */ + if (hashtable->imBucket[bucket] != NULL + && hashtable->imBucket[bucket]->hashvalue == hashvalue) + return bucket; + + /* + * Must have run into an empty location or a frozen bucket which means the + * tuple with this hashvalue is not to be handled as if it matches with an + * in-memory bucket. + */ + return IM_INVALID_BUCKET; + } + + /* + * + * ExecHashFreezeNextIMBucket + * + * Freeze the tuples of the next in-memory bucket by pushing + * them into the main hashtable. Buckets are frozen in order + * so that the best tuples are kept in memory the longest. + * + */ + static bool + ExecHashFreezeNextIMBucket(HashJoinTable hashtable) + { + int bucketToFreeze; + int bucketno; + int batchno; + uint32 hashvalue; + HashJoinTuple hashTuple; + HashJoinTuple nextHashTuple; + HashJoinIMBucket *bucket; + MinimalTuple mintuple; + + /* Calculate the imBucket index of the bucket to freeze. */ + bucketToFreeze = hashtable->imBucketFreezeOrder + [hashtable->nUsedIMBuckets - 1 - hashtable->nIMBucketsFrozen]; + + /* Grab a pointer to the actual IM bucket. */ + bucket = hashtable->imBucket[bucketToFreeze]; + hashvalue = bucket->hashvalue; + + /* + * Grab a pointer to the first tuple in the soon to be frozen IM bucket. + */ + hashTuple = bucket->tuples; + + /* + * Calculate which bucket and batch the tuples belong to in the main + * non-IM hashtable. + */ + ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno, &batchno); + + /* until we have read all tuples from this bucket */ + while (hashTuple != NULL) + { + /* + * Some of this code is very similar to that of ExecHashTableInsert. + * We do not call ExecHashTableInsert directly as + * ExecHashTableInsert expects a TupleTableSlot and we already have + * HashJoinTuples. + */ + mintuple = HJTUPLE_MINTUPLE(hashTuple); + + /* Decide whether to put the tuple in the hash table or a temp file. */ + if (batchno == hashtable->curbatch) + { + /* Put the tuple in hash table. */ + nextHashTuple = hashTuple->next; + hashTuple->next = hashtable->buckets[bucketno]; + hashtable->buckets[bucketno] = hashTuple; + hashTuple = nextHashTuple; + hashtable->spaceUsedIM -= HJTUPLE_OVERHEAD + mintuple->t_len; + } + else + { + /* Put the tuples into a temp file for later batches. */ + Assert(batchno > hashtable->curbatch); + ExecHashJoinSaveTuple(mintuple, hashvalue, + &hashtable->innerBatchFile[batchno]); + /* + * Some memory has been freed up. This must be done before we + * pfree the hashTuple of we lose access to the tuple size. + */ + hashtable->sp
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> Here is a cleaned-up version. I fixed a number of whitespace issues, > improved a few comments, and rearranged one set of nested if-else > statements (hopefully without breaking anything in the process). > > Josh / eggyknap - > > Can you rerun your performance tests with this version of the patch? To help with testing, we have constructed a patch specifically for testing. The patch is the same as Robert's version except that it tracks and prints out statistics during the join on how many tuples are affected and has the enable_hashjoin_usestatmcvs variable defined so that it is easy to turn on/off skew handling. This is useful as although the patch reduces the number of I/Os performed, this improvement may not be seen in some queries which are dominated by other cost factors (non-skew joins, CPU time, time to scan input relations, etc.). The sample output looks like this: LI-P Values: 100 Skew: 0.27 Est. tuples: 59986052.00 Batches: 512 Est. Save: 16114709.99 Total Inner Tuples: 200 IM Inner Tuples: 83 Batch Zero Inner Tuples: 3941 Batch Zero Potential Inner Tuples: 3941 Total Outer Tuples: 59986052 IM Outer Tuples: 16074146 Batch Zero Outer Tuples: 98778 Batch Zero Potential Outer Tuples: 98778 Total Output Tuples: 59986052 IM Output Tuples: 16074146 Batch Zero Output Tuples: 98778 Batch Zero Potential Output Tuples: 98778 Percentage less tuple IOs than HHJ: 25.98 The other change is that the system calculates the skew and will not use the in-memory skew partition if the skew is less than 1%. Finally, we have attached some performance results for the TPCH 10G data set (skew factors z=1 and z=2). For the Customer-Orders-Lineitem-Part query that Josh was testing, we see no overall time difference that is significant compared to experimental error (although there is I/O benefit for the Lineitem-Part join). This query cost is dominated by the non-skew joins of Customer-Orders and Orders-Lineitem and output tuple construction. The joins with skew, Lineitem-Supplier and Lineitem-Part, show significantly improved performance. Note how the statistics show that the percentage I/O savings is directly proportional to the skew. However, the overall query time savings is always less than this as there are other costs such as reading the relations, performing the hash comparisons, building the output tuples, etc. that are unaffected by the optimization. At this point, we await further feedback on what is necessary to get this patch accepted. We would also like to thank Josh and Robert again for their review time. Sincerely, Ramon Lawrence and Bryce Cutt