Archive for the 'NFS Performance' Category

Automatic Databases Automatically Detect Storage Capabilities, Don’t They?

Doug Burns has started an interesting blog thread about the Oracle Database 11g PARALLEL_IO_CAP_ENABLED parameter in his blog entry about Parallel Query and Oracle Database 11g. Doug is discussing Oracle’s new concept of built-in I/O subsystem calibration-a concept aimed at more auto-tuning database instances. The idea is that Oracle is trying to make PQ more aware of the down-wind I/O subsystem capability so that it doesn’t obliterate it with a flood of I/O. Yes, a kinder, gentler PQO.

I have to admit that I haven’t yet calibrated this calibration infrastructure. That is, I aim to measure the difference between what I know a given I/O subsystem is capable of and what DBMS_RESOURCE_MANAGER.CALIBRATE_IO thinks it is capable of. I’ll blog the findings of course.

In the meantime, I recommend you follow what Doug is up to.

A Really Boring Blog Entry
Nope, this is not just some look at that other cool blog over there post. At first glance I would hope that all the regular readers of my blog would wonder what value there is in throttling I/O all the way up in the database itself given the fact that there are several points at which I/O can/does get throttled downwind. For example, if the I/O is asynchronous, all operating systems have a maximum number of asynchronous I/O headers (the kernel structures used to track asynchronous I/Os) and other limiting factors on the number of outstanding asynchronous I/O requests. Likewise, SCSI kernel code is fit with queues of fixed depth and so forth. So why then is Oracle doing this up in the database? The answer is that Oracle can run on a wide variety of I/O subsystem architectures and not all of these are accessed via traditional I/O system calls. Consider Direct NFS for instance.

With Direct NFS you get disk I/O implemented via the remote procedure call interface (RPC). Basically, Oracle shoots the NFS commands directly at the NAS device as opposed to using the C library read/write routines on files in an NFS mount-which eventually filters down to the same thing anyway, but with more overhead. Indeed, there is throttling in the kernel for the servicing of RPC calls, as is the case with traditional disk I/O system calls, but I think you see the problem. Oracle is doing the heavy lifting that enables you to take advantage of a wide array of storage options-and not all of them are accessed with age-old traditional I/O libraries. And it’s not just DNFS. There is more coming down the pike, but I can’t talk about that stuff for several months given the gag order. If I could, it would be much easier for you to visualize the importance of DBMS_RESOURCE_MANAGER.CALIBRATE_IO. In the meantime, use your imagination. Think out of the box…way out of the box…

Manly Men Only Use Solid State Disk For Redo Logging. LGWR I/O is Simple, But Not LGWR Processing

Let’s look at some statspack data from an OLTP Order Entry benchmark run that achieved 133 transaction per second (TPS):

Top 5 Timed Events                                                    Avg %Total
~~~~~~~~~~~~~~~~~~                                                   wait   Call
Event                                            Waits    Time (s)   (ms)   Time
----------------------------------------- ------------ ----------- ------ ------
log file sync                                   68,965       1,117     16   64.6
db file sequential read                        159,712         241      2   14.0
CPU time                                                       163           9.4
log file switch (checkpoint incomplete)            164         146    890    8.4
db file parallel write                          19,651          31      2    1.8

And now let’s look at the stats from run number 2 of the same benchmark, same system, same disk setup, etc:

Top 5 Timed Events                                                    Avg %Total
~~~~~~~~~~~~~~~~~~                                                   wait   Call
Event                                            Waits    Time (s)   (ms)   Time
----------------------------------------- ------------ ----------- ------ ------
db file sequential read                        838,810       1,635      2   69.1
CPU time                                                       253          10.7
db file parallel write                         153,334         145      1    6.1
log file sync                                   93,100         143      2    6.0
log file parallel write                         93,417          73      1    3.1

Benchmark run number 2 achieved 200 TPS. That’s right, statspack number 1 and number 2 above are from the same system. The database files are stored in an an HP EFS Clustered Gateway NAS device and accesed via NFS and the redo logs are, get this, stored on a Texas Memory Systems Solid State Disk. Statspack 2 above was a very busy system (a lot of cached SGA work) and doing over 3,000 IOPS:

Load Profile                            Per Second       Per Transaction
~~~~~~~~~~~~                       ---------------       ---------------
                  Redo size:          1,138,491.64              7,166.65
              Logical reads:             14,640.16                 92.16
              Block changes:              5,538.83                 34.87
             Physical reads:              1,428.73                  8.99
            Physical writes:              1,742.27                 10.97
                 User calls:              2,352.99                 14.81

So if a) system is the same, and b) LGWR is writing redo to the fastest disk possible, what is the story? What changed from statspack 1 to statspack 2 to make log file sync wait events jump 8-fold-with the associated 34% drop in throughput? More users? No. Nothing that simple. I’ll explain.

