Using SSD for a temp tablespace on Exadata

January 02, 2014 by Guy Harrison in Oracle

I seem to be getting a lot of surprising performance results lately on our X-2 quarter rack Exadata system, which is good – the result you don’t expect is the one that teaches you something new.

This time, I was looking at using a temporary tablespace based on flash disks rather than spinning disks. In the past – using Fusion IO PCI cards, I found that using flash for temp tablespace was very effective in reducing the overhead of multi-pass sorts:

See (http://guyharrison.squarespace.com/ssdguide/04-evaluating-the-options-for-exploiting-ssd.html)

However, when I repeated these tests for Exadata, I got very disappointing results. SSD based temp tablespace actually lead to marginally worse performance:

Looking in depth at a particular point (the 500K SORT_AREA_SIZE point), we can see that although the SSD based temp tablespace has marginally better read times, it involves a significantly higher write overhead:

I can understand the higher read overhead (at least partially). It’s Yet Another time when sequential write operations to an SSD device have provided disappointing performance. However, it’s strange to see such poor read performance. How can a spinning disk serve blocks up at effectively the same latency an SSD?

So I dumped all the direct path read waits from a 10046 trace and plotted them logarithmically:

We can see in this chart, that the SDD based tablespace suffers from a small “spike” of high latencies between 600-1000 us (eg .6-1 ms). These are extremely high latencies for an SSD ! What could be causing them? Garbage collection being caused by the almost writes to the temp tablespaces? There was negliglbe concurrent activity on the system and the table concerned had flash cache disabled so for now that is my #1 theory.

For that matter, why are the HDD reads times so low? An average disk read latency of 500 us for a spinning disk is unreasonably low, is the storage cell somehow buffering temporary tablespace IO?

As always I’m wondering if there’s someone with more expertise in Exadata internals who could shed some light on all of this!

Can the Exadata Smart Flash Cache slow smart scans?

December 30, 2013 by Guy Harrison in Oracle

I’ve been doing some work on the Exadata Smart Flash Cache recently and came across a situation in which setting CELL_FLASH_CACHE to KEEP will significantly slow down smart scans on a table.

If we create a table with default settings, then the Exadata Smart Flash Cache (ESFC) will not be involved in smart scans, since by default only small IOs get cached. If we want the ESFC to be involved, we need to set the CELL_FLASH_CACHE to KEEP. Of course, we don’t expect immediate improvements, since we expect that the next smart scan will need to populate the cache before subsequent scans can benefit.

HOWEVER, what I’m seeing in practice is that the next smart scan following an ALTER TABLE … STORAGE(CELL_FLASH_CACHE KEEP) is significantly degraded, while subsequent scans get a performance boost. Here’s an example of what I observe:

The big increase in CELL IO time is in an increase in both the number and latency of cell smart table scans. The wait stats for the first scan with a default setting looked like this:

Elapsed times include waiting on following events:
Event waited on                             Times   Max. Wait Total Waited
----------------------------------------   Waited ---------- ------------
gc cr disk read                                 1        0.00          0.00
cell single block physical read                 2        0.01          0.01
row cache lock                                  2        0.00          0.00
gc cr grant 2-way                               1        0.00          0.00
SQL*Net message to client                    1021        0.00          0.00
reliable message                                1        0.00          0.00
enq: KO - fast object checkpoint                2        0.00          0.00
cell smart table scan                        9322        0.14          7.60
SQL*Net message from client                  1021        0.00          0.02

For the first scan with KEEP cache it looked like this:

Elapsed times include waiting on following events:
Event waited on                             Times   Max. Wait Total Waited
----------------------------------------   Waited ---------- ------------
SQL*Net message to client                    1021        0.00          0.00
reliable message                                1        0.00          0.00
enq: KO - fast object checkpoint                2        0.00          0.00
cell smart table scan                       14904        1.21         33.37
SQL*Net message from client                  1021        0.00          0.02

Looking at the raw trace file didn’t help – it just shows a bunch of lines like this, with only a small number (3 in this case) of unique cellhash values… I couldn’t see a pattern:

WAIT #… : nam='cell smart table scan' ela= 678 cellhash#=398250101 p2=0 p3=0 obj#=139207 tim= …

I’m at a loss to understand why there would be such a high penalty for the initial smart scan with CELL_FLASH_CACHE KEEP setting. You expect some overhead from constructing and storing the result set blocks in the cache, but an IO penalty of 200=300% seems way too high. Anybody seen anything like this or have a clear explanation?

