private void prettyPrint(PrintWriter pw, int indent) {
for (int i = 0; i < indent; i++) {
pw.print(" ");
}
if (neg) {
pw.print('!');
}
if (opt) {
pw.print('?');
}
pw.println(localString());
for (TregexPattern child : getChildren()) {
child.prettyPrint(pw, indent + 1);
}
}
private static void displayTree(Tree t, TreePrint tp, PrintWriter pw) {
if (t == null) {
pw.println("null");
} else {
tp.printTree(t, pw);
}
}
private static void testTransAndUntrans(
CharacterLevelTagExtender e, Treebank tb, PrintWriter pw) {
for (Tree tree : tb) {
Tree oldTree = tree.treeSkeletonCopy();
e.transformTree(tree);
CharacterLevelTagExtender.untransformTree(tree);
if (!tree.equals(oldTree)) {
pw.println("NOT EQUAL AFTER UNTRANSFORMATION!!!");
pw.println();
oldTree.pennPrint(pw);
pw.println();
tree.pennPrint(pw);
pw.println("------------------");
}
}
}
/**
* Usage: java edu.stanford.nlp.trees.tregex.tsurgeon.Tsurgeon [-s] -treeFile file-with-trees [-po
* matching-pattern operation] operation-file-1 operation-file-2 ... operation-file-n
*
* <h4>Arguments:</h4>
*
* Each argument should be the name of a transformation file that contains a list of pattern and
* transformation operation list pairs. That is, it is a sequence of pairs of a {@link
* TregexPattern} pattern on one or more lines, then a blank line (empty or whitespace), then a
* list of transformation operations one per line (as specified by <b>Legal operation syntax</b>
* below) to apply when the pattern is matched, and then another blank line (empty or whitespace).
* Note the need for blank lines: The code crashes if they are not present as separators (although
* the blank line at the end of the file can be omitted). The script file can include comment
* lines, either whole comment lines or trailing comments introduced by %, which extend to the end
* of line. A needed percent mark can be escaped by a preceding backslash.
*
* <p>For example, if you want to excise an SBARQ node whenever it is the parent of an SQ node,
* and relabel the SQ node to S, your transformation file would look like this:
*
* <blockquote>
*
* <code>
* SBARQ=n1 < SQ=n2<br>
* <br>
* excise n1 n1<br>
* relabel n2 S
* </code>
*
* </blockquote>
*
* <p>
*
* <h4>Options:</h4>
*
* <ul>
* <li><code>-treeFile <filename></code> specify the name of the file that has the trees
* you want to transform.
* <li><code>-po <matchPattern> <operation></code> Apply a single operation to
* every tree using the specified match pattern and the specified operation. Use this option
* when you want to quickly try the effect of one pattern/surgery combination, and are too
* lazy to write a transformation file.
* <li><code>-s</code> Print each output tree on one line (default is pretty-printing).
* <li><code>-m</code> For every tree that had a matching pattern, print "before" (prepended as
* "Operated on:") and "after" (prepended as "Result:"). Unoperated trees just pass through
* the transducer as usual.
* <li><code>-encoding X</code> Uses character set X for input and output of trees.
* <li><code>-macros <filename></code> A file of macros to use on the tregex pattern.
* Macros should be one per line, with original and replacement separated by tabs.
* <li><code>-hf <headfinder-class-name></code> use the specified {@link HeadFinder} class
* to determine headship relations.
* <li><code>-hfArg <string></code> pass a string argument in to the {@link HeadFinder}
* class's constructor. <code>-hfArg</code> can be used multiple times to pass in multiple
* arguments.
* <li><code>-trf <TreeReaderFactory-class-name></code> use the specified {@link
* TreeReaderFactory} class to read trees from files.
* </ul>
*
* <h4>Legal operation syntax:</h4>
*
* <ul>
* <li><code>delete <name></code> deletes the node and everything below it.
* <li><code>prune <name></code> Like delete, but if, after the pruning, the parent has
* no children anymore, the parent is pruned too. Pruning continues to affect all ancestors
* until one is found with remaining children. This may result in a null tree.