LGWR I/O? Who Cares-Simple Stuff
I see myriads of information on blogs, forums and all those expert repositories about the I/O aspects of redo logging, but very little about LGWR processing. Yes, a portion of LGWR’s job is to flush the redo buffer to the online redo log, but there’s more to LGWR’s job than writing redo. In fact, I never could understand the fascination with LGWR’s I/O since it is about as simple as it gets: sequential writes to a single file of sizes ranging from 512 bytes to a port-defined maximum (usually 128KB but often 1MB). Yes, it gets a little more complex with multiplexed redo, but that is just concurrent operations of the exact same profile. The part that seems to be hard to grasp for folks is where asynchronous I/O comes in to play.

LGWR Async I/O
If LGWR is clearing more than the port-defined maximum from the buffer, asynchronous I/O is important. Let’s consider an example. Let’s say LGWR has been posted to clear 1.75MB of redo from the buffer on a platform that establishes the LGWR I/O maximum to be 1MB. In this case, LGWR will issue a 1MB write asynchronously immediately followed by a 750KB asynchronous write. These writes are sequential. After the second I/O is in flight, LGWR starts to poll for the completions of the I/Os. So the question often becomes what if LGWR is only flushing, say, 600KB instead of 1.75MB, isn’t asynchronous I/O crucial in that case as well? The answer is no-unless you are using multiplexed redo. If LGWR is flushing an amount less than the port-defined maximum, asynchronous I/O offers nothing-for that specific flushing operation. See, LGWR is a lot different than DBWR. When DBWR has I/O in flight, it also has other stuff it needs to do like building the next write batch and so forth. LGWR on the other hand has nothing to do when its I/Os are in flight. It polls for the completions and once the flushing operation is complete, it then takes action to post the foregrounds that are waiting in a log file sync wait event. So asyncnronous I/O has no play in a LGWR buffer flush operation of an amount smaller than the port-defined maximum I/O size.

Oh, I forgot to mention, LGWR will keep up to 4 I/Os in flight (I need to check if that is more in late releases) when clearing more than the maximum allowed in a single physical write. All in all, LGWR I/O is very simple. So why do session waits, such as log file sync, generate so much folklore? I don’t know, but I know the folklore isn’t helpful.

Throw A Solid State Disk At It
I love that one. Let’s see, writing to solid state disk is faster than round-brown spinning thingies, so if any aspect of LGWR’s duties seem out of sorts, let’s get some really, really fast disk. Don’t get me wrong, I’m a big fan of solid state disk, but throwing it at the wrong problem is not the right thing to do.

The most complex topic regarding LGWR is the log file sync wait event. Why? Because it has very little to do with I/O, that’s why. Sure I/O is a part of it, but there is more to it.

Backgrounder
LGWR spends its time in a work loop consisting of very little, really. Well, in contrast to DBWR that is. Remember, DBWR has to manipulate both cache buffers chains and lrus and flush modified SGA buffers and post processes. While DBWR works on a large amount of metadata and buffers, LGWR does not. A glance at ps(1) output makes that clear. Notice in the following ps(1) output, LGWR manages to perform its tasks with a resident set size one 30th the size of DBWR-and of course that ratio would lean much more to the DBWR side on a large SGA system since DBWR has to map all the buffers in the SGA over the life of the instance (the exception to this is the indirect data buffers feature). LGWR on the other hand has very little working set because it only tends to the redo buffer and will only exercise a few latches (redo allocation, copy, etc).

