use DB_File; [$X =] tie %hash, 'DB_File', [$filename, $flags, $mode, $DB_HASH] ; [$X =] tie %hash, 'DB_File', $filename, $flags, $mode, $DB_BTREE ; [$X =] tie @array, 'DB_File', $filename, $flags, $mode, $DB_RECNO ; $status = $X->del($key [, $flags]) ; $status = $X->put($key, $value [, $flags]) ; $status = $X->get($key, $value [, $flags]) ; $status = $X->seq($key, $value, $flags) ; $status = $X->sync([$flags]) ; $status = $X->fd ; # BTREE only $count = $X->get_dup($key) ; @list = $X->get_dup($key) ; %list = $X->get_dup($key, 1) ; $status = $X->find_dup($key, $value) ; $status = $X->del_dup($key, $value) ; # RECNO only $a = $X->length; $a = $X->pop ; $X->push(list); $a = $X->shift; $X->unshift(list); @r = $X->splice(offset, length, elements); # DBM Filters $old_filter = $db->filter_store_key ( sub { ... } ) ; $old_filter = $db->filter_store_value( sub { ... } ) ; $old_filter = $db->filter_fetch_key ( sub { ... } ) ; $old_filter = $db->filter_fetch_value( sub { ... } ) ; untie %hash ; untie @array ;
Berkeley DB is a C library which provides a consistent interface to a number of database formats. DB_File provides an interface to all three of the database types currently supported by Berkeley DB.
The file types are:
A default hashing algorithm, which will be adequate for most applications, is built into Berkeley DB. If you do need to use your own hashing algorithm it is possible to write your own in Perl and have DB_File use it instead.
As with the DB_HASH format, it is possible to provide a user defined Perl routine to perform the comparison of keys. By default, though, the keys are stored in lexical order.
If you want to make use of the new features available in Berkeley DB 2.x or greater, use the Perl module BerkeleyDB instead.
Note: The database file format has changed multiple times in Berkeley DB version 2, 3 and 4. If you cannot recreate your databases, you must dump any existing databases with either the "db_dump" or the "db_dump185" utility that comes with Berkeley DB. Once you have rebuilt DB_File to use Berkeley DB version 2 or greater, your databases can be recreated using "db_load". Refer to the Berkeley DB documentation for further details.
Please read ``COPYRIGHT'' before using version 2.x or greater of Berkeley DB with DB_File.
In addition to the tie() interface, it is also possible to access most of the functions provided in the Berkeley DB API directly. See ``THE API INTERFACE''.
DB* dbopen (const char * file, int flags, int mode, DBTYPE type, const void * openinfo)
The parameter "type" is an enumeration which specifies which of the 3 interface methods (DB_HASH, DB_BTREE or DB_RECNO) is to be used. Depending on which of these is actually chosen, the final parameter, openinfo points to a data structure which allows tailoring of the specific interface method.
This interface is handled slightly differently in DB_File. Here is an equivalent call using DB_File:
tie %array, 'DB_File', $filename, $flags, $mode, $DB_HASH ;
The "filename", "flags" and "mode" parameters are the direct equivalent of their dbopen() counterparts. The final parameter $DB_HASH performs the function of both the "type" and "openinfo" parameters in dbopen().
In the example above $DB_HASH is actually a pre-defined reference to a hash object. DB_File has three of these pre-defined references. Apart from $DB_HASH, there is also $DB_BTREE and $DB_RECNO.
The keys allowed in each of these pre-defined references is limited to the names used in the equivalent C structure. So, for example, the $DB_HASH reference will only allow keys called "bsize", "cachesize", "ffactor", "hash", "lorder" and "nelem".
To change one of these elements, just assign to it like this:
$DB_HASH->{'cachesize'} = 10000 ;
The three predefined variables $DB_HASH, $DB_BTREE and $DB_RECNO are usually adequate for most applications. If you do need to create extra instances of these objects, constructors are available for each file type.
Here are examples of the constructors and the valid options available for DB_HASH, DB_BTREE and DB_RECNO respectively.
