Encapsulating VT-d Accelerated ZFS Storage within ESXi

Some time ago I found myself conceptually provisioning ESXi hosts that could transition local storage in a distributed manner within an array of hypervisors. The architectural model likens itself to an amorphous cluster of servers which share a common VM client service that self provisions shared storage to it’s parent hypervisor or even other external hypervisiors. This concept originally became a reality in one of my earlier blog entries named Provisioning Disaster Recovery with ZFS, iSCSI and VMware. With this previous success of a DR scope we can now explore more adventurous applications of storage encapsulation and further coin the phrase of “rampent layering violations of storage provisioning” thanks to Jeff Bonwick, Jim Moore and many other brilliant creative minds  behind the  ZFS storage technology advancements. One of the main barriers of success for this concept was the serious issue of circular latency from within the self provisioning storage VM. What this commonly means is we have a long wait cycle for the storage VM to ready the requested storage since it must wait for the hypervisior to schedule access to the raw storage blocks  for the virtualized shared target which then will re-provision it to other VM’s. This issue is acceptable for a DR application but it’s a major show stopper for applications that require normal performance levels.

This major issue now has a solution with the introduction of Intel’s VT-d technology. VT-d allows us to accelerate storage I/O functionality directly inside a VM served by a VMware based ESX and ESXi hypervisors. VMware has leveraged Intel’s VT-d technology on ESXi 4.x (AMD I/O Virtualization Technology (IOMMU) is also supported) as part of the named feature VMDirectPath. This feature now allows us to insert high speed devices inside a VM which can now host a device that operates at the hardware speed of the PCI Bus and that my friend allows virtualized ZFS storage provisioning VMs to dramatically reduce or eliminate the hypervisor’s circular latency issue.

Very exciting indeed, so lets leverage a visual diagram of this amorphous server cluster concept to better capture what this envisioning actually entails.

Encapsulated Accelerated ZFS Architecture


The concept depicted here sets a multipoint NFS share strategy. Each ESXi host provisions it’s own NFS share from it’s local storage which can be accessed by any of the other hosts including itself. Additionally each encapsulated storage VM incorporates ZFS replication to a neighboring storage VM in a ring pattern thus allowing for crash based recovery in the event of a host failure. Each ESXi instance hosts a DDRdrive X1 PCIe Card which is presented to it’s storage VM over VT-d and VMDirectPath aka. PCI Pass Through. When managed via vCenter this solution allows us to svMotion VM’s across the cluster allowing rolling upgrades or hardware servicing.

The ZFS replication cycle works as a background ZFS send receive script process that incrementally updates the target storage VM. One very useful feature of  ZFS send receive capability is the include ZFS properties flag -p. When this flag is used any NFS share properties that are defined using “sharenfs= ” will be sent the the target host. Thus the only required action to enable access to the replicated NFS share is to add it as an NFS storage target on our ESXi host. Of course we would also need to stop replication if we wish to use the backup or clone it to a new share for testing. Testing the backup without cloning will result in a modified ZFS target file system and this could force a complete ZFS resend of the file system in some cases.

Within this architecture our storage VM is built with OpenSolaris snv_134 thus we have the ability to engage in ZFS deduplication. This not only improves the storage capacity it also grants improved performance when we allocate sufficient memory to the storage VM. ZFS Arc caching needs only to cache these dedup block hits once which accelerates all depup access requests. For example if this cluster served a Virtual Desktop Environment (VDI) we would see all the OS file allocation blocks enter into the ZFS Arc cache and thus all VMs that reference the same OS file blocks would be cache accelerated. Dedup also grants a benefit with ZFS replication with the use of the ZFS send -D flag. This flag instructs ZFS send to the stream in dedup format and this dramatically reduces replication bandwidth and time consumption in a VMware environment.

With VT-d we now have the ability to add a non-volatile disk device as a dedicated ZIL accelerator commonly called a SLOG or Separate Intent Log. In this proof of concept architecture I have defined the DDRdrive X1 as a SLOG disk over VMware VMDirectPath to our storage VM. This was a challenge to accomplish as VT-d is just emerging and has many unknown behaviors with system PCI BUS timing and IRQ handling. Coaxing VT-d to work correctly proved to be the most technically difficult component of this proof of concept, however success is at hand using a reasonably cost effective ASUS motherboard in my home lab environment.

Let’s begin with the configuration of VT-d and VMware VMDirectPath.

VT-d requires system BIOS support and this function is available on the ASUS P6X58D series of motherboards. The feature is not enabled by default you must change it in BIOS. I have found that enabling VT-d does impact how ESXi behaves, for example some local storage devices that were available prior to enabling VT-d may not be accessible after enabling it and could result in messages like “cannot retrieve extended partition information”.

The following screen shots demonstrate where you would find the VT-d BIOS setting on the P6X58D mobo.


VT-d-BIOS-Enable1

VT-d-BIOS-Enable2.png

If your using an AMD 890FX based ASUS Crosshair IV mobo then look for the IOMMU setting as depicted here:

Thanks go to Stu Radnidge over at http://vinternals.com/ for the screen shot!

IOMMU on AMD 890FX Based Mobos

Once VT-d or IOMMU is enabled ESXi VMDirectPath can be enabled from the VMware vSphere client host configuration-> advanced menu and will require a reboot to complete any further PCI sharing configurations.

One challenge I encountered was PCIe BUS timing issues, fortunately the ASUS P6X58D overclocking capability grants us the ability to align our clock timing on the PCIe BUS by tuning the frequency and voltage and thus I was able to stabilize the PCIe interface running on the DDRdrive X1.  Here are original values I used that worked.  Since that time I have pushed the i7 CPU to 4.0Ghz, but that can be risky since you need to up the CPU and DRAM voltages so I will leave the safe values for public consumption.


P6X58D-Overclock-Tuning1


P6X58D-Overclock-Tuning2


ESXi-Console_Shot


Once VT-d is active you will be able to edit the enumerated PCI device list check boxes and allow pass through for the device of your choice. There are three important PCI values to note. The device ID, Vendor ID and the Class ID of which you can Google it or take this short cut http://www.pcidatabase.com/ and discover who owns the device and what class it belongs to. In this case I needed to ID the DDRdrive X1 and I know by the class ID 0100 that it is a SCSI device.


VMDirectPath Enabled


Once our DDRdrive X1 device is added to the encapsulated OpenSolaris VM it’s shared IRQ mode will need to be adjusted such that no other IRQ’s are chained to it. This is adjusted by adding a custom VM config parameter named pciPassthru0.msiEnabled and setting its value to false.


VMPassThru-msiEnabled=false


In this proof of concept the storage VM is assigned 4Gb of memory which is reasonable for non-deduped storage.  If you plan to dedup the storage I would suggest significantly more memory to allow the block hash table to be held in memory, this is important for performance and is also needed if you have to delete a ZFS file system. The amount will vary depending on the total storage provisioned. I would rough estimate about 8GB of memory for each 1TB of used storage. As  well we have two network interfaces of which one will provision the storage traffic only. Keep in mind that dedup is still developing and should be heavily tested, you should expect some issues.


.VM Settings

If you have read my previous blog entry Running ZFS Over NFS as a VMware Store you will find the next section to be very similar. This is essentially many of the same steps but excludes  aggregation and IPMP capability.

Using a basic OpenSolaris Indiana completed install we can proceed to configure a shared NFS store so let’s begin with the IP interface. We don’t need a complex network configuration for this storage VM and therefore we will just setup simple static IP interfaces, one to manage the OpenSolaris storage VM and one to provision the NFS store. Remember that you should normally separate storage networks from other network  types from both a management and security perspective.

OpenSolaris will default to a dynamic network service configuration named nwam, this needs to be disabled and the physical:default service enabled.

root@uss1:~# svcadm disable svc:/network/physical:nwam
root@uss1:~# svcadm enable svc:/network/physical:default

To persistently configure the interfaces we can store the IP address in the local hosts file. The file will be referenced by the physical:default service to define the network IP address of the interfaces when the service starts up.

Edit /etc/hosts to have the following host entries.

::1 localhost
127.0.0.1 uss1.local localhost loghost
10.0.0.1 uss1 uss1.domain.name
10.1.0.1 uss1.esan.data1

As an option if you don’t normally use vi you can install nano.

root@uss1:~# pkg install SUNWgnu-nano

When an OpenSolaris host starts up the physical:default service will reference the /etc directory and match any plumbed network device to a file which contains the interface name a prefix of “hostname” and an extension using the interface name.  For example in this VM we have defined two Intel e1000 interfaces which will be plumbed using the following commands.

root@uss1:~# ifconfig e1000g0 plumb
root@uss1:~# ifconfig e1000g1 plumb

Once plumbed these network devices will be enumerated by the physical:default service and if a file exists in the /etc directory named hostname.e1000g0 the service will use the content of this file to configure this interface in the format that ifconfig uses. Here we have created the file using echo, the “uss1.esan.data1″ name will be looked up in the hosts file and maps to IP 10.1.0.1, the network mask and broadcast will be assigned as specified.

root@uss1:~# echo uss1.esan.data1 netmask 255.255.0.0  broadcast 10.1.255.255 > /etc/hostname.e1000g0

One important note:  if your /etc/hostname.e1000g0 file has blank lines you may find that persistence fails on any interface after the blank line, thus no blank in the file sanity check would be advised.

One important requirement is the default gateway or route. Here we will assign a default route to network 10.0.0.1 which is the management network. also we need to add a route for network 10.1.0.0. using the following commands. Normally the routing function will dynamically assign the route for 10.1.0.0 so assigning a static one will ensure that no undesired discovered gateways are found and used which may cause poor performance.

root@uss1:~# route -p add default 10.0.0.254
root@uss1:~# route -p add 10.1.0.0 10.1.0.1


When using NFS I prefer provisioning name resolution as a additional layer of access control. If we use names to define NFS shares and clients we can externally validate the incoming IP  with a static file or DNS based name lookup. An OpenSolaris NFS implementation inherently grants this methodology.  When a client IP requests access to an NFS share we can define a forward lookup to ensure the IP maps to a name which is granted access to the targeted share. We can simply define the desired FQDNs against the NFS shares.

In small configurations static files are acceptable as is in the case here. For large host farms the use of a DNS service instance would ease the admin cycle. You would just have to be careful that your cached TimeToLive (TTL) value is greater that 2 hours thus preventing excessive name resolution traffic. The TTL value will control how long the name is cached and this prevents constant external DNS lookups.