$ ps -eF | egrep 'UID|lgwr|dbw' | grep -v grep
UID        PID  PPID  C    SZ  RSS PSR STIME TTY          TIME CMD
oracle   19062     1  1 377082 851808 0 16:11 ?       00:00:08 ora_dbw0_bench1
oracle   19064     1  2 379943 29816 0 16:11 ?        00:00:09 ora_lgwr_bench1

Log File Sync
When a foreground process commits changes to the database, it allocates space in the redo buffer and copies the redo information into the buffer-protected either by the redo allocation latch itself or a redo copy latch. The process then enqueues itself for service from LGWR and posts the LGWR (most ports use IPC semaphores for posting). The process then goes to sleep waiting for the return post from LGWR indicating its redo is flushed to disk. So, we now have a process waiting for log file sync event (LFS). Let’s call this process waiter1. How long waiter1 waits depends on a lot of factors.

The first factor that will affect waiter1′s LFS wait is what LGWR was doing when it posted him. Remember, Oracle is a multi-user database on a multi-processor system. There is 1 LGWR and a lot of consumers of his service. On a busy system, odds are quite good that any time LGWR get posted it is in the process of servicing a batch of prior waiters. That is, when waiter1 posted LGWR the odds are good it was already busy flushing a bunch of redo for some other group of processes who are themselves waiting in LFS. This is where it gets dicey.

Before LGWR can flush waiter1′s redo, he has to finish flushing the prior batch and post all of those waiters. Let’s say there was 256KB of redo to flush for 2 waiters on a platform with the port-defined maximum LGWR I/O size set at 128KB. On this platform, LGWR will have to issue 2 asynchronous 128KB writes and poll for those to complete. Once the I/O is complete, LGWR will post each of the two waiters using the post-wait mechanism for that port of Oracle-which is an IPC Semaphore semop() call for most platforms. So, LGWR has made system calls to write, and system calles to poll for I/O completion and finally 2 calls to semop(). LGWR is just a normal user-mode process so all this dipping into the kernel introduces processing delays. Yes, these system calls I listed are non-blocking, but when a processor transitions from kernel to user mode there is opportunity to switch to higher-priority runable processes. In fact, the very act of LGWR posting these 2 processes can cause it to lose CPU. Huh? Sure. What if instead of 2 there were 16 in the batch and there were only 4 CPUs on the system. We call that the thundering herd and it wreaks havoc on LGWR. These process scheduling storms can be quite problematic. Think about it. You have one process (LGWR) that just made 4,8 or 16 or more processes runable by semop()ing them from their log file sync wait which makes them runable in kernel mode which trumps a runable user-mode process. If that happens on a system with, say 8 cores, those processes will need to run somewhere. It is a scheduling storm. For this reason you should always set LGWR’s scheduling priority to the highest possible (with renice for instance).

Without elevated scheduling priority for LGWR, it can often be the case that the processes LGWR wakes up will take the CPU from LGWR. Some platforms (Legacy Unix) support the notion of making processes non-preemptable as well. On those platforms you can make LGWR non-preemptable. Without preemption protection, LGWR can lose CPU before it has exhausted its fair time slice.
Once LGWR loses his CPU it may be quite some time until he gets it back. For instance, if LGWR is preempted in the middle of trying to perform a redo buffer flush, there may be several time slices of execution for other processes before LGWR gets back on CPU. Why am I putting you to sleep about this? Because those time slices that LGWR was off CPU will be charged to foreground processes waiting in a log file sync wait event. Yes, if a foreground is in log file sync wait and LGWR is piled under other processes and can’t get CPU for, say, a few time slices (10ms each), that foreground process’ log file sync will have 10, 20 or more milliseconds of extra wait tacked onto it before LGWR even gets a chance to do I/O. LGWR’s I/O is merely a component of a foreground process’ LFS wait.

So what happened to the benchmark run behind statspack 2 above? CPU starvation specifically for LGWR! How did I do that? Easy. I have a simple program that uses the Linux sched_setaffinity() API call to assign hard processor affinity to processes. These tests were done on a 4-core x86 system and in both cases all the background processes were started up with hard CPU affinity to CPU 0. Once the database was started, I reassign LGWR’s hard affinity to CPU 3. The Pro*C benchmark processes and their associated shadow processes are all running split equally with hard affinity between CPUs 1 and 2. This is the model for both benchmark runs. Yes, LGWR is all alone on CPU 3.