$a = new DB_File::HASHINFO ; $a->{'bsize'} ; $a->{'cachesize'} ; $a->{'ffactor'}; $a->{'hash'} ; $a->{'lorder'} ; $a->{'nelem'} ; $b = new DB_File::BTREEINFO ; $b->{'flags'} ; $b->{'cachesize'} ; $b->{'maxkeypage'} ; $b->{'minkeypage'} ; $b->{'psize'} ; $b->{'compare'} ; $b->{'prefix'} ; $b->{'lorder'} ; $c = new DB_File::RECNOINFO ; $c->{'bval'} ; $c->{'cachesize'} ; $c->{'psize'} ; $c->{'flags'} ; $c->{'lorder'} ; $c->{'reclen'} ; $c->{'bfname'} ;
The values stored in the hashes above are mostly the direct equivalent of their C counterpart. Like their C counterparts, all are set to a default values - that means you don't have to set all of the values when you only want to change one. Here is an example:
$a = new DB_File::HASHINFO ; $a->{'cachesize'} = 12345 ; tie %y, 'DB_File', "filename", $flags, 0777, $a ;
A few of the options need extra discussion here. When used, the C equivalent of the keys "hash", "compare" and "prefix" store pointers to C functions. In DB_File these keys are used to store references to Perl subs. Below are templates for each of the subs:
sub hash { my ($data) = @_ ; ... # return the hash value for $data return $hash ; } sub compare { my ($key, $key2) = @_ ; ... # return 0 if $key1 eq $key2 # -1 if $key1 lt $key2 # 1 if $key1 gt $key2 return (-1 , 0 or 1) ; } sub prefix { my ($key, $key2) = @_ ; ... # return number of bytes of $key2 which are # necessary to determine that it is greater than $key1 return $bytes ; }
See ``Changing the BTREE sort order'' for an example of using the "compare" template.
If you are using the DB_RECNO interface and you intend making use of "bval", you should check out ``The 'bval' Option''.
tie %A, "DB_File", "filename" ;
is equivalent to:
tie %A, "DB_File", "filename", O_CREAT|O_RDWR, 0666, $DB_HASH ;
It is also possible to omit the filename parameter as well, so the call:
tie %A, "DB_File" ;
is equivalent to:
tie %A, "DB_File", undef, O_CREAT|O_RDWR, 0666, $DB_HASH ;
See ``In Memory Databases'' for a discussion on the use of "undef" in place of a filename.
use warnings ; use strict ; use DB_File ; our (%h, $k, $v) ; unlink "fruit" ; tie %h, "DB_File", "fruit", O_RDWR|O_CREAT, 0666, $DB_HASH or die "Cannot open file 'fruit': $!\n"; # Add a few key/value pairs to the file $h{"apple"} = "red" ; $h{"orange"} = "orange" ; $h{"banana"} = "yellow" ; $h{"tomato"} = "red" ; # Check for existence of a key print "Banana Exists\n\n" if $h{"banana"} ; # Delete a key/value pair. delete $h{"apple"} ; # print the contents of the file while (($k, $v) = each %h) { print "$k -> $v\n" } untie %h ;
here is the output:
Banana Exists orange -> orange tomato -> red banana -> yellow
Note that the like ordinary associative arrays, the order of the keys retrieved is in an apparently random order.
use warnings ; use strict ; use DB_File ; my %h ; sub Compare { my ($key1, $key2) = @_ ; "\L$key1" cmp "\L$key2" ; } # specify the Perl sub that will do the comparison $DB_BTREE->{'compare'} = \&Compare ; unlink "tree" ; tie %h, "DB_File", "tree", O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open file 'tree': $!\n" ; # Add a key/value pair to the file $h{'Wall'} = 'Larry' ; $h{'Smith'} = 'John' ; $h{'mouse'} = 'mickey' ; $h{'duck'} = 'donald' ; # Delete delete $h{"duck"} ; # Cycle through the keys printing them in order. # Note it is not necessary to sort the keys as # the btree will have kept them in order automatically. foreach (keys %h) { print "$_\n" } untie %h ;
Here is the output from the code above.
mouse Smith Wall
There are a few point to bear in mind if you want to change the ordering in a BTREE database:
sub compare { my($key1, $key2) = @_; lc $key1 cmp lc $key2 || $key1 cmp $key2; }
And now you will only have duplicates when the keys themselves are truly the same. (note: in versions of the db library prior to about November 1996, such duplicate keys were retained so it was possible to recover the original keys in sets of keys that compared as equal).