Test script is here, and formatted tkprof here

Update on 2014-01-02 10:23 by Guy Harrison

@kevinclosson was kind enough to genlty correct my embarassing misconception about how the Exadata Smart Flash Cache (ESFC) deals with smart scans. Somehow I had got the impression that the ESFC was storing parts of the smart scan results - kind of like the result set cache. I really can't remember where I got that impression but as Kevin pointed out, its completely incorrect. What is being cached are the underlying table blocks - and you can clearly see this using LIST FLASHCACHECONTENT and looking at the flash hit rates for other queries.

So the overhead then is easier to understand since we are looking at placing all the blocks for a reasonably large table into the flash cache. This involves a large number of write operations over a very short period of time which in turn probably requires some on the fly garbage collection and signifcant write amplification.

The conclusion to draw is probably NOT to set CELL_FLASH_CACHE KEEP for a table of significant size unless you know for sure that it will be re-scanned within a short period of time. If the blocks age out of the cache and have to be reloaded you'll probably see a degradation rather than an improvement in scan performance.

Redo on SSD: effect of redo size (Exadata)

November 26, 2013 by Guy Harrison

Of all the claims I make about SSD for Oracle databases, the one that generates the most debate is that placing redo logs on SSD is not likely to be effective. I’ve published data to that effect in particular see Using SSD for redo on Exadata - pt 2 and 04 Evaluating the options for Exploiting SSD.

I get a lot of push back on these findings – often on theoretical grounds from Flash vendors (“our SSD use advanced caching and garbage collection that support high rates of sequential IO”) or from people who say that they’ve used flash for redo and it “worked fine”.

Unfortunately, every single test I do comparing performance of redo on flash and HDD shows redo with little or no advantage and in some cases with a clear disadvantage.

One argument for flash SSD that I’ve heard is that while for the small transactions I use for testing flash might not have the advantage but for “big” redo writes – such as those associated with LOB updates – flash SSD would work better. The idea is that the overhead of garbage collection and free page pool processing is less with big writes since you don’t hit the same flash SSD pages in rapid succession as you would with smaller writes. On the other hand a reader who knows more about flash than I do (flashdba.com) recently commented: “in foreground garbage collection a larger write will require more pages to be erased, so actually will suffer from even more performance issues.”

It’s taken me a while to get around to testing this, but I tried on our Exadata X-2 recently with a test that generates a variable amount of redo and then commits. The relationship between the size of the redo and redo log sync time is shown below

I’m now putting on my flame retardant underwear in anticipation of some dispute over this data…. but, this suggests that while SSD and HDD (at least on Exadata) are about at parity for small writes, flash degrades much more steeply than HDD as the size of the redo entry increases. Regardless of whether the redo is on flash or HDD, there’s a break at the 1MB point which corresponds to log buffer flush threshold. When a redo entry is only slightly bigger than 1MB then the chances are high that some of it will have been flushed already – see Redo log sync time vs redo size for a discussion of this phenomenon.

The SSD redo files were on an ASM disk group carved out of the Exadata flash disks - see Configuring Exadata flash as grid disk to see how I created these. Also the redo logs were created with 4K blocksize as outlined in Using SSD for redo on Exadata - pt 2. The database was in NoarchiveLog mode. Smart flash logging was disabled. As far as I can determine, there was no other significant activity on the flash disks (the grid disks were supporting all the database tablespaces, so if anything the SSD had the advantage).

Why are we seeing such a sharp dropoff in performance for the SSD as the redo write increases in size? Well one explanation was given by flashdba in this comment thread. It has to do with understanding what happens when a write IO which modifies an existing block hits a flash SSD. I tried to communicate my limited understanding of this process in Fundamentals of Flash SSD Technology. Instead of erasing the existing page, the flash controller will pull a page off a “free list” of pages and mark the old page as invalid. Later on, the garbage collection routines will reorganize the data and free up invalid pages. In this case, it’s possible that no free blocks were available because garbage collection fell behind during the write intensive workload. The more blocks written by LGWR, the more SSD pages had to be erased during these un-optimized writes and therefore the larger the redo log write the worse the performance of the SSD.

Any other theories and/or observations?

