NAME Algorithm::AM - Perl extension for Analogical Modeling using a parallel algorithm VERSION version 2.32 AUTHOR Theron Stanford , Nathan Glenn COPYRIGHT AND LICENSE This software is copyright (c) 2013 by Royall Skousen. This is free software; you can redistribute it and/or modify it under the same terms as the Perl 5 programming language system itself. SYNOPSIS use Algorithm::AM; my $p = Algorithm::AM->new('finnverb', -commas => 'no'); $p->(); DESCRIPTION Analogical Modeling is an exemplar-based way to model language usage. "Algorithm::AM" is a Perl module which analyzes data sets using Analogical Modeling. How to create data sets is not explained here. See the appendices in the "red book", *Analogical Modeling: An exemplar-based approach to language*, for details on that. See also the "green book", *Analogical Modeling of Language*, for an explanation of the method in general, and the "blue book", *Analogy and Structure*, for its mathematical basis. METHODS "new" Arguments: see "Initializing a Project" (TODO: reorganize POD properly) Creates and returns a subroutine to classify the data in a given project. HISTORY Initially, Analogical Modeling was implemented as a Pascal program. Subsequently, it was ported to Perl, with substantial improvements made in 2000. In 2001, the core of the algorithm was rewritten in C, while the parsing, printing, and statistical routines remained in C; this was accomplished by embedding a Perl interpreter into the C code. In 2004, the algorithm was again rewritten, this time in order to handle more variables and large data sets. It breaks the supracontextual lattice into the direct product of four smaller ones, which the algorithm manipulates individually before recombining them. Because these lattices could be manipulated in parallel, using the right hardware, the module was named "AM::Parallel". Later it was renamed "Algorithm::AM" to fit better into the CPAN ecostystem. To provide more flexibility and to more closely follow "the Perl way", the C core is now an XSUB wrapped within a Perl module. Instead of specifying a configuration file, parameters are passed to the "new()" function of "Algorithm::AM". The core functionality of the module has been stripped down; the only reports available are the statistical summary, the analogical set, and the gang listings. However, hooks are provided for users to create their own reports. They can also manipulate various parameters at run time and redirect output. It is expected that future improvements will maintain a Perl interface to an XSUB. However, the design will remain simple enough that users without much programming experience will still be able to use the module with the least amount of trouble. PROJECTS "Algorithm::AM" assumes the existence of a *project*, a directory containing the data set, the test set, and the outcome file (named, not surprisingly, data, test, and outcome). Once the project is initialized, the user can set various parameters and run the algorithm. If no outcome file is given, one is created using the outcomes which appear in the data set. If no test set is given, it is assumed that the data set functions as the test set. Initializing a Project A project is initialized using the syntax *$p* = Algorithm::AM->new(*directory*, -commas => *commas*, ?*options*?); The first parameter must be the name of the directory where the files are. It can be an absolute or a relative path. The following parameter is required: -commas Tells how to parse the lines of the data file. May be set to either "yes" or "no". Any other value will trigger a warning and stop creation of the project, as will omitting this option entirely. See details in the "red book" to determine how to set this. The following options are available: -nulls Tells how to treat nulls, i.e., variables marked with an equals sign "=". Can be "include" or "exclude"; any other value will revert back to the default. Default: "exclude". -given Tells whether or not to include the test item as a data item if it is found in the data set. Can be "include" or "exclude"; any other value will revert back to the default. Default: "exclude". -linear Determines if the analogical set will be computed using *occurrences* (linearly) or *pointers* (quadratically). If "-linear" is set to "yes", the analogical set will be computed using occurrences; otherwise, it will be computed using pointers. Default: compute using pointers. -probability Sets the probability of including any one data item. Default: "undef". (TODO: what's undef do here?) -repeat Determines how many times each individual test item will be analyzed. Only makes sense if the probability is less than 1. Default: 1. -skipset Determines whether or not the analogical set is printed. Can be "yes" or "no"; any other value