AMPLE Reference Manual A Morphological Parser for Linguistic Exploration version 3.6 June 2002 by Stephen McConnel and H. Andrew Black Copyright (C) 2000-2002 SIL International Published by: Language Software Development SIL International 7500 W. Camp Wisdom Road Dallas, TX 75236 U.S.A. Permission is granted to make and distribute verbatim copies of this file provided the copyright notice and this permission notice are preserved in all copies. The author may be reached at the address above or via email as `steve@acadcomp.sil.org'. Introduction to the AMPLE program ********************************* Since it was released in 1988, the AMPLE program has been used for morphological analysis in many different languages. It is a complex program designed to tackle a complex problem. This manual is intended for reference purposes, to clarify fine points of input and behavior. It is not designed as a tutorial or as a "cookbook" of how to use AMPLE. AMPLE uses a plethora of input files to control its behavior. These include two mandatory control files (the analysis data file and dictionary code table file), two optional control files (the dictionary orthography change table file and text control file), and a set of dictionary files. The format of each of these files is described in this manual. New features ............ 1. Version 3.1 (July 1998) introduced enhanced multibyte character handling, especially with regard to capitalization. 2. Version 3.2 (October 1998) introduced reduplication patterns in the allomorph fields of the dictionary files. 3. Version 3.3 (May 1999) introduced punctuation environment constraints in the allomorph fields of the dictionary files. These are handled by a new built-in test called PEC_ST. This version also added two punctuation-oriented clauses to user-written tests. 4. Version 3.3.4 (November 1999) added XAMPLE compilation to the standard distribution, and added the `\patr' field to the analysis data file for use by XAMPLE in controlling the PCPATR word parser. 5. Version 3.3.7 (January 2000) added the `PromoteDefAtoms' value to the `\patr' field in the analysis data file for use by XAMPLE in controlling the PCPATR word parser. 6. Version 3.3.10 (April 2000) added the `PropertyIsFeature' value to the `\patr' field in the analysis data file for use by XAMPLE in controlling the PCPATR word parser. 7. Version 3.4.0 (July 2001) added the `\\catcr' field in the analysis data file for words which consist solely of compound roots (i.e. no affixes). It indicates whether the category of the word (i.e. the content of the `\\cat' field in the analysis file) should come from the leftmost or the rightmost root in the compound. The field content should be either `left' or `right'. 8. Version 3.5.0 (March 2002) added the `\\ancc' field in the analysis data file for use by XAMPLE for handling allomorphs never co-occur constraints. 9. Version 3.6.0 (June 2002) allows for an orderclass pair (min, max) which delimits the order class span of the affix. Running AMPLE ************* AMPLE is a batch process oriented program. It reads a number of control files, and then processes one or more input text files to produce an equal number of output analysis files. AMPLE Command Options ===================== The AMPLE program uses an old-fashioned command line interface following the convention of options starting with a dash character (`-'). The available options are listed below in alphabetical order. Those options which require an argument have the argument type following the option letter. `-a' causes debugging output for allomorph conditions. `-b' allows the allomorph identifiers to be stored in memory. (This feature was added to support LinguaLinks.) `-c character' selects the control file comment character. The default is the vertical bar (`|'). `-d number' selects the maximum dictionary trie depth. The default is 2, which favors reduced memory needs over speed. `-e filename' selects the PCPATR grammar file for XAMPLE to use. (XAMPLE is a version of AMPLE that adds a PCPATR style word parser to AMPLE.) This option is not recognized by AMPLE. `-f filename' opens a command file containing the names of the control and data files. The default is to read those names from the standard input (keyboard); see `Program Interaction' below. `-g' causes root glosses to be output in the analysis file, and enables the internal code `G' in the dictionary code table. `-i filename' selects a single input text file. `-m' monitors progress of an analysis: `*' means an analysis failure, `.' means a single analysis, `2'-`9' means 2-9 ambiguities, and `>' means 10 or more ambiguities. This is not compatible with the `-q' option. `-n number' sets the maximum recommended morphname length. Any morphnames longer than `number' characters are truncated (with a warning message). `-o filename' selects a single output analysis file. `-q' causes AMPLE to operate "quietly" with minimal screen output. This is not compatible with the `-m' option. `-p' causes ambiguous word percentages to be reported. `-r' checks references to morphnames in all tests. `-s filename' opens a file contains morphnames (or allomorphs) for a selective analysis. This is usually used together with the `-t' (trace) option. `-t' causes analyses to be traced. This produces a huge amount of output. Repeating the `-t' option causes SGML style trace output to be produced. `-u' signals that dictionaries are unified, not split into prefix, infix, suffix, and root files. `-w fields' selects one or more of these optional output fields for writing to the analysis file: `d' enables writing the `\d' (morpheme decomposition) field `p' enables writing the `\p' (properties) field `w' enables writing the `\w' (original word) field The default is to ask interactively about the `\d' and `\w' fields, and to write the `\p' field without asking. All three fields can be selected for output by `-w dpw' or by `-w d -w p -w w'. `-x fields' prevents one or more of these optional output fields from being written to the analysis file: `d' disables writing the `\d' (morpheme decomposition) field `p' disables writing the `\p' (properties) field `w' disables writing the `\w' (original word) field The default is to ask interactively about the `\d' and `\w' fields, and to write the `\p' field without asking. All three fields can be excluded from output by `-x dpw' or by `-x d -x p -x w'. `-v' verifies tests by pretty printing the parse trees. The following options exist only in beta-test versions of the program, since they are used only for debugging. `-/' increments the debugging level. The default is zero (no debugging output). `-z filename' opens a file for recording a memory allocation log. `-Z address,count' traps the program at the point where `address' is allocated or freed for the `count''th time. Program Interaction =================== If the `-f', `-i', and `-o' command options are not used, AMPLE prompts for a number of file names, reading the standard input for the desired values. The interactive dialog goes like this: C> ample AMPLE: A Morphological Parser for Linguistic Exploration Version 3.0b9 (April 4, 1997), Copyright 1997 SIL, Inc. Beta test version compiled Apr 4 1997 12:18:27 Analysis Performed Wed Apr 4 14:41:02 1997 Analysis data file (xxAD01.CTL): hgad01.ctl Dictionary code table (xxANCD.TAB or xxGyCD.TAB): hgancd.tab Dictionary orthography change table (xxORDC.TAB) [none]: Suffix dictionary file (xxSF01.DIC): hgsf01.dic 8 changes loaded from suffix dictionary code table. SUFFIX DICTIONARY: Loaded 116 records Root dictionary file (xxRTnn.DIC): hgrt01.dic 7 changes loaded from root dictionary code table. ROOT DICTIONARY: Loaded 43 records Next Root dictionary file (xxRTnn.DIC) [no more]: Text Control File (xxINTX.CTL) [none]: hgintx.ctl Include the original word in the output (Y or N) [n]? y Include the morpheme decomposition in the output (Y or N) [n]? y First Input file: hgtest.txt Output file: hgtest.ana INPUT: 78 words processed. Next Input file [no more]: C> Note that each prompt contains a reminder of the expected form of the answer in parentheses and ends with a colon. Several of the prompts also contain the default answer in brackets. Using the command options does not change the appearance of the program screen output significantly, but the program displays the answers to each of its prompts without waiting for input. Assume that the file `hgtest.cmd' contains the following, which is the same as the answers given above: hgad01.ctl hgancd.tab hgsf01.dic hgrt01.dic hgintx.ctl y y Then running AMPLE with the command options produces screen output like the following: C> ample -f hgtest.cmd -i hgtest.txt -o hgtest.ana AMPLE: A Morphological Parser for Linguistic Exploration Version 3.0b9 (April 4, 1997), Copyright 1997 SIL, Inc. Beta test version compiled Apr 4 1997 12:18:27 Analysis Performed Wed Apr 4 14:41:32 1997 Analysis data file (xxAD01.CTL): hgad01.ctl Dictionary code table (xxANCD.TAB or xxGyCD.TAB): hgancd.tab Dictionary orthography change table (xxORDC.TAB) [none]: Suffix dictionary file (xxSF01.DIC): hgsf01.dic 8 changes loaded from suffix dictionary code table. SUFFIX DICTIONARY: Loaded 116 records Root dictionary file (xxRTnn.DIC): hgrt01.dic 7 changes loaded from root dictionary code table. ROOT DICTIONARY: Loaded 43 records Next Root dictionary file (xxRTnn.DIC) [no more]: Text Control File (xxINTX.CTL) [none]: hgintx.ctl Include the original word in the output (Y or N) [n]? y Include the morpheme decomposition in the output (Y or N) [n]? y INPUT: 78 words processed. C> The only difference in the screen output is that the prompts for the input text file and the output analysis file are not displayed. Standard format *************** The input control files that AMPLE reads and the output analysis files that AMPLE writes are all "standard format" files. This means that the files are divided into records and fields. Each file contains at least one record, and some files may contain a large number of records. Each record contains one or more fields. Each field occupies at least one line, and is marked by a "field code" at the beginning of the line. A field code begins with a backslash character (`\'), and contains 1 or more printing characters (usually alphabetic) in addition. If the file is designed to have multiple records, then one of the field codes must be designated to be the "record marker", and every record begins with that field, even if it is empty apart from the field code. If the file contains only one record, then the relative order of the fields is constrained only by their semantics. It is worth emphasizing that field codes must be at the _beginning_ of a line. Even a single space before the backslash character prevents it from being recognized as a field code. It is also worth emphasizing that record markers _must_ be present even if that field has no information for that record. Omitting the record marker causes two records to be merge into a single record, with unpredictable results. Analysis Data File ****************** The primary control file for the AMPLE program is called the "analysis data file". It is a standard format file containing a single data record. Analysis Data File Fields ========================= The fields that AMPLE recognizes for the analysis data file are described below. Fields that start with any other backslash codes are ignored by AMPLE. Allomorphs Never Co-occur Constraint: \ancc ------------------------------------------- Allomorphs Never Co-occur constraints are valid only for XAMPLE. An