There are some difficulties in using the tied hash interface if you want to manipulate a BTREE database with duplicate keys. Consider this code:
use warnings ; use strict ; use DB_File ; my ($filename, %h) ; $filename = "tree" ; unlink $filename ; # Enable duplicate records $DB_BTREE->{'flags'} = R_DUP ; tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; # Add some key/value pairs to the file $h{'Wall'} = 'Larry' ; $h{'Wall'} = 'Brick' ; # Note the duplicate key $h{'Wall'} = 'Brick' ; # Note the duplicate key and value $h{'Smith'} = 'John' ; $h{'mouse'} = 'mickey' ; # iterate through the associative array # and print each key/value pair. foreach (sort keys %h) { print "$_ -> $h{$_}\n" } untie %h ;
Here is the output:
Smith -> John Wall -> Larry Wall -> Larry Wall -> Larry mouse -> mickey
As you can see 3 records have been successfully created with key "Wall" - the only thing is, when they are retrieved from the database they seem to have the same value, namely "Larry". The problem is caused by the way that the associative array interface works. Basically, when the associative array interface is used to fetch the value associated with a given key, it will only ever retrieve the first value.
Although it may not be immediately obvious from the code above, the associative array interface can be used to write values with duplicate keys, but it cannot be used to read them back from the database.
The way to get around this problem is to use the Berkeley DB API method called "seq". This method allows sequential access to key/value pairs. See ``THE API INTERFACE'' for details of both the "seq" method and the API in general.
Here is the script above rewritten using the "seq" API method.
use warnings ; use strict ; use DB_File ; my ($filename, $x, %h, $status, $key, $value) ; $filename = "tree" ; unlink $filename ; # Enable duplicate records $DB_BTREE->{'flags'} = R_DUP ; $x = tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; # Add some key/value pairs to the file $h{'Wall'} = 'Larry' ; $h{'Wall'} = 'Brick' ; # Note the duplicate key $h{'Wall'} = 'Brick' ; # Note the duplicate key and value $h{'Smith'} = 'John' ; $h{'mouse'} = 'mickey' ; # iterate through the btree using seq # and print each key/value pair. $key = $value = 0 ; for ($status = $x->seq($key, $value, R_FIRST) ; $status == 0 ; $status = $x->seq($key, $value, R_NEXT) ) { print "$key -> $value\n" } undef $x ; untie %h ;
that prints:
Smith -> John Wall -> Brick Wall -> Brick Wall -> Larry mouse -> mickey
This time we have got all the key/value pairs, including the multiple values associated with the key "Wall".
To make life easier when dealing with duplicate keys, DB_File comes with a few utility methods.
$count = $x->get_dup($key) ; @list = $x->get_dup($key) ; %list = $x->get_dup($key, 1) ;
In a scalar context the method returns the number of values associated with the key, $key.
In list context, it returns all the values which match $key. Note that the values will be returned in an apparently random order.
In list context, if the second parameter is present and evaluates TRUE, the method returns an associative array. The keys of the associative array correspond to the values that matched in the BTREE and the values of the array are a count of the number of times that particular value occurred in the BTREE.
So assuming the database created above, we can use "get_dup" like this:
use warnings ; use strict ; use DB_File ; my ($filename, $x, %h) ; $filename = "tree" ; # Enable duplicate records $DB_BTREE->{'flags'} = R_DUP ; $x = tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; my $cnt = $x->get_dup("Wall") ; print "Wall occurred $cnt times\n" ; my %hash = $x->get_dup("Wall", 1) ; print "Larry is there\n" if $hash{'Larry'} ; print "There are $hash{'Brick'} Brick Walls\n" ; my @list = sort $x->get_dup("Wall") ; print "Wall => [@list]\n" ; @list = $x->get_dup("Smith") ; print "Smith => [@list]\n" ; @list = $x->get_dup("Dog") ; print "Dog => [@list]\n" ;
and it will print:
Wall occurred 3 times Larry is there There are 2 Brick Walls Wall => [Brick Brick Larry] Smith => [John] Dog => []
$status = $X->find_dup($key, $value) ;
This method checks for the existence of a specific key/value pair. If the pair exists, the cursor is left pointing to the pair and the method returns 0. Otherwise the method returns a non-zero value.