I hope soon to have a Dell system with Dell express flash so as I can repeat these tests on a non-exadata system. The F20 cards used in my X-2 are not state of the art, so it’s possible that different results could be obtained with a more recent flash card, or with a less contrived workload.

However, yet again I’m gathering data that suggests that using flash for redo logs is not worthwhile. I’d love to argue the point but even better than argument would be some hard data in either direction….

Exadata Write-back cache and free buffer waits

November 22, 2013 by Guy Harrison

Prior to storage server software version 11.2.3.2.0 (associated with Exadata X3), Exadata Smart Flash Cache was a “write-through” cache, meaning that write operations are applied both to the cache and to the underlying disk devices, but are not signalled as complete until the IO to the disk has completed.

Starting with 11.2.3.2.0 of the Exadata storage software[1], Exadata Smart Flash Cache may act as a write-back cache. This means that a write operation is made to the cache initially and de-staged to grid disks at a later time. This can be effective in improving the performance of an Exadata system that is subject to IO write bottlenecks on the Oracle datafiles.

Writes to datafile generally happen as a background task in Oracle, and most of the time we don’t actually “wait” on these IOs. That being the case, what advantage can we expect if these writes are optimized? To understand the possible advantages of the write-back cache let’s review the nature of datafile write IO in Oracle and the symptoms that occur when write IO becomes the bottleneck.

When a block in the buffer cache is modified, it is the responsibility of the database writer (DBWR) to write these “dirty” blocks to disk. The DBWR does this continuously and uses asynchronous IO processing, so generally sessions do not have to wait for the IO to occur – the only time sessions wait directly on write IO is when a redo log sync occurs following a COMMIT.

However, should all the buffers in the buffer cache become dirty then a session may wait when it wants to bring a block into the cache – resulting in a “free buffer wait”.

Free buffer waits can occur in update-intensive workloads when the IO bandwidth of the Oracle sessions reading into the cache exceeds the IO bandwidth of the database writer. Because the database writer uses asynchronous parallelized write IO, and because all processes concerned are accessing the same files, free buffer waits usually happen when the IO subsystem can service reads faster than it can service writes.

There exists just such an imbalance between reads and write latency in Exadata X2 – the Exadata Smart Flash Cache accelerates reads by a factor of perhaps 4-10 times, while offering no comparable advantage for writes. As a result, a very busy Exadata X2 system could become bottlenecked on free buffer waits. The Exadata Smart Flash Cache write-back cache provides acceleration to datafile writes as well as reads and therefore reduces the chance of free buffer wait bottlenecks.

The figure below illustrates the effectiveness of the write-back cache for workloads that encounter free buffer waits. The workload used to generate this data was heavily write-intensive with very little read IO overhead (all the necessary read data was in cache). As a result, it experienced a very high degree of free buffer waits and some associated buffer busy waits. Enabling the write-back cache completely eliminated the free buffer waits by effectively accelerating the write IO bandwidth of the database writer. As a result, throughput increased four fold.

However, don’t be misled into thinking that the write-back cache will be a silver bullet for any workload. Workloads that are experiencing free buffer waits are likely to see this sort of performance gain. Workloads where the dominant waits are for CPU, read IO, global cache co-ordination, log writes and so on will be unlikely to see any substantial benefit from the write-back cache.

[1] 11.2.3.2.1 is recommended as the minimum version for this feature as it contains fixes to significant issues discovered in the initial release.

Exadata Smart Flash Logging–Outliers

September 17, 2012 by Guy Harrison in Oracle

In my last post, I looked at the effect of the Exadata smart flash logging. Overall, there seemed to be a slight negative effect on median redo log sync times. This chart (slightly different from the last post because of different load and configuration of the system), shows how there’s a “hump” of redo log syncs that take slightly longer when the flash logging is enabled:

But of course, the flash logging feature was designed to improve performance not of the “average” redo log sync, but of the “outliers”.