histojoin_testing.patch Description: histojoin_testing.patch TPC-H 10G Skew Factor Z=1 results - LI-P Regular HJ: (time in milliseconds) 990344 1022562 1071250 1003219 1049000 989953 Average: 1021054.667 LI-P Skew-enabled HJ: (time in milliseconds) 883593 960860 934906 1007282 937406 948078 Average: 945354.1667 % Difference: 7.4% LI-P Values: 100 Skew: 0.27 Est. tuples: 59986052.00 Batches: 512 Est. Save: 16114709.99 Total Inner Tuples: 200 IM Inner Tuples: 83 Batch Zero Inner Tuples: 3941 Batch Zero Potential Inner Tuples: 3941 Total Outer Tuples: 59986052 IM Outer Tuples: 16074146 Batch Zero Outer Tuples: 98778 Batch Zero Potential Outer Tuples: 98778 Total Output Tuples: 59986052 IM Output Tuples: 16074146 Batch Zero Output Tuples: 98778 Batch Zero Potential Output Tuples: 98778 Percentage less tuple IOs than HHJ: 25.98 LI-P-S Regular HJ: (time in milliseconds) 1833016 1567515 1504625 Average: 1635052 LI-P-S Skew-enabled HJ: (time in milliseconds) 883593 1280297 1423984 Average: 1195958 % Difference: 27% LI-S Values: 100 Skew: 0.19 Est. tuples: 59986052.00 Batches: 32 Est. Save: 11097357.16 Total Inner Tuples: 10 IM Inner Tuples: 78 Batch Zero Inner Tuples: 3123 Batch Zero Potential Inner Tuples: 3125 Total Outer Tuples: 59986052 IM Outer Tuples: 11563695 Batch Zero Outer Tuples: 1577432 Batch Zero Potential Outer Tuples: 1693632 Total Output Tuples: 59986052 IM Output Tuples: 11563695 Batch Zero Output Tuples: 1577432 Batch Zero Potential Output Tuples: 1693632 Percentage less tuple IOs than HHJ: 19.61 (LI-S)-P Values: 100 Skew: 0.27 Est. tuples: 59986052.00 Batches: 512 Est. Save: 16114709.99 Total Inner Tuples: 200 IM Inner Tuples: 83 Batch Zero Inner Tuples: 3941 Batch Zero Potential Inner Tuples: 3941 Total Outer Tuples: 59986052 IM Outer Tuples: 16074146 Batch Zero Outer Tuples: 98778 Batch Zero Potential Outer Tuples: 98778 Total Output Tuples: 59986052 IM Output Tuples: 16074146 Batch Zero Output Tuples: 98778 Batch Zero Potential Output Tuples: 98778 Percentage less tuple IOs than HHJ: 25.98 TPC-H 10G Skew Factor Z=2 results - LI-P Regular HJ: (time in milliseconds) 505672 424922 303250 361610 358125 Average: 390715.8 LI-P Skew-enabled HJ: (time in milliseconds) 219078 210078 212938 210094 212500 Average: 212937.6 % difference: 4
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Tue, Jan 06, 2009 at 11:49:57PM -0500, Robert Haas wrote: > Josh / eggyknap - > > Can you rerun your performance tests with this version of the patch? > > ...Robert Will do, as soon as I can. signature.asc Description: Digital signature
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> We would really appreciate help on finalizing this patch, especially in > regard to style issues. Thank you for all the help. Here is a cleaned-up version. I fixed a number of whitespace issues, improved a few comments, and rearranged one set of nested if-else statements (hopefully without breaking anything in the process). Josh / eggyknap - Can you rerun your performance tests with this version of the patch? ...Robert *** a/src/backend/executor/nodeHash.c --- b/src/backend/executor/nodeHash.c *** *** 53,58 ExecHash(HashState *node) --- 53,222 return NULL; } + /* + * + * ExecHashGetIMBucket + * + * Returns the index of the in-memory bucket for this + * hashvalue, or IM_INVALID_BUCKET if the hashvalue is not + * associated with any unfrozen bucket (or if skew + * optimization is not being used). + * + * It is possible for a tuple whose join attribute value is + * not a MCV to hash to an in-memory bucket due to the limited + * number of hash values but it is unlikely and everything + * continues to work even if it does happen. We would + * accidentally cache some less optimal tuples in memory + * but the join result would still be accurate. + * + * hashtable->imBucket is an open addressing hashtable of + * in-memory buckets (HashJoinIMBucket). + * + */ + int + ExecHashGetIMBucket(HashJoinTable hashtable, uint32 hashvalue) + { + int bucket; + + if (!hashtable->enableSkewOptimization) + return IM_INVALID_BUCKET; + + /* Modulo the hashvalue (using bitmask) to find the IM bucket. */ + bucket = hashvalue & (hashtable->nIMBuckets - 1); + + /* + * While we have not hit a hole in the hashtable and have not hit the + * actual bucket we have collided in the hashtable so try the next + * bucket location. + */ + while (hashtable->imBucket[bucket] != NULL + && hashtable->imBucket[bucket]->hashvalue != hashvalue) + bucket = (bucket + 1) & (hashtable->nIMBuckets - 1); + + /* + * If the bucket exists and has been correctly determined return + * the bucket index. + */ + if (hashtable->imBucket[bucket] != NULL + && hashtable->imBucket[bucket]->hashvalue == hashvalue) + return bucket; + + /* + * Must have run into an empty location or a frozen bucket which means the + * tuple with this hashvalue is not to be handled as if it matches with an + * in-memory bucket. + */ + return IM_INVALID_BUCKET; + } + + /* + * + * ExecHashFreezeNextIMBucket + * + * Freeze the tuples of the next in-memory bucket by pushing + * them into the main hashtable. Buckets are frozen in order + * so that the best tuples are kept in