will revert to the default. Default: "yes". -gangs Determines whether or not gang effects will be printed. Can be one of the following three values: * "yes": Prints which contexts affect the result, how many pointers they contain, and which data items are in them. * "summary": Prints which contexts affect the result and how many pointers they contain. * "no": Omits any information about gang effects. Any other value will revert to the default. Default: "no". So, the minimal invocation to initialize a project would be something like $p = Algorithm::AM->new('finnverb', -commas => 'no'); while something fancier might be $p = Algorithm::AM->new('negpre', -commas => 'yes', -probability => 0.2, -repeat => 5, -skipset => 'no', -gangs => 'summary'); Initializing a project doesn't do anything more than read in the files and prepare them for analysis. To actually do any work, read on. Running a project To run an already initialized project with the defaults set at initialization time, use the following: $p->(); Yep, that's all there is to it. The call to "new()" in "Algorithm::AM" returns a reference to a subroutine, so to run it all you need to do is dereference it. Of course, you can override the defaults. Any of the options set at initialization can be temporarily overridden. So, for instance, you can run your project twice, once including nulls and once excluding them, as follows: $p->(-nulls => 'include'); $p->(-nulls => 'exclude'); Or, if you didn't specify a value at initialization time and accepted the default, you can merely use $p->(-nulls => 'include'); $p->(); Or you can play with the probabilities: $p->(-probability => 0.5, -repeat => 2); $p->(-probability => 0.2, -repeat => 5); $p->(-probability => 0.1, -repeat => 10); Output Output from the program is appended to the file amcpresults in the project directory by default. Internally, "Algorithm::AM" opens amcpresults at the beginning each run and selects its file handle to be current, so that the output of all "print()" statements gets directed to it. Directing output elsewhere is possible, but you can't do it the "obvious" way; the following won't work: ## do not use this code -- it is a BAD example open FH5, ">results05"; open FH2, ">results02"; open FH1, ">results01"; select FH5; $p->(-probability => 0.5, -repeat => 2); select FH2; $p->(-probability => 0.2, -repeat => 5); select FH1; $p->(-probability => 0.1, -repeat => 10); close FH1; close FH2; close FH5; That's because at the very beginning of each run, the code for $p reselects the file handle. However, you can do this using a hook; see "-beginhook" for a simple example of redirected output and "-beginrepeathook" for a more complicated one. Warnings and error messages get sent to STDERR. If there are no fatal errors and the program runs normally, status messages are sent to STDERR. You can see how long the program has been running, what test item it's currently on, and even which iteration of an individual test item it's on if the repeat is set greater than one. USING HOOKS "Algorithm::AM" provides *power* and *flexibility*. The *power* is in the C code; the *flexibility* is in the *hooks* provided for the user to interact with the algorithm at various stages. Hook Placement in "Algorithm::AM" Hooks are just references to subroutines that can be passed to the project at run time; the subroutine references can be either named or anonymous. They are passed as any other option. The following hooks are currently implemented: -beginhook This hook is called before any test items are run. -endhook This hook is called after all test items are run. Example: To send all the output from a run to another file, you can do the following: $p->(-beginhook => sub {open FH, ">myoutput"; select FH;}, -endhook => sub {close FH;}); -begintesthook This hook is called at the beginning of each new test item. If a test item will be run more than once, this hook is called just once before the first iteration. -endtesthook This hook is called at the end of each test item. If a test item will be run more than once, this hook is called just once after the last iteration. Example: If each test item is run just once, and you want to keep a running tally of how many test items are correctly predicted, you can use the variables $curTestOutcome, $pointermax, and @sum: $count = 0; $countsub = sub { ## must use eq instead of == in following statement ++$count if $sum[$curTestOutcome] eq $pointermax; }; $p->(-endtesthook => $countsub, -endhook => sub {print "Number of correct predictions: $count\n";}); -beginrepeathook This hook is called at the beginning of each iteration of a test item. -endrepeathook This hook is called at the end of each iteration of a test item. Example: To vary the probability of each iteration through a test item, you