In my tests, I had 40 concurrent processes writing redo as fast as they could. Occasionally this would result in some really long wait times. For instance, in this trace you see an outlier of 291,780 microseconds (the biggest outlier in my tests BTW) within an otherwise unremarkable set of waits:

WAIT #47124064145648: nam='log file sync' ela= 1043 buffer#=101808 sync scn=1266588527 p3=0 obj#=-1 tim=1347583167588250
WAIT #47124064145648: nam='log file sync' ela= 2394 buffer#=130714 sync scn=1266588560 p3=0 obj#=-1 tim=1347583167590888
WAIT #47124064145648: nam='log file sync' ela= 932 buffer#=101989 sync scn=1266588598 p3=0 obj#=-1 tim=1347583167592057
WAIT #47124064145648: nam='log file sync' ela= 291780 buffer#=102074 sync scn=1266588637 p3=0 obj#=-1 tim=1347583167884090
WAIT #47124064145648: nam='log file sync' ela= 671 buffer#=102196 sync scn=1266588697 p3=0 obj#=-1 tim=1347583167885294
WAIT #47124064145648: nam='log file sync' ela= 957 buffer#=102294 sync scn=1266588730 p3=0 obj#=-1 tim=1347583167886575

To see if the flash logging feature was successful in removing these outliers, I extracted the top 10,000 waits from each of the roughly 8,000,000 waits I recorded in each category. Here’s a plot (non-logarithmic) of those waits:

So – the flash log feature was effective in eliminating or at least reducing very extreme outlying redo log sync times. Most redo log sync operations will experience no improvement or maybe even a slight degradation. But for the small number of log syncs that would have experienced a really excessive delay, the feature works as advertised – it reduces the chance of really excessive log file syncs.

In my opinion, this effect doesn't imply that the flash can process a redo log write faster than the magnetic disks - in fact probably the opposite is true. But given two desitinations to choose from, we avoid really long delays that occur when one of the destinations only is overloaded.

Exadata smart flash logging

August 09, 2012 by Guy Harrison in Oracle

Exadata storage software 11.2.2.4 introduced the Smart flash logging feature. The intent of this is to reduce overall redo log sync times - especially outliers - by allowing the exadata flash storage to serve as a secondary destination for redo log writes. During a redo log sync, Oracle will write to the disk and flash simultaneously and allow the redo log sync operation to complete when the first device completes.

Jason Arneil reports some initial observations here, and Luis Moreno Campos summarized it here.

I’ve reported in the past on using SSD for redo including on Exadata and generally I’ve found that SSD is a poor fit for redo log style sequential write IO. But this architecture should at least do now harm and on the assumption that the SSD will at least occasionally complete faster than a spinning disk I tried it out.

My approach involved the same workload I’ve used in similar tests. I ran 20 concurrent processes each of which performed 200,000 updates and commits – a total of 4,000,000 redo log sync operations. I captured every redo log sync wait from 10046 traces and loaded them in R for analysis.

I turned flash logging on or off by using an ALTER IORMPLAN command like this (my DB is called SPOT):

ALTER IORMPLAN dbplan=((name='SPOT', flashLog=$1),(name=other,flashlog=on))'

And I ran “list metriccurrent where objectType='FLASHLOG'” before and after each run so I could be sure that flash logging was on or off.

When flash logging was on, I saw data like this:

Before:

     FL_DISK_FIRST                     FLASHLOG     32,669,310 IO requests
     FL_FLASH_FIRST                    FLASHLOG     7,318,741 IO requests
     FL_PREVENTED_OUTLIERS             FLASHLOG     774,146 IO requests

After:

    FL_DISK_FIRST                     FLASHLOG     33,201,462 IO requests
     FL_FLASH_FIRST                    FLASHLOG     7,337,931 IO requests
     FL_PREVENTED_OUTLIERS             FLASHLOG     774,146 IO requests

So for this particular cell the flash disk “won” only 3.8% of times (7,337,931-7,318,741)*100/(7,337,931-7,318,741+33,201,462-32,669,310) and prevented no “outliers”. Outliers are defined as being redo log syncs that would have taken longer than 500 ms to complete.

Looking at my 4 million redo log sync times, I saw that the average and median times where statistically significantly higher when the smart flash logging was involved:

> summary(flashon.data$synctime_us) #Smart flash logging ON
   Min. 1st Qu. Median    Mean 3rd Qu.    Max.
    1.0   452.0   500.0   542.4   567.0 3999.0
> summary(flashoff.data$synctime_us) #Smart flash logging OFF
   Min. 1st Qu. Median    Mean 3rd Qu.    Max.
   29.0   435.0   481.0   508.7   535.0 3998.0
> t.test(flashon.data$synctime_us,flashoff.data$synctime_us,paired=FALSE)

    Welch Two Sample t-test

data: flashon.data$synctime_us and flashoff.data$synctime_us
t = 263.2139, df = 7977922, p-value < 2.2e-16
alternative hypothesis: true difference in means is not equal to 0
95 percent confidence interval:
33.43124 33.93285
sample estimates:
mean of x mean of y
542.3583 508.6763

Plotting the distribution of redo log sync times we can pretty easily see that there’s actually a small “hump” in times when flash logging is on (note logarithmic scale):

This is of course the exact opposite of what we expect, and I checked my data very carefully to make sure that I had not somehow switched samples. And I repeated the test many times and always saw the same pattern.