* <li><code>excise <name1> <name2></code> The name1 node should either dominate
* or be the same as the name2 node. This excises out everything from name1 to name2. All
* the children of name2 go into the parent of name1, where name1 was.
* <li><code>relabel <name> <new-label></code> Relabels the node to have the new
* label. <br>
* There are three possible forms: <br>
* <code>relabel nodeX VP</code> - for changing a node label to an alphanumeric string <br>
* <code>relabel nodeX /''/</code> - for relabeling a node to something that isn't a valid
* identifier without quoting <br>
* <code>relabel nodeX /^VB(.*)$/verb\\/$1/</code> - for regular expression based
* relabeling. In this case, all matches of the regular expression against the node label
* are replaced with the replacement String. This has the semantics of Java/Perl's
* replaceAll: you may use capturing groups and put them in replacements with $n. For
* example, if the pattern is /foo/bar/ and the node matched is "foo", the replaceAll
* semantics result in "barbar". If the pattern is /^foo(.*)$/bar$1/ and node matched is
* "foofoo", relabel will result in "barfoo". <br>
* When using the regex replacement method, you can also use the sequences ={node} and
* %{var} in the replacement string to use captured nodes or variable strings in the
* replacement string. For example, if the Tregex pattern was "duck=bar" and the relabel is
* /foo/={bar}/, "foofoo" will be replaced with "duckduck". <br>
* To concatenate two nodes named in the tregex pattern, for example, you can use the
* pattern /^.*$/={foo}={bar}/. Note that the ^.*$ is necessary to make sure the regex
* pattern only matches and replaces once on the entire node name. <br>
* To get an "=" or a "%" in the replacement, using \ escaping. Also, as in the example you
* can escape a slash in the middle of the second and third forms with \\/ and \\\\. <br>
* <li><code>insert <name> <position></code> or <code>
* insert <tree> <position></code> inserts the named node or tree into the
* position specified.
* <li><code>move <name> <position></code> moves the named node into the
* specified position.
* <p>Right now the only ways to specify position are:
* <p><code>$+ <name></code> the left sister of the named node<br>
* <code>$- <name></code> the right sister of the named node<br>
* <code>>i <name></code> the i_th daughter of the named node<br>
* <code>>-i <name></code> the i_th daughter, counting from the right, of the
* named node.
* <li><code>replace <name1> <name2></code> deletes name1 and inserts a copy of
* name2 in its place.
* <li><code>replace <name> <tree> <tree2>...</code> deletes name and
* inserts the new tree(s) in its place. If more than one replacement tree is given, each of
* the new subtrees will be added in order where the old tree was. Multiple subtrees at the
* root is an illegal operation and will throw an exception.
* <li>{@code createSubtree <new-label> <name1> [<name2>]} Create a subtree out of all the nodes
* from {@code <name1>} through {@code <name2>} and puts the new subtree where that span
* used to be. To limit the operation to just one node, elide {@code <name2>}.
* <li><code>adjoin <auxiliary_tree> <name></code> Adjoins the specified auxiliary
* tree into the named node. The daughters of the target node will become the daughters of
* the foot of the auxiliary tree.
* <li><code>adjoinH <auxiliary_tree> <name></code> Similar to adjoin, but
* preserves the target node and makes it the root of <tree>. (It is still accessible
* as <code>name</code>. The root of the auxiliary tree is ignored.)
* <li><code>adjoinF <auxiliary_tree> <name></code> Similar to adjoin, but
* preserves the target node and makes it the foot of <tree>. (It is still accessible
* as <code>name</code>, and retains its status as parent of its children. The root of the
* auxiliary tree is ignored.)
* <li>
* <dt><code>coindex <name1> <name2> ... <nameM> </code> Puts a (Penn
* Treebank style) coindexation suffix of the form "-N" on each of nodes name_1 through
* name_m. The value of N will be automatically generated in reference to the existing
* coindexations in the tree, so that there is never an accidental clash of indices across
* things that are not meant to be coindexed.