Assuming the database from the previous example:
use warnings ; use strict ; use DB_File ; my ($filename, $x, %h, $found) ; $filename = "tree" ; # Enable duplicate records $DB_BTREE->{'flags'} = R_DUP ; $x = tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; $found = ( $x->find_dup("Wall", "Larry") == 0 ? "" : "not") ; print "Larry Wall is $found there\n" ; $found = ( $x->find_dup("Wall", "Harry") == 0 ? "" : "not") ; print "Harry Wall is $found there\n" ; undef $x ; untie %h ;
prints this
Larry Wall is there Harry Wall is not there
$status = $X->del_dup($key, $value) ;
This method deletes a specific key/value pair. It returns 0 if they exist and have been deleted successfully. Otherwise the method returns a non-zero value.
Again assuming the existence of the "tree" database
use warnings ; use strict ; use DB_File ; my ($filename, $x, %h, $found) ; $filename = "tree" ; # Enable duplicate records $DB_BTREE->{'flags'} = R_DUP ; $x = tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; $x->del_dup("Wall", "Larry") ; $found = ( $x->find_dup("Wall", "Larry") == 0 ? "" : "not") ; print "Larry Wall is $found there\n" ; undef $x ; untie %h ;
prints this
Larry Wall is not there
$x->seq($key, $value, R_CURSOR) ;
Here is the relevant quote from the dbopen man page where it defines the use of the R_CURSOR flag with seq:
Note, for the DB_BTREE access method, the returned key is not necessarily an exact match for the specified key. The returned key is the smallest key greater than or equal to the specified key, permitting partial key matches and range searches.
In the example script below, the "match" sub uses this feature to find and print the first matching key/value pair given a partial key.
use warnings ; use strict ; use DB_File ; use Fcntl ; my ($filename, $x, %h, $st, $key, $value) ; sub match { my $key = shift ; my $value = 0; my $orig_key = $key ; $x->seq($key, $value, R_CURSOR) ; print "$orig_key\t-> $key\t-> $value\n" ; } $filename = "tree" ; unlink $filename ; $x = tie %h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_BTREE or die "Cannot open $filename: $!\n"; # Add some key/value pairs to the file $h{'mouse'} = 'mickey' ; $h{'Wall'} = 'Larry' ; $h{'Walls'} = 'Brick' ; $h{'Smith'} = 'John' ; $key = $value = 0 ; print "IN ORDER\n" ; for ($st = $x->seq($key, $value, R_FIRST) ; $st == 0 ; $st = $x->seq($key, $value, R_NEXT) ) { print "$key -> $value\n" } print "\nPARTIAL MATCH\n" ; match "Wa" ; match "A" ; match "a" ; undef $x ; untie %h ;
Here is the output:
IN ORDER Smith -> John Wall -> Larry Walls -> Brick mouse -> mickey PARTIAL MATCH Wa -> Wall -> Larry A -> Smith -> John a -> mouse -> mickey
In order to make RECNO more compatible with Perl, the array offset for all RECNO arrays begins at 0 rather than 1 as in Berkeley DB.
As with normal Perl arrays, a RECNO array can be accessed using negative indexes. The index -1 refers to the last element of the array, -2 the second last, and so on. Attempting to access an element before the start of the array will raise a fatal run-time error.
The delimiting byte to be used to mark the end of a record for variable-length records, and the pad charac- ter for fixed-length records. If no value is speci- fied, newlines (``\n'') are used to mark the end of variable-length records and fixed-length records are padded with spaces.
The second sentence is wrong. In actual fact bval will only default to "\n" when the openinfo parameter in dbopen is NULL. If a non-NULL openinfo parameter is used at all, the value that happens to be in bval will be used. That means you always have to specify bval when making use of any of the options in the openinfo parameter. This documentation error will be fixed in the next release of Berkeley DB.