allomorphs never co-occur constraint is defined by the `\ancc' field code followed by one or more allomorph identification strings, and finally an allomorphs never co-occur environment. This constraint states that the indicated allomorph identification strings may never co-occur. If there is more than one environment, the various environments are logically ANDed together (i.e. when all of the indicated environments are found, then the constraint will fail; if some, but not all, of the environments are found, then the constraint will succeed). For the syntax of allomorphs never co-occur constraints, see `Allomorphs Never Co-occur Constraint Syntax' below. If no `\ancc' fields appear in the analysis data file, then AMPLE does not eliminate any analyses by the `ANCC_FT' test. Allomorph properties: \ap ------------------------- Allomorph properties are defined by the field code `\ap' followed by one or more allomorph property names. An allomorph property name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. A maximum of 255 properties (including both allomorph and morpheme properties) may be defined. Any number of `\ap' fields may be used so long as the number of property names does not exceed 255. If no `\ap' fields appear in the analysis data file, then AMPLE does not allow allomorph properties to be used in the dictionary files or in the tests. Categories: \ca --------------- Categories are defined by the field code `\ca' followed by one or more category names. A category name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. A maximum of 255 categories may be defined. Any number of `\ca' fields may be used so long as the number of category names does not exceed 255. If no `\ca' fields appear in the analysis data file, then AMPLE does not allow categories to be used in the dictionary entries or in the tests. This is inconceivable for AMPLE's model of morphology. Category output control: \cat ----------------------------- The category information to write to the analysis output file is defined by the field code `\cat' followed by one or two words. The first word must be either `prefix' or `suffix' (or an abbreviation of one of those words), either capitalized or lowercase. The second word, if present, must be `morpheme' (or an abbreviation thereof), either capitalized or lowercase. In addition, the `\catcr' further defines what category to use for the case that a word consists solely of compound roots. The `\cat' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\cat' fields appear in the analysis data file, then AMPLE does not write any category information to the output file. Category output control for compound roots: \catcr -------------------------------------------------- The `\catcr' defines what category to output in the analysis output file for the case when a word consists solely of compound roots. The first word must be either `left' or `right' (or an abbreviation of one of those words), either capitalized or lowercase. If the word is `left', then the category of the leftmost root in the compound will be used. If the word is `right', then the category of the rightmost root in the compound will be used. If a `\cat' field appears, but no `\catcr' field, then the default is to use the rightmost root. The `\catcr' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\cat' field appears in the analysis data file, then AMPLE does not write any category information to the output file, regardless of the setting of the `\catcr' field. That is, the `\catcr' field has no effect whatsoever unless the `\cat' field is also present. Category class: \ccl -------------------- A category class is defined by the field code `\ccl' followed by the class name, which is followed in turn by one or more category names or (previously defined) category class names. A category class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. The category names must have been defined by an earlier `\ca' field. Each `\ccl' field defines a single category class. Any number of `\ccl' fields may appear in the file. If no `\ccl' fields appear in the analysis data file, then AMPLE does not allow any category classes to be used in tests or morpheme environment constraints. Compound root category pair: \cr -------------------------------- An allowable compound root category pair is defined by the `\cr' field code followed by two category names previously defined in a `\ca' field. The order of the category names is significant. Any number of compound root category pairs may be declared. If compound roots are not allowed by a `\maxr' field, then the compound root category pairs are ignored. If no `\cr' fields appear in the analysis data file, then AMPLE does not allow any compound roots. This is, of course, immaterial if the maximum number of roots is one (1). Dictionary decapitalization control: \dicdecap ---------------------------------------------- The `\dicdecap' field indicates that allomorph strings in dictionary entries should be decapitalized. Only the field code is significant; anything else in the field is ignored. The `\dicdecap' field may appear any number of times, but once is enough. If no `\dicdecap' fields appear in the analysis data file, then AMPLE stores dictionary entries verbatim without decapitalizing allomorph strings. Final test: \ft --------------- A final test is defined by the `\ft' field code followed by the test name and possibly a test body. The test body is not needed if the test name is that of a built-in test (either MEC_FT or MCC_FT), or a previously defined successor test that is to be used as a final test. Any number of final tests may be defined in the file. For details about the syntax of final tests, see `Test Syntax' below. If no `\ft' fields appear in the analysis data file, AMPLE still applies the built-in final tests MEC_FT and MCC_FT. Infix ad hoc pair: \iah ----------------------- An infix ad hoc pair is defined by the `\iah' field code followed by two morpheme identifiers. The first morphname may belong to a prefix, root, or suffix depending on what is allowed by the infix dictionary entries. The second must belong to an infix. Any number of infix ad hoc pairs may be defined in the file. However, their use is strongly discouraged on linguistic grounds. If no `\iah' fields appear in the analysis data file, then AMPLE never eliminates any analyses via the infix `ADHOC_ST' test. Infix successor test: \it ------------------------- An infix successor test is defined by the `\it' field code followed by the test name and possibly a test body. The test body is not needed if the test name is that of a built-in test (either SEC_ST ADHOC_ST, or PEC_ST), or a previously defined prefix test that is to be used as an infix test. Infix tests are applied in the order they appear in the analysis data file. If not explicitly listed, SEC_ST, ADHOC_ST, and PEC_ST are applied after all the user-defined infix tests. Any number of infix successor tests may be defined in the file. For the syntax of successor tests, see `Test Syntax' below. If no `\it' fields appear in the analysis data file, AMPLE still applies the built-in infix tests SEC_ST, ADHOC_ST and PEC_ST. Maximum number of infixes: \maxi -------------------------------- The maximum number of infixes that may appear in a word is defined by the `\maxi' field code followed by a number greater than or equal to zero. The `\maxi' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\maxi' fields appear in the analysis data file, then AMPLE assumes that the language does not have infixes. Maximum number of null allomorphs: \maxnull ------------------------------------------- The maximum number of null allomorphs that may appear in a word is defined by the `\maxnull' field code followed by a number greater than or equal to zero. The `\maxnull' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\maxnull' fields appear in the analysis data file, then AMPLE limits the number of null allomorphs in a word to ten (10). Maximum number of prefixes: \maxp --------------------------------- The maximum number of prefixes that may appear in a word is defined by the `\maxp' field code followed by a number greater than or equal to zero. The `\maxp' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\maxp' fields appear in the analysis data file, then AMPLE assumes that the language does not have prefixes. Maximum number of properties: \maxprops --------------------------------------- The maximum number of properties that can be defined can be increased from the default of 255 by giving the `\maxprops' field code followed by a number greater than or equal to 255 but less than 65536. The `\maxprops' field may appear any number of times, but once is enough. If more than one such field occurs, the one containing the largest valid value is the one that is used. The `\maxprops' must be used before any properties are defined. This is the case for both morpheme and allomorph properties. If no `\maxprops' fields appear in the analysis data file, then AMPLE limits the number of properties which can be defined to 255. Maximum number of roots: \maxr ------------------------------ The maximum number of roots that may appear in a word is defined by the `\maxr' field code followed by a number greater than or equal to one. The `\maxr' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\maxr' fields appear in the analysis data file, then AMPLE assumes that only a single root can appear in a word. Maximum number of suffixes: \maxs --------------------------------- The maximum number of suffixes that may appear in a word is defined by the `\maxs' field code followed by a number greater than or equal to zero. The `\maxs' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\maxs' fields appear in the analysis data file, then AMPLE assumes that up to 100 suffixes can occur in a word. Morpheme Co-occurrence Constraint: \mcc --------------------------------------- A morpheme co-occurrence constraint is defined by the `\mcc' field code followed by one or more morpheme names or morpheme class names, and finally a morpheme environment constraint. Each morpheme class name must be enclosed in square brackets, and must have been defined by a prior `\mcl' field. For the syntax of morpheme co-occurrence constraints, see `Morpheme Co-occurrence Constraint Syntax' below. If no `\mcc' fields appear in the analysis data file, then AMPLE does not eliminate any analyses by the `MCC_FT' test. Morpheme class: \mcl -------------------- A morpheme class is defined by the `\mcl' field code followed by the class name, which is followed in turn by one or more morpheme names or (previously defined) morpheme class names. A morpheme class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. The morpheme names should be defined by an entry in one of the dictionary files. Each `\mcl' field defines a single morpheme class. Any number of `\mcl' fields may appear in the file. If no `\mcl' fields appear in the analysis data file, then AMPLE does not allow any morpheme classes in morpheme environment constraints or tests. Morpheme properties: \mp ------------------------ Morpheme properties are defined by the field code `\mp' followed by one or more morpheme property names. An morpheme property name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. A maximum of 255 properties (including both allomorph and morpheme properties) may be defined. Any number of `\mp' fields may be used so long as the number of property names does not exceed 255. If no `\mp' fields appear in the analysis data file, then