To configure name resolution for both file and DNS we simply copy the predefined config file named nsswitch.dns to the active config file nsswitch.conf as follows:

root@uss1:~# cp /etc/nsswitch.dns /etc/nsswitch.conf

Enabling DNS will require the configuration of our /etc/resolv.conf file which defines our name servers and namespace.

e.g.

root@ss1:~# cat /etc/resolv.conf
domain laspina.ca
nameserver 10.1.0.200
nameserver 10.1.0.201

You can also use the static /etc/hosts file to define any resolvable name to IP mapping, which is my preferred method but since were are using ESXi I will use DNS to ease the administration cycle and avoid the unsupported console hack of ESXi.

It is now necessary to define a zpool using our VT-d enabled PCI DDRdrive X1 and VMDK. The VMDK can be located on any suitable VT-d compatible adapter. There is a good change that some HBA devices will not work with VT-d correctly with your system BIOS. As a tip I suggest you use a USB disk to provision the ESXi installation as it almost always works and is easy to backup and transfer to other hardware. In this POC I used a 500GB SATA disk attached over an ICH10 AHCI interface. Obviously there are other better performing disk subsystems available, however this is a POC and not for production consumption.

To establish the zpool we need to ID the PCI to CxTxDx device mappings, there are two ways that I am aware to find these names. You can ream the output of the prtconf -v command and look for disk instances and dev_links or do it the easy way and use the format command like the following.

root@uss1:~# format
Searching for disks…done

AVAILABLE DISK SELECTIONS:
0. c8t0d0 <DEFAULT cyl 4093 alt 2 hd 128 sec 32>
/pci@0,0/pci15ad,1976@10/sd@0,0
1. c8t1d0 <VMware-Virtual disk-1.0-256.00GB>
/pci@0,0/pci15ad,1976@10/sd@1,0
2. c11t0d0 <DDRDRIVE-X1-0030-3.87GB>
/pci@0,0/pci15ad,7a0@15/pci19e3,8@0/sd@0,0
Specify disk (enter its number): ^C
root@uss1:~#

With the device link info handy we can define the zpool with the DDRdrive X1 as a ZIL using the following command:

root@uss1:~# zpool create sp1 c8t1d0 log c11t0d0

root@uss1:~# zpool status
pool: rpool
state: ONLINE
scrub: none requested

config:
NAME        STATE     READ WRITE CKSUM
rpool       ONLINE       0     0     0
c8t0d0s0    ONLINE       0     0     0

errors: No known data errors

pool: sp1
state: ONLINE
scrub: none requested

config:
NAME        STATE     READ WRITE CKSUM
sp1         ONLINE       0     0     0
c8t1d0      ONLINE       0     0     0
logs
c11t0d0     ONLINE       0     0     0
errors: No known data errors

With a functional IP interface and ZFS pool complete you can define the NFS share and ZFS file system. Always define  NFS properties using ZFS set sharenfs=, the share parameters will store as part of the ZFS file system which is ideal for a system failure recovery or ZFS relocation.

zfs create -p sp1/nas/vol0
zfs set mountpoint=/export/uss1-nas-vol0 sp1/nas/vol0
zfs set sharenfs=rw,nosuid,root=vh3-nas:vh2-nas:vh1-nas:vh0-nas sp1/nas/vol0

To connect a VMware ESXi host to this  NFS store(s) we need to define a vmkernel network interface which I like to name eSAN-Interface1. This interface should only connect to the storage network vSwitch. The management network and VM network  should be on another separate vSwitch.

vmkernel eSAN-Interface1

Since we are encapsulating the storage VM on the same server we also need to connect the VM to the storage interface over a VM network port group as show above.  At this point we have all the base NFS services ready, we can now connect our ESXi host to the newly defined NAS storage target.

Add NFS Store

Thus we now have an Encapsulated NFS storage VM provisioning an NFS share to it’s parent hypervisor.

Encapsulated NFS Share





You may have noticed that the capacity of this share is ~390GB however we only granted  a 256GB vmdk to this storage VM. The capacity anomaly is the result of ZFS deduplication on the shared file system. There are 10 16GB Windows XP hosts and 2 32GB Linux host located on this file system which would normally require 224GB of storage.  Obviously dedup is a serious benefit in this case however you need to be aware of the costs, in order to sustain performance levels similar to non-deduped storage you MUST grant the ZFS code sufficient memory to hold the block hash table in memory. If this is memory not provisioned in sufficient amounts, your storage VM will be relegated to a what appears to be a permanent storage bottle neck, in other words you will enter a “processing time vortex”. (Thus as I have cautioned in the past ZFS dedup is maturing and needs some code changes before trusting it to mission critical loads, always test, test, test and repeat until you’re head spins)

Here’ s the result of using dedup within the encapsulated storage VM.

root@uss1:~# zpool list
NAME    SIZE  ALLOC   FREE    CAP  DEDUP  HEALTH  ALTROOT
rpool  7.94G  3.64G  4.30G    45%  1.00x  ONLINE  -
sp1     254G  24.9G   229G     9%  6.97x  ONLINE  -

And here’s a look at what’s it’s serving.

Encapsulated VM


Incredibly the IO performance is simply jaw dropping fast, here we are observing a grueling 100% random read load at 512 bytes per request. Yes that’s correct we are reaching 40,420 IOs per second.

Sample IOMeter IOPS

Even more incredible is the IO performance with a 100% random write load at 512 bytes per request. it’s simply unbelievable seeing 38491 IOs per second inside a VM which is served from a peer VM all on the same hypervisor.

Sample IOMeter IOPS 100% Random 512 Byte Writes

With a successfully configured and operational  NFS share provisioned the next logical task is to define and automate the replication of this share and any others shares we may we to add to a neighboring encapsulated storage VM or for that matter any OpenSolaris host.

The basic elements to this functionality as follows:

  • Define a dedicated secured user to execute the replication functions.
  • Grant the appropriate permissions to this user to access a cron and ZFS.
  • Assign an RSA Key pair for automated ssh authentication.
  • Define a snapshot replication script using ZFS send/receive calls.
  • Define a cron job to regularly invoke the script.

Let define the dedicated replication user. In this example I will use the name zfsadm.

First we need to create the zfsadm user on all of our storage VMs.

root@uss1:~# useradd -s /bin/bash -d /export/home/zfsadm -P ‘ZFS File System Management’ zfsadm
root@uss1:~# mkdir /export/home/zfsadm
root@uss1:~# cp /etc/skel/* /export/home/zfsadm
root@uss1:~# echo PATH=/bin:/sbin:/usr/ucb:/etc:. > /export/home/zfsadm/.profile
root@uss1:~# echo export PATH >> /export/home/zfsadm/.profile
root@uss1:~# echo PS1=$’${LOGNAME}@$(/usr/bin/hostname)’~#’ ‘ >> /export/home/zfsadm/.profile

root@uss1:~# chown –R zfsadm /export/home/zfsadm
root@uss1:~# passwd zfsadm

In order to use an RSA key for authentication we must first generate an RSA private/public key pair on the storage head. This is performed using ssh-keygen while logged in as the zfsadm user. You must set the passphrase as blank otherwise the session will prompt for it.

root@uss1:~# su – zfsadm

zfsadm@uss1~#ssh-keygen -t rsa
Generating public/private rsa key pair.
Enter file in which to save the key (/export/home/zfsadm/.ssh/id_rsa):
Created directory ‘/export/home/zfsadm/.ssh’.
Enter passphrase (empty for no passphrase):
Enter same passphrase again:
Your identification has been saved in /export/home/zfsadm/.ssh/id_rsa.
Your public key has been saved in /export/home/zfsadm/.ssh/id_rsa.pub.
The key fingerprint is:
0c:82:88:fa:46:c7:a2:6c:e2:28:5e:13:0f:a2:38:7f zfsadm@uss1
zfsadm@uss1~#

The id_rsa file should not be exposed outside of this directory as it contains the private key of the pair, only the public key file id_rsa.pub needs to be exported. Now that our key pair is generated we need to append the public portion of the key pair to a file named authorized_keys2.

# cat $HOME/.ssh/id_rsa.pub >> $HOME/.ssh/authorized_keys2

Repeat all the crypto key steps on the target VM as well.

We will use the Secure Copy command to place the public key file on the target hosts zfsadm users home directory. It’s very important that the private key is secured properly and it is not necessary to back it up as you can regenerate them if required.

From the local server here named uss1 (The remote server is uss2)

zfsadm@uss1~# scp $HOME/.ssh/id_rsa.pub uss2:$HOME/.ssh/uss1.pub
Password:
id_rsa.pub      100% |**********************************************|   603       00:00
zfsadm@uss1~# scp uss2:$HOME/.ssh/id_rsa.pub $HOME/.ssh/uss2.pub
Password:
id_rsa.pub      100% |**********************************************|   603       00:00
zfsadm@uss1~# cat $HOME/.ssh/uss2.pub >> $HOME/.ssh/authorized_keys2

And on the remote server uss2

# ssh uss2
password:
zfsadm@uss2~# cat $HOME/.ssh/uss1.pub >> $HOME/.ssh/authorized_keys2
# exit

Now that we are able to authenticate without a password prompt we need to define the automated replication launch using cron. Rather that using the /etc/cron.allow file to grant permissions to the zfsadm user we are going to use a finer instrument and grant the user access at the user properties level shown here. Keep in mind you can not use both ways simultaneously.

root@uss1~# usermod -A solaris.jobs.user zfsadm
root@uss1~# crontab –e zfsadm
59 23 * * * ./zfs-daily-rpl.sh zfs-daily.rpl

Hint: crontab uses vi – http://www.kcomputing.com/kcvi.pdf  “vi cheat sheet”

The key sequence would be hit “i” and key in the line then hit “esc :wq” and to abort “esc :q!”

