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qingchuwudi:
有用,非常感谢!
erlang进程的优先级 -
zfjdiamond:
你好 这条命令 在那里输入??
你们有yum 我有LuaRocks -
simsunny22:
这个是在linux下运行的吧,在window下怎么运行escr ...
escript的高级特性 -
mozhenghua:
http://www.erlang.org/doc/apps/ ...
mnesia 分布协调的几个细节 -
fxltsbl:
A new record of 108000 HTTP req ...
Haproxy 1.4-dev2: barrier of 100k HTTP req/s crossed
原文地址: http://streamhacker.wordpress.com/2008/12/20/how-to-fix-erlang-out-of-memory-crashes-when-using-mnesia/
December 20, 2008 at 9:53 am (erlang) (database, dets, ets, iteration, memory, mnesia, records, transactions)
If you’re getting erlang out of memory crashes when using mnesia, chances are you’re doing it wrong, for various values of it. These out of memory crashes look something like this:
Crash dump was written to: erl_crash.dump
eheap_alloc: Cannot allocate 999999999 bytes of memory (of type "heap")
Possible Causes
You’re doing it wrong
Someone else is doing it wrong
You don’t have enough RAM
While it’s possible that the crash is due to not having enough RAM, or that some other program or process is using too much RAM for itself, chances are it’s your fault.
One of the reasons these crashes can catch you by surprise is that the erlang VM is using a lot more memory than you might think. Erlang is a functional language with single assignment and no shared memory. A major consequence is that when you change a variable or send a message to another process, a new copy of the variable is created. So an operation as simple as dict:update_counter(”foo”, 1, Dict1) consumes twice the memory of Dict1 since Dict1 is copied to create the return value. And anything you do with ets, dets, or mnesia will result in at least 2 copies of every term: 1 copy for your process, and 1 copy for each table. This is because mnesia uses ets and/or dets for storage, which both use 1 process per table. That means every table operation results in a message pass, sending your term to the table or vice-versa. So that’s why erlang may be running out of memory. Here’s how to fix it.
Use Dirty Operations
If you’re doing anything in a transaction, try to figure out how to do it dirty, or at least move as many operations as possible out of the transaction. Mnesia transactions are separate processes with their own temporary ets tables. That means there’s the original term(s) that must be passed in to the transaction or read from other tables, any updated copies that your code creates, copies of terms that are written to the temporary ets table, the final copies of terms that are written to actual table(s) at the end of the transaction, and copies of any terms that are returned from the transaction process. Here’s an example to illustrate:
example() ->
T = function() ->
Var1 = mnesia:read(example_table, "foo"),
Var2 = update(Var2), % a user-defined function to update Var1
ok = mnesia:write(Var2),
Var2
end,
{atomic, Var2} = mnesia:transaction(T),
Var2.
First off, we already have a copy of Var1 in example_table. It gets sent to the transaction process when you do mnesia:read, creating a second copy. Var1 is then updated, resulting in Var2, which I’ll assume has the same memory footprint of Var1. So now we have 3 copies. Var2 is then written to a temporary ets table because mnesia:write is called within a transaction, creating a fourth copy. The transaction ends, sending Var2 back to the original process, and also overwriting Var1 with Var2 in example_table. That’s 2 more copies, resulting in a total of 6 copies. Let’s compare that to a dirty operation.
example() ->
Var1 = mnesia:dirty_read(example_table, "foo"),
Var2 = update(Var1),
ok = mnesia:dirty_write(Var2),
Var2.
Doing it dirty results in only 4 copies: the original Var1 in example_table, the copy sent to your process, the updated Var2, and the copy sent to mnesia to be written. Dirty operations like this will generally have 2/3 the memory footprint of operations done in a transaction.
Reduce Record Size
Figuring out how to reduce your record size by using different data structures can create huge gains by drastically reducing the memory footprint of each operation, and possibly removing the need to use transaction. For example, let’s say you’re storing a large record in mnesia, and using transactions to update it. If the size of the record grows by 1 byte, then each transactional operation like the above will require an additional 5 bytes of memory, or dirty operations will require an additional 3 bytes. For multi-megabyte records, this adds up very quickly. The solution is to figure how to break that record up into many small records. Mnesia can use any term as a key, so for example, if you’re storing a record with a dict in mnesia such as {dict_record, “foo”, Dict}, you can split that up into many records like [{tuple_record, {"foo", Key1}, Val1}]. Each of these small records can be accessed independently, which could eliminate the need to use transactions, or at least drastically reduce the memory footprint of each transaction.