memory the longest. + * + */ + static bool + ExecHashFreezeNextIMBucket(HashJoinTable hashtable) + { + int bucketToFreeze; + int bucketno; + int batchno; + uint32 hashvalue; + HashJoinTuple hashTuple; + HashJoinTuple nextHashTuple; + HashJoinIMBucket *bucket; + MinimalTuple mintuple; + + /* Calculate the imBucket index of the bucket to freeze. */ + bucketToFreeze = hashtable->imBucketFreezeOrder + [hashtable->nUsedIMBuckets - 1 - hashtable->nIMBucketsFrozen]; + + /* Grab a pointer to the actual IM bucket. */ + bucket = hashtable->imBucket[bucketToFreeze]; + hashvalue = bucket->hashvalue; + + /* + * Grab a pointer to the first tuple in the soon to be frozen IM bucket. + */ + hashTuple = bucket->tuples; + + /* + * Calculate which bucket and batch the tuples belong to in the main + * non-IM hashtable. + */ + ExecHashGetBucketAndBatch(hashtable, hashvalue, &bucketno, &batchno); + + /* until we have read all tuples from this bucket */ + while (hashTuple != NULL) + { + /* + * Some of this code is very similar to that of ExecHashTableInsert. + * We do not call ExecHashTableInsert directly as + * ExecHashTableInsert expects a TupleTableSlot and we already have + * HashJoinTuples. + */ + mintuple = HJTUPLE_MINTUPLE(hashTuple); + + /* Decide whether to put the tuple in the hash table or a temp file. */ + if (batchno == hashtable->curbatch) + { + /* Put the tuple in hash table. */ + nextHashTuple = hashTuple->next; + hashTuple->next = hashtable->buckets[bucketno]; + hashtable->buckets[bucketno] = hashTuple; + hashTuple = nextHashTuple; + hashtable->spaceUsedIM -= HJTUPLE_OVERHEAD + mintuple->t_len; + } + else + { + /* Put the tuples into a temp file for later batches. */ + Assert(batchno > hashtable->curbatch); + ExecHashJoinSaveTuple(mintuple, hashvalue, + &hashtable->innerBatchFile[batchno]); + /* + * Some memory has been freed up. This must be done before we + * pfree the hashTuple of we lose access to the tuple size. + */ +
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
The latest version of the patch is attached. The revision considerably cleans up the code, especially variable naming consistency. We have adopted the use of IM (in-memory) in variable names for the hash table structures as suggested. Two other implementations changes: 1) The overhead of the hash table has been reduced by allocating an array of pointers instead of an array of structs and only allocating the structs as they are needed to store MCVs. IM buckets are now frozen by first removing all tuples then deleting the struct from memory. This allows more memory to be freed as well as the removal of the frozen field in the IM bucket struct which now makes that struct only 8 bytes on a 32bit machine. If for some reason all IM buckets are frozen all IM struct overhead is removed from memory to further reduce the memory footprint. 2) This patch supports using a set percentage of work_mem (currently 2%) to store the build tuples that join frequently with probe relation tuples. The code only allocates MCVs up to the maximum amount and will flush from the in-memory hash table if the memory is ever exceeded. The code also ensures that the overall join memory used (the MCV hash table and batch 0 in memory) does not exceed spaceAllocated as usual. If this 2% of memory is not used by the MCV hash table then it can be used by batch 0. These changes are mostly relate to style, although some of the cleanup has made the code slightly faster. We would really appreciate help on finalizing this patch, especially in regard to style issues. Thank you for all the help. - Dr. Ramon Lawrence and Bryce Cutt On Sun, Jan 4, 2009 at 6:48 PM, Robert Haas wrote: >> 1) Isn't ExecHashFreezeNextMCVPartition actually a most common TUPLE >> partition, rather than a most common VALUE partition (and similarly for >> ExecHashGetMCVPartition)? >> >> A partition stores all tuples that correspond to that MCV value. It is >> usually one for foreign key joins but may be more than one. (Plus, it >> may store other tuples that have the same hash value for the join >> attribute as the MCV value.) > > I guess my point is - check that your variable/function/structure > member naming is consistent between different parts of the code. The > ExecHashGetMCVPartition function accesses structure members called > nMostCommonTuplePartitionHashBuckets, nMostCommonTuplePartition, and > mostCommonTuplePartition. It seems inconsistent that the function > name uses MCVPartition and > the structure members use mostCommonTuplePartition - aren't we talking > about the same thing in both cases? > > And, more to the point, the terminology just seems wrong to me, the > more I think about it. I mean, ExecHashGetMCVParitition is not > finding a partition of the MCVs. It's finding a partition of an > in-memory hash table which we plan to populate with MCVs. That's why > I'm wondering if we should make it ExecHashGetIMPartition, > nIMPartitionHashBuckets, etc. > >> 2) Have you done any performance testing on the impact of this change? >> >> Yes, the ability to use MCVs for more than sequential scans >> significantly improves performance in multi-join cases. The