Be aware of the timezone the cron service runs under, you should check it and adjust it if required. Here is a example of whats required to set it.

root@uss1~# pargs -e `pgrep -f /usr/sbin/cron`

8550:   /usr/sbin/cron
envp[0]: LOGNAME=root
envp[1]: _=/usr/sbin/cron
envp[2]: LANG=en_US.UTF-8
envp[3]: PATH=/usr/sbin:/usr/bin
envp[4]: PWD=/root
envp[5]: SMF_FMRI=svc:/system/cron:default
envp[6]: SMF_METHOD=start
envp[7]: SMF_RESTARTER=svc:/system/svc/restarter:default
envp[8]: SMF_ZONENAME=global
envp[9]: TZ=PST8PDT

Let’s change it to CST6CDT

root@uss1~# svccfg -s system/cron:default setenv TZ CST6DST

Also the default environment path for cron may cause some script “command not found” issues, check for a path and adjust it if required.

root@uss1~# cat /etc/default/cron
#
# Copyright 1991 Sun Microsystems, Inc.  All rights reserved.
# Use is subject to license terms.
#
#pragma ident   “%Z%%M% %I%     %E% SMI”
CRONLOG=YES

This one has no default path, add the path using echo.

root@uss1~# echo PATH=/usr/bin:/usr/sbin:/usr/ucb:/etc:. > /etc/default/cron
# svcadm refresh cron
# svcadm restart cron

The final part of the replication process is a script that will handle the ZFS send/recv invocations. I have written a script in the past that can serve this task with some very minor changes.   

Here is the link for the modified zfs-daily-rpl.sh replication script you will need to grant exec rights to this file e.g.

# chmod 755 zfs-daily-rpl.sh

This script will require that a zpool named sp2 exists on the target system, this is shamefully hard coded in the script.

A file containing the file system to replicate and the target are required as well.

e.g.

zfs-daily-rpl.sh filesystems.lst

Where filesystems.lst contains:

sp1/nas/vol0 uss2
sp1/nas/vol1 uss2


With any ZFS replicated file system  that you wish to invoke on a remote host it is important to remember not make changes to the active replication stream. You must take a clone of this replication stream and this will avoid forcing  a complete resend or other replication issues when you wish to test or validate that it’s operating as you expect.

For example:

We take a clone of one of the snapshots and then share it via NFS:

root@uss2~# zfs clone sp2/nas/vol0@31-04-10-23:59 sp2/clones/uss1/nas/vol0
root@uss2~# zfs set mountpoint=/export/uss1-nas-vol0 sp2/clones/uss1/nas/vol0
root@uss2~# zfs set sharenfs=rw,nosuid,root=vh3-nas:vh2-nas:vh1-nas:vh0-nas sp2/clones/uss1/nas/vol0

Well I hope you found this entry interesting.

Regards,

Mike

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Site Contents: © 2010  Mike La Spina

Running ZFS over NFS as a VMware Store


NFS is definitely a very well rounded high performance file storage system and it certainly serves VMware Stores successfully over many storage products. Recently one of my subscribers asked me if there was a reason why my blogs were more centric to iSCSI. Thus the question was probing for a answer to a question many of us ask ourselves. Is NFS superior to block based iSCSI and which one should I choose for VMware. The answer to this question is not which protocol is superior but which protocol serves to provision the features and function you require most effectively. I use both protocols and find they both have desirable capability and functionality and conversely have some negative points as well.

NFS typically is generally more accessible because its a file level protocol and sits higher up on the network stack. This makes it very appealing when working with VMware virtual disks aka vmdk’s simply because they also exist at the same layer. NFS is ubiquitous across NAS vendors and can be provisioned by multiple agnostic implementation endpoints.  An NFS protocol hosts the capability to be virtualized and encapsulated within any Hypevisor instance either clustered or standalone. The network file locking and share semantics of NFS grant it a multitude of configurable elements which can serve a wide range of applications.

In this blog entry we will explore how to implement an NFS share for VMware ESX using OpenSolaris and ZFS. We will also explore a new way of accelerating the servers I/O performance with a new product called the DDRdrive X1.

OpenSolaris is an excellent choice for provisioning NFS storage volumes on VMware.  It hosts many advanced desirable storage features that set it far ahead of other Unix flavors. We can use the advanced networking features and ZFS including the newly integrated dedup functionality to craft the best NFS functionality available today.

Let start by examining the overall NAS storage architecture.


NFS OpenSolaris/VMware Architecture by Mike La Spina



In this architecture we are defining a fault tolerant configuration using two physical 1Gbe switches with a quad or dual Ethernet adapter(s). On the OpenSolaris storage head we are using IPMP aka IP Multipathing to establish a single IP address to serve our NFS store endpoint. A single IP is more appropriate for VMware environments as they do not support multiple NFS IP targets per NFS mount point.  IPMP provisions layer 3 load balancing and interface fault tolerance. IPMP commonly uses ICMP and default routes to determine interface failure states thus it well suited for a NAS protocol service layer. In a effort to reduce excessive ICMP rates we will aggregate the two dual interfaces into a single channel connection to each switch. This will allow us to define two test IP addresses for the IPMP service and keep our logical interface count down to a minimum. We are also defining a 2 port trunk/aggregate between the two physical switches which provides more path availability and reduces  switch failure detection times.

On the ESX host side we are defining 1 interface per switch. This type of configuration requires that only one of the VMware interfaces is an active team member vmnic within a single vSwitch definition. If this is not configured this way the ESX host will fail to detect and activate the second nic under some failure modes. This is not a bandwidth constraint issue since the vmkernel IP interface will only activity use one nic.

With an architecture set in place let now explore some of the pros and cons of running VMware on Opensolaris NFS.

Some of the obvious pros are:

  • VMware uses NFS in a thin provisioned format.
  • VMDKs are stored as files and are mountable over a variety of hosts.
  • Simple backup and recovery.
  • Simple cloning and migration.
  • Scalable storage volumes.

And some of the less obvious pros:

  • IP based transports can be virtualized and encapsulated for disaster recovery.
  • No vendor lock-in
  • ZFS retains NFS share properties within the ZFS filesystem.
  • ZFS will dedup VMDKs files at the block level.

And there are the cons:

  • Every write I/O from VMware is an O_SYNC write.
  • Firewall setups are complex.
  • Limited in its application. Only NFS clients can consume NFS file systems.
  • General  protocol security challenges. (RPC)
  • VMware kernel constraints
  • High CPU overhead.
  • Bursty data flow.

Before we break out into the configuration detail level lets examine some of the VMware and NFS behaviors so as to gain some insight into the reason I primarily use iSCSI for most VMware implementations.

I would like demonstrate some characteristics that are primarily a VMware client side behavior and it’s important that you are aware of them when your considering NFS as a Datastore.

This VMware performance chart of an IOMeter generated load reveals the burst nature of the NFS protocol. The VMware NFS client exclusively uses a O_SYNC flag on write operations which requires a committed response for the NFS server. At some point the storage system will not be able to complete every request and thus a pause in transmission will occur. The same occurs on reads when the network component buffers reach saturation. In this example chart we are observing a single 1Gbe interface at saturation from a read stream.


NFS VMware Network I/O Behavior by Mike La Spina


In this output we are observing a read stream across vh0 which is one of two active ESX4 host VMs loading our OpenSolaris NFS store and we can see the maximum network throughput is achieved which is ~81MB/s. If you examine the average value of 78MB/s you can see the burst events do not have significant impact and is not a bandwidth concern with ~3MB/s of loss.


NFS VMware Network Read I/O Limit Behavior by Mike La Spina


At the same time we are recording this write stream chart on vh3 a second ESX 4 host loading the same NFS OpenSolaris store.  As I would expect, its very similar to the read stream except that we can see the write performance is lower and that’s to be expected with any write operations. We can also identify that we are using a full duplex path transmission across to our OpenSolaris NFS host since vh0 is reading (recieving) and vh3 is writing(transmitting).


NFS VMware Network Write I/O Limit Behavior by Mike La Spina


In this chart we are observing a limiting characteristic of the VMware vmkernel NFS client process. We have introduced a read stream in combination with a preexisting active write stream on a single ESX host. As you can see the transmit and receive packet rates are both reduced and now sum to a maximum of ~75MB/s.



NFS VMware Network Mixed Read Write I/O Limit Behavior by Mike La Spina


Transitioning from read to write active streams confirms the transmission is limited to ~75Mb/s regardless the full duplex interface capability.  This information demonstrates that a host using 1Gbe ethernet connections will be constrained based on its available resources. This is a important element to consider when using NFS as a VMware datastore.


NFS VMware Network Mixed Read Write I/O Flip Limit Behavior by Mike La Spina


Another important element to consider is the CPU load impact of running the vmkernel NFS client. There is a significant CPU cycle cost on VMware hosts and this is very apparent under heavier loads. The following screen shot depicts a running IOmeter load test against our OpenSolaris NFS store. The important elements are as follows. IOMeter is performing 32KB reads in a 100% sequential access mode which drives a CPU load on the VM of ~35% however this is not the only CPU activity that occurs for this VM.


NFS IOMeter ZFS Throughput 32KB-Seq


When we examine the ESX host resource summary for the running VM we can now observe the resulting overhead load which is realized by viewing the Consumed Host CPU value. The VM in this case is granted 2 CPUs each are a 3.2Ghz Intel hypervisor resource. We can see that the ESX host is running at 6.6Ghz to drive the vmkernel NFS I/O load.


NFS VMware ESX 4 CPU Load


Lets see the performance chart results when we svMotion the activily loaded running VM on the same ESX host to an iSCSI VMFS based store on the same OpenSolaris storage host. The only elements changing in this test are the underlying storage protocols. Here we can clearly see CPU object 0 is the ESX host CPU load. During the svMotion activity we begin to see some I/O drop off due to the addition background disk load. Finally we observe the VM transition at the idle point and the resultant CPU load of iSCSI I/O impact. We clearly see the ESX host CPU load drop from 6.6Ghz to 3.5Ghz which makes it very apparent the NFS requires substantially higher CPU that iSCSI.


VM Trasitioned with vMotion from NFS to iSCSI on same ZFS Storage host


With the svMotion completed we now observe the same IOMeter screen shot retake and its very obvious that our throughput and IOPS have increased significantly and the VM granted CPU load has not changed significantly.   A decrease of ESX host CPU load in the order of  ~55% and and increase of ~32% in IOPS and 45% of throughput shows us there are some negative behaviors to be cognizant of. Keep in mind that this is not that case when the I/O type is small and random like that of a Database in those cases  NFS is normally the winner, however VMware normally hosts mixed loads and thus we need to consider this negative effect at design time and when targeting VM I/O characteristics.


iSCSI IOMeter ZFS X1DDR Cache Throughput 32KB-Seq Mike La Spina

iSCSI ESX 4 CPU Load by Mike La Spina


With a clear understanding of some important negative aspects to implementing NFS for VMware ESX hosts we can proceed to the storage system build detail. The first order of business is the hardware configuration detail. This build is simply one of my generic white boxes and it hosts the following hardware:


GA-EP45-DS3L Mobo with an Intel 3.2Ghz E8500 Core Duo

1 x 70GB OS Disk

2 x 500GB SATA II ST3500320AS disks

2GB of Ram

1 x Intel Pro 1000 PT Quad Network Adapter


As a very special treat on this configuration I am also privileged to run an DDRDrive X1 Cache Accelerator which I am currently testing some newly developed beta drivers for OpenSoalris. Normally I would use 4GB of ram as a minimum but I needed to constraint this build in a effort to load down the dedicated X1 LOG drive and the physical SATA disks thus this instance is running only 2GB of ram. In this blog entry I will not be detailing the OpenSolaris install process, we will begin from a Live CD installed OS.