It may be that there is a slight overhead to running the race between disk and flash, and that that overhead makes redo log sync times slightly higher. That overhead may become more negligible on a busy system. But for now I personally can’t confirm that smart flash logging provides the intended optimization and in fact I observed a small but statistically significant and noticeable degradation in redo log sync times when it is enabled.

Using SSD for redo on Exadata - pt 2

December 06, 2011 by Guy Harrison in Oracle

In my previous post on this topic, I presented data showing that redo logs placed on an ASM diskgroup created from exadata griddisks created from flash performed far worse than redo logs placed on ASM created from spinning SAS disks.

Of course, theory predicts that flash will not outperform spinning magnetic disk for the sequential write IOs experienced by redo logs, but on Exadata, flash disk performed much worse than seemed reasonable and worse than experience on regular Oracle with FusionIO SSD would predict (see this post).

Greg Rahn and Kevin Closson were both kind enough to help explain this phenomenon. In particular, they pointed out that the flash cards might be performing poorly because of the default 512 byte redo block size and that I should try a 4K blocksize. Unfortunately, at least on my patch level (11.2.2.3.2), there appears to be a problem with setting a 4K blocksize

ALTER DATABASE add logfile thread 1 group 9 ('+DATA_SSD') size 4096M blocksize 4096
*
ERROR at line 1:
ORA-01378: The logical block size (4096) of file +DATA_SSD is not compatible with the disk sector size (media sector size is 512 and host sector size is 512)

According to Greg, the F20 SSD cards are incorrectly reporting their physical characteristics and this is fixed in the current patch level. Luckily, you can override the check by setting

ALTER SYSTEM SET "_disk_sector_size_override"=TRUE SCOPE=BOTH;

Greg and Kevin really know their stuff: setting a 4k redo log block size resulted in dramatic improvements to redo log throughput – elapsed time reduced by 70%:

As expected, redo log performance for SSD still slightly lags that of SAS spinning disks. It’s clear that you can’t expect a performance improvement by placing redo on SSD, but at least the 4K blocksize fix makes the response time comparable. Of course, with the price of SSD being what it is, and the far higher benefits provided for other workloads – especially random reads – it’s hard to see an economic rationale for SSD-based redo. But at least with a 4K blocksize it’s tolerable.

When our Exadata system is updated to the latest storage cell software, I’ll try comparing workloads with the Exadata smart flash logging feature.

Using flash disk for Redo on Exadata

October 27, 2011 by Guy Harrison in Oracle

In this Quest white paper and on my SSD blog here, I report on how using a FusionIO flash SSD compares with SAS disk for various configurations – datafile, flash cache, temp tablespace and redo log. Of all the options I found that using flash for redo was the least suitable, with virtually no performance benefit:

That being the case, I was surprised to see that Oracle had decided to place Redo logs on flash disk within the database appliance, and also that the latest release of the exadata storage cell software used flash disk to cache redo log writes (Greg Rahn explains it here). I asked around at OOW hoping someone could explain the thinking behind this, but generally I got very little insight.

I thought I better repeat my comparisons between spinning and solid state disk on our Exadata system here at Quest. Maybe the “super capacitor” backed 64M DRAM on each flash chip would provide enough buffering to improve performance. Or maybe I was just completely wrong in my previous tests (though I REALLY don’t think so :-/).

Our Exadata 1/4 rack has a 237GB disk group constructed on top of storage cell flash disk. I described how that is created in this post. I chose 96GB per storage cell in order to allow the software to isolate the grid disks created on flash to 4 24GB FMODs (each cell has 16 FMODs). Our Exadata system has fast SAS spinning disks – 12 per storage cell for a total of 36 disks. Both the SAS and SSD disk groups had normal redundancy.

I ran an identical redo-intensive workload on the system using SAS or SSD diskgroups for the redo logs. Redo logs were 3 groups of 4GB per instance. I ran the workload on it’s own, and as10 separate concurrent sessions.