* </ul>
*
* <p>In the context of <code>adjoin</code>, <code>adjoinH</code>, and <code>adjoinF</code>, an
* auxiliary tree is a tree in Penn Treebank format with <code>@</code> on exactly one of the
* leaves denoting the foot of the tree. The operations which use the foot use the labeled node.
* For example: <br>
* Tsurgeon: <code>adjoin (FOO (BAR@)) foo</code> <br>
* Tregex: <code>B=foo</code> <br>
* Input: <code>(A (B 1 2))</code> Output: <code>(A (FOO (BAR 1 2)))</code>
*
* <p>Tsurgeon applies the same operation to the same tree for as long as the given tregex
* operation matches. This means that infinite loops are very easy to cause. One common situation
* where this comes up is with an insert operation will repeats infinitely many times unless you
* add an expression to the tregex that matches against the inserted pattern. For example, this
* pattern will infinite loop:
*
* <blockquote>
*
* <code>
* TregexPattern tregex = TregexPattern.compile("S=node << NP"); <br>
* TsurgeonPattern tsurgeon = Tsurgeon.parseOperation("insert (NP foo) >-1 node");
* </code>
*
* </blockquote>
*
* This pattern, though, will terminate:
*
* <blockquote>
*
* <code>
* TregexPattern tregex = TregexPattern.compile("S=node << NP !<< foo"); <br>
* TsurgeonPattern tsurgeon = Tsurgeon.parseOperation("insert (NP foo) >-1 node");
* </code>
*
* </blockquote>
*
* <p>Tsurgeon has (very) limited support for conditional statements. If a pattern is prefaced
* with <code>if exists <name></code>, the rest of the pattern will only execute if the
* named node was found in the corresponding TregexMatcher.
*
* @param args a list of names of files each of which contains a single tregex matching pattern
* plus a list, one per line, of transformation operations to apply to the matched pattern.
* @throws Exception If an I/O or pattern syntax error
*/
public static void main(String[] args) throws Exception {
String headFinderClassName = null;
String headFinderOption = "-hf";
String[] headFinderArgs = null;
String headFinderArgOption = "-hfArg";
String encoding = "UTF-8";
String encodingOption = "-encoding";
if (args.length == 0) {
System.err.println(
"Usage: java edu.stanford.nlp.trees.tregex.tsurgeon.Tsurgeon [-s] -treeFile <file-with-trees> [-po <matching-pattern> <operation>] <operation-file-1> <operation-file-2> ... <operation-file-n>");
System.exit(0);
}
String treePrintFormats;
String singleLineOption = "-s";
String verboseOption = "-v";
String matchedOption =
"-m"; // if set, then print original form of trees that are matched & thus operated on
String patternOperationOption = "-po";
String treeFileOption = "-treeFile";
String trfOption = "-trf";
String macroOption = "-macros";
String macroFilename = "";
Map<String, Integer> flagMap = Generics.newHashMap();
flagMap.put(patternOperationOption, 2);
flagMap.put(treeFileOption, 1);
flagMap.put(trfOption, 1);
flagMap.put(singleLineOption, 0);
flagMap.put(encodingOption, 1);
flagMap.put(headFinderOption, 1);
flagMap.put(macroOption, 1);