OpenSolaris will default to a dynamic network service configuration named nwam, this needs to be disabled and the physical:default service enabled.

root@uss1:~# svcadm disable svc:/network/physical:nwam
root@uss1:~# svcadm enable svc:/network/physical:default

To establish an aggregation we need to un-configure any interfaces that we previously configured before proceeding.

root@uss1:~# ifconfig -a
lo0: flags=2001000849<UP,LOOPBACK,RUNNING,MULTICAST,IPv4,VIRTUAL> mtu 8232 index 1
inet 127.0.0.1 netmask ff000000
e1000g0: flags=1000843<UP,BROADCAST,RUNNING,MULTICAST,IPv4> mtu 1500 index 2
inet 10.1.0.1 netmask ffff0000 broadcast 10.255.255.255
ether 0:50:56:bf:11:c3
lo0: flags=2002000849<UP,LOOPBACK,RUNNING,MULTICAST,IPv6,VIRTUAL> mtu 8252 index 1
inet6 ::1/128

root@uss1:~# ifconfig e1000g0 unplumb

Once cleared the assignment of the physical devices is possible using the following commands

dladm create-aggr –d e1000g0 –d e1000g1 –P L2,L3 1
dladm create-aggr –d e1000g2 –d e1000g3 –P L2,L3 2

Here we have set the policy allowing layer 2 and 3 and defined two aggregates aggr1 and aggr2. We can now define the VLAN based interface shown here as VLAN 500 instances 1 are 2 respective of the aggr instances. You just need to apply the following formula for defining the VLAN interface.

(Adaptor Name) + vlan * 1000 + (Adaptor Instance)

ifconfig aggr500001 plumb up 10.1.0.1 netmask 255.0.0.0
ifconfig aggr500002 plumb up 10.1.0.2 netmask 255.0.0.0

Each pair of interfaces needs to be attached to a trunk definition on its switch path. Typically this will be a Cisco or HP switch in most environments. Here is a sample of how to configure each brand.

Cisco:

configure terminal
interface port-channel 1
interface ethernet 1/1
channel-group 1
interface ethernet 1/2
channel-group 1
interface ethernet po1
switchport mode trunk allowed vlan 500
exit

HP Procurve:

trunk 1-2 trk1 trunk
vlan 500
name “eSAN1″
tagged trk1

 

Once we have our two physical aggregates setup we can define the IP multipathing interface components.  As a best practice we should define the IP addresses in our hosts file and then refer to those names in the remaining configuration tasks.

Edit /etc/hosts to have the following host entries.

::1 localhost
127.0.0.1 uss1.local localhost loghost
10.0.0.1 uss1 uss1.domain.name
10.1.0.1 uss1.esan.data1
10.1.0.2 uss1.esan.ipmpt1
10.1.0.3 uss1.esan.ipmpt2

Here we have named the IPMP data interface aka a public IP as uss1.esan-data1 this ip will be the active connection for our VMware storage consumers.  The other two named uss1.esan-ipmpt1 and uss1.esan-ipmpt2 are beacon probe  IP test addresses and will not be available to external connections.

IPMP functionallity is included with OpenSolaris and is configured with the ifconfig utility. The follow sets up the first aggregate with a real public IP and a test address. The deprecated keyword defines the IP as a test address and the failover keyword defines if the IP can be moved in the event of interface failure.

ifconfig aggr500001 plumb uss1.esan.ipmpt1 netmask + broadcast + group ipmpg1 deprecated -failover up addif uss1.esan.data1 netmask + broadcast + failover up
ifconfig aggr500002 plumb uss1.esan.ipmpt2 netmask + broadcast + group ipmpg1 deprecated -failover up

To persist the IPMP network configuration on boot you will need to create hostname files matching the interface names with the IPMP configuration statement store in them. The following will address it.

echo uss1.esan.ipmpt1 netmask + broadcast + group ipmpg1 deprecated -failover up addif uss1.esan.data1 netmask + broadcast + failover up > /etc/hostname.aggr500001

echo uss1.esan.ipmpt1 netmask + broadcast + group ipmpg1 deprecated -failover up > /etc/hostname.aggr500002

The resulting interfaces will look like the following:

root@uss1:~# ifconfig -a
lo0: flags=2001000849<UP,LOOPBACK,RUNNING,MULTICAST,IPv4,VIRTUAL> mtu 8232 index 1
inet 127.0.0.1 netmask ff000000
aggr1: flags=9040843<UP,BROADCAST,RUNNING,MULTICAST,DEPRECATED,IPv4,NOFAILOVER> mtu 1500 index 2
inet 10.1.0.2 netmask ff000000 broadcast 10.255.255.255
groupname ipmpg1
ether 0:50:56:bf:11:c3
aggr2: flags=9040843<UP,BROADCAST,RUNNING,MULTICAST,DEPRECATED,IPv4,NOFAILOVER> mtu 1500 index 3
inet 10.1.0.3 netmask ff000000 broadcast 10.255.255.255
groupname ipmpg1
ether 0:50:56:bf:6e:2f
ipmp0: flags=8001000843<UP,BROADCAST,RUNNING,MULTICAST,IPv4,IPMP> mtu 1500 index 5
inet 10.1.0.1 netmask ff000000 broadcast 10.255.255.255
groupname ipmpg1
lo0: flags=2002000849<UP,LOOPBACK,RUNNING,MULTICAST,IPv6,VIRTUAL> mtu 8252 index 1
inet6 ::1/128

In order for IPMP to detect failures in this configuration you will need to define target probe addresses for IPMP use. For example I use multiple ESX hosts as probe target on the storage network.

e.g.

root@uss1:~# route add -host 10.1.2.1 10.1.2.1 -static
root@uss1:~# route add -host 10.1.2.2 10.1.2.2 -static

This network configuration yields 2,2Gbe aggregate paths bound to a single logical active IP address on 10.1.0.1, with  interfaces aggr1 and aggr2 the keyword deprecated directs the IPMP mpathd service daemon to prevent application session connection packets establishment and the nofailover keyword instructs mpathd not to allow the bound IP to failover to any other interface in the IPMP group.

There are many other possible configurations but I prefer this method because it remains logically easy to diagnose and does not introduce unnecessary complexity.

Now that we have layer 3 network connectivity we should establish the other essential OpenSolaris static TCP/IP configuration elements. We need to ensure we have a persistent default gateway and our DNS client resolution enabled.

The persistent default gateway is very simple to define as is done with the route utility command as follows.

root@uss1:~# route -p add default 10.1.0.254
add persistent net default: gateway

When using NFS I prefer provisioning name resolution as a additional layer of access control. If we use names to define NFS shares and clients we can externally validate the incoming IP  with a static file or DNS based name lookup. An OpenSolaris NFS implementation inherently grants this methodology.  When a client IP requests access to an NFS share we can define a forward lookup to ensure the IP maps to a name which is granted access to the targeted share. We can simply define the desired FQDNs against the NFS shares.

In small configurations static files are acceptable as is in the case here. For large host farms the use of a DNS service instance would ease the admin cycle. You would just have to be careful that your cached TimeToLive (TTL) value is greater that 2 hours thus preventing excessive name resolution traffic. The TTL value will control how long the name is cached and this prevents constant external DNS lookups.

To configure name resolution for both file and DNS we simply copy the predefined config file named nsswitch.dns to the active config file nsswitch.conf as follows:

root@uss1:~# cp /etc/nsswitch.dns /etc/nsswitch.conf

Enabling DNS will require the configuration of our /etc/resolv.conf file which defines our name servers and namespace.

e.g.

root@ss1:~# cat /etc/resolv.conf
domain laspina.ca
nameserver 10.1.0.200
nameserver 10.1.0.201

You can also use the static /etc/hosts file to define any resolvable name to IP mapping.

With OpenSolaris you should always define your NFS share properties using the ZFS administrative tools. When this method is used we can the take advantage of keeping the NFS share properties inside of ZFS. This is really useful when you replicate or clone the ZFS file system to an alternate host as all the share properties will be retained. Here are the basic elements of an NFS share configuration for use on VMware storage consumers.

zfs create -p sp1/nas/vol1
zfs set mountpoint=/export/uss1-nas-vol1 sp1/nas/vol1
zfs set sharenfs=rw,nosuid,root=vh3-nas:vh2-nas:vh1-nas:vh0-nas sp1/nas/vol1

The ACL NFS share property of rw sets the entire share as read write, you could alternately use rw=hostname for each host but it seems redundant to me.  The nosuid prevents any incoming connection from switching user ids for example from a non-root value to 0. Finally the root=hostname property grants the incoming host name access to the share with root access permissions.  Any files created by the host will be as the root id. While these steps are some level of access control it falls well short of secure thus I also keep the NAS subnets fully isolated or firewalled to prevent external network access to the NFS share hosts.

Once our NFS share is up and running we can proceed to configure the VMware network components and share connection properties. VMware requires a vmkernel network interface definition to provision NFS connectivity. You should dedicate a vmnic team and a vswitch for your storage network.

Here is a visual  example of a vmkernel configuration with a teamed pair of vmnics

vmkernel eNAS-Interface by Mike La Spina

As you can see we have dedicated the vSwitch and vmnics on VLAN 500, no other traffic should be permitted on this network. You should also set the default vmkernel gateway to its own address. This will promote better performance as there is no need to leave this network.

For eNAS-Interface1 you should define one active and one standby vmnic. This will ensure proper interface fail-over in all failure modes.  The VMware NFS kernel instance will only use a single vmnic so your not loosing any bandwidth. The vmnic team only serves as a fault tolerant connection and is not a load balanced configuration.

VMkernel Team Stanby by Mike La Spina


At this point you should validate your network connectivity by pinging the vmkernel IP address from the OpenSolaris host. If you chose to ping from ESX use vmkping instead of ping otherwise you will not get a response.