Iterate in Batches
Instead of getting a whole bunch of records from mnesia all at once, using mnesia:dirty_match_object or mnesia:dirty_select, iterate over the records in batches. This is analagous to using lists operations on mnesia tables. The match_object methods may return a huge number of records, and all those records have to be sent from the table process to your process, doubling the amount of memory required. By iteratively doing operations on batches of records, you’re only accessing a portion at a time, reducing the amount of memory being used at once. Here’s some code examples that only access 1 record at a time. Note that if the table changes during iteration, the behavior is undefined. You could also use the select operations to process records in batches of NObjects at a time.
Dirty Mnesia Foldl
dirty_foldl(F, Acc0, Table) ->
dirty_foldl(F, Acc0, Table, mnesia:dirty_first(Table)).
dirty_foldl(_, Acc, _, '$end_of_table') ->
Acc;
dirty_foldl(F, Acc, Table, Key) ->
Acc2 = lists:foldl(F, Acc, mnesia:dirty_read(Table, Key)),
dirty_foldl(F, Acc2, Table, mnesia:dirty_next(Table, Key)).
Dirty Mnesia Foreach
dirty_foreach(F, Table) ->
dirty_foreach(F, Table, mnesia:dirty_first(Table)).
dirty_foreach(_, _, '$end_of_table') ->
ok;
dirty_foreach(F, Table, Key) ->
lists:foreach(F, mnesia:dirty_read(Table, Key)),
dirty_foreach(F, Table, mnesia:dirty_next(Table, Key)).
Conclusion
It’s probably your fault
Do as little as possible inside transactions
Use dirty operations instead of transactions
Reduce record size
Iterate in small batches
Ulf said,
January 7, 2009 at 1:44 pm
Recommending dirty operations over transactions should come with a very big caveat: you change the semantics and forego safety, esp. if you have a replicated system. Dirty operations do not guarantee that replication works, for example. It may even work partially, given certain error situations, causing database inconsistency.
I normally advice people to use mnesia:activity(Type, F) rather than mnesia:transaction(F), and to always start with real transactions, then measure and - only if really necessary (and safe!), switch to dirty where neeeded. This can then be done by just changing Type from ‘transaction’ to ‘async_dirty’.
In my experience, the “iterate in small batches” should be one of the first points. It is very good advice. Also, monitor ets and mnesia tables to see if they keep growing. Inserting temporary objects and forgetting to delete them is a fairly common source of memory growth.
In other cases, a form of load control may well be what’s needed, making sure that the system doesn’t take on more work than it can handle (easy to do in an asynchronous environment). One very simple such device would be a gen_server that workers ask (synchronously) for permission before starting a new task. The server can monitor the ‘run_queue’ to guard against cpu overload, memory usage, number of running processes, etc., depending on where your bottlenecks are. Keep it very simple.
December 20, 2008 at 9:53 am (erlang) (database, dets, ets, iteration, memory, mnesia, records, transactions)
If you’re getting erlang out of memory crashes when using mnesia, chances are you’re doing it wrong, for various values of it. These out of memory crashes look something like this:
Crash dump was written to: erl_crash.dump
eheap_alloc: Cannot allocate 999999999 bytes of memory (of type "heap")
Possible Causes
You’re doing it wrong
Someone else is doing it wrong
You don’t have enough RAM
While it’s possible that the crash is due to not having enough RAM, or that some other program or process is using too much RAM for itself, chances are it’s your fault.
One of the reasons these crashes can catch you by surprise is that the erlang VM is using a lot more memory than you might think. Erlang is a functional language with single assignment and no shared memory. A major consequence is that when you change a variable or send a message to another process, a new copy of the variable is created. So an operation as simple as dict:update_counter(”foo”, 1, Dict1) consumes twice the memory of Dict1 since Dict1 is copied to create the return value. And anything you do with ets, dets, or mnesia will result in at least 2 copies of every term: 1 copy for your process, and 1 copy for each table. This is because mnesia uses ets and/or dets for storage, which both use 1 process per table. That means every table operation results in a message pass, sending your term to the table or vice-versa. So that’s why erlang may be running out of memory. Here’s how to fix it.
