New NSV Interface: ------------------ January, 2000 The new nsv interface of AOLserver 3.0 was added to provide a high performance, more flexible alternative to ns_share. The model is similar to the existing (and undocumented) ns_var command but uses an array syntax and includes more features. Basics: ------- The following commands currently make up the nsv interface: nsv_get - get key value nsv_exists - check key existence nsv_set - set key value nsv_append - append value nsv_lappend - append value as list element nsv_incr - increment and return value nsv_unset - unset a value nsv_array - manage nsv arrays Commands for the most part mirror the cooresponding Tcl command for ordinary variables. Basically, to set a value, simply use the nsv_set command: nsv_set myarray foo $value and to get a value, simply use the nsv_get command: set value [nsv_get myarray foo] Migrating From ns_share: ------------------------ Migrating from ns_share is straightforward. If your init.tcl included commands such as: ns_share myshare set myshare(lock) [ns_mutex create] use instead: nsv_set myshare lock [ns_mutex create] In your procedures, instead of: proc myproc {} { ns_share myshare ns_mutex lock $myshare(lock) ... use: proc myproc {} { ns_mutex lock [nsv_get myshare lock] ... and within an ADP page, instead of: <% ns_share myshare ns_puts $myshare(key1) %> <%=$myshare(key2)%> use: <% ns_puts [nsv_get myshare key1] %> <%=[nsv_get myshare key2]%> Notice that, unlike ns_share, no command is required to define the shared array. The first attempt at setting the variable through any means will automaticaly create the array. Also notice that only arrays are supported. However, to migrate from ns_share you can simply package up all existing ns_share scalars into a single array with a short name, perhaps just ".". For example, if you had: ns_share mylock myfile set myfile /tmp/some.file set mylock [ns_mutex create] you can use: nsv_set . myfile /tmp/some.file nsv_set . mylock [ns_mutex create] Multithreading Features: ------------------------ One advantages of nsv is built in interlocking for thread safety. For example, consider a case of a "increment-by-one" unique id system. Here's the ns_share solution: ns_share ids set ids(lock) [ns_mutex create] set ids(next) 0 proc nextid {} { ns_share ids ns_mutex lock $ids(lock) set next [incr ids(next)] ns_mutex unlock $ids(lock) return $next } and here's an nsv solution: nsv_set ids next 0 proc nextid {} { return [nsv_incr ids next] } Note that the nsv solution does not need a mutex as the nsv_incr command is internally interlocked. Compatibility with Tcl Arrays: ------------------------------ Another useful feature of nsv is the nsv_array command which works much like the Tcl array command. This can be used to import and export values from ordinary Tcl arrays. For example, to copy from Tcl use: nsv_array set meta [array get tmpmeta] and to copy to Tcl use: array set metacopy [nsv_array get meta] As with all other nsv command, nsv_array is atomic and no explicit locking is required. This feature can be used to contruct a new nsv array by first filling up an ordinary temporary Tcl array via some time consuming process and then swapping it into place as above. While the new temporary array is being constructed, other threads can access the old array without delay or inconsistant data. You can even reset a complete nsv array in one step with "reset". For example, instead of: ns_share lock meta set lock [ns_mutex create] ns_mutex lock $lock unset meta array set meta [array get tmpmeta] ns_mutex unlock $lock you can simply use: nsv_array reset meta [array get tmpmeta] The reset option will flush and then reset all values atomically, eliminating the need for the explicit lock. Other options for the nsv_array command include: nsv_array exists array - test existance of array nsv_array size array - return # of elements in array nsv_array names array - return keys of array Configuration: -------------- The nsv system uses a common multithreading technique to reduce the potential for lock contention which is to split the locks to acheive finer grained locking. This technique groups arrays randomly into buckets and only the arrays within a particular bucket share a lock. The number of buckets to be used can be configured by setting the "nsvbuckets" tcl parameters, e.g.: [ns/server/server1/tcl] nsvbuckets=20 The default is 8 which should be reasonalbe. Note that you can monitor the lock contention, if any, by enabling mutex metering: [ns/threads] mutexmetering=on and then viewing the results of "ns_info locks" command after the server has been running for some time. The nsv locks all have names of the form "nsv:##". If you find many lock attempts which did not successed immediately, try increasing nsvbuckets. Feedback: --------- Please send any feedback, including ideas for additional features, to feedback@aolserver.com.