Provided your network connectivity is good you can define your vmkernel NFS share properties. Here is a visual example.

Add an NFS share by Mike La Spina

And if you prefer an ESX command line method:

esxcfg-nas -a -o uss1-nas -s /export/uss1-nas-vol1 uss1-nas-vol1

In this example we are using a DNS based name of uss1-nas. This would allow you to change the host IP without having to reconfigure VMware hosts. You will want to make sure the DNS name cache TTL in not a small value for two reasons. One an DNS outage would impact the IP resolution and as well you do not want excessive resolution traffic on the eSAN subnet(s).

The NFS share configuration info is maintained in the /etc/vmware/esx.conf file and looks like the following example.

/nas/uss1-nas-vol1/enabled = “true”
/nas/uss1-nas-vol1/host = “uss1-nas”
/nas/uss1-nas-vol1/readOnly = “false”
/nas/uss1-nas-vol1/share = “/export/uss1-nas-vol1″

If your trying to change NFS share parameters and the NFS share is not available after a successful configuration you could run into a messed up vmkernel NFS state and you’ll receive the following message:

Unable to get Console path for Mount

You will need to reboot the ESX server to clean it up so don’t mess with anything else until that is performed. (I’ve wasted a few hours on that buggy VMware kernel NFS client behavior).

Once the preceeding steps are successful the result will be a NAS based NFS share which is now available like this example.

Running NFS shares by Mike La Spina

With a working NFS storage system we can now look at optimizing the I/O capability of ZFS and NFS.

VMware performs write operations over NFS using an O_SYNC control flag. This will force the storage system to commit all write operations to disk to ensure VM file integrity. This can be very expensive when it comes to high performance IOPS especially when using SATA architecture. We could disable our ZIL aka ZFS Intent Log but this could result in severe corruption in the event of a systems fault or environmental issue. A much better alternative is to use a non-volatile ZIL device. In this case we have an DDRdrive X1 which is a 4GB high speed externally powered dram bank with a high speed SCSI interface and also hosts 4GB of flash for long term shutdowns.  The DDRdrive X1 IO capability reaches the 200,000/sec range and up. By using an external UPS power source we can economically prevent ZFS corruption and reap the high speed benefits of dram even when unexpected system interruptions occur.

In this blog our storage host is using Seagate ST3500320AS disk which are challenged to achieve ~180 IOPS. And that IO rate is under ideal sequential read write loads. With a cache we can expect that these disks will deliver no greater than 360 IOPS under ideal conditions.

Now lets see if this is true based on some load tests using Microsoft’s SQLIO tool. First we will disable our ZFS ZIL caching DDRdrive X1 show here as device c9t0d0

NAME        STATE     READ WRITE CKSUM
sp1         DEGRADED     0     0     0
mirror-0  ONLINE       0     0     0
c6t1d0  ONLINE       0     0     0
c6t2d0  ONLINE       0     0     0
logs
c9t0d0  OFFLINE      0     0     0

No lets run the SQLIO test for 5 minutes with random 8K I/O write requests which are simply brutal for any SATA disk to keep up with.  We have defined a file size of 32GB to ensure we hit the disk by exceeding our 2GB cache memory foot print. As you can see from the output we achieve 227 IOs/sec which is below the mirrored drive pair capability.

C:Program FilesSQLIO>sqlio -kW -s300 -frandom -o4 -b8 -LS -Fparam.txt
sqlio v1.5.SG
using system counter for latency timings, 3579545 counts per second
parameter file used: param.txt
file c:testfile.dat with 2 threads (0-1) using mask 0×0 (0)
2 threads writing for 300 secs to file c:testfile.dat
using 8KB random IOs
enabling multiple I/Os per thread with 4 outstanding
using specified size: 32768MB for file: c:testfile.dat
initialization done
CUMULATIVE DATA:
throughput metrics:
IOs/sec:   227.76
MBs/sec:     1.77

latency metrics:
Min_Latency(ms): 8
Avg_Latency(ms): 34
Max_Latency(ms): 1753
histogram:
ms: 0  1  2  3  4  5  6  7  8  9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24+
%:  0  0  0  0  0  0  0  0  0  0  0  0  0  0  0  1  1 29  7  3  2  1  1  1 54

new  name   name  attr  attr lookup rddir  read read  write write
file remov  chng   get   set    ops   ops   ops bytes   ops bytes
0     0     0   300     0      0     0     3   16K   146 1.12M /export/uss1-nas-vol1
0     0     0   617     0      0     0     0     0   309 2.39M /export/uss1-nas-vol1
0     0     0   660     0      0     0     0     0   329 2.52M /export/uss1-nas-vol1
0     0     0   677     0      0     0     0     0   338 2.63M /export/uss1-nas-vol1
0     0     0   638     0      0     0     0     0   321 2.46M /export/uss1-nas-vol1
0     0     0   496     0      0     0     0     0   246 1.88M /export/uss1-nas-vol1
0     0     0    44     0      0     0     0     0    21  168K /export/uss1-nas-vol1
0     0     0   344     0      0     0     0     0   172 1.32M /export/uss1-nas-vol1
0     0     0   646     0      0     0     0     0   323 2.51M /export/uss1-nas-vol1
0     0     0   570     0      0     0     0     0   285 2.20M /export/uss1-nas-vol1
0     0     0   695     0      0     0     0     0   350 2.72M /export/uss1-nas-vol1
0     0     0   624     0      0     0     0     0   309 2.38M /export/uss1-nas-vol1
0     0     0   562     0      0     0     0     0   282 2.15M /export/uss1-nas-vol1


Now lets enable the DDRdrive X1 ZIL cache and see where that takes us.

NAME        STATE     READ WRITE CKSUM
sp1         ONLINE       0     0     0
mirror-0  ONLINE       0     0     0
c6t1d0  ONLINE       0     0     0
c6t2d0  ONLINE       0     0     0
logs
c9t0d0  ONLINE       0     0     0

Again we run the identical SQLIO test and results are dramatically different, we immediately see a 4X improvement in IOPS but whats much more important is the reduction in latency which will make any database workload fly.

C:Program FilesSQLIO>sqlio -kW -s300 -frandom -o4 -b8 -LS -Fparam.txt
sqlio v1.5.SG
using system counter for latency timings, 3579545 counts per second
parameter file used: param.txt
file c:testfile.dat with 2 threads (0-1) using mask 0×0 (0)
2 threads writing for 300 secs to file c:testfile.dat
using 8KB random IOs
enabling multiple I/Os per thread with 4 outstanding
using specified size: 32768 MB for file: c:testfile.dat
initialization done
CUMULATIVE DATA:
throughput metrics:
IOs/sec:   865.75
MBs/sec:     6.76

latency metrics:
Min_Latency(ms): 0
Avg_Latency(ms): 8
Max_Latency(ms): 535
histogram:
ms: 0  1  2  3  4  5  6  7  8  9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24+
%: 56 13  9  3  1  0  1  1  1  1  1  1  1  1  1  0  0  0  0  0  0  0  0  0  7

new  name   name  attr  attr lookup rddir  read read  write write
file remov  chng   get   set    ops   ops   ops bytes   ops bytes
0     0     0   131     0      0     0     0     0    66  516K /export/uss1-nas-vol1
0     0     0 3.23K     0      0     0     0     0 1.62K 12.8M /export/uss1-nas-vol1
0     0     0    95     0      0     0     2    8K    43  324K /export/uss1-nas-vol1
0     0     0 2.62K     0      0     0     0     0 1.31K 10.3M /export/uss1-nas-vol1
0     0     0   741     0      0     0     0     0   369 2.78M /export/uss1-nas-vol1
0     0     0 1.99K     0      0     0     0     0  1019 7.90M /export/uss1-nas-vol1
0     0     0 1.34K     0      0     0     0     0   687 5.32M /export/uss1-nas-vol1
0     0     0   937     0      0     0     0     0   468 3.62M /export/uss1-nas-vol1
0     0     0 2.60K     0      0     0     0     0 1.30K 10.3M /export/uss1-nas-vol1
0     0     0 2.02K     0      0     0     0     0 1.01K 7.84M /export/uss1-nas-vol1
0     0     0 1.91K     0      0     0     0     0   978 7.58M /export/uss1-nas-vol1
0     0     0 1.94K     0      0     0     0     0   992 7.67M /export/uss1-nas-vol1

DDRdrive X1 Performance Chart by Mike La Spina


NFSStat Chart I/O DB Cache Compare by Mike La Spina


When we look at ZFS ZIL caching devices there are some important elements to consider. For most provisioned VMware storage systems you do not require large volumes of ZIL cache to generate good I/O performance.  What you need to do is carefully determine the active data write footprint size. Remember that ZIL is a write only world and that those writes will be relocated to a slower disk at some point. These relocation functions are processed in batches or as Ben Rockwood likes to say in a regular breathing cycle.  This means that random I/O operations can queued up and converted to a more sequential like behavior characteristic. Random synchronous write operations can be safely acknowledged immediately and then the ZFS DMU can process them more efficiently in the background. This means that if we provision cache devices that are closer to the system bus and have lower latency the back end core compute hardware will be able to move the data ahead of the bursting I/O peak up ramps and thus we deliver higher IOPS with significantly less cache requirements. Devices like the DDRdrive X1 are a good example of implementing this strategy.

I hope you found this blog entry to be interesting and useful.

Regards,

Mike

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Site Contents: © 2010  Mike La Spina

Protecting Active Directory with Snapshot Strategies

Using snapshots to protect Active Directory (AD) without careful planning will most definitely end up in a complete disaster. AD is a loosely consistent distributed multi-master database and it must not be treated as a static system.  Without carefully addressing how AD works with Time Stamps, Version Stamps, Update Sequence Numbers (USNs), Globally Unique Identification numbers (GUIDs), Relative Identification numbers (RIDs),  Security Identifiers (SIDs) and restoration requirements the system could quickly become unusable or severally damaged in the event of an incorrectly invoked snapshot reversion.

There are many negative scenarios that can occur if we were to re-introduce an AD replica to service from a snapshot instance without special handling. In the event of a snapshot based re-introduction the RID functional component is seriously impacted. In any AD system RIDs are created in range blocks and assigned for use to a participating Domain Controller (DC) by the RID master DC AD role. RIDs are used to create SIDs for all AD objects like Group or User objects and they must all be unique. Lets take a closer look at the SID to understand why RIDs are such a critical function.