AMPLE does not allow any morpheme properties in dictionary files or tests. Prefix ad hoc pair: \pah ------------------------ A prefix ad hoc pair is defined by the `\pah' field code followed by two morpheme identifiers. The first morphname may belong to either a prefix or an infix (if infixes exist and can mingle with prefixes). The second must belong to an prefix. Any number of prefix ad hoc pairs may be defined in the file. However, their use is strongly discouraged on linguistic grounds. If no `\pah' fields appear in the analysis data file, then AMPLE never eliminates any analyses via the prefix `ADHOC_ST' test. Word parser parameter settings: \patr ------------------------------------- The `\patr' field is recognized only by XAMPLE, not by AMPLE, and has effect only if a grammar file is selected by the `-e' command line option. Each instance of this field sets one of the PCPATR control parameters. Several instances of the field can occur in the analysis data file in order to set several different parameters. Each field contains a parameter name followed by an argument giving its value. These parameters and allowable arguments are discussed below. Note that the parameter names and arguments following the `\patr' field code are not case sensitive: `ON' is the same as `On', which is the same as `on'. Also, the parameter names and arguments may be abbreviated to the shortest unique value: `off' could be written `of', since that is sufficient to distinguish it from `on'. `CheckCycles' This parameter controls a check against introducing cycles into the parse chart. This makes the parse safer, but slows it down. Legal grammars should not introduce cycles, but it can happen while developing grammars. `\patr CheckCycles ON' enables this check, and `\patr CheckCycles OFF' disables it. The default is `ON'. `DebuggingLevel' This parameter specifies the amount of PCPATR debugging information which will be written to the log file. Its argument is a number greater than or equal to zero. If zero, then no extra debugging information will be written to the log file. The default value is `0'. NOTE: this parameter is most useful for the programmer. It can produce _huge_ amounts of cryptic output. `FeatureStyle' This parameter controls the way that feature structures are written to either the output analysis file or the log file, but not whether they are written. `\patr FeatureStyle Full' causes features to be displayed in an indented format that makes obvious the embedded structure of each feature. `\patr FeatureStyle Flat' causes features to be displayed in a flat, linear string that uses less space. The default style is `Flat'. `MaxAmbiguity' This parameter controls the maximum number of different parses for a particular AMPLE word analysis that will be written to either the output analysis file or the log file. Its argument is a number greater than or equal to one. The default maximum is 10. `PromoteDefAtoms' This parameter controls whether default atomic feature values loaded from the lexicon are "promoted" to ordinary atomic feature values before parsing begins. `\patr PromoteDefAtoms On' causes default atomic values to be promoted. `\patr PromoteDefAtoms Off' causes parsing to use default atomic values still marked as default. (This can affect feature unification since a conflicting default value does not cause a failure: the default value merely disappears.) The default value is `On'. `PropertyIsFeature' This parameter controls whether the values in the AMPLE analysis `\p' (property) field are to be interpreted as feature template names, the same as the values in the AMPLE analysis `\fd' (feature descriptor) field. `\patr PropertyIsFeature On' turns on this behavior, and `\patr PropertyIsFeature Off' turns it off. The default value is `On'. `ShowAllFeatures' This parameter controls whether the feature structures for all nodes in the parse tree are written to the output files, or just the feature structure for the top node in the parse tree. `\patr ShowAllFeatures On' causes features for all nodes to be written. `\patr ShowAllFeatures Off' causes only the feature structure for the top node of the parse to be written. The default value is `On'. `ShowFailures' This parameter controls how the parser handles parse failures. An AMPLE analysis may fail to parse either by failing the feature constraints or by failing the phrase structure rules. `\patr ShowFailures On' causes partial results indicating the cause of parse failures to be written to the log file. `\patr ShowFailures Off' prevents any extra output to the log file. The default value is `Off'. NOTE: since the purpose of using the PCPATR word parser in XAMPLE is to weed out incorrect AMPLE analyses, a large number of parse failures are to be expected, which can cause _huge_ log files. This parameter is best used in conjunction with the `-t' command line option when tracing the analysis of a single word, or a small number of words. `ShowFeatures' This parameter controls whether or not any feature structures are written to the output analysis file or the log file. It does not affect any of the other parameters related to how feature structures are written. `\patr ShowFeatures On' enables writing feature structures to the output files. `\patr ShowFeatures Off' disables writing feature structures. The default value is `On'. `ShowGlosses' This parameter controls whether morpheme glosses are displayed in the parse tree output. `\patr ShowGlosses On' enables writing glosses in the parse tree output. `\patr ShowGlosses Off' disables writing glosses. If no morpheme glosses exist in the dictionary, then this parameter is ignored. The default value is `On'. `TimeLimit' This parameter limits the amount of time that parsing an AMPLE analysis can take. Its argument is a number greater than or equal to zero, which is the maximum number of seconds than a parse is allowed before being cancelled. The default value is `0', which has the special meaning that no limit is imposed. NOTE: this feature is new and still somewhat experimental. It may not be fully debugged, and may cause unforeseen side effects such as program crashes some time after one or more parses are cancelled due to exceeding the set time limit. `TopDownFilter' This parameter controls whether simple top-down filtering based on the grammar categories is applied to the parse process. `\patr TopDownFilter On' enables this top-down filtering. `\patr TopDownFilter Off' disables the top-down filtering, slowing down the parse but possibly finding more solutions. The default value is `On'. `TreeStyle' This parameter controls how parse trees are written to either the analyis output file or the log file. `\patr TreeStyle Full' causes parses to be written in a somewhat graphic tree display format, using ASCII characters to draw the branches of the tree. `\patr TreeStyle Flat' causes parses to be written as parenthesized strings, similar to the way that LISP represents trees. This is the default value: it may be cryptic, but it requires the least space. `\patr TreeStyle Indented' causes parses to be written in an indented format sometimes called a _northwest tree_. `\patr TreeStyle XML' causes parses to be written in an XML format, with each node containing the feature structure associated with that node of the parse tree. This setting causes the `FeatureStyle' parameter to be ignored. `\patr TreeStyle Off' prevents parses from being written. This allows PCPATR word grammars to be used for filtering invalid AMPLE analyses without cluttering up the output analysis files. `TrimEmptyFeatures' This parameter controls whether empty feature structures are written to the output files. `\patr TrimEmptyFeatures On' disables the display of empty feature values. `\patr TrimEmptyFeatures Off' enables the display of empty features. The default value is `Off'. `Unification' This parameter controls whether the parsing process allows unification failures to block successful parsing. `\patr Unification On' causes the constituent structure rules to constrain the parse. `\patr Unification Off' causes feature unification failures to be ignored while parsing. (Most likely, this would be useful only while debugging the word grammar.) The default value is `On'. Punctuation class: \pcl ----------------------- A punctuation class is defined by the field code `\pcl' followed by the class name, which is followed in turn by one or more punctuation characters or (previously defined) punctuation class names. A punctuation class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. The individual members of the class are separated by spaces, tabs, or newlines. Each `\pcl' field defines a single punctuation class. Any number of `\pcl' fields may appear in the file. If no `\pcl' fields appear in the analysis data file, then AMPLE does not allow any punctuation classes in tests, and does not allow any punctuation classes in punctuation environment constraints. Prefix successor test: \pt -------------------------- A prefix successor test is defined by the `\pt' field code followed by the test name and possibly a test body. The test body is not needed if the test name is that of a built-in test (either SEC_ST, ADHOC_ST, or PEC_ST). Prefix tests are applied in the order they appear in the analysis data file. If not explicitly listed, SEC_ST, ADHOC_ST, and PEC_ST are applied after all the user-defined prefix tests. Any number of prefix successor tests may be defined in the file. For the syntax of successor tests, see `Test Syntax' below. If no `\pt' fields appear in the analysis data file, AMPLE still applies the built-in prefix tests SEC_ST, ADHOC_ST, and PEC_ST. Root ad hoc pair: \rah ---------------------- A root ad hoc pair is defined by the `\rah' field code followed by two morpheme identifiers. The first identifier may belong to a prefix, an infix (if infixes exist and can mingle with prefixes or roots), or a root (if compound roots are allowed). The second morpheme identifier must belong to a root. A prefix or infix identifier in a root ad hoc pair must be the affix's morphname. A root identifier in a root ad hoc pair must be given exactly as it occurs in the analysis (an etymology or a gloss, depending on the assignment to the `M' field in the root section of the dictionary code table). Any number of root ad hoc pairs may be defined in the file. However, their use is strongly discouraged on linguistic grounds. If no `\rah' fields appear in the analysis data file, then AMPLE never eliminates any analyses via the root `ADHOC_ST' test. Root Delimiter Characters: \rd ------------------------------ The root delimiter characters used in the output analysis file are defined by the `\rd' field code followed by two characters, possibly separated by spaces. The first character is used to mark the beginning of a root analysis and the second is used to mark its end. The `\rd' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\rd' fields appear in the analysis data file, then AMPLE uses the delimiter characters `<' and `>'. Root successor test: \rt ------------------------ A root successor test is defined by the `\rt' field code followed by the test name and possibly a test body. The test body is not needed if the test name is that of a built-in test (SEC_ST, ADHOC_ST, ROOTS_ST, or PEC_ST), or a previously defined prefix or infix test that is to be used as a root test. Root tests are applied in the order they appear in the analysis data file. If not explicitly listed, SEC_ST, ADHOC_ST, ROOT_ST, and PEC_ST are applied after all the user-defined