Well, this is often a tricky situation, where you are running into Virtual Address Fragmentation and getting OOM (out-of-memory) errors in your SQL Server. Most often, people do not understand the difference between physical memory pressure vs. virtual memory pressure. Adding more RAM is definitely not a solution here! Here are some sample error messages you might have seen in your SQL Errorlog which will indicate if this is physical memory or virtual memory issue,
WARNING: Failed to reserve contiguous memory of Size= 65536.
SQL Server could not spawn process_loginread thread.
Failed Virtual Allocate Bytes: FAIL_VIRTUAL_RESERVE 122880
Error: 701, Severity: 17, State: 123.
There is insufficient system memory to run this query.
As the errors above indicate, the problem is in reserving a fixed size in the virtual address space of SQL Server. Note: the size indicated above in in bytes. e.g. 65536/1024 = 64 KB
Typical symptoms you would notice in these situations are :-
1) Database or Log Backups might start failing
2) You are unable to make a new connections to SQL.
3) Certain jobs which require memory from non-BPool region will fail. Many a time, these problems go away automatically without any action taken. This indicates an intermittent problem where at a certain point in time, there was virtual memory pressure which resulted in above messages being printed to the SQL Errorlog. Dealing with VAS fragmentation or running out of VAS on SQL server 2000 was rather painful and required setting up additional debugging techniques to get down to the bottom of the issue. You might have used some of the following tools :-
2) Debugging Tools for Windows (to capture a manual dump of sqlservr.exe)
3) T2551 to generate a filtered dump in SQL Server when running into a OOM condition.
4) TLIST.exe to identify modules loaded in SQL Server. Luckily, starting with SQL 2005 there is a in-memory DMV which tracks the virtual address space (VAS) of your SQL Server process.
Here are some queries which will help you find out how much virtual address is available on sqlservr.exe which is FREE and how much is total available (Free+InUse)
1. Will tell you the size of the biggest contiguous block in VAS
DBCC MEMORYSTATUS also has good information on whether the usage from the non-BPool region is coming from SQL or non-SQL components. If its SQL 2000, check the value of “OS Committed” and it is SQL 2005/2008 look at the value of “MultiPage Allocator” for each memory clerk. Just to re-state my assumption in case you are not sure: 1) Any OLE/COM components loaded in SQL Server HTH.
SELECT convert(varchar,getdate(),120) as [Timestamp], max(region_size_in_bytes)/1024 [Total max contiguous block size in KB] from sys.dm_os_virtual_address_dump where region_state = 0x00010000 --- MEM_FREE
2. Will also tell us size of largest contiguous block plus the region marked as MEM_RESERVE (this is your non-BPool area reserved during SQL Startup, sometimes referred to as MTL – MemToLeave)
With VASummary(Size,Reserved,Free) AS
Size = VaDump.Size,
Reserved = SUM(CASE(CONVERT(INT, VaDump.Base)^0)
WHEN 0 THEN 0 ELSE 1 END),
Free = SUM(CASE(CONVERT(INT, VaDump.Base)^0)
WHEN 0 THEN 1 ELSE 0 END)
SELECT CONVERT(VARBINARY, SUM(region_size_in_bytes))
AS Size, region_allocation_base_address AS Base
WHERE region_allocation_base_address <> 0x0
GROUP BY region_allocation_base_address
SELECT CONVERT(VARBINARY, region_size_in_bytes), region_allocation_base_address
WHERE region_allocation_base_address = 0x0
GROUP BY Size)
SELECT SUM(CONVERT(BIGINT,Size)*Free)/1024 AS [Total avail Mem, KB] ,CAST(MAX(Size) AS BIGINT)/1024 AS [Max free size, KB]
WHERE Free <> 0
3. Now, below query will identify the memory reserved by non-BPool components in SQL Server
select SUM(virtual_memory_reserved_kb)/1024 as virtual_memory_reserved_mb from sys.dm_os_memory_clerks where type not like '%bufferpool%'
SELECT SUM(PAGESUSED)*8/1024 'MB of MemToLeave memory consumed by procedures' FROM MASTER.DBO.SYSCACHEOBJECTS WHERE PAGESUSED >1
1 SQL Server Page = 8 KB –> SinglePage Allocator
> 1 Page or > 8KB –> MultiPage Allocator Apart from these you need to pay special attention to the following components are all of the below do not use memory from the Buffer Pool region but make direct VirtualAlloc() calls to reserve memory and then commit them:
2) Extended Stored Procedures (use sys.dm_os_loaded_modules to identify the module loaded in sqlserver process space).
3) SQL Mail components
4) Any prepared documents using sp_xml_preparedocument
5) Linked Server Providers
6) Large Plans stored in Procedure Cache
7) Very frequent Backups also may cause MTL area depletion. (Please investigate using the parameters MAXTRANSFERSIZE and BUFFERCOUNT, if this is the case).
8) SQL CLR (recommended to be used on 64-bit SQL Servers)
Above list is certainly not exhaustive, but is more enough to get started in looking at the right areas. While we are on this topic, it is important to understand the difference between a Reserve and a Commit. These are windows concepts are remain the same for SQL Server as well, after all its VirtualAlloc() underneath the covers.
MEM_COMMIT – Region in VAS this is backed by RAM/paging file
MEM_RESERVE – Region in VAS with no actual physical storage either in RAM or in the paging file. The problems we talked about so far occur when a call to VirtualAlloc() with MEM_RESERVE is made and that “reservation” fails resulting in the errors printed to errorlog. Most times, the call to reserve is subsequently followed by a COMMIT, but its not mandatory. I can reserve now and commit later on using the base address of the reservation. SQL Server is smart enough and during starting reserves a certain region of the address space referred to as MTL or Non-BPool region. It is here the crunch is and it is here the issue needs to be investigated/fixed.
A quick workaround for above issues is to add the startup parameter –gXXX. (Sample usage- -g512)
XXX- is the amount in MBytes to reserve on startup.I would advise against doing this as this is a workaround where you are increasing the MTL region rather than find out who/what is consuming it. Slava’s blog is a good read also on this topic.
DBCC MEMORYSTATUS also has good information on whether the usage from the non-BPool region is coming from SQL or non-SQL components. If its SQL 2000, check the value of “OS Committed” and it is SQL 2005/2008 look at the value of “MultiPage Allocator” for each memory clerk. Just to re-state my assumption in case you are not sure:
1) Any OLE/COM components loaded in SQL Server