A SID is composed with the following symbolic format: S-R-IA-SA-RID:

  • S: Indicates the type of value is a  SID.
  • R: Indicates the revision of the SID.
  • IA: Indicates the issuing authority. Most are the NT Authority identity number 5.
  • SA: Indicates the sub-authority aka domain identifier.
  • RID: Indicates the Relative ID.

Now looking at some real SID example values we see that on a DC instance only the RID component of the SID is unique as show here in red text.

DS0User1      = S-1-5-21-3725033245-1308764377-180088833-3212
DS0UserGroup1 = S-1-5-21-3725033245-1308764377-180088833-7611

When an older snapshot image of a DC is reintroduced it’s assigned RID range will likely have RID entries that were already used to generate SIDs. Those SIDs would have replicated to the other DCs in the AD forest. When the reintroduced DC starts up it will try to participate in replication and servicing authentications of accounts. Depending on the age and configuration of its secure channel the DC could be successfully connected. This snapshot reintroduction event should be avoided since any RID usage from the aged DC will very likely result in duplicated SID creations and is obviously very undesirable.

Under normal AD recovery methods we would either need to restore AD or build a new server and perform a DC promo on it and possibly seize DC roles if required . The most important element of an normal AD restore process is the DC GUID reinitialization function. The DC GUID value reinitialization operation  allows the restoration of an AD DC to occur correctly. A  newly generated GUID becomes part of the Domain Identifier and thus the DC can create SIDs that are unique despite the fact that the RID assignment range it holds may be from a previously used one.

When we use a snapshot image of a guest DC VM none of the required Active Directory restore requirements will occur on  system startup and thus we must manually bring the host online in DSRM mode without a network connection and then set the NTDS restore mode up. I see this as a serious security risk as there a is significant probability that the host could be brought online without these steps occurring and potentially create integrity issues.

One mitigation to this identified risk is to perform the required changes before a snapshot is captured and once the capture is complete revert the change back to the non-restore state. This action will completely prevent a snapshot image of a DC from coming online from a past time reference.

In order to achieve this level of server state and snapshot automation we would need to provision a service channel from our storage head to the involved VMs or for that matter any storage consumer. A service channel can provide other functionality beyond the NDTS state change as well. One example is the ability to flush I/O using VSS or sync etc.

We can now look at a practical example of how to implement this strategy on OpenSolaris based storage heads and W2K3 or W2K8 servers.

The first part of the process is to create the service channel on a VM or any other windows host which can support VB or Power Shell etc. In this specific case we need to provision an SSH Server daemon that will allow us to issue commands directed towards the storage consuming guest VM from the providing storage head. There are many possible products available that can provide this service. I personally like MobaSSH which I will use in this example. Since this is a Domain Controller we need to use the Pro version which supports domain based user authentication from our service channel VM.

We need to create a dedicated user that is a member of the domains BUILTINAdministrators group. This poses a security risk and thus you should mitigate it by restricting this account to only the machines it needs to service.

e.g. in AD restrict it to the DCs or possibly any involved VM’s to be managed and the Service Channel system itself.

Restricting user machine logins

A dedicated user allows us to define authentication from the storage head to the service channel VM  using a trusted ssh RSA key that is mapped to the user instance on both the VM and OpenSolaris storage host. This user will launch any execution process that is issued from the OpenSolaris storage head.

In this example I will use the name scu, which is short for Service Channel User.

First we need to create the scu user on our OpenSolaris storage head.

root@ss1:~# useradd -s /bin/bash -d /export/home/scu -P ‘ZFS File System Management’ scu
root@ss1:~# mkdir /export/home/scu
root@ss1:~# cp /etc/skel/* /export/home/scu
root@ss1:~# echo PATH=/bin:/sbin:/usr/ucb:/etc:. > /export/home/scu/.profile
root@ss1:~# echo export PATH >> /export/home/scu/.profile
root@ss1:~# echo PS1=$’${LOGNAME}@$(/usr/bin/hostname)’~#’ ‘ >> /export/home/scu/.profile

root@ss1:~# chown –R scu /export/home/scu
root@ss1:~# passwd scu

In order to use an RSA key for authentication we must first generate an RSA private/public key pair on the storage head. This is performed using ssh-keygen while logged in as the scu user. You must set the passphrase as blank otherwise the session will prompt for it.

root@ss1:~# su – scu

scu@ss1~#ssh-keygen -t rsa
Generating public/private rsa key pair.
Enter file in which to save the key (/export/home/scu/.ssh/id_rsa):
Created directory ‘/export/home/scu/.ssh’.
Enter passphrase (empty for no passphrase):
Enter same passphrase again:
Your identification has been saved in /export/home/scu/.ssh/id_rsa.
Your public key has been saved in /export/home/scu/.ssh/id_rsa.pub.
The key fingerprint is:
0c:82:88:fa:46:c7:a2:6c:e2:28:5e:13:0f:a2:38:7f scu@ss1
scu@ss1~#

We now have the public key available in the file named id_rsa.pub the content of this file must be copied to the target ssh instance file named .ssh/authorized_keys. The private key file named id_rsa MUST NOT be exposed to any other location and should be secured. You do not need to store the private key anywhere else as you can regenerate the pair anytime if required.

Before we can continue we must install and configure the target Service Channel VM with MobaSSH.

Its a simple setup, just download MobaSSH Pro to the target local file system.

Execute it.

Click install.

Configure only the scu domain based user and clear all others from accessing the host.

e.g.















Moba Domain Users















Once MobaSSH is installed and restarted we can connect to it and finalize the secured ssh session. Don’t forget to add the scu user to your AD domains BUILTINAdministrators group before proceeding.  Also you need to perform an initial NT login to the Service Channel Windows VM using the scu user account prior to using the SSH daemon, this is required to create it’s home directories.

In this step we are using  putty to establish an ssh session to the Service Channel VM and then secure shelling to the storage server named ss1. Then we transfer the public key back to our self using scp and exit host ss1. Finally we use cat to append the public key file content to our  .ssh/authorized_key file in the scu users profile. Once these steps are complete we can establish an automated prompt less secured encrypted session from ss1 to the Service Channel Windows NT VM.

[Fri Dec 18 - 19:47:24] ~
[scu.ws0] $ ssh ss1
The authenticity of host ‘ss1 (10.10.0.1)’ can’t be established.
RSA key fingerprint is 5a:64:ea:d4:fd:e5:b6:bf:43:0f:15:eb:66:99:63:6b.
Are you sure you want to continue connecting (yes/no)? yes
Warning: Permanently added ‘ss1,10.10.0.1′ (RSA) to the list of known hosts.
Password:
Last login: Fri Dec 18 19:47:28 2009 from ws0.laspina.ca
Sun Microsystems Inc.   SunOS 5.11      snv_128 November 2008

scu@ss1~#scp .ssh/id_rsa.pub ws0:/home/scu/.ssh/ss1-rsa-scu.pub
scu@ws0′s password:
id_rsa.pub           100% |*****************************|   217       00:00
scu@ss1~#exit

[Fri Dec 18 - 19:48:09]
[scu.ws0] $ cat .ssh/ss1-rsa-scu.pub >> .ssh/authorized_keys

With our automated RSA key password definition completed we can proceed to customize the MobaSSH service instance to run as the scu user. We need to perform this modification in order to enable VB script WMI DCOM impersonate caller rights when instantiating objects. In this case we are calling a remote regedit object over WMI and modifying the NTDS service registry start up values and thus this can only be performed by an administrator account. This modification essentially extends the storage hosts capabilities to reach any Windows host that need integral system management function calls.

On our OpenSolaris Storage head we need to invoke a script which will remotely change the NTDS service state and then locally snapshot the provisioned storage  and lastly return the NTDS service back to a normal state.  To accomplish this function we will define a cron job. The cron job needs some basic configuration steps as follows.

The solaris.jobs.user is required to submit a cron job, this allows us to create the job but not administer the cron service.
If an /etc/cron.d/cron.allow file exists then this RBAC setting will be overridden by the files existence and you will need to add the user to that file or convert to the best practice methods of RBAC.

root@ss1~# usermod -A solaris.jobs.user scu
root@ss1~# crontab –e scu
59 23 * * * ./vol1-snapshot.sh

Hint: crontab uses vi – http://www.kcomputing.com/kcvi.pdf  “vi cheat sheet”

The key sequence would be hit “i” and key in the line then hit “esc :wq” and to abort “esc :q!”

Be aware of the timezone the cron service runs under, you should check it and adjust it if required. Here is a example of whats required to set it.

root@ss1~# pargs -e `pgrep -f /usr/sbin/cron`

8550:   /usr/sbin/cron
envp[0]: LOGNAME=root
envp[1]: _=/usr/sbin/cron
envp[2]: LANG=en_US.UTF-8
envp[3]: PATH=/usr/sbin:/usr/bin
envp[4]: PWD=/root
envp[5]: SMF_FMRI=svc:/system/cron:default
envp[6]: SMF_METHOD=start
envp[7]: SMF_RESTARTER=svc:/system/svc/restarter:default
envp[8]: SMF_ZONENAME=global
envp[9]: TZ=PST8PDT

Let’s change it to CST6CDT

root@ss1~# svccfg -s system/cron:default setenv TZ CST6DST

Also the default environment path for cron may cause some script “command not found” issues, check for a path and adjust it if required.

root@ss1~# cat /etc/default/cron
#
# Copyright 1991 Sun Microsystems, Inc.  All rights reserved.
# Use is subject to license terms.
#
#pragma ident   “%Z%%M% %I%     %E% SMI”
CRONLOG=YES

This one has no default path, add the path using echo.

root@ss1~# echo PATH=/usr/bin:/usr/sbin:/usr/ucb:/etc:. > /etc/default/cron
# svcadm refresh cron
# svcadm restart cron

With a cron job defined to run the script named vol1-snapshot.sh in the default home directory of the scu user we are now ready to create the script content. Our OpenSolaris storage host needs to call a batch file on the remote Service Channel VM and it will execute  a vbscript from there to set the NTDS start up mode . To do this from a unix bash script we will use the following statements in the vol1-snapshot.sh file.

ssh -t ws0 NTDS-PreSnapshot.bat
snap_date=”$(date +%d-%m-%y-%H:%M)”
pfexec zfs snapshot rp1/san/vol1@$snap_date
ssh -t ws0 NTDS-PostSnapshot.bat
exit