Map<String, String[]> argsMap = StringUtils.argsToMap(args, flagMap);
args = argsMap.get(null);
if (argsMap.containsKey(headFinderOption))
headFinderClassName = argsMap.get(headFinderOption)[0];
if (argsMap.containsKey(headFinderArgOption)) headFinderArgs = argsMap.get(headFinderArgOption);
if (argsMap.containsKey(verboseOption)) verbose = true;
if (argsMap.containsKey(singleLineOption)) treePrintFormats = "oneline,";
else treePrintFormats = "penn,";
if (argsMap.containsKey(encodingOption)) encoding = argsMap.get(encodingOption)[0];
if (argsMap.containsKey(macroOption)) macroFilename = argsMap.get(macroOption)[0];
TreePrint tp = new TreePrint(treePrintFormats, new PennTreebankLanguagePack());
PrintWriter pwOut = new PrintWriter(new OutputStreamWriter(System.out, encoding), true);
TreeReaderFactory trf;
if (argsMap.containsKey(trfOption)) {
String trfClass = argsMap.get(trfOption)[0];
trf = ReflectionLoading.loadByReflection(trfClass);
} else {
trf = new TregexPattern.TRegexTreeReaderFactory();
}
Treebank trees = new DiskTreebank(trf, encoding);
if (argsMap.containsKey(treeFileOption)) {
trees.loadPath(argsMap.get(treeFileOption)[0]);
}
List<Pair<TregexPattern, TsurgeonPattern>> ops =
new ArrayList<Pair<TregexPattern, TsurgeonPattern>>();
TregexPatternCompiler compiler;
if (headFinderClassName == null) {
compiler = new TregexPatternCompiler();
} else {
HeadFinder hf;
if (headFinderArgs == null) {
hf = ReflectionLoading.loadByReflection(headFinderClassName);
} else {
hf = ReflectionLoading.loadByReflection(headFinderClassName, (Object[]) headFinderArgs);
}
compiler = new TregexPatternCompiler(hf);
}
Macros.addAllMacros(compiler, macroFilename, encoding);
if (argsMap.containsKey(patternOperationOption)) {
TregexPattern matchPattern = compiler.compile(argsMap.get(patternOperationOption)[0]);
TsurgeonPattern p = parseOperation(argsMap.get(patternOperationOption)[1]);
ops.add(new Pair<TregexPattern, TsurgeonPattern>(matchPattern, p));
} else {
for (String arg : args) {
List<Pair<TregexPattern, TsurgeonPattern>> pairs =
getOperationsFromFile(arg, encoding, compiler);
for (Pair<TregexPattern, TsurgeonPattern> pair : pairs) {
if (verbose) {
System.err.println(pair.second());
}
ops.add(pair);
}
}
}
for (Tree t : trees) {
Tree original = t.deepCopy();
Tree result = processPatternsOnTree(ops, t);
if (argsMap.containsKey(matchedOption) && matchedOnTree) {
pwOut.println("Operated on: ");
displayTree(original, tp, pwOut);
pwOut.println("Result: ");
}
displayTree(result, tp, pwOut);
}
}
/**
* for testing -- CURRENTLY BROKEN!!!
*
* @param args input dir and output filename
* @throws IOException
*/
public static void main(String[] args) throws IOException {
if (args.length != 3) {
throw new RuntimeException("args: treebankPath trainNums testNums");
}
ChineseTreebankParserParams ctpp = new ChineseTreebankParserParams();
ctpp.charTags = true;
// TODO: these options are getting clobbered by reading in the
// parser object (unless it's a text file parser?)