In the case where the benchmark only got 133TPS, I have a “noise” process running on the same CPU as LGWR. This noise process also is pinned to the CPU with hard affinity. What does this “noise” process do that is so heinous as to affect Oracle’s OLTP throughput by 34%? After all, it is only a single process. Yes, single, but also running on the same CPU as LGWR. The noise program is:

double sqrt();
main () { int i; double z; for (;;) { for (i = 0; i < 1000000; i++) { z = sqrt (i); } poll (0, 0, 1); } }

Simple enough. That loop of sqrt() calls from libm takes about 3ms on the CPUs in this benchmark system. So the way this works is that about every 3ms, this process will go to sleep for 1ms using the poll() system call. If this process is running when LGWR needs to run, LGWR will have to wait for 3ms. If that process isn’t executing, LGWR has no impediment to peforming his tasks and LFS are a measely 2ms and OLTP throughput jumps 34%.

This little parasite noise process gets in LGWR’s way a lot too. Basically, any time LGWR gets posted to perform a flush, this noise process is in the way (chalk up 3ms), any time LGWR blocks on an I/O (e.g., a flush that is smaller than the port maximum and therefore a single I/O) this noise process is in the way once the I/O is complete (chalk up 3ms), any time LGWR unluckily loses his CPU to a time slice switch this process will run and take 3ms from LGWR. It all adds up. And in this test case, processes posted by LGWR can never take his CPU (since I’ve set up hard affinity) so this is a nicer test case actually.

Don’t Write At All

Just to be evil, I’ll take it a step further. Did you know that if you set the initialization parameter _disable_logging=TRUE LGWR does everything it normally does except it omits performing the I/O for a redo flush. Don’t do this if you like your database because anything other than a shutdown normal is going to leave your database unrecoverable. However, this is a great test because if performance doesn’t increase when you set this parameter in this fashion, then you have a LGWR I/O processing problem and not a LGWR I/O problem. So I did a run of the same benchmark like this:

SQL> show parameter _disable

NAME                                 TYPE        VALUE
------------------------------------ ----------- ------------------------------
_disable_logging                     boolean     TRUE

Everything else was the same but now instead of really fast Solid State Disk I/Os, LGWR doesn’t even bother writing to disk at all. What did that do to the benchmark results? Nothing. I still get 133TPS.

Summary
LGWR I/O is very simple. LGWR processing on the other hand is a bit more complex.

Manly Men Only Deploy Oracle with Fibre Channel – Part II. What’s So Simple and Inexpensive About NFS for Oracle?

The things I routinely hear from DBAs leads me to believe that they often don’t understand storage. Likewise, the things I hear from Storage Administrators convinces me they don’t always know what DBAs and system administrators have to do with those chunks of disk they dole out for Oracle. This is a long blog entry aimed at closing that gap with a particular slant to Oracle over NFS. Hey, it is my blog after all.

I also want to clear up some confusion about points I made in a recent blog entry. The confusion was rampant as my email box will attest so I clearly need to fix this.

I was catching up on some blog reading the other day when I ran across this post on Nuno Souto’s blog dated March 18, 2006. The blog entry was about how Noon’s datacenter had just taken on some new SAN gear. The gist of the blog entry is that they did a pretty major migration from one set of SAN gear to the other with very limited impact—largely due to apparent 6-Ps style forethought. Noons speaks highly of the SAN technology they have.

Anyone that participates in the oracle-l email list knows Noons and his important contributions to the list. In short, he knows his stuff—really well. So why am I blogging about this? It dawned on me that my recent post about Manly Men Only Deploy Oracle with Fibre Channel Storage jumped over a lot of ground work. I assure you all that neither Noons nor the tens of thousands of Oracle shops using Oracle on FCP are Manly Men as I depicted in my blog entry. I’m not trying to suggest that people are fools for using Fibre Channel SANs. Indeed, after waiting patiently from about 1997 to about 2001 for the stuff to actually work warrants at least some commitment to the technology. OK, ok, I’m being snarky again. But wait, I do have a point to make.

Deploying Oracle on NAS is Simpler and Cheaper, Isn’t It?