allocation >> of a percentage of memory of only 1% will not affect any performance >> results as all our testing was done with the MCV value of 10 or 100 >> which is significantly below a 1% allocation of work_mem. If anything, >> performance would be improved when using more MCVs. > > That is a very good thing. > >> Finally, any help you can provide on style concerns to make this easier >> to commit would be appreciated. We will put all the effort required >> over the next few days to get this into 8.4. > > If I have time, I might be willing to make a style run over the next > version of the patch after you post it to the list, and just correct > anything I see and repost. This might be faster than sending comments > back and forth, if you are OK with it. I have a day job so this would > probably need to be Tuesday or Wednesday night. My main advice is > "read the diff before you post it". Sometimes things will just pop > out at you that are less obvious when you are head-down in the code. > > Random stuff I notice in v4 patch: make sure all lines fit in 80 > columns (except for long error messages if any), missing space before > closing comment delimiter in ExecHashGetMCVPartition, extraneous blank > line added to nodeHash.c just before the comment that says "and remove > from hash table", comment in ExecHashJoinGetMostCommonValues just > after the get_attstatsslot call is formatted strangely, still extra > curly braces around the calls to > ExecScanHashMostCommonValuePartition/ExecScanHashBucket. > > ...Robert > histojoin_v5.patch Description: Binary data -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
On Tue, Dec 30, 2008 at 12:29 AM, Bryce Cutt wrote: > Here is the next patch version. Thanks for posting this update. This is definitely getting better, but I still see some style issues. We can work on fixing those once the rest of the details have been finalized. However, one question in this area - isn't ExecHashFreezeNextMCVPartition actually a most common TUPLE partition, rather than a most common VALUE partition (and similarly for ExecHashGetMCVPartition)? I'm not quite sure what to do about this as the names are already quite long - is there some better name for the functions and structure members than MostCommonTuplePartition? Maybe we could call it the in-memory partition and abbreviate it IMPartition throughout. I think that might make things more clear. > The code can now find the the MCVs in more cases. Even if the probe > side is an operator other than a seq scan (such as another hashjoin) > the code can now find the stats tuple for the underlying relation. You're using varnoold in a way that directly contradicts the comment in primnodes.h (essentially, that it's not used for anything other than debugging). I don't think this is a bad thing, but you have to patch the comment. Have you done any performance testing on the impact of this change? > The new idea of limiting the number of MCVs to a percentage of memory > has not been added yet. That's a pretty important change, I think, though it would be nice to have one of the committers chime in here. For those who may not have been following the thread closely, the current implementation's memory usage can go quite a bit higher than work_mem - the in-memory open hash table can be up to 1MB or so (if statistics_target = 10K) plus it can contain up to work_mem of tuples plus each batch can contain another work_mem of tuples. The proposal is to carve out 1-3% of work_mem for the in-memory hash table and leave the rest for the batches, thus hopefully not affecting the # of batches very much. If it doesn't look like the whole MCV list will fit, we'll take a shot at guessing what length prefix of it will. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
Here is the next patch version. The naming and style concerns have been addressed. The patch now only touches 5 files. 4 of those files are hashjoin specific and 1 is to add a couple lines to a hashjoin specific struct in another file. The code can now find the the MCVs in more cases. Even if the probe side is an operator other than a seq scan (such as another hashjoin) the code can now find the stats tuple for the underlying relation. The new idea of limiting the number of MCVs to a percentage of memory has not been added yet. - Bryce Cutt On Mon, Dec 29, 2008 at 8:55 PM, Robert Haas wrote: >> I think that setting aside a minimum percentage of work_mem may be a >> reasonable approach. For instance, setting aside 1% at even 1 MB >> work_mem would be 10 KB which is enough to store about 40 MCV tuples of >> the TPC-H database. Such a small percentage would be very unlikely (but >> still possible) to change the number of batches used. Then, given the >> memory allocation and the known tuple size + overhead, only that number >> of MCVs are selected for the MCV table regardless how many there are. >> The MCV table size would then increase as work_mem is changed up to a >> maximum given by the number of MCVs. > > Sounds fine. Maybe 2-3% would be better. > >> The code when building the MCV hash table keeps track of the order of >> insertion of the