Options op = new Options(ctpp);
op.doDep = false;
op.testOptions.maxLength = 90;
LexicalizedParser lp;
try {
FileFilter trainFilt = new NumberRangesFileFilter(args[1], false);
lp = LexicalizedParser.trainFromTreebank(args[0], trainFilt, op);
try {
String filename = "chineseCharTagPCFG.ser.gz";
System.err.println("Writing parser in serialized format to file " + filename + ' ');
System.err.flush();
ObjectOutputStream out = IOUtils.writeStreamFromString(filename);
out.writeObject(lp);
out.close();
System.err.println("done.");
} catch (IOException ioe) {
ioe.printStackTrace();
}
} catch (IllegalArgumentException e) {
lp = LexicalizedParser.loadModel(args[1], op);
}
FileFilter testFilt = new NumberRangesFileFilter(args[2], false);
MemoryTreebank testTreebank = ctpp.memoryTreebank();
testTreebank.loadPath(new File(args[0]), testFilt);
PrintWriter pw =
new PrintWriter(new OutputStreamWriter(new FileOutputStream("out.chi"), "GB18030"), true);
WordCatEquivalenceClasser eqclass = new WordCatEquivalenceClasser();
WordCatEqualityChecker eqcheck = new WordCatEqualityChecker();
EquivalenceClassEval eval = new EquivalenceClassEval(eqclass, eqcheck);
// System.out.println("Preterminals:" + preterminals);
System.out.println("Testing...");
for (Tree gold : testTreebank) {
Tree tree;
try {
tree = lp.parseTree(gold.yieldHasWord());
if (tree == null) {
System.out.println("Failed to parse " + gold.yieldHasWord());
continue;
}
} catch (Exception e) {
e.printStackTrace();
continue;
}
gold = gold.firstChild();
pw.println(Sentence.listToString(gold.preTerminalYield()));
pw.println(Sentence.listToString(gold.yield()));
gold.pennPrint(pw);
pw.println(tree.preTerminalYield());
pw.println(tree.yield());
tree.pennPrint(pw);
// Collection allBrackets = WordCatConstituent.allBrackets(tree);
// Collection goldBrackets = WordCatConstituent.allBrackets(gold);
// eval.eval(allBrackets, goldBrackets);
eval.displayLast();
}
System.out.println();
System.out.println();
eval.display();
}
// todo: add an option to only print each tree once, regardless. Most useful in conjunction
// with -w
public void visitTree(Tree t) {
treeNumber++;
if (printTree) {
pw.print(treeNumber + ":");
pw.println("Next tree read:");
tp.printTree(t, pw);
}
TregexMatcher match = p.matcher(t);
if (printNonMatchingTrees) {
if (match.find()) numMatches++;
else tp.printTree(t, pw);
return;
}
Tree lastMatchingRootNode = null;
while (match.find()) {
if (oneMatchPerRootNode) {
if (lastMatchingRootNode == match.getMatch()) continue;
else lastMatchingRootNode = match.getMatch();
}
numMatches++;
if (printFilename && treebank instanceof DiskTreebank) {
DiskTreebank dtb = (DiskTreebank) treebank;
pw.print("# ");
pw.println(dtb.getCurrentFilename());
}
if (printSubtreeCode) {
pw.print(treeNumber);
pw.print(':');
pw.println(match.getMatch().nodeNumber(t));
}
if (printMatches) {
if (reportTreeNumbers) {
pw.print(treeNumber);
pw.print(": ");
}
if (printTree) {
pw.println("Found a full match:");
}
if (printWholeTree) {
tp.printTree(t, pw);
} else if (handles != null) {
if (printTree) {
pw.println("Here's the node you were interested in:");
}
for (String handle : handles) {
Tree labeledNode = match.getNode(handle);
if (labeledNode == null) {
System.err.println(
"Error!! There is no matched node \""
+ handle
+ "\"! Did you specify such a label in the pattern?");
} else {
tp.printTree(labeledNode, pw);
}
}
} else {
tp.printTree(match.getMatch(), pw);
}
// pw.println(); // TreePrint already puts a blank line in
} // end if (printMatches)
} // end while match.find()
} // end visitTree
/**
* Prints out all matches of a tree pattern on each tree in the path. Usage: <br>
* <br>
* <code>
* java edu.stanford.nlp.trees.tregex.TregexPattern [[-TCwfosnu] [-filter] [-h <node-name>]]* pattern
* filepath </code>
*
* <p>Arguments:<br>
*
* <ul>
* <li><code>pattern</code>: the tree pattern which optionally names some set of nodes (i.e.,
* gives it the "handle") <code>=name</code> (for some arbitrary string "name")
* <li><code>filepath</code>: the path to files with trees. If this is a directory, there will
* be recursive descent and the pattern will be run on all files beneath the specified
* directory.
* </ul>
*
* <p>Options:<br>
* <li><code>-C</code> suppresses printing of matches, so only the number of matches is printed.
* <li><code>-w</code> causes the whole of a tree that matches to be printed.