can use the variables $probability and $pass: open FH5, ">results05"; open FH2, ">results02"; $repeatsub = sub { $probability = (0.5, 0.2)[$pass]; select((FH5, FH2)[$pass]); }; $p->(-beginrepeathook => $repeatsub); Then on iteration 0, the test item is analyzed with the probability of any data item being included set to 0.5, with output sent to file results05, while on iteration 1, the test item is analyzed with the probability of any data item being included set to 0.2, with output sent to file results02. -datahook This hook is called for each data item considered during a test item run. Unlike other hooks, which receive no arguments, this hook is passed the index of the data item under consideration. The value of this index ranges from one less than the number of data items to 0 (data items are considered in reverse order in "Algorithm::AM" for various reasons not gone into here). The index passed is not a copy but the actual index variable used in "Algorithm::AM"; be careful not to change it -- for example, by assigning to $_[0] -- unless that is what is intended. This hook should return a true value (in the Perl sense of true) if the data item should still be included in the test run, and should return a false value otherwise. To ensure this, it's a good idea to end the subroutine assigned to the hook with return 1; since return; returns an undefined value. If the probability of including any data item is less than one, this hook is called *before* a call to "rand()" to see whether or not to include the item. If you don't like this, set "-probability" to 1 in the option list and call "rand()" yourself somewhere within the hook. Example: The results for *sorta-* in the "red book" do not match what you get when you run finnverb. That's because the "red book" omitted all data items with outcome *a-oi*. You can do this using the variables @curTestItem, @outcome, and %outcometonum: $datasub = sub { ## we use @curTestItem because finnverb/test has no specifiers return 1 unless join('', @curTestItem) eq 'SO0=SR0=TA'; return 1 unless $outcome[$_[0]] eq $outcometonum{'a-oi'}; return 0; }; $p->(-datahook => $datasub); Hook Variables Various variables can be read and even manipulated by the hooks. Note: All hook variables are exported into package "main". If you don't know what this means, chances are you don't need to worry about it; if you *do* know what it means, you'll know how to deal with it. However, these variables exist in package "main" only while a project is being run (they are exported using "local()"). Thus, you can only access them through a hook, and they will not clobber the values of variables of the same name outside of the run. Variables Fixed at Initialization These variables should be considered read-only, unless you're really sure what you're doing. @outcomelist This array lists all possible outcomes. It is generated either from the outcome file, if it exists, or from the outcomes that appear in the data file. If there is a "short" version and a "long" version of each outcome, @outcomelist contains the "long" version. Outcomes are assigned positive integer values; outcome 0 is reserved for internal use of "Algorithm::AM". (You'll have to look at the source code and its documentation for further details, which most likely you won't need.) Example: File finnverb/outcome is as follows: A V-i B a-oi C tV-si During initialization, "Algorithm::AM" makes a series of assignments equivalent to the following: @outcomelist = ('', 'V-i', 'a-oi', 'tV-si'); %outcometonum This hash maps outcome strings (the "long" ones that appear in @outcomelist) to their respective positions in @outcomelist. @outcome $outcome[$i] contains the outcome of data item $i as an integer index into @outcomelist. @data $data[$i] is a reference to an array containing the variables of data item $i. @spec $spec[$i] contains the specifier for data item $i. Example: Line 80 of file finnverb/data is as follows: C MU0=SR0=TA MURTA During initialization, "Algorithm::AM" makes a series of assignments equivalent to the following: $outcome[79] = 3; $data[79] = ['M', 'U', '0', '=', 'S', 'R', '0', '=', 'T', 'A']; $spec[79] = 'MURTA'; Variables Used for a Specific Test Item These variables should be considered read-only, unless you're really sure what you're doing. $curTestOutcome Contains the outcome index for the outcome of the current test item, as determined by @outcomelist, if an outcome has been specified, and 0 otherwise. @curTestItem Contains the variables of the current test item. $curTestSpec Contains the specifier of the current test item, if one has been specified, and is empty otherwise. Variables Used for a Specific Iteration of a Test Item Run $probability Setting this changes the likelihood of including any one particular data item in a