That clarifies the situation with regards Berkeley DB itself. What about DB_File? Well, the behavior defined in the quote above is quite useful, so DB_File conforms to it.
That means that you can specify other options (e.g. cachesize) and still have bval default to "\n" for variable length records, and space for fixed length records.
Also note that the bval option only allows you to specify a single byte as a delimiter.
use warnings ; use strict ; use DB_File ; my $filename = "text" ; unlink $filename ; my @h ; tie @h, "DB_File", $filename, O_RDWR|O_CREAT, 0666, $DB_RECNO or die "Cannot open file 'text': $!\n" ; # Add a few key/value pairs to the file $h[0] = "orange" ; $h[1] = "blue" ; $h[2] = "yellow" ; push @h, "green", "black" ; my $elements = scalar @h ; print "The array contains $elements entries\n" ; my $last = pop @h ; print "popped $last\n" ; unshift @h, "white" ; my $first = shift @h ; print "shifted $first\n" ; # Check for existence of a key print "Element 1 Exists with value $h[1]\n" if $h[1] ; # use a negative index print "The last element is $h[-1]\n" ; print "The 2nd last element is $h[-2]\n" ; untie @h ;
Here is the output from the script:
The array contains 5 entries popped black shifted white Element 1 Exists with value blue The last element is green The 2nd last element is yellow
To make the interface more useful for older versions of Perl, a number of methods are supplied with DB_File to simulate the missing array operations. All these methods are accessed via the object returned from the tie call.
Here are the methods:
use warnings ; use strict ; my (@h, $H, $file, $i) ; use DB_File ; use Fcntl ; $file = "text" ; unlink $file ; $H = tie @h, "DB_File", $file, O_RDWR|O_CREAT, 0666, $DB_RECNO or die "Cannot open file $file: $!\n" ; # first create a text file to play with $h[0] = "zero" ; $h[1] = "one" ; $h[2] = "two" ; $h[3] = "three" ; $h[4] = "four" ; # Print the records in order. # # The length method is needed here because evaluating a tied # array in a scalar context does not return the number of # elements in the array. print "\nORIGINAL\n" ; foreach $i (0 .. $H->length - 1) { print "$i: $h[$i]\n" ; } # use the push & pop methods $a = $H->pop ; $H->push("last") ; print "\nThe last record was [$a]\n" ; # and the shift & unshift methods $a = $H->shift ; $H->unshift("first") ; print "The first record was [$a]\n" ; # Use the API to add a new record after record 2. $i = 2 ; $H->put($i, "Newbie", R_IAFTER) ; # and a new record before record 1. $i = 1 ; $H->put($i, "New One", R_IBEFORE) ; # delete record 3 $H->del(3) ; # now print the records in reverse order print "\nREVERSE\n" ; for ($i = $H->length - 1 ; $i >= 0 ; -- $i) { print "$i: $h[$i]\n" } # same again, but use the API functions instead print "\nREVERSE again\n" ; my ($s, $k, $v) = (0, 0, 0) ; for ($s = $H->seq($k, $v, R_LAST) ; $s == 0 ; $s = $H->seq($k, $v, R_PREV)) { print "$k: $v\n" } undef $H ; untie @h ;
and this is what it outputs:
ORIGINAL 0: zero 1: one 2: two 3: three 4: four The last record was [four] The first record was [zero] REVERSE 5: last 4: three 3: Newbie 2: one 1: New One 0: first REVERSE again 5: last 4: three 3: Newbie 2: one 1: New One 0: first
Notes:
foreach $i (@h)
it is necessary to use either this:
foreach $i (0 .. $H->length - 1)
or this:
for ($a = $H->get($k, $v, R_FIRST) ; $a == 0 ; $a = $H->get($k, $v, R_NEXT) )
To do this you need to store a copy of the object returned from the tie.
$db = tie %hash, "DB_File", "filename" ;
Once you have done that, you can access the Berkeley DB API functions as DB_File methods directly like this:
$db->put($key, $value, R_NOOVERWRITE) ;
Important: If you have saved a copy of the object returned from "tie", the underlying database file will not be closed until both the tied variable is untied and all copies of the saved object are destroyed.
use DB_File ; $db = tie %hash, "DB_File", "filename" or die "Cannot tie filename: $!" ; ... undef $db ; untie %hash ;
See ``The untie() Gotcha'' for more details.