In my blog entry about “Manly Man”, I stated matter-of-factly that it is less expensive to deploy Oracle on NAS using NFS than on SANs. Guess what, I’m right, it is. But I didn’t sufficiently qualify what I was talking about. I produced that blog entry presuming readers would have the collective information of my prior blog posts about Oracle over NFS in mind. That was a weak presumption. No, when someone like Noons says his life is easier with SAN he means it. Bear in mind his post was comparing SAN to DAS, but no matter. Yes, Fibre Channel SAN was a life saver for too many sites to count in the late 90s. For instance, sites that bought into the “server consolidation” play of the late 1990s. In those days, people turned off their little mid-range Unix servers with DAS and crammed the workloads into a large SMP. The problem was that eventually the large SMP couldn’t physically attach any more DAS. It turns out that Fibre was needed first and foremost to get large numbers of disks connected to the huge SMPs of the era. That is an entirely different problem to solve than getting large numbers of servers connected to storage.

Put Your Feet in the Concrete
Most people presume that Oracle over NFS must be exponentially slower than Fibre Channel SAN. They presume this because at face value the wires are faster (e.g., 4Gb FCP versus 1Gb Ethernet). True, 4Gb is more bandwidth than 1Gb, but you can have more than one NFS path to storage and the latencies are a wash. I wanted to provide some numbers so I thought I’d use Network Appliance’s data that suggested a particular test of 8-way Solaris servers running Oracle OLTP over NFS comes within 21% of what is possible on a SAN. Using someone else’s results was mistake number 1. Folks, 21% degredation for NFS compared to SAN is not a number cast in stone. I just wanted to show that it is not a day and night difference and I wanted to use Network Appliance numbers for validity. I would not be happy with 21% either and that is good, because the numbers I typically see are not even in that range to start with. I see more like 10% and that is with 10g. 11g closes the gap nicely.

I’ll be producing data for those results soon enough, but let’s get back to the point. 21% of 8 CPUs worth of Oracle licenses would put quite a cost-savings burden on NAS in order to yield a net gain. That is, unless you accept the fact that we are comparing Oracle on NAS versus Oracle on SAN in which case the Oracle licensing gets cancelled out. And, again, let’s not hang every thought on that 21% of 8 CPUs performance difference because it is by no means a constant.

Snarky Email
After my Manly Man post, a fellow member of the OakTable Network emailed me the viewpoint of their very well-studied Storage Administrator. He calculated the cost of SAN connectivity for a very, very small SAN (using inexpensive 8-port FC switches) and factored in Oracle Enterprise Edition licensing to produce a cost per throughput using the data from that Network Appliance paper—the one with the 21% deficit. That is, he used the numbers at hand (21% degradation), Oracle Enterprise Edition licensing cost and his definition of a SAN (low connectivity requirements) and did the math correctly. Given those inputs, the case for NAS was pretty weak. To my discredit, I lashed back with the following:

…of course he is right that Oracle licensing is the lion’s share of the cost. Resting on those laurels might enable him to end up the last living SAN admin.

Folks, I know that 21% of 8 is 1.7 and that 1.7 Enterprise Edition Licenses can buy a lot of dual-port FCP HBAs and even a midrange Fibre Channel switch, but that is not the point I failed to make. The point I failed to make was that I’m not talking about solving the supposed difficulties of provisioning storage to those one or two remaining refrigerator-sized Legacy Unix boxes you might have. There is no there, there. It is not difficult at all to run a few 4Gb FCP wires to separate 8 or 16 port FC switches and then back to the storage array. Even Manly Man can do that. That is not a problem that needs solved because that is neither difficult nor is it expensive (at least the SAN aspect isn’t). As the adage goes, a picture speaks a thousand words. The following is a visual of a problem that doesn’t need to be solved—a simple SAN connected to a single server. Ironically, what it depicts is potentially millions of dollars worth of server and storage connected with merely thousands of dollars worth of Fibre Channel connectivity gear. In case the photo isn’t vivid enough, I’ll point out that on the left is a huge SMP (e.g., HP Superdome) and on the right is an EMC DMX. In the middle is a redundant set of 8-port switches—cheap, and simple. Even providing private and public Ethernet connectivity in such a deployment is a breeze by the way.

simplesan.jpg

I Ain’t Never Doing That Grid Thing.