* <li><code>-f</code> causes the filename to be printed.
* <li><code>-i <filename></code> causes the pattern to be matched to be read from <code>
* <filename></code> rather than the command line. Don't specify a pattern when this
* option is used.
* <li><code>-o</code> Specifies that each tree node can be reported only once as the root of a
* match (by default a node will be printed once for every <em>way</em> the pattern matches).
* <li><code>-s</code> causes trees to be printed all on one line (by default they are pretty
* printed).
* <li><code>-n</code> causes the number of the tree in which the match was found to be printed
* before every match.
* <li><code>-u</code> causes only the label of each matching node to be printed, not complete
* subtrees.
* <li><code>-t</code> causes only the yield (terminal words) of the selected node to be printed
* (or the yield of the whole tree, if the <code>-w</code> option is used).
* <li><code>-encoding <charset_encoding></code> option allows specification of character
* encoding of trees..
* <li><code>-h <node-handle></code> If a <code>-h</code> option is given, the root tree
* node will not be printed. Instead, for each <code>node-handle</code> specified, the node
* matched and given that handle will be printed. Multiple nodes can be printed by using the
* <code>-h</code> option multiple times on a single command line.
* <li><code>-hf <headfinder-class-name></code> use the specified {@link HeadFinder} class
* to determine headship relations.
* <li><code>-hfArg <string></code> pass a string argument in to the {@link HeadFinder}
* class's constructor. <code>-hfArg</code> can be used multiple times to pass in multiple
* arguments.
* <li><code>-trf <TreeReaderFactory-class-name></code> use the specified {@link
* TreeReaderFactory} class to read trees from files.
* <li><code>-v</code> print every tree that contains no matches of the specified pattern, but
* print no matches to the pattern.
* <li><code>-x</code> Instead of the matched subtree, print the matched subtree's identifying
* number as defined in <tt>tgrep2</tt>:a unique identifier for the subtree and is in the form
* s:n, where s is an integer specifying the sentence number in the corpus (starting with 1),
* and n is an integer giving the order in which the node is encountered in a depth-first
* search starting with 1 at top node in the sentence tree.
* <li><code>-extract <code> <tree-file></code> extracts the subtree s:n specified by
* <tt>code</tt> from the specified <tt>tree-file</tt>. Overrides all other behavior of
* tregex. Can't specify multiple encodings etc. yet.
* <li><code>-extractFile <code-file> <tree-file></code> extracts every subtree
* specified by the subtree codes in <tt>code-file</tt>, which must appear exactly one per
* line, from the specified <tt>tree-file</tt>. Overrides all other behavior of tregex. Can't
* specify multiple encodings etc. yet.
* <li><code>-filter</code> causes this to act as a filter, reading tree input from stdin
* <li><code>-T</code> causes all trees to be printed as processed (for debugging purposes).
* Otherwise only matching nodes are printed.