test run. Note: If the option "-probability" is not set at either initialization time or at run time, setting the value of $probability inside a hook has no effect. (This is an intentional optimization; see the source code and its documentation for the reason why.) Therefore, if you plan to change the probability during test item runs, make sure to specify a value (1 is a good choice) for the option "-probability". $pass This variable indicates the current iteration of a test item run; it will range from 0 to one less than the number specified by the "-repeat" option. Note: You cannot (easily) change the number of repetitions from within a hook. You can only do this (easily) using the "-repeat" option at run time. This is because typically you want each test item to be subjected to the same number of repetitions. (But if for some reason you really want to do this, you can increase $pass so that "Algorithm::AM" will skip some passes. You're on your own figuring out which hook to put this in.) $datacap This variable determines how many data items will be considered. It is initially set to "scalar @data". However, if it is set smaller, only the first $datacap items in the data file will be considered. "Algorithm::AM" automatically truncates $datacap if it isn't an integer, so you don't have to. Example: It is often of interest to see how results change as the number of data items considered decreases. Here's one way to do it: $repeatsub = sub { $datacap = (1, 0.5, 0.25)[$pass] * scalar @data; }; $p->(-repeat => 3, -beginrepeathook => $repeatsub); Note that this will give different results than the following: $repeatsub = sub { $probability = (1, 0.5, 0.25)[$pass]; }; $p->(-probability => 1, -repeat => 3, -beginrepeathook => $repeatsub); The first way would be useful for modeling how predictions change as more examples are gathered -- say, as a child grows older (though the way it's written, it looks like the child is actually growing younger). The second way would be useful for modeling how predictions change as memory worsens -- say, as an adult grows older. Note that option "-probability" must be specified at run time if it hasn't been at initialization time; otherwise, calling the hook has no effect. Variables Available at the End of a Test Run Iteration Before looking at these variables, it is important to know what they contain. "Algorithm::AM" works with really big integers, much larger than what 32 bits can hold. The XSUB uses a special internal format for storing them. (You can read all about it in the usual place: the source code and its documentation.) However, when the XSUB has finished its computations, it converts these integers into something that the Perl code finds more useful. The scalar values returned from the XSUB are *dual-valued* scalars; they have different values depending on the context they're called in. In string context, you get a string representation of the integer. In numeric context, you get a double. For example, if $n and $d are big integers returned from the XSUB, you can write print $n/$d; to see the decimal value of the fraction you get when you divide $n by $d, because the division will use the numeric values, while print "$n/$d"; will let you see this fraction expressed as the quotient of two integers, because the quotation marks will interpolate the string values. Because of this, you can't use "==" to test if two big integers have the same value -- they might be so big that the double representation doesn't give enough accuracy to distinguish them. Use "eq" to test equality. If you need a comparison operator, you can use "bigcmp()". @sum Contains the number of pointers for each outcome index. (Remember that outcome indices start with 1.) $pointertotal Contains the total number of pointers. $pointermax Contains the maximum value among all the values in @sum. Note that there is no variable reporting which outcome has the most pointers. That's because there could be a tie, and different users treat ties in different ways. So, if you want to see which outcomes have the highest number of pointers, try something like this: @winners = (); for ($i = 1; $i < @sum; ++$i) { push @winners, $i if $sum[$i] eq $pointermax; ## use eq, not == } For another example using these variables, see "-endtesthook". Variables Useful for Formatting You may want to create your own reports. These variables can help your formatting. (They are also used by "Algorithm::AM" to format the standard reports.) $dformat Leaves enough space to hold an integer equal to the number of data items. Justifies right. $sformat Leaves enough space to hold a specifier. Justifies left. $oformat Leaves enough space to hold a "long" outcome. Justifies left. $vformat Formats a list of variables. Set "-gangs" to "yes" for an