best MCVs. It then flushes the MCV partitions in >> decreasing order of frequency of MCVs. Thus, by the end of the build >> partitioning phase the MCV hash table should only store the most >> frequent MCV tuples. Even with many-to-many joins as long as we keep >> all build tuples that have a given MCV in memory, then everything is >> fine. You would get into problems if you only flushed some of the >> tuples of a certain MCV but that will not happen. > > OK, I'll read it again - I must not have understood. > > It would be good to post an updated patch soon, even if not everything > has been addressed. > > ...Robert > histojoin_v4.patch Description: Binary data -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> I think that setting aside a minimum percentage of work_mem may be a > reasonable approach. For instance, setting aside 1% at even 1 MB > work_mem would be 10 KB which is enough to store about 40 MCV tuples of > the TPC-H database. Such a small percentage would be very unlikely (but > still possible) to change the number of batches used. Then, given the > memory allocation and the known tuple size + overhead, only that number > of MCVs are selected for the MCV table regardless how many there are. > The MCV table size would then increase as work_mem is changed up to a > maximum given by the number of MCVs. Sounds fine. Maybe 2-3% would be better. > The code when building the MCV hash table keeps track of the order of > insertion of the best MCVs. It then flushes the MCV partitions in > decreasing order of frequency of MCVs. Thus, by the end of the build > partitioning phase the MCV hash table should only store the most > frequent MCV tuples. Even with many-to-many joins as long as we keep > all build tuples that have a given MCV in memory, then everything is > fine. You would get into problems if you only flushed some of the > tuples of a certain MCV but that will not happen. OK, I'll read it again - I must not have understood. It would be good to post an updated patch soon, even if not everything has been addressed. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> I thought about this, but upon due reflection I think it's the wrong > approach. Raising work_mem is a pretty common tuning step - it's 4MB > even on my small OLTP systems, and in a data-warehousing environment > where this optimization will bring the most benefit, it could easily > be higher. Furthermore, if someone DOES change the statistics target > for that column to 10,000, there's a pretty good chance that they had > a reason for doing so (or at the very least it's not for us to assume > that they were doing something stupid). I think we need some kind of > code to try to tune this based on the actual situation. > > We might try to size the in-memory hash table to be the largest value > that won't increase the total number of batches, but if the number of > batches is large then this won't be the right decision. Maybe we > should insist on setting aside some minimum percentage of work_mem for > the in-memory hash table, and fill it with however many MCVs we think > will fit. I think that setting aside a minimum percentage of work_mem may be a reasonable approach. For instance, setting aside 1% at even 1 MB work_mem would be 10 KB which is enough to store about 40 MCV tuples of the TPC-H database. Such a small percentage would be very unlikely (but still possible) to change the number of batches used. Then, given the memory allocation and the known tuple size + overhead, only that number of MCVs are selected for the MCV table regardless how many there are. The MCV table size would then increase as work_mem is changed up to a maximum given by the number of MCVs. > I agree. However, there's no reason at all to assume that the tuples > we flush out of the table are any better or worse than the new ones we > add back in later. In fact, although it's far from a guarantee, if > the order of the tuples in the table is random, then we're more likely > to encounter the most common values first. We might as well just keep > the ones we had rather than dumping them out and adding in different > ones. Err, except, maybe we can't guarantee correctness that way, in > the case of a many-to-many join? The code when building the MCV hash table keeps track of the order of insertion of the best MCVs. It then flushes the MCV partitions in decreasing order of frequency of MCVs. Thus, by the end of the build partitioning phase the MCV hash table should only store the most frequent MCV tuples. Even with many-to-many joins as long as we keep all build tuples that have a given MCV in memory, then everything is fine. You would get into problems if you only flushed some of the tuples of a certain MCV but that will not happen. -- Ramon Lawrence -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> I totally agree that 10,000 MCVs changes things. Ideally, these 10,000 > MCVs should be kept in memory because they will join with the most > tuples. However, the size of the MCV hash table (as you point out) can > be bigger than work_mem *by itself* not even considering the tuples in > the table or in the