Here we are running a secure shell call to the MobaSSH daemon with a -t option which runs the tty screen locally and this allows use to issue an “exit” from the remote calling script closing the secure shell. On the Service Channel VM the followng batch file vbscript calls are executed using the pre and post batch files illustrated as follows.

scu Batch Files

NTDS-PreSnapshot.bat
cscript NTDS-SnapshotRestoreModeOn.vbs DS0
exit

NTDS-PostSnapshot.bat
cscript NTDS-SnapshotRestoreModeOff.vbs DS0
exit

NTDS-SnapshotRestoreModeOn.vbs

strComputer = Wscript.Arguments(0)  
const HKLM=&H80000002
Set oregService=GetObject(“WinMgmts:{impersonationLevel=impersonate}!\” & strComputer & “rootdefault:stdRegProv”)
oregService.SetDWordValue HKLM, “SYSTEMCurrentControlSetServicesntdsparameters”, “Database restored from   backup”, 1
Set oregService=Nothing

NTDS-SnapshotRestoreModeOff.vbs

strComputer = Wscript.Arguments(0)  
const HKLM=&H80000002
Set oregService=GetObject(“WinMgmts:{impersonationLevel=impersonate}!\” & strComputer & “rootdefault:stdRegProv”)
oregService.SetDWordValue HKLM, “SYSTEMCurrentControlSetServicesntdsparameters”, “Database restored from   backup”, 0
Set oregService=Nothing

We now have Windows integrated storage volume snapshot functionality that allows an Active Directory domain controller to be securely protected using a snapshot strategy. In the event we need to fail back to a previous point in time there will be no danger that the snapshot will cause AD corruption. The integration process has other highly desirable capabilities such as the ability to call VSS snapshots and any other application backup preparatory function calls.  We could also branch out using more sophisticated PowerShell calls to VMware hosts in a fully automated recovery strategy using ZFS replication and remote sites.

Hope you enjoyed this entry.

Seasons Greetings to All.

Regards,

Mike



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Site Contents: © 2009  Mike La Spina

SUN Delivers De-duplication on ZFS

Today marks yet another great milestone for OpenSolaris and OpenStorage. SUN has as promised, delivered a much anticipated de-duplication feature for us to explore and use.  I must say that I am very excited about it and with no doubt this is a very cool feature indeed The ideas for how to use it are running around in my head like neurons do and your sure to see some of those ideas surface in a blog or two.

Now before we get too excited we need to keep in mind that this is the first release of this feature to the public space and we are sure to find the odd bump or two along the road while seeing this new very great file system feature mature. I’m sure that we will be more than pleased with the new feature and the many other capabilities that are sure to come.

If your interested in experimenting with the development releases you should be able to get your hands on the feature in about 3-4 weeks through IPS or SXCE. Or if your an advanced kernel type IT pro you could build it using the source code now….right…so then, for the rest of us.

To try it out the easy way when it becomes available just download and install OpenSolaris with the LiveCD (I recommend an x64 CPU with 4G of ram)

http://dlc.sun.com/osol/opensolaris/2009/06/osol-0906-x86.iso

Then set your repository publisher to the dev IPS image server and issue the pkg image-update command

e.g.

$ pfexec pkg set-publisher -O http://pkg.opensolaris.org/dev opensolaris.org

$ pfexec pkg image-update

And explore!


Jeff Bonwick, Bill Moore and company are definitely thinking up some brilliant technical and practical applications of their knowledge bringing us a powerful new storage direction that has changed the game.

Thanks go to the ZFS team.

You rock!

Regards,

Mike

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Site Contents: © 2009  Mike La Spina

Multi Protocol Storage Provisioning with COMSTAR

 COMSTAR is a new breed of open source storage product available to the world. What was traditionally a closed and proprietary storage capability is now available to our open source communities. With OpenSolaris and COMSTAR the ability to freely provision virtual storage services over very mature high end protocols on standard commodity server hardware is now a reality. High performance transports are integral within the feature sets of COMSTAR and Sun’s open source portfolio of projects. The COMSTAR product is revolutionary in its method of provisioning storage virtualization and transport services to storage resource consumers.
COMSTAR provisions virtualized SCSI block storage over multiple SCSI transport protocols. While this function class is not new to us the ease of implementation using COMSTAR certainly is. All the complexities of using a multi protocol target services platform are cleaned up. It is simple to use and facilitates advanced high performance storage provisioning at the block level.
The services within this product have multiple common storage provisioning applications. One very interesting application is a storage gateway server and this blog demonstrates howto build a Fiber Channel (FC) storage gateway using the COMSTAR service layers and as well provision some additional features using the target services.

 

 COMSTAR FC Gateway Architecture by Mike La Spina


In this example instance we are re-provisioning an existing storage system with an OpenSolaris COMSTAR configuration running on a commodity white box which functions as a storage server head that can compress, scrub, thin provision, replicate, snapshot and clone the existing block storage attachments. The example FC based storage could also be comprised of a JBOD FC array directly attached to the OpenSolaris storage head if we so desired or many other commonly available SCSI attachment methods. The objective here is to extend and enhance any block storage system with high performance transports and virtualization features. Of course we could also formalize the white box to an industrial strength host once we are satisfied that the proof of concept is mature and optimal.  

The reality is that many older existing FC storage systems are installed without these features primarily due to the excessive licensing costs of them. And even when these features are available, its use is probably restricted to like proprietary systems thus obsolescing the entire lot of any useful future functionality. But what if you could re-purpose an older storage system to act as a DR store or backup cache system or maybe a test and development environment. With today’s economy this is from a cost perspective, very attractive and can be accomplished with very little risk on the investment side.

One of the possible applications for this flexible storage service is the re-provisioning of existing LUN’s from an existing system to newer more flexible SCSI transport protocols. This is particularly useful when we need to re-target the existing storage system from FC to iSCSI or the likes of. We can begin by exploring this functionality and explain how COMSTAR can provide us with this service.

First we need to understand the high level functionality of the COMSTAR service layers. Virtual LUN’s on COMSTAR are provisioned with a service layer named the LU provider. This layer maps backing stores of various types to a storage GUID assignment and additionally defines other properties like the LUN ID and size dimensions. This layer allows us to carve out the available block storage devices that are accessible on our OpenSolaris storage host. For example if we attached an FC Initiator to an external storage system we can then map the accessible SCSI block devices to the LU provider layer and then present this virtualized LUN to the other COMSTAR service layers for further processing.

Once we have defined the LU’s we can present this storage resource to the SCSI Target Mode Framework Service (STMF) layer which acts as the storage gate keeper. At this layer we define which clients (initiators) can connect to the LU’s based on Membership of Target Groups and Host Groups that are assigned logical views of the LU(s). The STMF layer routes the defined LU(s) as SCSI targets over a multiprotocol interface connection pool to a Port Provider. Port Providers are the protocol connection service instances which can be the likes of FC, iSCSI, SAS, iSER, FCoE and so on. 

With these COMSTAR basics in mind let us begin by diving into some of the details of how this can be applied.  

Sun has detailed howto setup COMSTAR at dlc.sun.com so no need to re-invent the wheel here.

Just as a note SXCE snv_103 and up integrate the COMSTAR FC and iSCSI port provider code. With the COMSTAR software components and FC target setup we can demonstrate the re-provisioning of an existing FC based storage server. Since I don’t have the luxury of having a proprietary storage server at home I will emulate this storage using an additional COMSTAR white box to act as the FC storage target to be re-provisioned.

On the existing FC target system we need to create Raid0 arrays of three disks each which will total up to a set of six trios. We will use these six non-fault tolerant disk groups as vdevs for a ZFS raidz2 group. This will allow us to create fault tolerant arrays from the existing storage server. The reasons for sets of three Raid0 groupings are to reduce the possibility of reaching the LUN maximums of the proprietary storage system and also we do not want to erode the performance by layering Raid 5 groups. As well we can tolerate a disk failure in two of the trios since we have Raidz2 across the Raid0 trio groups. Additionally using these Raid0 disk groups actually lowers the array failure probability rate. For example if a second disk were to failure in a single Raid0 set there would be no additional impact to other trios, thus reducing the overall failure rate. 

To create the emulated FC storage system I have defined the following 16G ZFS sparse volumes respectively named trio1 through trio6 each as a representation of the 3 disk Raid0 spanned LUN on a source storage host named ss1. 

root@ss1:~# zfs create sp1/gw
root@ss1:~# zfs create -s -V 16G sp1/gw/trio1
root@ss1:~# zfs create -s -V 16G sp1/gw/trio2
root@ss1:~# zfs create -s -V 16G sp1/gw/trio3
root@ss1:~# zfs create -s -V 16G sp1/gw/trio4
root@ss1:~# zfs create -s -V 16G sp1/gw/trio5
root@ss1:~# zfs create -s -V 16G sp1/gw/trio6

Once these mockup volumes are created they are then defined as backing stores using the sbdadm utility as follows.

root@ss1:~# sbdadm create-lu /dev/zvol/rdsk/sp1/gw/trio1

Created the following LU:

              GUID                    DATA SIZE           SOURCE
——————————–  ——————-  —————-
600144f01eb3862c0000494b55cd0001      17179803648      /dev/zvol/rdsk/sp1/gw/trio1

All the backing stores were added to the LU provider service layer to which in turn were assigned to the STMF service layer. Here we can see the automatically generated GUID’s that are assigned to the ZFS backing stores.

root@ss1:~# sbdadm list-lu

Found 6 LU(s)

              GUID                    DATA SIZE           SOURCE
——————————–  ——————-  —————-
600144f01eb3862c0000494b56000006      17179803648      /dev/zvol/rdsk/sp1/gw/trio6
600144f01eb3862c0000494b55fd0005      17179803648      /dev/zvol/rdsk/sp1/gw/trio5
600144f01eb3862c0000494b55fa0004      17179803648      /dev/zvol/rdsk/sp1/gw/trio4
600144f01eb3862c0000494b55f80003      17179803648      /dev/zvol/rdsk/sp1/gw/trio3
600144f01eb3862c0000494b55f50002      17179803648      /dev/zvol/rdsk/sp1/gw/trio2
600144f01eb3862c0000494b55cd0001      17179803648      /dev/zvol/rdsk/sp1/gw/trio1

A host group was defined named GW1 and respectively these LU GUID’s were added to the GW1 host group as LU views assigning LUN 0 to 5.