Simply put, if the only Oracle you have deployed—now and forever—sits in a couple of refrigerator-sized legacy SMP boxes, I’m going to sound like a loon on this topic. I’m talking about provisioning storage to commodity servers—grid computing. Grid may not be where you are today, but it is in fact where you will be someday. Consider the fact that most datacenters are taking their huge machines and chopping them up into little machines with hardware/software virtualization anyway so we might as well just get to the punch and deploy commodity servers. When we do, we feel the pain of Fibre Channel SAN connectivity and storage provisioning. Because connecting large numbers of servers to storage was not exactly a design center for Fibre Channel SAN technology. Just the opposite is true; SANs were originally meant to connect a few servers to a huge number of disks—more than was possible with DAS.

Commodity Computing (Grid) == Huge SAN
Large numbers of servers connected to a SAN makes the SAN very complex. Not necessarily more disks, but the presentation and connectivity aspects get very difficult to deal with.

If you are unlucky enough to be up to your knees in the storage provisioning, connectivity and cost nightmare associated with even a moderate number of commodity servers in a SAN environment you know what I’m talking about. In these types of environments, people are deploying and managing director-class Fibre Channel switches where each port can cost up to $5,000 and they are deploying more than one switch for redundancy sake. That is, each commodity server needs a 2 port FC HBA and 2 paths to two different switches. Between the HBAs and the FC switch ports, the cost is as much as $10,000-$12,000 just to connect a “pizza box” to the SAN. That’s the connectivity story and the provisioning story is not much prettier.

Once the cabling is done, the Storage Administrator has to zone the switches and provision storage (e.g., create LUNs, LUN masking, etc). For RAC, that would be a minimum of 3 masked LUNs for each database. Then the System Administrator has to make sure Oracle has access to those LUNs. That is a lot of management overhead. NAS on the other hand uses very inexpensive NICs and switches. Ah, now there is an interesting point. Using NAS means each server only has one type of network connectivity instead of two (e.g., FC and Ethernet). Storage provisioning is also simpler—the database server administrator simply mounts the NFS filesystem and the DBA can go straight to work with RAC or non-RAC Oracle databases. How simple. And yes, the Oracle licensing cost is a constant, so in this paradigm, the only way to recuperate cost is in the storage connectivity side. The savings are worth consideration, and the simplicity is very difficult to argue.

It’s time for another picture. The picture below depicts a small commodity server deployment—38 servers that need storage.

complexsan.jpg

Let’s consider the total connectivity problem starting with the constant—Ethernet. Yes, every one of these 38 servers needs both Ethernet and Fibre Channel connectivity. For simplicity, let’s say only 8 of these servers are using RAC. The 8 that host RAC will need a minimum of 4 Gigabit Ethernet NICs/cables—2 for the public interfaces and two for a bonded, private network for Oracle Cache Fusion (GCS, GES) for a total of 32. The remaining 30 could conceivably do fine with 2 public networks each for a subtotal of 60. All told, we have 92 Ethernet paths to deal with before we look at storage networking.

On the storage side, we’ll need redundant paths for all 38 server to multiple switches so we start with 38 dual-port HBAs and 76 front-side Fibre Channel switch ports. Each switch will need a minimum of 2 paths back to storage, but honestly, would anyone try to feed 38 modern commodity servers with 2 4Gb paths worth of storage bandwidth? Likely not. On the other hand, it is unlikely the 30 smaller servers will each need dedicated 4Gb I/O bandwidth to storage so we’ll play zone trickery on the switch and group sets of 2 from the 30 yielding a requirement for 15 back-side I/O paths from each switch for a subtotal of 30 back-side paths. Following in suit, the remaining 8 RAC servers will require 4 back-side paths from each of the two switches for a subtotal of 8 back-side paths. To sum it up, we have 76 front-side and 38 back-side paths for a total of 114 storage paths. Yes, I know this can be a lot simpler by limiting the number of switch-to-storage paths. That’s a game called Which Servers Should We Starve for I/O and it isn’t fun to play. These arrangements are never attempted with small switches. That’s why the picture depicts large, expensive director-class switches.

Here’s our mess. We have 92 Ethernet paths and 114 storage paths. How would NAS make this simpler? Well, Ethernet is the constant here so we simply add more inexpensive Ethernet infrastructure. We still need redundant switches and I/O paths, but Ethernet is cheap and simple and we are down to a single network topology instead of two. Just add some simple NICs and simple Ethernet switches and go. And oh, by the way, the two network-topologies-model (e.g., GbE_+ FCP) generally means two different “owners” since the SAN would generally be owned by the Storage Group and the Ethernet would be owned by the Networking Group. With NAS, all connectivity from the Ethernet switches forward can be owned by the Networking Group freeing the Storage Group to focus on storage—as opposed to storage networking.