Use Dirty Operations
If you’re doing anything in a transaction, try to figure out how to do it dirty, or at least move as many operations as possible out of the transaction. Mnesia transactions are separate processes with their own temporary ets tables. That means there’s the original term(s) that must be passed in to the transaction or read from other tables, any updated copies that your code creates, copies of terms that are written to the temporary ets table, the final copies of terms that are written to actual table(s) at the end of the transaction, and copies of any terms that are returned from the transaction process. Here’s an example to illustrate:
example() ->
T = function() ->
Var1 = mnesia:read(example_table, "foo"),
Var2 = update(Var2), % a user-defined function to update Var1
ok = mnesia:write(Var2),
Var2
end,
{atomic, Var2} = mnesia:transaction(T),
Var2.
First off, we already have a copy of Var1 in example_table. It gets sent to the transaction process when you do mnesia:read, creating a second copy. Var1 is then updated, resulting in Var2, which I’ll assume has the same memory footprint of Var1. So now we have 3 copies. Var2 is then written to a temporary ets table because mnesia:write is called within a transaction, creating a fourth copy. The transaction ends, sending Var2 back to the original process, and also overwriting Var1 with Var2 in example_table. That’s 2 more copies, resulting in a total of 6 copies. Let’s compare that to a dirty operation.
example() ->
Var1 = mnesia:dirty_read(example_table, "foo"),
Var2 = update(Var1),
ok = mnesia:dirty_write(Var2),
Var2.
Doing it dirty results in only 4 copies: the original Var1 in example_table, the copy sent to your process, the updated Var2, and the copy sent to mnesia to be written. Dirty operations like this will generally have 2/3 the memory footprint of operations done in a transaction.
Reduce Record Size
Figuring out how to reduce your record size by using different data structures can create huge gains by drastically reducing the memory footprint of each operation, and possibly removing the need to use transaction. For example, let’s say you’re storing a large record in mnesia, and using transactions to update it. If the size of the record grows by 1 byte, then each transactional operation like the above will require an additional 5 bytes of memory, or dirty operations will require an additional 3 bytes. For multi-megabyte records, this adds up very quickly. The solution is to figure how to break that record up into many small records. Mnesia can use any term as a key, so for example, if you’re storing a record with a dict in mnesia such as {dict_record, “foo”, Dict}, you can split that up into many records like [{tuple_record, {"foo", Key1}, Val1}]. Each of these small records can be accessed independently, which could eliminate the need to use transactions, or at least drastically reduce the memory footprint of each transaction.
Iterate in Batches
Instead of getting a whole bunch of records from mnesia all at once, using mnesia:dirty_match_object or mnesia:dirty_select, iterate over the records in batches. This is analagous to using lists operations on mnesia tables. The match_object methods may return a huge number of records, and all those records have to be sent from the table process to your process, doubling the amount of memory required. By iteratively doing operations on batches of records, you’re only accessing a portion at a time, reducing the amount of memory being used at once. Here’s some code examples that only access 1 record at a time. Note that if the table changes during iteration, the behavior is undefined. You could also use the select operations to process records in batches of NObjects at a time.
Dirty Mnesia Foldl
dirty_foldl(F, Acc0, Table) ->
dirty_foldl(F, Acc0, Table, mnesia:dirty_first(Table)).
dirty_foldl(_, Acc, _, '$end_of_table') ->
Acc;
dirty_foldl(F, Acc, Table, Key) ->
Acc2 = lists:foldl(F, Acc, mnesia:dirty_read(Table, Key)),
dirty_foldl(F, Acc2, Table, mnesia:dirty_next(Table, Key)).
Dirty Mnesia Foreach
dirty_foreach(F, Table) ->
dirty_foreach(F, Table, mnesia:dirty_first(Table)).
dirty_foreach(_, _, '$end_of_table') ->
ok;
dirty_foreach(F, Table, Key) ->
lists:foreach(F, mnesia:dirty_read(Table, Key)),
dirty_foreach(F, Table, mnesia:dirty_next(Table, Key)).