All the functions defined in dbopen are available except for close() and dbopen() itself. The DB_File method interface to the supported functions have been implemented to mirror the way Berkeley DB works whenever possible. In particular note that:
Other return codes are defined. See below and in the Berkeley DB documentation for details. The Berkeley DB documentation should be used as the definitive source.
$X = tie %x, 'DB_File', $filename, O_RDWR|O_CREAT, 0777, $DB_BTREE or die "Cannot tie $filename: $!" ; # Get the first key/value pair and set the cursor $X->seq($key, $value, R_FIRST) ; # this line will modify the cursor $count = scalar keys %x ; # Get the second key/value pair. # oops, it didn't, it got the last key/value pair! $X->seq($key, $value, R_NEXT) ;
The code above can be rearranged to get around the problem, like this:
$X = tie %x, 'DB_File', $filename, O_RDWR|O_CREAT, 0777, $DB_BTREE or die "Cannot tie $filename: $!" ; # this line will modify the cursor $count = scalar keys %x ; # Get the first key/value pair and set the cursor $X->seq($key, $value, R_FIRST) ; # Get the second key/value pair. # worked this time. $X->seq($key, $value, R_NEXT) ;
All the constants defined in dbopen for use in the flags parameters in the methods defined below are also available. Refer to the Berkeley DB documentation for the precise meaning of the flags values.
Below is a list of the methods available.
If the key does not exist the method returns 1.
No flags are currently defined for this method.
If you use either the R_IAFTER or R_IBEFORE flags, the $key parameter will have the record number of the inserted key/value pair set.
Valid flags are R_CURSOR, R_IAFTER, R_IBEFORE, R_NOOVERWRITE and R_SETCURSOR.
A return code of 1 means that the requested key was not in the database.
R_CURSOR is the only valid flag at present.
See ``Locking: The Trouble with fd'' for an explanation for why you should not use "fd" to lock your database.
Both the $key and $value parameters will be set to the key/value pair read from the database.
The flags parameter is mandatory. The valid flag values are R_CURSOR, R_FIRST, R_LAST, R_NEXT and R_PREV.
R_RECNOSYNC is the only valid flag at present.
There are four methods associated with DBM Filters. All work identically, and each is used to install (or uninstall) a single DBM Filter. Each expects a single parameter, namely a reference to a sub. The only difference between them is the place that the filter is installed.
To summarise:
You can use any combination of the methods, from none, to all four.
All filter methods return the existing filter, if present, or "undef" in not.
To delete a filter pass "undef" to it.
$hash{"$key\0"} = "$value\0" ;
Similarly the NULL needs to be taken into account when you are considering the length of existing keys/values.
It would be much better if you could ignore the NULL terminations issue in the main application code and have a mechanism that automatically added the terminating NULL to all keys and values whenever you write to the database and have them removed when you read from the database. As I'm sure you have already guessed, this is a problem that DBM Filters can fix very easily.
use warnings ; use strict ; use DB_File ; my %hash ; my $filename = "filt" ; unlink $filename ; my $db = tie %hash, 'DB_File', $filename, O_CREAT|O_RDWR, 0666, $DB_HASH or die "Cannot open $filename: $!\n" ; # Install DBM Filters $db->filter_fetch_key ( sub { s/\0$// } ) ; $db->filter_store_key ( sub { $_ .= "\0" } ) ; $db->filter_fetch_value( sub { s/\0$// } ) ; $db->filter_store_value( sub { $_ .= "\0" } ) ; $hash{"abc"} = "def" ; my $a = $hash{"ABC"} ; # ... undef $db ; untie %hash ;
Hopefully the contents of each of the filters should be self-explanatory. Both ``fetch'' filters remove the terminating NULL, and both ``store'' filters add a terminating NULL.
$hash{12345} = "something" ;
the key 12345 will get stored in the DBM database as the 5 byte string ``12345''. If you actually want the key to be stored in the DBM database as a C int, you will have to use "pack" when writing, and "unpack" when reading.