root tests. Any number of root successor tests may be defined in the file. For the syntax of successor tests, see `Test Syntax' below. If no `\rt' fields appear in the analysis data file, AMPLE still applies the built-in root tests SEC_ST, ADHOC_ST, ROOTS_ST, and PEC_ST. Suffix ad hoc pair: \sah ------------------------ A suffix ad hoc pair is defined by the `\sah' field code followed by two morpheme identifiers. The first identifier may belong to a root, an infix (if infixes exist and can mingle with roots or suffixes), or a suffix. The second morpheme identifier must belong to a suffix. A suffix or infix identifier in a suffix ad hoc pair must be the affix's morphname. A root identifier in a suffix ad hoc pair must be given exactly as it occurs in the analysis (an etymology or a gloss, depending on the assignment to the `M' field in the root section of the dictionary code table). Any number of suffix ad hoc pairs may be defined in the file. However, their use is strongly discouraged on linguistic grounds. If no `\sah' fields appear in the analysis data file, then AMPLE never eliminates any analyses via the suffix `ADHOC_ST' test. String class: \scl ------------------ A string class is defined by the `\scl' field code followed by the class name, which is followed in turn by one or more contiguous character strings or (previously defined) string class names. A string class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. The actual character strings have no such restrictions. The individual members of the class are separated by spaces, tabs, or newlines. Each `\scl' field defines a single string class. Any number of `\scl' fields may appear in the file. If no `\scl' fields appear in the analysis data file, then AMPLE does not allow any string classes in tests, and does not allow any string classes in string environment constraints unless they are defined in the text input control file or the dictionary orthography changes file. Suffix successor test: \st -------------------------- A suffix successor test is defined by the `\st' field code followed by the test name and possibly a test body. The test body is not needed if the test name is that of a built-in test (either SEC_ST, ADHOC_ST, or PEC_ST), or a previously defined prefix, infix, or root test that is to be used as a suffix test. Suffix tests are applied in the order they appear in the analysis data file. If not explicitly listed, SEC_ST, ADHOC_ST, and PEC_ST are applied after all the user-defined suffix tests. Any number of suffix successor tests may be defined in the file. For the syntax of successor tests, see `Test Syntax' below. If no `\st' fields appear in the analysis data file, AMPLE still applies the built-in suffix tests SEC_ST, ADHOC_ST, and PEC_ST. Valid allomorph and string environment characters: \strcheck ------------------------------------------------------------ The characters considered to be valid for allomorph strings and string environment constraints are defined by a `\strcheck' field code followed by the list of characters. Spaces are not significant in this list. The `\strcheck' field may appear any number of times, but once is enough. If more than one such field occurs, the last one is the one that is used. If no `\strcheck' fields appear in the analysis data file, then AMPLE does not check allomorph strings and string environment constraints for containing only valid characters. Test Syntax =========== The remainder of this chapter presents grammatical descriptions of the syntax of tests and morpheme co-occurrence constraints in BNF notation. The following comments explain how to read the syntax rules given below: 1. Names shown inside wedges (`<>') are nonterminal symbols. These must eventually be expanded into terminal symbols. 2. The symbol `::=' means "is replaced by." 3. Items on the righthand side of the rule (following the `::=') that are not enclosed in wedges are terminal symbols, and appear in the rule exactly as they must appear in an AMPLE control file. Whitespace is largely optional; it is required only to separate identifiers and keywords. (Keywords are the alphabetic terminal symbols shown in the rules below.) 4. Alternative ways of replacing a nonterminal symbol are listed on separate lines. 1. ::= 2a. ::= 2b. IF THEN 2c. 2d. 2e. 3a. ::= NOT 3b. ( ) 3c. 3d. 3e. 3f. 3g. 3h. 3i. 4. ::= property is 5a. ::= morphname is 5b. morphname is member 5c. morphname is morphname 5d. allomorph is 5e. allomorph is member 5f. allomorph is allomorph 5g. allomorph matches 5h. allomorph matches member 5i. allomorph matches allomorph 5j. surface is 5k. surface is member 5l. surface is allomorph 5m. surface matches 5n. surface matches member 5o. surface matches allomorph 5p. word is 5q. word is member 5r. word matches 5s. word matches member 6. ::= type is 7a. ::= fromcategory is fromcategory 7b. fromcategory is tocategory 7c. tocategory is fromcategory 7d. tocategory is tocategory 7e. fromcategory is member 7f. tocategory is member 7g. fromcategory is 7h. tocategory is 8a. ::= allomorph is capitalized 8b. word is capitalized 9a. ::= orderclass orderclass 9b. orderclass orderclassmin 9c. orderclass orderclassmax 9d. orderclassmin orderclass 9e. orderclassmin orderclassmin 9f. orderclassmin orderclassmax 9g. orderclassmax orderclass 9h. orderclassmax orderclassmin 9i. orderclassmax orderclassmax 9j. orderclass 9k. orderclassmin 9l. orderclassmax 10a. ::= punctuation is 10b. punctuation is member 11. ::= AND OR XOR IFF 12. ::= FOR_ALL_LEFT FOR-ALL-LEFT FORALLLEFT FOR_SOME_LEFT FOR-SOME-LEFT FORSOMELEFT 13. ::= FOR_ALL_RIGHT FOR-ALL-RIGHT FORALLRIGHT FOR_SOME_RIGHT FOR-SOME-RIGHT FORSOMERIGHT 14. ::= last next 15. ::= prefix infix root suffix initial final 16. ::= = > >= <= < ~= 17. ::= left right current LEFT RIGHT INITIAL FINAL 18a. ::= "" 18b. '' 18c. .. 18d. [] 18e. 19. ::= 20. ::= one of the following characters: !"#$%&'*+,-./0123456789:;? @ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_ `abcdefghijklmnopqrstuvwxyz{} \200-\376 (character codes 128-254) 21. ::= - 22. ::= 23. ::= one of the following characters: 0123456789 Comments on selected BNF rules .............................. 1. A test consists of an identifier followed by the body of the test. The identifier is the name by which a test is known. The body consists of the expressions which are interpreted to evaluate the test. 4. The identifier in a property expression must be a property name defined with `\mp' or `\ap' in the analysis data file. 5a. In a string expression involving morphnames, an identifier must be equal to some morphname; for example, `left morphname is "PAST"' indicates that the name of the morpheme to the left is PAST. 5b. A member identifier in such expressions must be the name of a class of morphnames defined with `\mcl' in the analysis data file. 5dgjmpr. In a string expression involving allomorphs, surface strings, or adjacent words, an identifier must be equal to some portion of a word after any orthography change has been applied. For example, `left allomorph is "abadaba"' indicates that the allomorph of the morpheme to the left is abadaba. 5ehknqs. A member identifier in such expressions must be the name of a class of strings defined with `\scl' in the analysis data file. 5d-i. If reference is made to left, LEFT or INITIAL, the allomorph is tested to see if it ends with the string; for example, `left allomorph matches "ba"' indicates that the allomorph of the morpheme to the left ends in ba. If reference is made to current, right, RIGHT, or FINAL, the allomorph is tested to see if it begins with the string. 5j-o. If reference is made to left, LEFT or INITIAL, the surface string is tested to see if it ends with the given value. If reference is made to current, right, RIGHT, or FINAL, the surface string is tested to see if it begins with the given value. 5p-s. If reference is made to last, the word is tested to see if it ends with the string. If reference is made to next, the word is tested to see if it begins with the string. (These should be avoided, and other means used to prune analyses based on adjacent words.) 6. The type must be a keyword indicating whether the morpheme referred to is a prefix, an infix, a root, and so on 7ef. The identifier must be the name of a class of categories defined with `\ccl' in the analysis data file. 7gh. The identifier must be a category defined with `\ca' in the analysis data file. 9a-l. A constant is an integer between -32767 and (positive) 32767. The relational operator (relop) must be among those listed in rule 16. The terminals `orderclass' and `orderclassmin' are treated identically. Both refer to the first of potentially two order class numbers in a dictionary order class field. The terminal `orderclassmax' refers to the second order class number in a dictionary order class field. If the second number is not present, `orderclassmax' is set to the same value as `orderclass'. 10. Punctuation expressions always refer to punctuation either immediately before or after the current word. A `' value of `last' refers to immediately before the current word and a `' value of `next' refers to immediately after the current word. 18a-d. The quoted forms of an identifier are needed only if the identifier is the same as one of the AMPLE test keywords. It is recommended that the quoted identifier not contain the closing quote character. Morpheme Co-occurrence Constraint Syntax ======================================== This section presents a grammatical description of the syntax of morpheme co-occurrence constraints in BNF notation. These constraints are found either in the analysis data file (see `Morpheme Co-occurrence Constraint: \mcc' above) or in a dictionary file (see `Morpheme Co-occurrence Constraint (internal code Z)' below). 1a. ::= 1b. { } 2a. ::= 2b. 2c. [ ] 2d. [ ] 3a. ::= 3b. 4a. ::= 4b. 4c. 5a. ::= 5b. 5c. 5d. # 5e. # 6a. ::= 6b. 6c. 6d. # 6e. # 7a. ::= 7b. 7c. ... 8a. ::= 8b. ( ) 9a. ::= ~ 9b. 9c. [ ] 9d. { } 10. ::= / +/ 11. ::= _ ~_ 12. ::= # ~# 13. ::= one or more contiguous characters Comments on selected BNF rules .............................. 1b. A literal enclosed in braces is an arbitary identifier for this morpheme co-occurrence constraint. (This feature was added to support LinguaLinks.) 2ab. A literal is a morphname from one of the dictionary files. 2cd. A literal enclosed in square brackets must be the name of a morpheme class defined by a `\mcl' field in the analysis data file. 5-6. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 5de. 6de. These should be avoided, and other means used to prune analyses based on adjacent words. 7c. An ellipsis (`...') indicates a possible break in contiguity. 8b. Something enclosed in parentheses is optional. 9a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 9b. A literal is a morphname from one of the dictionary files. 9c. A literal enclosed in square brackets must be the name of a morpheme class defined by a `\mcl' field in the analysis data file. 9d. A literal enclosed in curly braces must be one of the following (checked in this order): 1. one of the keywords `root', `prefix', `infix', or `suffix' 2. a property name defined by an `\ap' or `\mp' field in the analyis data file 3. a category name defined by a `\ca' field in the analysis data file 4. a category class name defined by a `\ccl' field in the analysis data file 5. a morpheme class name defined by a `\mcl' field in the analysis data file 10. A `/' is usually used for string environment constraints, but may used for morpheme environment constraints in `\mcc' fields in the analysis data file. 11. A tilde (`~') attached to the environment bar inverts the sense of the constraint as a whole. 