Just as a note the group names are case sensitive. 
root@ss1:~#stmfadm create-hg GW1

Here we assigned the GUID’s a LUN value on the GW1 host group with the -n parm.   

root@ss1:~# stmfadm add-view -h GW1 -n 0 600144F01EB3862C0000494B55CD0001
root@ss1:~# stmfadm add-view -h GW1 -n 1 600144F01EB3862C0000494B55F50002
root@ss1:~# stmfadm add-view -h GW1 -n 2 600144F01EB3862C0000494B55F80003
root@ss1:~# stmfadm add-view -h GW1 -n 3 600144F01EB3862C0000494B55FA0004
root@ss1:~# stmfadm add-view -h GW1 -n 4 600144F01EB3862C0000494B55FD0005
root@ss1:~# stmfadm add-view -h GW1 -n 5 600144F01EB3862C0000494B56000006

With the LU’s now available in a host group view we can add the COMSTAR re-provisioning gateway server FC wwn’s to this host group and it will become available as a storage resource on the re-provisioning gateway server named ss2. We need to obtain the wwn from the gateway server using the fcinfo hba-port command.  
root@ss2:~# fcinfo hba-port
HBA Port WWN: 210000e08b100163
        Port Mode: Initiator
        Port ID: 10300
        OS Device Name: /dev/cfg/c8
        Manufacturer: QLogic Corp.
        Model: QLA2300
        Firmware Version: 03.03.27
        FCode/BIOS Version:  BIOS: 1.47;
        Serial Number: not available
        Driver Name: qlc
        Driver Version: 20080617-2.30
        Type: N-port
        State: online
        Supported Speeds: 1Gb 2Gb
        Current Speed: 2Gb
        Node WWN: 200000e08b100163
        NPIV Not Supported

Using the stmfadm utility we add the gateway server’s wwn address to the GW1 host group. 
root@ss1:~# stmfadm add-hg-member -g GW1 wwn.210000e08b100163

Once added to ss1 we can see that it is indeed available and online. 
root@ss1:~# stmfadm list-target -v

Target: wwn.2100001B320EFD58
    Operational Status: Online
    Provider Name     : qlt
    Alias             : qlt2,0
    Sessions          : 1
        Initiator: wwn.210000E08B100163
            Alias: :qlc1
            Logged in since: Fri Dec 19 01:47:07 2008

The cfgadm command will scan for the newly available LUN’s and now we can access the emulated (aka boat anchor) storage system using our gateway server ss2. Of course we could also set up more initiators and access it over a multipath connection.  

cfgadm -a

root@ss2:~# format
Searching for disks…done

AVAILABLE DISK SELECTIONS:
       0. c0t600144F01EB3862C0000494B55CD0001d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b55cd0001

       1. c0t600144F01EB3862C0000494B55F50002d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b55f50002

       2. c0t600144F01EB3862C0000494B55F80003d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b55f80003

       3. c0t600144F01EB3862C0000494B55FA0004d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b55fa0004

       4. c0t600144F01EB3862C0000494B55FD0005d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b55fd0005

       5. c0t600144F01EB3862C0000494B56000006d0 <DEFAULT cyl 2086 alt 2 hd 255 sec 63>
          /scsi_vhci/disk@g600144f01eb3862c0000494b56000006

Now that we some FC LUN connections configured from to the storage system to be re-provisioned we can create a ZFS based pool which grants us the ability to carve out the block storage in a virtual manner. As discussed previously we will use raid dp a.k.a. raidz2 to provide a higher level of availability with the zpool create raidz2 option command.

root@ss2:~# zpool create gwrp1 raidz2 c0t600144F01EB3862C0000494B55CD0001d0 c0t600144F01EB3862C0000494B55F50002d0 c0t600144F01EB3862C0000494B55F80003d0 c0t600144F01EB3862C0000494B55FA0004d0 c0t600144F01EB3862C0000494B55FD0005d0 c0t600144F01EB3862C0000494B56000006d0

A quick status check reveals all is well with the ZFS pool.

root@ss2:~# zpool status gwrp1
  pool: gwrp1
 state: ONLINE
 scrub: none requested
config:

        NAME                                       STATE     READ WRITE CKSUM
        gwrp1                                      ONLINE       0     0     0
          raidz2                                   ONLINE       0     0     0
            c0t600144F01EB3862C0000494B55CD0001d0  ONLINE       0     0     0
            c0t600144F01EB3862C0000494B55F50002d0  ONLINE       0     0     0
            c0t600144F01EB3862C0000494B55F80003d0  ONLINE       0     0     0
            c0t600144F01EB3862C0000494B55FA0004d0  ONLINE       0     0     0
            c0t600144F01EB3862C0000494B55FD0005d0  ONLINE       0     0     0
            c0t600144F01EB3862C0000494B56000006d0  ONLINE       0     0     0

Let’s carve out some of this newly created pool as a 32GB sparse volume. The -p option creates the full path if it does not currently exist.


root@ss2:~# zfs create -p -s -V 32G gwrp1/stores/lun0
 

root@ss2:~# zfs list
NAME                         USED  AVAIL  REFER  MOUNTPOINT
gwrp1                        220K  62.6G  38.0K  /gwrp1
gwrp1/stores                67.9K  62.6G  36.0K  /gwrp1/stores
gwrp1/stores/lun0           32.0K  62.6G  32.0K  -

With a slice of the pool created we can now assign a GUID within the LU Provider layer using the sbdadm utility.

root@ss2:~# sbdadm create-lu /dev/zvol/rdsk/gwrp1/stores/lun0

Created the following LU:

              GUID                    DATA SIZE           SOURCE
——————————–  ——————-  —————-
600144f07ed404000000496813070001      34359672832      /dev/zvol/rdsk/gwrp1/stores/lun0

The LU Provider layer can also provision sparse based storage. However in this case the ZFS backing store is already thin provisioned. If this were a physical disk backing store it would be prudent to use the LU Provider’s sparse/thin provisioning feature. At this point we are ready to create the STMF Host Group and View that will be used to demonstrate a real world example of the multi protocol capability with the COMSTAR OpenStorage ss2 host. In this case I will use VMware ESX as a storage consumer. To reflect the host group type we will name it ESX1 and then we need to add a view for the LU GUID of the virtualized storage.

root@ss2:~# stmfadm create-hg ESX1

root@ss2:~# stmfadm add-view -h ESX1 -n 1 600144f07ed404000000496813070001

root@ss2:~# stmfadm list-view -l 600144F07ED404000000496813070001
View Entry: 0
    Host group   : ESX1
    Target group : All
    LUN          : 1

With a view defined for the VMware hosts let’s add an ESX host FC HBA wwn membership to the defined ESX1 host group. We need to retrieve the wwn from the VMware server using either the console or a Virtual Infrastructure Client GUI. Personally I like the console esxcfg-info tool, however if it’s an ESXi host then the GUI will serve the info just as well.


VMware Screen shot WWN by Mike La Spina

[root@vh1 root]# esxcfg-info -s | grep ‘Adapter WWN’
                     |—-Adapter WWNN…………………………20:00:00:e0:8b:01:f7:e2

root@ss2:~# stmfadm add-hg-member -g ESX1 wwn.210000e08b01f7e2

And the result of this change after we issue a rescan on vmhba1 and create a VMFS volume named ss2-cstar-zs0.0 with the re-provisioned storage is reflected here.

VMware Screen shot VMFS volume by Mike La Spina

This crafted storage is now a thinly provisioned VMFS store that can deliver replication, snapshots, cloning, advanced error detection and can also be re-platformed to a new storage system at a later date using ZFS’s hardware autonomy. The storage server is very attractive as it creates a level of future proofing and insulates the storage consumers from proprietary vendor lock in. But that’s not the best part of this example. Let’s say you wish provide different tiers of connectivity services for your storage consumers. For example we could attach a development or test environment using an iSCSI protocol and the more critical environments can use FC or FCoE based protocol.
So let’s look at how we can add a second SCSI transport protocol to this interesting configuration.
Just as a note the new iSCSI port provider is a kernel based implementation and has superior performance to its predecessor iscsitgt user land implementation.


To add the iSCSI protocol we need to enable the iscsi/target port provider service.



 



 


 


 

root@ss2:~# svcadm enable iscsi/target

Now we need to create an iSCSI target and iSCSI initiator definition so that we can add the iSCSI initiator to the ESX1 host group. As well we should define a target portal group so we can control what host IP(s) will service this target.

root@ss2:~# itadm create-tpg 2 10.0.0.1

root@ss2:~# itadm create-target

root@ss2:~# itadm create-target -n iqn.1986-03.com.sun:02:ss2.0 -t 2
Target iqn.1986-03.com.sun:02:ss2.0 successfully created

By default the iqn will be created as a member of the All targets group.

If we left out the parameters the itadm utility would create an iqn GUID and use the default target portal group of 1. And yes for those familiar with the predecessor iscsitadm utility we can now create a iqn name at the command line.

At this point we need to define the initiator iqn to the iSCSI port provider service and if required additionally secure it using CHAP. We need to retrieve the VMware initiator iqn name from either the Virtual Infrastructure Client GUI or console command line. Just as a note if we did not specify a host group when we defined our view the default would allow any initiator FC, iSCSI or otherwise to connect to the LU and this may have a purpose but generally it is a bad practice to allow in most configurations. Once created the initiator is added to the ESX1 host group thus enables our second access protocol to the same LU.

[root@vh1 root]# esxcfg-info -s | grep ‘iqn’
         |—-ISCSI Name……………………………………..iqn.1998-01.com.vmware:vh1.1
         |—-ISCSI Alias…………………………………….iqn.1998-01.com.vmware:vh1.1

root@ss2:~# itadm create-initiator iqn.1998-01.com.vmware:vh1.1

root@ss2:~# stmfadm add-hg-member -g ESX1 iqn.1998-01.com.vmware:vh1.1

After adding the ss2 iSCSI interface IP to VMware’s Software iSCSI initiator we now have a multipath multiprotocol connection to our COMSTAR storage host.

 VMware iqn example By Mike La Spina

VMware mpath example by Mike La Spina 

This is simply the most functional and advanced Open Source storage product in the world today. Here we have commodity white boxes serving advanced storage protocols in my home lab, can you imagine what could be done with Data Center class server hardware and Fishworks. You can begin to see the advantages of this future proof platform. As protocols like FCoE, Infiniband and iSER (iSCSI without the TCP session overhead) already working in COMSTAR the Sun Software Engineers and OpenSolaris community are crafting outstanding storage products.

Hope you found this blog to be interesting.
Regards,


Mike



 



 


 


 














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