Conclusion
It’s probably your fault
Do as little as possible inside transactions
Use dirty operations instead of transactions
Reduce record size
Iterate in small batches
Ulf said,
January 7, 2009 at 1:44 pm
Recommending dirty operations over transactions should come with a very big caveat: you change the semantics and forego safety, esp. if you have a replicated system. Dirty operations do not guarantee that replication works, for example. It may even work partially, given certain error situations, causing database inconsistency.
I normally advice people to use mnesia:activity(Type, F) rather than mnesia:transaction(F), and to always start with real transactions, then measure and - only if really necessary (and safe!), switch to dirty where neeeded. This can then be done by just changing Type from ‘transaction’ to ‘async_dirty’.
In my experience, the “iterate in small batches” should be one of the first points. It is very good advice. Also, monitor ets and mnesia tables to see if they keep growing. Inserting temporary objects and forgetting to delete them is a fairly common source of memory growth.
In other cases, a form of load control may well be what’s needed, making sure that the system doesn’t take on more work than it can handle (easy to do in an asynchronous environment). One very simple such device would be a gen_server that workers ask (synchronously) for permission before starting a new task. The server can monitor the ‘run_queue’ to guard against cpu overload, memory usage, number of running processes, etc., depending on where your bottlenecks are. Keep it very simple.
发表评论
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OTP R14A今天发布了
2010-06-17 14:36 2677以下是这次发布的亮点,没有太大的性能改进, 主要是修理了很多B ... -
R14A实现了EEP31,添加了binary模块
2010-05-21 15:15 3030Erlang的binary数据结构非常强大,而且偏向底层,在作 ... -
如何查看节点的可用句柄数目和已用句柄数
2010-04-08 03:31 4814很多同学在使用erlang的过程中, 碰到了很奇怪的问题, 后 ... -
获取Erlang系统信息的代码片段
2010-04-06 21:49 3475从lib/megaco/src/tcp/megaco_tcp_ ... -
iolist跟list有什么区别?
2010-04-06 20:30 6529看到erlang-china.org上有个 ... -
erlang:send_after和erlang:start_timer的使用解释
2010-04-06 18:31 8386前段时间arksea 同学提出这个问题, 因为文档里面写的很不 ... -
Latest news from the Erlang/OTP team at Ericsson 2010
2010-04-05 19:23 2013参考Talk http://www.erlang-factor ... -
对try 异常 运行的疑问,为什么出现两种结果
2010-04-05 19:22 2842郎咸武<langxianzhe@163.com> ... -
Erlang ERTS Async基础设施
2010-03-19 00:03 2517其实Erts的Async做的很不错的, 相当的完备, 性能又高 ... -
CloudI 0.0.9 Released, A Cloud as an Interface
2010-03-09 22:32 2476基于Erlang的云平台 看了下代码 质量还是不错的 完成了不 ... -
Memory matters - even in Erlang (再次说明了了解内存如何工作的必要性)
2010-03-09 20:26 3439原文地址:http://www.lshift.net/blog ... -
Some simple examples of using Erlang’s XPath implementation
2010-03-08 23:30 2050原文地址 http://www.lshift.net/blog ... -
lcnt 环境搭建
2010-02-26 16:19 2614抄书:otp_doc_html_R13B04/lib/tool ... -
Erlang强大的代码重构工具 tidier
2010-02-25 16:22 2486Jan 29, 2010 We are very happy ... -
[Feb 24 2010] Erlang/OTP R13B04 has been released
2010-02-25 00:31 1387Erlang/OTP R13B04 has been rele ... -
R13B04 Installation
2010-01-28 10:28 1390R13B04后erlang的源码编译为了考虑移植性,就改变了编 ... -
Running tests
2010-01-19 14:51 1486R13B03以后 OTP的模块加入了大量的测试模块,这些模块都 ... -
R13B04在细化Binary heap
2010-01-14 15:11 1508从github otp的更新日志可以清楚的看到otp R13B ... -
R13B03 binary vheap有助减少binary内存压力
2009-11-29 16:07 1668R13B03 binary vheap有助减少binary内存 ... -
erl_nif 扩展erlang的另外一种方法
2009-11-26 01:02 3218我们知道扩展erl有2种方法, driver和port. 这2 ...
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