12b. The boundary marker preceded by a tilde (`~#') indicates that it must not be a word boundary. 13. The special characters used by environment constraints can be included in a literal only if they are immediately preceded by a backslash: \+ \/ \# \~ \[ \] \( \) \{ \} \. \_ \\ Allomorphs Never Co-occur Constraint Syntax =========================================== This section presents a grammatical description of the syntax of allomorphs never co-occur constraints in BNF notation. These constraints are found in the analysis data file (see `Allomorphs Never Co-occur Constraint: \ancc' above). 1a. ::= 1b. { } 2a. ::= 2b. 3a. ::= 3b. 4a. ::= 4b. 4c. 5a. ::= 5b. 5c. 5d. # 5e. # 6a. ::= 6b. 6c. 6d. # 6e. # 7a. ::= 7b. 7c. ... 8a. ::= 8b. ( ) 9a. ::= ~ 9b. 10. ::= / ~/ 11. ::= _ ~_ 12. ::= # ~# 13. ::= one or more contiguous characters Comments on selected BNF rules .............................. 1b. A literal enclosed in braces is an arbitary identifier for this allomorphs never co-occur constraint. 2ab. A literal is an allomorph identification string from one of the dictionary files. 5-6. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 5de. 6de. These should be avoided, and other means used to prune analyses based on adjacent words. 7c. An ellipsis (`...') indicates a possible break in contiguity. 8b. Something enclosed in parentheses is optional. 9a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 9b. A literal is an allomorph identification string from one of the dictionary files. 10. A `/' is usually used for string environment constraints, but may used for allomorphs never co-occur environment constraints in `\ancc' fields in the analysis data file. 11. A tilde (`~') attached to the environment bar inverts the sense of the constraint as a whole. 12b. The boundary marker preceded by a tilde (`~#') indicates that it must not be a word boundary. 13. The special characters used by environment constraints can be included in a literal only if they are immediately preceded by a backslash: \+ \/ \# \~ \[ \] \( \) \{ \} \. \_ \\ Dictionary Code Table File ************************** The second control file read by AMPLE contains the dictionary code table. Each entry of an AMPLE dictionary (whether for roots, prefixes, infixes, or suffixes) is structured by field codes that indicate the type of information that follows. The dictionary code table maps the field codes used in the dictionary files onto the internal codes that AMPLE uses. This allows linguists to use their favorite dictionary field codes rather than constraining them to a predefined set. The dictionary code table is divided into one or more sections, one for each type of dictionary file. Each section contains several mappings of field codes in the form of simple changes. The field codes used in the dictionary code table file are described in the remainder of this chapter. Change standard format marker to internal code: \ch =================================================== A dictionary field code change is defined by `\ch' followed by two quoted strings. The first string is the field code used in the dictionary (including the leading backslash character). The second string is the single capital letter designating the field type. For the lists of dictionary field type codes, see `Dictionary Files' below. Any character not found in either the dictionary field code string or the dictionary field type code may be used as the quoting character. The double quote (`"') or single quote (`'') are most often used for this purpose. Infix dictionary fields: \infix =============================== The set of dictionary field code changes for an infix dictionary file begins with `\infix', optionally followed by the record marker field code for the infix dictionary. If the record marker is not given, then the field code ("from string") from the first infix dictionary field code change is used. See `Dictionary Files' below for the set of infix dictionary field type codes. Prefix dictionary fields: \prefix ================================= The set of dictionary field code changes for a prefix dictionary file begins with `\prefix', optionally followed by the record marker field code for the prefix dictionary. If the record marker is not given, then the field code ("from string") from the first prefix dictionary field code change is used. See `Dictionary Files' below for the set of prefix dictionary field type codes. Root dictionary fields: \root ============================= The set of dictionary field code changes for a root dictionary file begins with `\root', optionally followed by the record marker field code for the root dictionary. If the record marker is not given, then the field code ("from string") from the first root dictionary field code change is used. See `Dictionary Files' below for the set of root dictionary field type codes. Suffix dictionary fields: \suffix ================================= The set of dictionary field code changes for a suffix dictionary file begins with `\suffix', optionally followed by the record marker field code for the suffix dictionary. If the record marker is not given, then the field code ("from string") from the first suffix dictionary field code change is used. See `Dictionary Files' below for the set of suffix dictionary field type codes. Unified dictionary fields: \unified =================================== The set of dictionary field code changes for a unified dictionary file begins with `\unified', optionally followed by the record marker field code for the unified dictionary. If the record marker is not given, then the field code ("from string") from the first unified dictionary field code change is used. See `Dictionary Files' below for the set of unified dictionary field type codes. Dictionary Orthography Change Table File **************************************** The third control file read by AMPLE, and the first optional one, contains the dictionary orthography change table. This table maps the allomorph strings in the dictionary files into the internal orthographic representation. When the text and internal orthographies differ, it may be desirable to have the allomorphs in the dictionaries stored in the same orthography as the texts, or it may be desirable to have them in the internal form, or it might even be desirable to have them in a third form. AMPLE allows for any of these choices. The dictionary orthography change table is defined by a special standard format file. This file contains a single record with two types of fields, either of which may appear any number of times. The rest of this chapter describes these fields, focusing on the syntax of the orthography changes. Dictionary Orthography Change: \ch ================================== An orthography change is defined by the `\ch' field code followed by the actual orthography change. Any number of orthography changes may be defined in the dictionary orthography change table. The output of each change serves as the input the following change. That is, each change is applied as many times as necessary to a dictionary allomorph before the next change from the dictionary orthography change table is applied. See `Text Orthography Change: \ch' below for the syntax of orthography changes. String class: \scl ================== A string class is defined by the `\scl' field code followed by the class name, which is followed in turn by one or more contiguous character strings or (previously defined) string class names. A string class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. The actual character strings have no such restrictions. The individual members of the class are separated by spaces, tabs, or newlines. Each `\scl' field defines a single string class. Any number of `\scl' fields may appear in the file. The only restriction is that a string class must be defined before it is used. If no `\scl' fields appear in the dictionary orthography changes file, then AMPLE does not allow any string classes in dictionary orthography change environment constraints unless they are defined in the analysis data file. Dictionary Files **************** This chapter describes the content of AMPLE dictionary files. These are normally divided into 1. a prefix dictionary file (if needed), 2. an infix dictionary file (if needed), 3. an suffix dictionary file (if needed), and 4. one or more root dictionary files. With the `-u' command line option in conjunction with the `\unified' field in the dictionary code table file, the dictionary can be stored as one or more files containing entries of any type: prefix, infix, suffix, or root. The following sections describe the different types of fields used in the different types of dictionary files. Remember, the mapping from the actual field codes used in the dictionary files to the type codes that AMPLE uses internally is controlled by the dictionary code table file (see `Dictionary Code Table File' above). Allomorph (internal code A) =========================== Each dictionary entry must contain one or more allomorph fields. Each of these contains one of the infix's allomorphs, that is, the string of characters by which the affix is represented in text and recognized by AMPLE. If an affix has multiple allomorphs, each one must be entered in its own allomorph field. These fields should be ordered with those on which the strictest constraints have been imposed preceding those with less strict or no constraints. The only exception to this is the use of indexed string classes to indicate reduplication. (See lines 20 and 21 below.) Properties, constraints, and comments may follow the allomorph string. Any properties must be listed before any constraints. String, punctuation and morpheme environment constraints may be intermixed, but must come before any comments. A complete BNF grammar of an allomorph field is given below. 1a. ::= 1b. 1c. 1d. 1e. 1f. 1g. 1h. 2a. ::= 2b. { } 2c. 2d. { } 3a. ::= 3b. 4a. ::= 4b. 4c. 4d. 4e. 4f. 5. ::= anything to the end of the line 6a. ::= / 6b. / 6c. / 7a. ::= 7b. 7c. 7d. # 7e. # 8a. ::= 8b. 8c. 8d. # 8e. # 9a. ::= 9b. 9c. ... 10a. ::= 10b. ( ) 11a. ::= ~ 11b. 11c. [ ] 11d. [ ] 12a. ::= +/ 12b. +/ 12c. +/ 13a. ::= 13b. 13c. 13d. # 13e. # 14a. ::= 14b. 14c. 14d. # 14e. # 15a. ::= 15b. 15c. ... 16a. ::= 16b. ( ) 17a. ::= ~ 17b. 17c. [ ] 17d. { } 18a. ::= ./ 18b. ./ 18c. ./ 19a. ::= 19b. 19c. 20a. ::= 20b. 20c. 21a. ::= 21b. 22a. ::= 22b. ( ) 23a. ::= ~ 23b. 23c. [ ] 24a. ::= _ 24b. ~_ 25a. ::= # 25b. ~# 26a. ::= [ ] 26b. [ ] 26c. [ ] 26d. [ ] 26e. [ ] 27. ::= ^ 28. ::= one or more contiguous characters 29. ::= character defined by `-c' command line option, or `|' by default 30. ::= one or more contiguous digits (0-9) Comments on selected BNF rules .............................. 2. The (first) literal string is a surface form representation of the morpheme. The literal string enclosed in braces is a unique allomorph identification string. (The identification string is a feature added to support LinguaLinks. It is not stored unless the `-b' command line option is used. 3. Each literal string is an allomorph property defined by a `\ap' field in the analysis data file. 4. String, punctuation and morpheme constraints can be mixed together, but it is recommended that you group the string constraints together, the punctuation constraints together and the morpheme constraints together. 5. A comment begins with a specified character and ends with the end of the line. 7-8. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 7de. 8de. These should be avoided, and other means used to prune analyses based on adjacent words. 9c. An ellipsis (`...') indicates a possible break in contiguity. 10b. Something enclosed in parentheses is optional. 11a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 11b. A literal is matched against the surface form of the word. 11c. A literal enclosed in square brackets must be the name of a string class defined by a `\scl' field in the analysis data file or the dictionary orthography change table file. 11d. The indexed literal enclosed in square brackets must match an indexed literal given as part of the reduplication allomorph pattern. (See 2c, 2d, and 26.) 13-14. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 13de. 14de. These should be avoided, and other means used to prune analyses based on adjacent words. 15c. An ellipsis (`...') indicates a possible break in contiguity. 16b. Something enclosed in parentheses is optional. 17a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 17b. A literal is a morphname from one of the dictionary files. 17c. A literal enclosed in square brackets must be the name of a morpheme class defined by a `\mcl' field in the analysis data file. 17d. A literal enclosed in curly braces must be one of the following (checked in this order): 1. one of the keywords `root', `prefix', `infix', or `suffix' 2. a property name defined by an `\ap' or `\mp' field in the analyis data file 3. a category name defined by a `\ca' field in the analysis data file 4. a category class name defined by a `\ccl' field in the analysis data file 5. a morpheme class name defined by a `\mcl' field in the analysis data file 19-20. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 22b. Something enclosed in parentheses is optional. 23a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 23b. A literal is a punctuation character. All such punctuation characters should not be listed in the set of word formation characters. See `Text Input Control File' below. The punctuation characters can match punctuation characters either before or after the current word. Unlike string constraints, punctuation constraints effectively ignore the position of the conditioned allomorph within the word. All that matters are any punctuation characters immediately preceding or following the current word. Further note that neither ellipsis nor cross word boundary conditions are allowed. 24. A tilde (`~') attached to the environment bar inverts the sense of the constraint as a whole. 25b. The boundary marker preceded by a tilde (`~#') indicates that it must not be a word boundary. 26-27. Although the BNF has spaces in it to improve readability, these two items cannot have embedded spaces in the dictionary file. 26. The reduplication allomorph pattern contains references to string classes and possibly literal strings. The string class names are indexed to indicate identical shared values, either in the string environment constraint or in more than one location in the reduplication allomorph pattern itself. _Note: this has been implemented only for AMPLE at this point._ 27. The literal (without the following index given by an ASCII caret (`^') and a number) must be the name of a string class defined by a `\scl' field in the analysis data file or the dictionary orthography change table file. 28. The special characters used by environment constraints can be included in a literal only if they are immediately preceded by a backslash: \+ \/ \# \~ \[ \] \( \) \{ \} \. \_ \\ The allomorph field is used in all types of dictionary entries: prefix, infix, suffix, and root. Category (internal code C) ========================== Each dictionary entry must contain a category field. If multiple category fields exist, then their contents are merged together. For affix entries, this field must contain at least one category pair for the morpheme, but may contain any number of category pairs separated by spaces or tabs. Each category pair consists of two category names separated by a slash (`/'). The category names must have been defined by a `\ca' field in the analysis data file. The first category is the "from category", that is, the category of the unit to which this morpheme can be affixed. The second category is the "to category", that is, the category of the result after this morpheme has been affixed. For root entries, this field contains one or more morphological categories as defined by a `\ca' field in the analysis data file. If multiple categories are listed, they should be separated by spaces or tabs. The category field is used in all types of dictionary entries: prefix, infix, suffix, and root. Elsewhere Allomorph (internal code E) ===================================== For compatibility with STAMP, the "elsewhere" field defines an allomorph. In AMPLE, this field also provides a default value for the underlying form. The syntax of the elsewhere allomorph field is the same as the syntax of the normal allomorph field. See `Allomorph (internal code A)' above. The elsewhere allomorph field is used in all types of dictionary entries: prefix, infix, suffix, and root. Feature Descriptor (internal code F) ==================================== The feature descriptor field is always optional. It contains the names of one or more features that are written verbatim to the `\fd' field of the output analysis file. It is not otherwise used by AMPLE. If a dictionary entry contains multiple feature descriptor fields, their contents are merged together. The feature descriptor field is used in all types of dictionary entries: prefix, infix, suffix, and root. Root Gloss (internal code G) ============================ The root gloss field contains an alternative morphname for writing to the output analysis file. It is enabled by the `-g' command line option. Without this command line option, it is totally ignored by AMPLE. See `Morphname (internal code M)' below. Only one root gloss field is allowed in each dictionary entry. If an entry has more than one root gloss field, then the first one is used and the others trigger provoke an error message. The root gloss field is used only in root dictionary entries. Infix location (internal code L) ================================ The infix location field serves to restrict where infixes may be found, and must be included in each infix dictionary entry. Subject to the constraints imposed by the infix location field, AMPLE searches the rest of the word for any occurrence of any allomorph string of the infix. This makes infixes rather expensive, computationally, so they should be constrained as much as possible. 1. ::= 2a. ::= 2b. 3a. ::= 3b. 4a. ::= 4b. 4c. 5a. ::= 5b. 5c. 6a. ::= 6b. 6c. 7a. ::= 7b. 7c. ... 8a. ::= 8b. ( ) 9a. ::= ~ 9b. 9c. [ ] 10a. ::= prefix 10b. root 10c. suffix 11a. ::= / 11b. +/ 12a. ::= _ 12b. ~_ 13a. ::= # 13b. ~# 14. ::= one or more contiguous characters Comments on selected BNF rules .............................. 2. The first part of the infix location field lists the type of morpheme in which the infix may be hidden. This consists of one or more of the words `prefix', `root', or `suffix'. If `prefix' is given, then AMPLE looks for infixes after exhausting the possible prefixes at a given point in the word, and resumes looking for more prefixes after finding an infix. Similarly, if `root' is given, then AMPLE looks for infixes after running out of roots while parsing the word, and if it finds an infix, it looks for more roots. Suffixes are treated the same way if `suffix' is given in the infix location field. 5. A boundary marker (`#') on the left side of the environment bar refers to the place in the word which the parse has reached before looking for infixes, not to the beginning of the word. 6. A boundary marker (`#') on the right side of the environment bar refers to the end of the word. 7c. An ellipsis (`...') indicates a possible break in contiguity. 8b. Something enclosed in parentheses is optional. 9a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 11. A `+/' is usually used for morpheme environment constraints, but may used for infix location environment constraints as well. 12. A tilde attached to the environment bar (`~_') inverts the sense of the constraint as a whole. 13b. The boundary marker preceded by a tilde (`~#') indicates that it must not be a word boundary. 14. The special characters used by environment constraints can be included in a literal only if they are immediately preceded by a backslash: \+ \/ \# \~ \[ \] \( \) \{ \} \. \_ \\ The infix location field is used only in infix dictionary entries. Morphname (internal code M) =========================== A morphname is an arbitrary name for a given morpheme. Only the first word (string of contiguous nonspace characters) following the morphname field code is used as the morphname. Morphnames must be less than 64 characters long. A morphname serves two important functions: 1. It identifies a morpheme in morpheme environment constraints, morpheme co-occurrence constraints, ad hoc pairs, and tests. 2. It is the default morpheme identifier written to the output analysis file. See `Root Gloss (internal code G)' above. Generally, a morphname is an identifier of a morpheme and does not need to faithfully represent that morpheme's meaning or function. If a dictionary entry has more than one morphname field, the morphname from the first one is used; the others cause an error message. The morphname field is used in all types of dictionary entries: prefix, infix, suffix, and root. The usage differs somewhat between affix and root dictionary entries, so these two types of morphnames are described separately. Affix morphnames ---------------- Every affix dictionary entry must have a morphname field. Users are strongly encouraged to observe the following suggestions in creating affix morphnames: 1. Make each morphname unique. If two morphemes have the same name, it is impossible to refer unambiguously to them. The same morphname should not be used in different affix dictionaries (that is, in the prefix dictionary and in the suffix dictionary). 2. Keep morphnames short. This reduces the size of analysis files and makes text glossing more aesthetically pleasing. For example, for a verbal person marker, use simply `1' rather than `1P' unless there is good reason to add the `P' for person or possessive. For a first person object marker, `1O' might serve as well as `1OBJ'. 