example. $pformat Leaves enough space to hold the big integer $pointertotal, and thus is big enough to hold $pointermax or any element of @sum as well. Justifies right. Note: This variable changes with each iteration of a test item. Hook Function The following function is also exported into package "main" and available for use in hooks. This is done with "local()", just as with hook variables, so it is not available outside of hooks. bigcmp() Compares two big integers, returning 1, 0, or -1 depending on whether the first argument is greater than, equal to, or less than the second argument. Remember that the syntax is different: you must write bigcmp($a, $b) instead of "$a bigcmp $b". MORE EXAMPLES Summarizing a Repeated Test Item Suppose you run each test item 5 times, each with probability 0.005, and you want to create a statistical analysis summarizing the results for each test item. Here's one way to do it: $begintest = sub { $valid = 0; @testPct = (); @testPctSq = (); $correct = 0; }; $endrepeat = sub { return unless $pointertotal; ++$valid; ++$correct if $sum[$curTestOutcome] eq $pointermax; for ($i = 1; $i < @outcomelist; ++$i) { $testPct[$i] += $sum[$i]/$pointertotal; $testPctSq[$i] += ($sum[$i]*$sum[$i])/($pointertotal*$pointertotal); } }; $endtest = sub { print "Summary for test item: $curTestSpec\n"; print "Valid runs: $valid out of 5\n\n"; print "\n" and return unless $valid; printf "$oformat Avg Std Dev\n", ""; for ($i = 1; $i < @outcomelist; ++$i) { next unless $testPct[$i]; if ($valid > 1) { printf "$oformat %7.3f%% %7.3f%%\n", $outcomelist[$i], 100 * $testPct[$i]/$valid, 100 * sqrt(($testPctSq[$i]-$testPct[$i]*$testPct[$i]/$valid)/($valid-1)); } else { printf "$oformat %7.3f%%\n", $outcomelist[$i], 100 * $testPct[$i]/$valid; } } printf "\nCorrect prediction occurred %7.3f%% (%i/5) of the time\n", 100 * $correct / 5, $correct; print "\n\n"; }; $p->(-probability => 0.005, -repeat => 5, -begintesthook => $begintest, -endrepeathook => $endrepeat, -endtesthook => $endtest); Creating a Confusion Matrix Suppose you want to compare correct outcomes with predicted outcomes. Here's one way to do it: $begin = sub { @confusion = (); }; $endrepeat = sub { if (!$pointertotal) { ++$confusion[$curTestOutcome][0]; return; } if ($sum[$curTestOutcome] eq $pointermax) { ++$confusion[$curTestOutcome][$curTestOutcome]; return; } my @winners = (); my $i; for ($i = 1; $i < @outcomelist; ++$i) { push @winners, $i if $sum[$i] == $pointermax; } my $numwinners = scalar @winners; foreach (@winners) { $confusion[$curTestOutcome][$_] += 1 / $numwinners; } }; $end = sub { my($i,$j); for ($i = 1; $i < @outcomelist; ++$i) { my $total = 0; foreach (@{$confusion[$i]}) { $total += $_; } next unless $total; printf "Test items with outcome $oformat were predicted as follows:\n", $outcomelist[$i]; for ($j = 1; $j < @outcomelist; ++$j) { my $t; next unless ($t = $confusion[$i][$j]); printf "%7.3f%% $oformat (%i/%i)\n", 100 * $t / $total, $outcomelist[$j], $t, $total; } if ($t = $confusion[$i][0]) { printf "%7.3f%% could not be predicted (%i/%i)\n", 100 * $t / $total, $t, $total; } print "\n\n"; } }; $p->(-probability => 0.005, -repeat => 5, -beginhook => $begin, -endrepeathook => $endrepeat, -endhook => $end); WARNINGS AND ERROR MESSAGES Project not specified No project was specified in the call to "Algorithm::AM->new". An empty subroutine is returned (so that batch scripts do not break). Project %s has no data file The project directory has no file named data. An empty subroutine is returned (so that batch scripts do not break). Project %s did not specify comma formatting The required parameter "-commas" was not provided. An empty subroutine is returned (so that batch scripts do not break). Project %s did not specify comma formatting correctly Parameter "-commas" must be either "yes" or "no". An empty subroutine is returned (so that batch scripts do not break). Project %s did not specify option -nulls correctly Parameter "-nulls" must be either "include" or "exclude". Displayed default value will be used. Project %s did not specify option -given correctly Parameter "-given" must be either "include" or "exclude". Displayed default value will be used. Project %s did not specify option -skipset correctly Parameter "-skipset" must be either "yes" or "no". Displayed default value will be used. Project %s did not specify option -gangs correctly Parameter "-gangs" must be either "yes", "summary", or "no". Displayed default value will be used. Couldn't open %s/test Project %s does not have a test file. The data file will be used. SEE ALSO Home page for Analogical Modeling: http://humanities.byu.edu/am/ Source code, documentation, and sample data sets are all available here. AUTHOR Theron Stanford COPYRIGHT AND LICENSE Copyright (C) 2004 by Royal Skousen