Here is a DBM Filter that does it:
use warnings ; use strict ; use DB_File ; my %hash ; my $filename = "filt" ; unlink $filename ; my $db = tie %hash, 'DB_File', $filename, O_CREAT|O_RDWR, 0666, $DB_HASH or die "Cannot open $filename: $!\n" ; $db->filter_fetch_key ( sub { $_ = unpack("i", $_) } ) ; $db->filter_store_key ( sub { $_ = pack ("i", $_) } ) ; $hash{123} = "def" ; # ... undef $db ; untie %hash ;
This time only two filters have been used --- we only need to manipulate the contents of the key, so it wasn't necessary to install any value filters.
The locking technique went like this.
$db = tie(%db, 'DB_File', 'foo.db', O_CREAT|O_RDWR, 0644) || die "dbcreat foo.db $!"; $fd = $db->fd; open(DB_FH, "+<&=$fd") || die "dup $!"; flock (DB_FH, LOCK_EX) || die "flock: $!"; ... $db{"Tom"} = "Jerry" ; ... flock(DB_FH, LOCK_UN); undef $db; untie %db; close(DB_FH);
In simple terms, this is what happens:
Here is the crux of the problem. A side-effect of opening the DB_File database in step 2 is that an initial block from the database will get read from disk and cached in memory.
To see why this is a problem, consider what can happen when two processes, say ``A'' and ``B'', both want to update the same DB_File database using the locking steps outlined above. Assume process ``A'' has already opened the database and has a write lock, but it hasn't actually updated the database yet (it has finished step 2, but not started step 3 yet). Now process ``B'' tries to open the same database - step 1 will succeed, but it will block on step 2 until process ``A'' releases the lock. The important thing to notice here is that at this point in time both processes will have cached identical initial blocks from the database.
Now process ``A'' updates the database and happens to change some of the data held in the initial buffer. Process ``A'' terminates, flushing all cached data to disk and releasing the database lock. At this point the database on disk will correctly reflect the changes made by process ``A''.
With the lock released, process ``B'' can now continue. It also updates the database and unfortunately it too modifies the data that was in its initial buffer. Once that data gets flushed to disk it will overwrite some/all of the changes process ``A'' made to the database.
The result of this scenario is at best a database that doesn't contain what you expect. At worst the database will corrupt.
The above won't happen every time competing process update the same DB_File database, but it does illustrate why the technique should not be used.
If using BerkeleyDB isn't an option, there are a number of modules available on CPAN that can be used to implement locking. Each one implements locking differently and has different goals in mind. It is therefore worth knowing the difference, so that you can pick the right one for your application. Here are the three locking wrappers:
The vast majority of problems that are reported in this area boil down to the fact that C strings are NULL terminated, whilst Perl strings are not. See ``DBM FILTERS'' for a generic way to work around this problem.
Here is a real example. Netscape 2.0 keeps a record of the locations you visit along with the time you last visited them in a DB_HASH database. This is usually stored in the file ~/.netscape/history.db. The key field in the database is the location string and the value field is the time the location was last visited stored as a 4 byte binary value.
If you haven't already guessed, the location string is stored with a terminating NULL. This means you need to be careful when accessing the database.
Here is a snippet of code that is loosely based on Tom Christiansen's ggh script (available from your nearest CPAN archive in authors/id/TOMC/scripts/nshist.gz).
use warnings ; use strict ; use DB_File ; use Fcntl ; my ($dotdir, $HISTORY, %hist_db, $href, $binary_time, $date) ; $dotdir = $ENV{HOME} || $ENV{LOGNAME}; $HISTORY = "$dotdir/.netscape/history.db"; tie %hist_db, 'DB_File', $HISTORY or die "Cannot open $HISTORY: $!\n" ;; # Dump the complete database while ( ($href, $binary_time) = each %hist_db ) { # remove the terminating NULL $href =~ s/\x00$// ; # convert the binary time into a user friendly string $date = localtime unpack("V", $binary_time); print "$date $href\n" ; } # check for the existence of a specific key # remember to add the NULL if ( $binary_time = $hist_db{"http://mox.perl.com/\x00"} ) { $date = localtime unpack("V", $binary_time) ; print "Last visited mox.perl.com on $date\n" ; } else { print "Never visited mox.perl.com\n" } untie %hist_db ;
Even if you don't currently make use of the API interface, it is still worth reading it.