in-memory batch. > > So, basically, we have a decision to make whether to try support a > larger number of MCVs or cap it at a reasonable number like a 100. You > can come up with situations where using all 10,000 MCVs is good (for > instance if all MCVs have frequency 1/1), but I expect 100 MCVs will > capture the majority of the cases as usually the top 100 MCVs are > significantly more frequent than later MCVs. I thought about this, but upon due reflection I think it's the wrong approach. Raising work_mem is a pretty common tuning step - it's 4MB even on my small OLTP systems, and in a data-warehousing environment where this optimization will bring the most benefit, it could easily be higher. Furthermore, if someone DOES change the statistics target for that column to 10,000, there's a pretty good chance that they had a reason for doing so (or at the very least it's not for us to assume that they were doing something stupid). I think we need some kind of code to try to tune this based on the actual situation. We might try to size the in-memory hash table to be the largest value that won't increase the total number of batches, but if the number of batches is large then this won't be the right decision. Maybe we should insist on setting aside some minimum percentage of work_mem for the in-memory hash table, and fill it with however many MCVs we think will fit. > The issue with building the MCV table is that the hash operator will not > be receiving tuples in MCV frequency order. It is possible that the MCV > table is filled up with tuples of less frequent MCVs when a more > frequent MCV tuple arrives. In that case, we would like to keep the > more frequent MCV and bump one of the less frequent MCVs. I agree. However, there's no reason at all to assume that the tuples we flush out of the table are any better or worse than the new ones we add back in later. In fact, although it's far from a guarantee, if the order of the tuples in the table is random, then we're more likely to encounter the most common values first. We might as well just keep the ones we had rather than dumping them out and adding in different ones. Err, except, maybe we can't guarantee correctness that way, in the case of a many-to-many join? I don't think there's any way to get around the possibility of a hash-table overflow completely. Besides many-to-many joins, there's also the possibility of hash collisions. The code assumes that anything that hashes to the same 32-bit value as an MCV is in fact an MCV, which is obviously false, but doesn't seem worth worrying about since the chances of a collision are very small and the equality test might be expensive. But clearly we want to minimize overflows as much as we can. ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> -Original Message- > From: Robert Haas [mailto:robertmh...@gmail.com] > I looked at this some more. I'm a little concerned about the way > we're maintaining the in-memory hash table. Since the highest legal > statistics target is now 10,000, it's possible that we could have two > orders of magnitude more MCVs than what you're expecting. As I read > the code, that could lead to construction of an in-memory hash table > with 64K slots. On a 32-bit machine, I believe that works out to 16 > bytes per partition (12 and 4), which is a 1MB hash table. That's not > necessarily problematic, except that I don't think you're considering > the size of the hash table itself when evaluating whether you are > blowing out work_mem, and the default size of work_mem is 1MB. I totally agree that 10,000 MCVs changes things. Ideally, these 10,000 MCVs should be kept in memory because they will join with the most tuples. However, the size of the MCV hash table (as you point out) can be bigger than work_mem *by itself* not even considering the tuples in the table or in the in-memory batch. Supporting that many MCVs would require more modifications to the hash join algorithm. 100 MCVs should be able to fit in memory though. Since the number of batches is rounded to a power of 2, there is often some hash_table_bytes that are not used by the in-memory batch that can be "used" to store the MCV table. The absolute size of the memory used should also be reasonable (depending on the tuple size in bytes). So, basically, we have a decision to make whether to try support a larger number of MCVs or cap it at a reasonable number like a 100. You can come up with situations where using all 10,000 MCVs is good (for instance if all MCVs have frequency 1/1), but I expect 100 MCVs will capture the majority of the cases as usually the top 100 MCVs are significantly more frequent than later MCVs. I now also see that the code should be changed to keep track of the MCV bytes separately from hashtable->spaceUsed as this is used to determine when to dynamically increase the number of batches. > I also don't really understand why we're trying to control the size of > the hash table by flushing tuples after the fact. Right now, when the > in-memory table fills up, we just keep adding tuples to it, which in > turn forces us to flush out other tuples to keep the size down. This > seems quite inefficient - not only are we doing a lot of unnecessary > allocating and freeing, but those flushed slots in the hash table > degrade performance (because they don't stop the scan for an empty > slot). It seems like we could simplify things considerably by adding > tuples to the in-memory hash table only to the point where the next > tuple would blow it out. Once we get to that point, we can skip the > isAMostCommonValue() test and send any future tuples straight to temp > files. (This would also reduce the memory consumption of the > in-memory table by a factor of two.) In the ideal case, we select a number of MCVs to support that we know will always fit in memory. The flushing is used to deal with the case where we are doing a many-to-many join and there may be multiple tuples with the given MCV value in the build relation. The issue with building the MCV table is that the hash operator will not be receiving tuples in MCV frequency order. It is possible that the MCV table is filled up with tuples of less frequent MCVs when a more frequent MCV tuple arrives. In that case, we would like to keep the more frequent MCV and bump one of the less frequent MCVs. > We could potentially improve on this even further if we can estimate > in advance how many MCVs we can fit into the in-memory hash table > before it gets blown out. If, for example, we have only 1MB of > work_mem but there 10,000 MCVs, getMostCommonValues() might decide to > only hash the first 1,000 MCVs. Even if we still blow out the > in-memory hash table, the earlier MCVs are more frequent than the > later MCVs, so the ones that actually make it into the table are > likely to be more beneficial. I'm not sure exactly how to do this > tuning though, since we'd need to approximate the size of the > tuples... I guess the query planner makes some effort to estimate that > but I'm not sure how to get at it. The number of batches (nbatch), inner_rel_bytes, and hash_table_bytes are calculated in ExecChooseHashTableSize in nodeHash.c. The number of bytes "free" not allocated to the in-memory batch is then: hash_table_bytes - inner_rel_bytes/nbatch Depending on the power of 2 rounding of nbatch, this may be almost 0 or quite large. You could change the calculation of nbatch or try to resize the in-memory batch, but that opens up a can of worms. It may be best to assume a small number of MCVs 10 or 100. > > > However, the join with Part and LineItem *should* show a benefit but may > > not because of a limitation of the patch implementation (not the idea). > > The MCV o
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> There is almost zero penalty for selecting incorrect MCV tuples to > buffer in memory. Since the number of MCVs is approximately 100, the > "overhead" is keeping these 100 tuples in memory where they *might* not > be MCVs. The cost is the little extra memory and the checking of the > MCVs which is very fast. I looked at this some more. I'm a little concerned about the way we're maintaining the in-memory hash table. Since the highest legal statistics target is now 10,000, it's possible that we could have two orders of magnitude more MCVs than what you're expecting. As I read the code, that could lead to construction of an in-memory hash table with 64K slots. On a 32-bit machine, I believe that works out to 16 bytes per partition (12 and 4), which is a 1MB hash table. That's not necessarily problematic, except that I don't think you're considering the size of the hash table itself when evaluating whether you are blowing out work_mem, and the default size of work_mem is 1MB. I also don't really understand why we're trying to control the size of the hash table by flushing tuples after the fact. Right now, when the in-memory table fills up, we just keep adding tuples to it, which in turn forces us to flush out other tuples to keep the size down. This seems quite inefficient - not only are we doing a lot of unnecessary allocating and freeing, but those flushed slots in the hash table degrade performance (because they don't stop the scan for an empty slot). It seems like we could simplify things considerably by adding tuples to the in-memory hash table only to the point where the next tuple would blow it out. Once we get to that point, we can skip the isAMostCommonValue() test and send any future tuples straight to temp files. (This would also reduce the memory consumption of the in-memory table by a factor of two.) We could potentially improve on this even further if we can estimate in advance how many MCVs we can fit into the in-memory hash table before it gets blown out. If, for example, we have only 1MB of work_mem but there 10,000 MCVs, getMostCommonValues() might decide to only hash the first 1,000 MCVs. Even if we still blow out the in-memory hash table, the earlier MCVs are more frequent than the later MCVs, so the ones that actually make it into the table are likely to be more beneficial. I'm not sure exactly how to do this tuning though, since we'd need to approximate the size of the tuples... I guess the query planner makes some effort to estimate that but I'm not sure how to get at it. > However, the join with Part and LineItem *should* show a benefit but may > not because of a limitation of the patch implementation (not the idea). > The MCV optimization is only enabled currently when the probe side is a > sequential scan. This limitation is due to our current inability to > determine a stats tuple of the join attribute on the probe side for > other operators. (This should be possible - help please?). Not sure how to get at this either, but I'll take a look and see if I can figure it out. Merry Christmas, ...Robert -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers
Re: [HACKERS] Proposed Patch to Improve Performance of Multi-BatchHash Join for Skewed Data Sets
> > > Because there is no nice way in PostgreSQL (that I know of) to derive > > > a histogram after a join (on an intermediate result) currently > > > usingMostCommonValues is only enabled on a join when the outer (probe) > > > side is a table scan (seq scan only actually). See > > > getMostCommonValues (soon to be called > > > ExecHashJoinGetMostCommonValues) for the logic that determines this. > > So my test case of "do a whole bunch of hash joins in a test query" > isn't really valid. Makes sense. I did another, more haphazard test on a > query with fewer joins, and saw noticeable speedups. > > > It's starting to seem to me that the case where this patch provides a > > benefit is so narrow that I'm not sure it's worth the extra code. > > Not that anyone asked, but I don't consider myself qualified to render > judgement on that point. Code size is, I guess, a maintainability issue, > and I'm not terribly experienced maintaining PostgreSQL :) > > > Is it realistic to think that the MCVs of the base relation might > > still be applicable to the joinrel? It's certainly easy to think of > > counterexamples, but it might be a good approximation more often than > > not. > > It's equivalent to our assumption that distributions of values in > columns in the same table are independent. Making that assumption in > this case would probably result in occasional dramatic speed > improvements similar to the ones we've seen in less complex joins, > offset by just-as-occasional dramatic slowdowns of similar magnitude. In > other words, it will increase the variance of our results. > > - Josh There is almost zero penalty for selecting incorrect MCV tuples to buffer in memory. Since the number of MCVs is approximately 100, the "overhead" is keeping these 100 tuples in memory where they *might* not be MCVs. The cost is the little extra memory and the checking of the MCVs which is very fast. On the other hand, the benefit is potentially tremendous if the MCV is very common in the probe relation. Every probe tuple that matches the MCV tuple in memory does not have to be written to disk. The potential speedup is directly proportional to the skew. The more skew the more benefit. An analogy is with a page buffering system where one goal is to keep frequently used pages in the buffer. Essentially the goal of this patch is to "pin in memory" the tuples that the join believes will match with the most tuples on the probe side. This reduces I/Os by making more probe relation tuples match during the first read of the probe relation. Regular hash join has no way to guarantee frequently matched build tuples remain memory-resident. The particular join with Customer, Orders, LineItem, and Part is a reasonable test case. There may be two explanations for the results. (I am running tests for this query currently.) First, the time to generate the tuples (select *) may be dominating the query time. Second, as mentioned by Bryce, I expect the issue is that only the join with Customer and Orders exploited the patch. Customer has some skew (but not dramatic) so there would be some speedup. However, the join with Part and LineItem *should* show a benefit but may not because of a limitation of the patch implementation (not the idea). The MCV optimization is only enabled currently when the probe side is a sequential scan. This limitation is due to our current inability to determine a stats tuple of the join attribute on the probe side for other operators. (This should be possible - help please?). Even if this stats tuple is on the base relation and may not exactly reflect the distribution of the intermediate relation on the probe side, it still could be very good. Even if it is not, once again the cost is negligible. In summary, the patch will improve performance of any multi-batch hash join with skew. It is useful right now when the probe relation has skew and is accessed using a sequential scan. It would be useful in even more situations if the code was modified to determine the stats for the join attribute of the probe relation in all cases (even when the probe relation is produced by another operator). -- Dr. Ramon Lawrence Assistant Professor, Department of Computer Science, University of British Columbia Okanagan E-mail: ramon.lawre...@ubc.ca -- Sent via pgsql-hackers mailing list (pgsql-hackers@postgresql.org) To make changes to your subscription: http://www.postgresql.org/mailpref/pgsql-hackers