* <li><code>-macros <filename></code> filename with macro substitutions to use. file with
* tab separated lines original-tab-replacement
* </ul>
*/
public static void main(String[] args) throws IOException {
Timing.startTime();
StringBuilder treePrintFormats = new StringBuilder();
String printNonMatchingTreesOption = "-v";
String subtreeCodeOption = "-x";
String extractSubtreesOption = "-extract";
String extractSubtreesFileOption = "-extractFile";
String inputFileOption = "-i";
String headFinderOption = "-hf";
String headFinderArgOption = "-hfArg";
String trfOption = "-trf";
String headFinderClassName = null;
String[] headFinderArgs = StringUtils.EMPTY_STRING_ARRAY;
String treeReaderFactoryClassName = null;
String printHandleOption = "-h";
String markHandleOption = "-k";
String encodingOption = "-encoding";
String encoding = "UTF-8";
String macroOption = "-macros";
String macroFilename = "";
String yieldOnly = "-t";
String printAllTrees = "-T";
String quietMode = "-C";
String wholeTreeMode = "-w";
String filenameOption = "-f";
String oneMatchPerRootNodeMode = "-o";
String reportTreeNumbers = "-n";
String rootLabelOnly = "-u";
String oneLine = "-s";
Map<String, Integer> flagMap = Generics.newHashMap();
flagMap.put(extractSubtreesOption, 2);
flagMap.put(extractSubtreesFileOption, 2);
flagMap.put(subtreeCodeOption, 0);
flagMap.put(printNonMatchingTreesOption, 0);
flagMap.put(encodingOption, 1);
flagMap.put(inputFileOption, 1);
flagMap.put(printHandleOption, 1);
flagMap.put(markHandleOption, 2);
flagMap.put(headFinderOption, 1);
flagMap.put(headFinderArgOption, 1);
flagMap.put(trfOption, 1);
flagMap.put(macroOption, 1);
flagMap.put(yieldOnly, 0);
flagMap.put(quietMode, 0);
flagMap.put(wholeTreeMode, 0);
flagMap.put(printAllTrees, 0);
flagMap.put(filenameOption, 0);
flagMap.put(oneMatchPerRootNodeMode, 0);
flagMap.put(reportTreeNumbers, 0);
flagMap.put(rootLabelOnly, 0);
flagMap.put(oneLine, 0);
Map<String, String[]> argsMap = StringUtils.argsToMap(args, flagMap);
args = argsMap.get(null);
if (argsMap.containsKey(encodingOption)) {
encoding = argsMap.get(encodingOption)[0];
System.err.println("Encoding set to " + encoding);
}
PrintWriter errPW = new PrintWriter(new OutputStreamWriter(System.err, encoding), true);
if (argsMap.containsKey(extractSubtreesOption)) {
List<String> subTreeStrings =
Collections.singletonList(argsMap.get(extractSubtreesOption)[0]);
extractSubtrees(subTreeStrings, argsMap.get(extractSubtreesOption)[1]);
return;
}
if (argsMap.containsKey(extractSubtreesFileOption)) {
List<String> subTreeStrings =
Arrays.asList(
IOUtils.slurpFile(argsMap.get(extractSubtreesFileOption)[0]).split("\n|\r|\n\r"));
extractSubtrees(subTreeStrings, argsMap.get(extractSubtreesFileOption)[0]);
return;
}
if (args.length < 1) {
errPW.println(
"Usage: java edu.stanford.nlp.trees.tregex.TregexPattern [-T] [-C] [-w] [-f] [-o] [-n] [-s] [-filter] [-hf class] [-trf class] [-h handle]* pattern [filepath]");
return;
}
String matchString = args[0];
if (argsMap.containsKey(macroOption)) {
macroFilename = argsMap.get(macroOption)[0];
}
if (argsMap.containsKey(headFinderOption)) {
headFinderClassName = argsMap.get(headFinderOption)[0];
errPW.println("Using head finder " + headFinderClassName + "...");
}
if (argsMap.containsKey(headFinderArgOption)) {
headFinderArgs = argsMap.get(headFinderArgOption);
}
if (argsMap.containsKey(trfOption)) {
treeReaderFactoryClassName = argsMap.get(trfOption)[0];
errPW.println("Using tree reader factory " + treeReaderFactoryClassName + "...");
}
if (argsMap.containsKey(printAllTrees)) {
TRegexTreeVisitor.printTree = true;
}
if (argsMap.containsKey(inputFileOption)) {
String inputFile = argsMap.get(inputFileOption)[0];