The results shocked me:

When running at a single level of concurrency, the SSD based ASM redo seemed to be around 4 times slower than the default SAS-based ASM redo. Things got substantially worse as I upped the level of concurrency with SSD being almost 20 times slower. Wow.

I had expected the SAS based redo to win – the SAS ASM disk group has 36 spindles to write to, while the SSD group is (probably) only writing to 12 FMODs. And we know that we don’t expect flash to be as good as SAS disks for sequential writes. But still, the performance delta is remarkable.

Conclusion

I’m yet to see any evidence that putting redo logs on SSD is a good idea, and I keep observing data from my own tests indicating that it is neutral at best and A Very Bad Idea at worse. Is anybody seeing any similar? Does anybody think there’s a valid scenario for flash-based redo?

Configuring Exadata flash as grid disk

September 27, 2011 by Guy Harrison in Oracle

The default – or at least a very common - configuration for Exadata is to configure all the flash as Exadata Smart Flash Cache (ESFC). This is a simple and generally performant configuration, but won’t be the best choice for all cases. In particular, if you have table which is performance critical, and it could fit in the flash storage you have available, you might be better off configuring some of your flash as grid disk, creating an ASM disk group from that, and putting the table there.

Here’s the procedure:

1. Drop the flash cache, create a new flashcache of a smaller size, then create the griddisks from the unallocated space. These CELLCLI commands do that:

CellCLI> drop flashcache
Flash cache exa1cel01_FLASHCACHE successfully dropped
CellCLI> create flashcache all size=288g
Flash cache exa1cel01_FLASHCACHE successfully created
CellCLI> create griddisk all flashdisk prefix=ssddisk

There’s 384G of flash on each storage cell, so the above commands create about 96G of SSD grid disk. Run those commands on each cell node, perhaps by using the CCLI command (see this post for an example).

2. The above procedure will create disks in the format o/cellIpAddress/ssddisk_FD_*_cellnode. Log into an ASM instance, and issue the following command to create a diskgroup from those disks:

SQL>
1 create diskgroup DATA_SSD normal redundancy disk 'o/*/ssddisk*'
2 attribute 'compatible.rdbms'='11.2.0.0.0',
3 'compatible.asm'='11.2.0.0.0',
4 'cell.smart_scan_capable'='TRUE',
5* 'au_size'='4M'

Alternatively you can use the database control for the ASM instance to create the new diskgroup. Your new flash disks should show up as candidate disks.

The relative performance of flash disks, vs flash cache is similar in Exadata to what I’ve seen using the Database flash cache. Placing an object directly on flash is faster than using the cache, although the cache is very effective. Here’s the results for 200,000 primary key lookups across 1,000,000 possible primary keys:

Clearing the Exadata smart flash cache using dcli

September 27, 2011 by Guy Harrison in Oracle

I’ve been doing some performance benchmarks on our exadata box specifically focusing on the performance of the smart flash cache. I found that even if I switched the CELL_FLASH_CACHE storage setting to NONE, the flash cache will still keep cached blocks in flash and would therefore give me artificially high values for “cell flash cache read hits” statistic when I set CELL_FLASH_CACHE back to DEFAULT or KEEP. What I needed was a way to flush the Exadata flash cache.

Unfortunately there doesn’t seem to be a good way to flush the flash cache – no obvious CELLCLI command. Maybe I’ve missed something, but for now I’m dropping and recreating the flash cache before each run.

Luckily the dcli command lets me drop and recreate on each cell directly from the database node and even sets up passwordless connections. Here’s how to do it.

Firstly, create a script that will drop and recreate the flash cache for a single cell:

$ cat flushcache.sh
cellcli <<!
drop flashcache;
create flashcache all;

Now, use ccli to execute that on each cell node (I have three named exa1cel01,exa1cel02,exa1cel03:

$ dcli -c exa1cel01,exa1cel02,exa1cel03 --serial -k -l userid -x flushcache.sh

The “-k” option copies the ssh key to the cell nodes which means that after the first execution you’ll be able to do this without typing in the password for each cell node. The “—serial” option makes each command happen one after another rather than all at once – you probably don’t need this…

Anyone know a better way to flush the Exadata flash cache?