And, yes, Oracle11g has features that make the connectivity requirement on the Ethernet side simpler but 10g environments can benefit from this architecture too.

Not a Sales Pitch
Thus far, this blog entry has been the what. This would make a pretty hollow blog entry if I didn’t at least mention the how. The odds are very slim that your datacenter would be able to do a 100% NAS storage deployment. So Network Appliance handles this by offering multiple protocol storage from their Filers. The devil shall not remain with the details.

Total NAS? Nope. Multi-Protocol Storage.
I’ll be brief. You are going to need both FCP and NAS, I know that. If you have SQL Server (ugh) you certainly aren’t going to connect those servers to NAS. There are other reasons FCP isn’t going to go away soon enough. I accept the fact that both protocols are required in real life. So let’s take a look a multi-protocol storage and how it fits into this thread.

Network Appliance Multi-Protocol Support
Network Appliance is an NFS device. If you want to use it for FCP or iSCSI SAN, large files in the Filer’s filesystem (WAFL) are served with either FCP or iSCSI protocol and connectivity. Fine. It works. I don’t like it that much, but it works. In this paradigm, you’d choose to run the simplest connectivity type you deem fit. You could run some FCP to a few huge Legacy SMPs, FCP to some servers running SQL Server (ugh), and most importantly Ethernet for NFS to whatever you choose—including Oracle on commodity servers. Multi-protocol storage in this fashion means total vendor lock-in, but it would allow you to choose between the protocols and it works.

SAN Gateway Multi-Protocol Support
Don’t get rid of your SAN until there is something reasonable to replace it with. How does that statement fit this thread? Well, as I point out in this paper, SAN-NAS gateway devices are worth consideration. Products in this space are the HP Enterprise File Services Clustered Gateway and EMC Celerra. With these devices you leverage your existing SAN by connecting the “NAS Heads” to the SAN using very low-end, simple Fibre Channel SAN connectivity (e.g., small switches, few cables). From there, you can provision NFS mounts to untold numbers of NFS clients—a few, dozens or hundreds. The mental picture here should be a very small amount of the complex, expensive connectivity (Fibre Channel) and a very large amount of the inexpensive, simple connectivity (Ethernet). What a pleasant mental picture that is. So what’s the multi-protocol angle? Well, since there is a down-wind SAN behind the NAS gateway, you can still directly cable your remaining Legacy Unix boxes with FCP. You get native FCP storage (unlike NetApp with the blocks-from-file approach) for the systems that need it and NAS for the ones that don’t.

I’m a Oracle DBA, What’s in It for Me?
Excellent question and the answer is simply simplicity! I’m not just talking simplicity, I’m talking simple, simple, simple. I’m not just talking about simplicity in the database tier either. As I’ve pointed out upteen times, NFS will support you from top to bottom—not just the database tier, but all your unstructured data such as software installations as well. Steve Chan chimes in on the simplicity of shared software installs in the E-Biz world too. After the NFS filesystem is mounted, you can do everything from ORACLE_HOME, APPL_TOP, clusterware files (e.g., the OCR and CSS disks), databases, RMAN, imp/exp, SQL*Loader/External Tables, ETL, compiled PL/SQL, UTL_FILE, BFILE, trace/logging, scripts, and on and on. Without NFS, what sort of mix-match of raw, filesystem, raw+ASM combination would be required? A complex one—and the really ironic part is you’d probably still end up with some NFS mounts in addition to all that raw disk and non-CFS filesystem space as well!

Whew. That was a long blog entry.


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This disclaimer was put into place on March 23, 2011.

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All content is © Kevin Closson and "Kevin Closson's Blog: Platforms, Databases, and Storage", 2006-2013. Unauthorized use and/or duplication of this material without express and written permission from this blog’s author and/or owner is strictly prohibited. Excerpts and links may be used, provided that full and clear credit is given to Kevin Closson and Kevin Closson's Blog: Platforms, Databases, and Storage with appropriate and specific direction to the original content.

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