Here is an example which illustrates the problem from a DB_File perspective:
use DB_File ; use Fcntl ; my %x ; my $X ; $X = tie %x, 'DB_File', 'tst.fil' , O_RDWR|O_TRUNC or die "Cannot tie first time: $!" ; $x{123} = 456 ; untie %x ; tie %x, 'DB_File', 'tst.fil' , O_RDWR|O_CREAT or die "Cannot tie second time: $!" ; untie %x ;
When run, the script will produce this error message:
Cannot tie second time: Invalid argument at bad.file line 14.
Although the error message above refers to the second tie() statement in the script, the source of the problem is really with the untie() statement that precedes it.
Having read perltie you will probably have already guessed that the error is caused by the extra copy of the tied object stored in $X. If you haven't, then the problem boils down to the fact that the DB_File destructor, DESTROY, will not be called until all references to the tied object are destroyed. Both the tied variable, %x, and $X above hold a reference to the object. The call to untie() will destroy the first, but $X still holds a valid reference, so the destructor will not get called and the database file tst.fil will remain open. The fact that Berkeley DB then reports the attempt to open a database that is already open via the catch-all ``Invalid argument'' doesn't help.
If you run the script with the "-w" flag the error message becomes:
untie attempted while 1 inner references still exist at bad.file line 12. Cannot tie second time: Invalid argument at bad.file line 14.
which pinpoints the real problem. Finally the script can now be modified to fix the original problem by destroying the API object before the untie:
... $x{123} = 456 ; undef $X ; untie %x ; $X = tie %x, 'DB_File', 'tst.fil' , O_RDWR|O_CREAT ...
This happens because Berkeley DB uses dynamic memory to allocate buffers which will subsequently be written to the database file. Being dynamic, the memory could have been used for anything before DB malloced it. As Berkeley DB doesn't clear the memory once it has been allocated, the unused portions will contain random junk. In the case where a Perl script gets written to the database, the random junk will correspond to an area of dynamic memory that happened to be used during the compilation of the script.
Unless you don't like the possibility of there being part of your Perl scripts embedded in a database file, this is nothing to worry about.
Check out the MLDBM module, available on CPAN in the directory modules/by-module/MLDBM.
Here are a couple of possibilities:
use warnings ; use strict ; use DB_File ; my %x ; tie %x, DB_File, "filename" ;
Running it produces the error in question:
Bareword "DB_File" not allowed while "strict subs" in use
To get around the error, place the word "DB_File" in either single or double quotes, like this:
tie %x, "DB_File", "filename" ;
Although it might seem like a real pain, it is really worth the effort of having a "use strict" in all your scripts.
I am sure there are bugs in the code. If you do find any, or can suggest any enhancements, I would welcome your comments.
This version of DB_File will work with either version 1.x, 2.x or 3.x of Berkeley DB, but is limited to the functionality provided by version 1.
The official web site for Berkeley DB is http://www.oracle.com/technology/products/berkeley-db/db/index.html. All versions of Berkeley DB are available there.
Alternatively, Berkeley DB version 1 is available at your nearest CPAN archive in src/misc/db.1.85.tar.gz.
If you are running IRIX, then get Berkeley DB version 1 from http://reality.sgi.com/ariel. It has the patches necessary to compile properly on IRIX 5.3.
Although DB_File is covered by the Perl license, the library it makes use of, namely Berkeley DB, is not. Berkeley DB has its own copyright and its own license. Please take the time to read it.
Here are are few words taken from the Berkeley DB FAQ (at http://www.oracle.com/technology/products/berkeley-db/db/index.html) regarding the license:
Do I have to license DB to use it in Perl scripts? No. The Berkeley DB license requires that software that uses Berkeley DB be freely redistributable. In the case of Perl, that software is Perl, and not your scripts. Any Perl scripts that you write are your property, including scripts that make use of Berkeley DB. Neither the Perl license nor the Berkeley DB license place any restriction on what you may do with them.
If you are in any doubt about the license situation, contact either the Berkeley DB authors or the author of DB_File. See ``AUTHOR'' for details.