A perl utility to improve exadata cellcli statistics

July 31, 2011 by Guy Harrison in Oracle

I’ve only recently had the opportunity to start experimenting with our relatively new Exadata 1/4 rack. Like most Exadata newbs the most immediately useful new tool is the cellcli utility which lets us get as storage cell utilities. Kerry Osborne’s blog post on top 10 commands is required reading when getting started.

Amongst Cellcli annoyances are:

You can’t join between METRICDEFINITION and METRICCURRENT or other metric tables. So you can’t easily see the descriptions of the metric values you are viewing.
CELLCLI only reports the values for the current storage cell, so you can’t get a global view across the cells.

I decided a good first project would be to write a utility that could display the metric definitions and the values together, and which would merge values from all of the storage cells. Since my old friend perl is present on the storage cells, it wasn’t too hard to put together a tool to do this. The script is here.

Setup

You’ll want to have password-less SSH connectivity between cells for this to work. Many of us will be familiar with doing this for RAC, but if you don’t, a quick primer is available at http://blogs.translucentcode.org/mick/archives/000230.html. I wrote this script to partially automate the procedure:

# Helper script to setup passwordless SSH

if [ $# -eq  0 ]

then

    echo "Usage $0 remoteHost"

    exit 1

fi

  

ssh-keygen -t dsa

while [ $# -gt 0 ]; do

    export remoteHost=$1

    scp ~/.ssh/id_dsa.pub ${remoteHost}:

    ssh $remoteHost 'mkdir .ssh; cat ~/id_dsa.pub >>~/.ssh/authorized_keys;chmod 644 ~/.ssh/authorized_keys '

    shift

done

From a database node, run the script with the names of all the storage cells on the command line. I have three cells so I issued the command like this:

[melbourne@exa1db02 ~]$ bash setup_ssh.sh exa1cel01 exa1cel02 exa1cel03

Then you will be prompted with various SSH messages about passphrases, and so on. Just hit return or “y” if prompted, except when asked for passwords. You’ll have to enter the password for each storage cell twice to get everything setup. After that you should be able to ssh to the storage cells without being prompted for a password.

Usage

Running the command with no arguments will generate the following usage message:

[melbourne@exa1db02 ~]$ perl cellcli.pl
Usage perl cellcli.pl [options]
Options:
        --hosts -H      comma seperated lists of cell nodes
        --mask -m       print metrics starting with this string
        --desc -d       print descriptions of metrics
        --cells -c      print individual cell metrics
        --sci -s        Use scientific notation
        --stats -a      Print min/max/avgs
        --help -h       print this

Example:
        perl cellcli -m FC_IO_RQ_R -h exa1cel01,exa1cel02,exa1cel03

NB: utility assumes passwordless SSH from this host to the cell nodes
see http://guyharrison.squarespace.com/blog/2011/7/31/aggregating-exadata-cellcli-statistics.html

The only compulsory argument is “—hosts”, which requires a comma-seperated list of the cell nodes. Most of the time you will want to use the “—mask” argument as well, which applies a filter to the metric names. With no other arguments you’ll then get a list of each matching statistic and the sum of values across all the cells:

[melbourne@exa1db02 ~]$ perl cellcli.pl --hosts exa1cel01,exa1cel02,exa1cel03 --mask FC_IO_RQ_R.*

Name                    Sum
----------------------- ------------
FC_IO_RQ_R               8.55164e+06
FC_IO_RQ_R_MISS               675223
FC_IO_RQ_R_MISS_SEC                0
FC_IO_RQ_R_SEC                   0.1
FC_IO_RQ_R_SKIP            1.742e+08
FC_IO_RQ_R_SKIP_SEC             33.6

Note that mask matches Unix regular expressions, not Oracle style “%” wildcards - '.*' matches anything.

The --desc argument adds the description (somewhat truncated) for each metric:

The --cells argument prints the values from each individual cell:

The --stats argument causes min,max and average values to be printed. The average is the average of sums across cells, not the average of all values. SOme statistics will have more than one value in each cell (GD_IO_RQ_W_SM for example) and the average is the average SUM of values across cells.

You can use all the arguments together, but you’re output might be very wide!

Restrictions and caveats

When a metric has multiple object values they are simply summed. That probably works OK for some statistics but maybe not for others. For instance the disk grid IO counters are broken down by the name of the grid disk within the cell:

My utility simply sums all of those values:

Hope you find this of use. Please let me know if you’ve got any suggestions…..