matchString = IOUtils.slurpFile(inputFile, encoding);
String[] newArgs = new String[args.length + 1];
System.arraycopy(args, 0, newArgs, 1, args.length);
args = newArgs;
}
if (argsMap.containsKey(quietMode)) {
TRegexTreeVisitor.printMatches = false;
TRegexTreeVisitor.printNumMatchesToStdOut = true;
}
if (argsMap.containsKey(printNonMatchingTreesOption)) {
TRegexTreeVisitor.printNonMatchingTrees = true;
}
if (argsMap.containsKey(subtreeCodeOption)) {
TRegexTreeVisitor.printSubtreeCode = true;
TRegexTreeVisitor.printMatches = false;
}
if (argsMap.containsKey(wholeTreeMode)) {
TRegexTreeVisitor.printWholeTree = true;
}
if (argsMap.containsKey(filenameOption)) {
TRegexTreeVisitor.printFilename = true;
}
if (argsMap.containsKey(oneMatchPerRootNodeMode)) TRegexTreeVisitor.oneMatchPerRootNode = true;
if (argsMap.containsKey(reportTreeNumbers)) TRegexTreeVisitor.reportTreeNumbers = true;
if (argsMap.containsKey(rootLabelOnly)) {
treePrintFormats.append(TreePrint.rootLabelOnlyFormat).append(',');
} else if (argsMap.containsKey(oneLine)) { // display short form
treePrintFormats.append("oneline,");
} else if (argsMap.containsKey(yieldOnly)) {
treePrintFormats.append("words,");
} else {
treePrintFormats.append("penn,");
}
HeadFinder hf = new CollinsHeadFinder();
if (headFinderClassName != null) {
Class[] hfArgClasses = new Class[headFinderArgs.length];
for (int i = 0; i < hfArgClasses.length; i++) hfArgClasses[i] = String.class;
try {
hf =
(HeadFinder)
Class.forName(headFinderClassName)
.getConstructor(hfArgClasses)
.newInstance(
(Object[])
headFinderArgs); // cast to Object[] necessary to avoid varargs-related
// warning.
} catch (Exception e) {
throw new RuntimeException("Error occurred while constructing HeadFinder: " + e);
}
}
TRegexTreeVisitor.tp =
new TreePrint(treePrintFormats.toString(), new PennTreebankLanguagePack());
try {
// TreePattern p = TreePattern.compile("/^S/ > S=dt $++ '' $-- ``");
TregexPatternCompiler tpc = new TregexPatternCompiler(hf);
Macros.addAllMacros(tpc, macroFilename, encoding);
TregexPattern p = tpc.compile(matchString);
errPW.println("Pattern string:\n" + p.pattern());
errPW.println("Parsed representation:");
p.prettyPrint(errPW);
String[] handles = argsMap.get(printHandleOption);
if (argsMap.containsKey("-filter")) {
TreeReaderFactory trf = getTreeReaderFactory(treeReaderFactoryClassName);
treebank =
new MemoryTreebank(
trf, encoding); // has to be in memory since we're not storing it on disk
// read from stdin
Reader reader = new BufferedReader(new InputStreamReader(System.in, encoding));
((MemoryTreebank) treebank).load(reader);
reader.close();
} else if (args.length == 1) {
errPW.println("using default tree");
TreeReader r =
new PennTreeReader(
new StringReader(
"(VP (VP (VBZ Try) (NP (NP (DT this) (NN wine)) (CC and) (NP (DT these) (NNS snails)))) (PUNCT .))"),
new LabeledScoredTreeFactory(new StringLabelFactory()));
Tree t = r.readTree();
treebank = new MemoryTreebank();
treebank.add(t);
} else {
int last = args.length - 1;
errPW.println("Reading trees from file(s) " + args[last]);
TreeReaderFactory trf = getTreeReaderFactory(treeReaderFactoryClassName);
treebank = new DiskTreebank(trf, encoding);
treebank.loadPath(args[last], null, true);
}
TRegexTreeVisitor vis = new TRegexTreeVisitor(p, handles, encoding);
treebank.apply(vis);
Timing.endTime();
if (TRegexTreeVisitor.printMatches) {
errPW.println("There were " + vis.numMatches() + " matches in total.");
}
if (TRegexTreeVisitor.printNumMatchesToStdOut) {
System.out.println(vis.numMatches());
}
} catch (IOException e) {
e.printStackTrace();
} catch (TregexParseException e) {
errPW.println("Error parsing expression: " + args[0]);
errPW.println("Parse exception: " + e.toString());
}
}