3. Use only uppercase alphabetic characters and numbers for contrast with root morphnames, which are generally made up of lowercase alphabetic characters. Be cautious in using hyphens, periods, underscores, slashes, backslashes, or other nonalphanumeric characters. The reason to avoid these is that other programs which apply to the resulting analysis may make use of nonalphanumerics in different ways. 4. Design a syntax of names and stick to it for inflectional morphemes which combine more than one semantic notion. For example, for Latin nominal inflections, which indicate gender, number, and case, the syntax might be MORPHNAME = GENDER CASE NUMBER where `GENDER' is `M' for masculine, `F' for feminine and `N' for neuter; `CASE' is `N' for nominative, `A' for accusative, `G' for genitive, and so on; and `NUMBER' is `S' for singular and `P' for plural. The name for masculine nominative singular would then be `MNS'. Root morphnames --------------- Root morphnames are generally either glosses or etymologies. Etymologies are frequently marked with a leading asterisk (`*'). (This is used by STAMP to indicate regular sound changes.) If the morphname field contains only an asterisk, the morphname becomes an asterisk followed by whatever allomorph is matched. If the morphname field is omitted, or if it contains only a comment, AMPLE puts whatever allomorph was matched in the text into the analysis. If the morpheme contains any alternate forms, it is wise to include an explicit morphname field. Order class (internal code O) ============================= The order class of an affix is a number indicating its position relative to other morphemes. Prefixes should be assigned negative numbers and suffixes should be assigned positive numbers. Infixes should be assigned order class values appropriate to where they can appear in the word relative to the prefixes and suffixes. If the order class field is omitted, then a default value of zero (0) is assigned to the affix. Order class values must be between -32767 and 32767. Order classes are used only by tests in the analysis data file. They are needed only if appropriate tests are written to take advantage of them. The order class field is used only in affix type dictionary entries: prefix, infix, and suffix. Roots always have an implicit order class of zero. Beginning with AMPLE version 3.6.0, one may have up to two order class numbers in an order class field (separated by white space). These represent the minimum and the maximum values of the positions this affix can span. The first number is the minimum and the second is the maximum. Therefore the first number should be less than or equal to the second. If only one number appears, both the minimum and maximum values are set to that number. If no number appears, then both the minimum and maximum are set to zero. Note that for STAMP, only the first order class number has any use (it is used for transfer insertion rules whose environments do not indicate a location where the morpheme is to be inserted). Morpheme property (internal code P) =================================== This field contains one or more morpheme properties. These properties must have been defined by a `\mp' field in the analysis data file. A morpheme property is inherited by all allomorphs of the morpheme. The morpheme property field is optional, and may be repeated. If multiple properties apply to a morpheme, they may be given all in a single field or each in a separate field. Morpheme properties typically indicate a characteristic of the morpheme which conditions the occurrence of allomorphs of an adjacent morpheme. Morpheme properties are used in tests defined in the analysis data file and in morpheme environment constraints. The morpheme property field is used in all types of dictionary entries: prefix, infix, suffix, and root. Morpheme type (internal code T) =============================== In a unified dictionary, the type of an entry is determined by the first letter following the morpheme type field code: `p' or `P' for prefixes, `i' or `I' for infixes, `s' or `S' for suffixes, and `r' or `R' for roots. The morpheme type field is not needed for root entries because the entry type defaults to root. The morpheme type field is used only in unified dictionary files, since the morpheme type is otherwise implicit. Underlying Form (internal code U) ================================= The underlying form field contains information for writing to `\u' fields in the output analysis file. If a mapping from a dictionary field code to internal code `U' is not defined in the dictionary code table file, then this field effectively does not exist. Only one underlying form field is allowed in each dictionary entry. If an entry has more than one underlying form field, then the first one is used and the others trigger provoke an error message. If a particular record in a dictionary file does not have an underlying form field, but does use an "elsewhere" field (see `Elsewhere Allomorph (internal code E)' above), then AMPLE uses the elsewhere entry for the underlying form. If an entry has neither an underlying form field nor an elsewhere field, AMPLE assumes that the underlying form is null and will output a zero (0) for the underlying form. The underlying form field is used in all types of dictionary entries: prefix, infix, suffix, and root. Morpheme Co-occurrence Constraint (internal code Z) =================================================== See `Morpheme Co-occurrence Constraint: \mcc' above for a description of morpheme co-occurrence constraint fields in the analysis data file. These fields can also occur in dictionary entries. This is appropriate only if the constraint is about that morpheme. One difference between morpheme co-occurrence constraints in the analysis data file and those found in dictionary entries is that the field code in the dictionary file is not necessarily `\mcc'. The primary difference is that morpheme co-occurrence constraints found in a dictionary entry are stored with the dictionary entry in memory, and those found in the analysis data file are stored together in one long list. If a constraint applies to more than one morpheme, it must be put in the analysis data file to work properly. The morpheme co-occurrence constraint field is optional. If more than one constraint applies to the morpheme, as many of these fields as desired may be included. The morpheme co-occurrence constraint field is used in all types of dictionary entries: prefix, infix, suffix, and root. Do not load (internal code !) ============================= When a "do not load" field is included in a record, AMPLE ignores the record altogether. This makes it possible to include records in the dictionary for linguistic purposes, while not needlessly taking up memory space if the dictionary is used for some other purpose. The "do not load" field is used in all types of dictionary entries: prefix, infix, suffix, and root. Text Input Control File *********************** This chapter describes the expected characteristics of an input text file, and the options offered for describing these characteristics by a "text input control file".(1) ---------- Footnotes ---------- (1) This chapter is adapted from chapters 7, 8, and 9 of Weber (1988). Input text files ================ Text input control files define a simple model of input text files. They are plain text files with two types of embedded format markers. 1. A primary format marker consists of one or more contiguous characters beginning with a special flag character. The default character initiating format markers is the backslash (`\'). Thus, each of the following would be recognized as a format marker and would not be processed by the program: \ \p \sp \begin{enumerate} \very-long.and;muddled/format*marker,to#be$sure Note that format markers cannot have a space or tab embedded in them; the first space or tab encountered terminates the format marker. One final note: the format character under discussion here applies only to the input text files which are to be processed. It has absolutely nothing to do with the use of backslash (`\') to flag field codes in control files such as the text input control file. 2. A secondary type of marker consists of a flag character followed by a single character from a list of known values. This secondary flag character must be different than the primary flag character. Its default value is the vertical bar (`|'), causing this type of format marker to be frequently called a bar code. The following could be valid (secondary) format markers and would not be processed by the program: |b |i |r Consider the following two lines of input text: \bgoodbye\r |bgoodbye|r Using the default definitions of format markers, the first line is considered to be a single format marker, and provides nothing which the program should try to parse. The second line, however contains two format markers, `|b' and `|r', and the word `goodbye' which would be processed by the program. The primary format markers serve to divide the text into fields. See `Fields to Exclude: \excl' and `Fields to Include: \incl' below for details on how these fields are used. There is no requirement that the format markers be at the beginning of a line as with the field codes used in AMPLE control files. Ambiguity Marker Character: \ambig ================================== The `\ambig' field defines the character used to mark ambiguities and failures in the analysis output file. For example, to use the hash mark (`#'), the text input control file would include: \ambig # This would cause an ambiguous analysis to be output as follows: \a #3#< N0 kay >#< V1 ka > IMP#< V1 ka > INF# It makes sense to use the `\ambig' field only once in the text input control file. If multiple `\ambig' fields do occur in the file, the value given in the first one is used. If the text input control file does not have an `\ambig' field, the percent sign (`%') is used. The first printing character following the `\ambig' field code is used as the ambiguity marker. The character currently being used to mark comments cannot be assigned to also mark ambiguities in the output file. Thus, the vertical bar (`|') cannot normally be used as the ambiguity marker. Logically, this field should be in the analysis data file rather than the text _input_ control file since it affects output instead of input. Nevertheless, compatibility demands that it stays this way. Bar code format marker character: \barchar ========================================== The `\barchar' defines the character that begins a two-character secondary format marker. For example, if this type of format marker begins with the dollar sign (`$'), the following would be placed in the text input control file: \barchar $ An empty `\barchar' field in the text input control file prevents any bar code format markers from being recognized. Thus, the following field effectively turns off special treatment of this style of format marking (assuming the `|' is marking comments): \barchar | no bar character It makes sense to use the `\barchar' field only once in the text input control file. If multiple `\barchar' fields do occur in the file, the value given in the first one is used. The first printing character following the `\barchar' field code is used as the bar code format marker. The character currently being used to mark comments cannot be assigned to also flag format markers in input text files. Thus, the default value (`|') cannot normally be explicitly defined (since `\barchar |' is treated as `\barchar' followed only by a comment), so it must be taken as given. Bar Code Format Code Characters: \barcodes ========================================== In conjunction with the special format marking character discussed in the previous section, the `\barcodes' field defines the individual characters used with in bar codes. These characters may be separated by spaces or lumped together. Thus, the following two fields are equivalent: \barcodes abcdefg | lumped together \barcodes a b c d e f g | separated If provided more than one `\barcodes' field in the text input control file, the combination of all characters defined in all such fields is used. No check is made for repeated characters: the previous example would be accepted without complaint despite the redundancy of the second line. The default value for the bar codes is `bdefhijmrsuvyz'. Therefore, if the text input control file contains neither a `\barchar' nor a `\barcodes' field, the following bar codes are considered to be formatting information by AMPLE: `|b', `|d', `|e', `|f', `|h', `|i', `|j', `|m', `|r', `|s', `|u', `|v', `|y', and `|z'. These are exactly the codes recognized by the SIL Manuscripter program that was in vogue when the concept of a text input control file was originally developed. Text Orthography Change: \ch ============================ An orthography change is defined by the `\ch' field code followed by the actual orthography change. Any number of orthography changes may be defined in the text input control file. The output of each change serves as the input the following change. That is, each change is applied as many times as necessary to an input word before the next change from the text input control file is applied. Basic changes ------------- To substitute one string of characters for another, these must be made known to the program in a change. (The technical term for this sort of change is a production, but we will simply call them changes.) In the simplest case, a change is given in three parts: (1) the field code `\ch' must be given at the extreme left margin to indicate that this line contains a change; (2) the match string is the string for which the program must search; and (3) the substitution string is the replacement for the match string, wherever it is found. The beginning and end of the match and substitution strings must be marked. The first printing character following `\ch' (with at least one space or tab between) is used as the delimiter for that line. The match string is taken as whatever lies between the first and second occurrences of the delimiter on the line and the substitution string is whatever lies between the third and fourth occurrences. For example, the following lines indicate the change of hi to bye, where the delimiters are the double quote mark (`"'), the single quote mark (`''), the period (`.'), and the at sign (`@'). \ch "hi" "bye" \ch 'hi' 'bye' \ch .hi. .bye. \ch @hi@ @bye@ Throughout this document, we use the double quote mark as the delimiter unless there is some reason to do otherwise. Change tables follow these conventions: 1. Any characters (other than the delimiter) may be placed between the match and substitution strings. This allows various notations to symbolize the change. For example, the following are equivalent: \ch "thou" "you" \ch "thou" to "you" \ch "thou" > "you" \ch "thou" --> "you" \ch "thou" becomes "you" 2. Comments included after the substitution string are initiated by a vertical bar (`|'), or whatever is indicated as the comment character by means of the `-c' option when AMPLE is started. The following lines illustrate the use of comments: \ch "qeki" "qiki" | for cases like wawqeki \ch "thou" "you" | for modern English 3. A change can be ignored temporarily by turning it into a comment field. This is done either by placing an unrecognized field code in front of the normal `\ch', or by placing the comment character (`|') in front of it. For example, only the first of the following three lines would effect a change: \ch "nb" "mp" \no \ch "np" "np" |\ch "mb" "nb" The changes in the text input control file are applied as an ordered set of changes. The first change is applied to the entire word by searching from left to right for any matching strings and, upon finding any, replacing them with the substitution string. After the first change has been applied to the entire word, then the next change is applied, and so on. Thus, each change applies to the result of all prior changes. When all the changes have been applied, the resulting word is returned. For example, suppose we have the following changes: \ch "aib" > "ayb" \ch "yb" > "yp" Consider the effect these have on the word paiba. The first changes i to y, yielding payba; the second changes b to p, to yield paypa. (This would be better than the single change of aib to ayp if there were sources of yb other than the output of the first rule.) The way in which change tables are applied allows certain tricks. For example, suppose that for Quechua, we wish to change hw to f, so that hwista becomes fista and hwis becomes fis. However, we do not wish to change the sequence shw or chw to sf or cf (respectively). This could be done by the following sequence of changes. (Note, `@' and `$' are not otherwise used in the orthography.) \ch "shw" > "@" | (1) \ch "chw" > "$" | (2) \ch "hw" > "f" | (3) \ch "@" > "shw" | (4) \ch "$" > "chw" | (5) Lines (1) and (2) protect the sh and ch by changing them to distinguished symbols. This clears the way for the change of hw to f in (3). Then lines (4) and (5) restore `@' and `$' to sh and ch, respectively. (An alternative, simpler way to do this is discussed in the next section.) Environmentally constrained changes ----------------------------------- It is possible to impose string environment constraints (SECs) on changes in the orthography change tables. The syntax of SECs is described in detail in section {No value for `words.vs.format'}. For example, suppose we wish to change the mid vowels (e and o) to high vowels (i and u respectively) immediately before and after q. This could be done with the following changes: \ch "o" "u" / _ q / q _ \ch "e" "i" / _ q / q _ This is not entirely a hypothetical example; some Quechua practical orthographies write the mid vowels e and o. However, in the environment of /q/ these could be considered phonemically high vowels /i/ and /u/. Changing the mid vowels to high upon loading texts has the advantage that-for cases like upun "he drinks" and upoq "the one who drinks"-the root needs to be represented internally only as upu "drink". But note, because of Spanish loans, it is not possible to change all cases of e to i and o to u. The changes must be conditioned. In reality, the regressive vowel-lowering effect of /q/ can pass over various intervening consonants, including /y/, /w/, /l/, /ll/, /r/, /m/, /n/, and /n/. For example, /ullq/ becomes ollq, /irq/ becomes erq, and so on. Rather than list each of these cases as a separate constraint, it is convenient to define a class (which we label `+resonant') and use this class to simplify the SEC. Note that the string class must be defined (with the `\scl' field code) before it is used in a constraint. \scl +resonant y w l ll r m n n~ \ch "o" "u" / q _ / _ ([+resonant]) q \ch "e" "i" / q _ / _ ([+resonant]) q This says that the mid vowels become high vowels after /q/ and before /q/, possibly with an intervening /y/, /w/, /l/, /ll/, /r/, /m/, /n/, or /n/. Consider the problem posed for Quechua in the previous section, that of changing hw to f. An alternative is to condition the change so that it does not apply adjacent to a member of the string class `Affric' which contains s and c. \scl Affric c s \ch "hw" "f" / [Affric] ~_ It is sometimes convenient to make certain changes only at word boundaries, that is, to change a sequence of characters only if they initiate or terminate the word. This conditioning is easily expressed, as shown in the following examples. \ch "this" "that" | anywhere in the word \ch "this" "that" / # _ | only if word initial \ch "this" "that" / _ # | only if word final \ch "this" "that" / # _ # | only if entire word Using text orthography changes ------------------------------ The purpose of orthography change is to convert text from an external orthography to an internal representation more suitable for morphological analysis. In many cases this is unnecessary, the practical orthography being completely adequate as the internal representation. In other cases, the practical orthography is an inconvenience that can be circumvented by converting to a more phonemic representation. Let us take a simple example from Latin. In the Latin orthography, the nominative singular masculine of the word "king" is rex. However, phonemically, this is really /reks/; /rek/ is the root meaning king and the /s/ is an inflectional suffix. If the program is to recover such an analysis, then it is necessary to convert the x of the external, practical orthography into ks internally. This can be done by including the following orthography change in the text input control file: \ch "x" "ks" In this, x is the match string and ks is the substitution string, as discussed in section {No value for `output.file'}. Whenever x is found, ks is substituted for it. Let us consider next an example from Huallaga Quechua. The practical orthography currently represents long vowels by doubling the vowel. For example, what is written as kaa is /ka:/ "I am", where the length (represented by a colon) is the morpheme meaning "first person subject". Other examples, such as upoo /upu:/ "I drink" and upichee /upi-chi-:/ "I extinguish", motivate us to convert all long vowels into a vowel followed by a colon. The following changes do this: \ch "aa" "a:" \ch "ee" "i:" \ch "ii" "i:" \ch "oo" "u:" \ch "uu" "u:" Note that the long high vowels (i and u) have become mid vowels (e and o respectively); consequently, the vowel in the substitution string is not necessarily the same as that of the match string. What is the utility of these changes? In the lexicon, the morphemes can be represented in their phonemic forms; they do not have to be represented in all their orthographic variants. For example, the first person subject morpheme can be represented simply as a colon (-:), rather than as -a in cases like kaa, as -o in cases like qoo, and as -e as in cases like upichee. Further, the verb "drink" can be represented as upu and the causative suffix (in upichee) can be represented as -chi; these are the forms these morphemes have in other (nonlowered) environments. As the next example, let us suppose that we are analyzing Spanish, and that we wish to work internally with k rather than c (before a, o, and u) and qu (before i and e). (Of course, this is probably not the only change we would want to make.) Consider the following changes: \ch "ca" "ka" \ch "co" "ko" \ch "cu" "ku" \ch "qu" "k" The first three handle c and the last handles qu. By virtue of including the vowel after c, we avoid changing ch to kh. There are other ways to achieve the same effect. One way exploits the fact that each change is applied to the output of all previous changes. Thus, we could first protect ch by changing it to some distinguished character (say `@'), then changing c to k, and then restoring `@' to ch: \ch "ch" "@" \ch "c" "k" \ch "@" "ch" \ch "qu" "k" Another approach conditions the change by the adjacent characters. The changes could be rewritten as \ch "c" "k" / _a / _o / _u | only before a, o, or u \ch "qu" "k" | in all cases The first change says, "change c to k when followed by a, o, or u." (This would, for example, change como to komo, but would not affect chal.) The syntax of such conditions is exactly that used in string environment constraints; see section {No value for `words.vs.format'}. Where orthography changes apply ------------------------------- Input orthography changes are made when the text being processed may be written in a practical orthography. Rather than requiring that it be converted as a prerequisite to running the program, it is possible to have the program convert the orthography as it loads and before it processes each word. The changes loaded from the text input control file are applied after all the text is converted to lower case (and the information about upper and lower case, along with information about format marking, punctuation and white space, has been put to one side.) Consequently, the match strings of these orthography changes should be all lower case; any change that has an uppercase character in the match string will never apply. A sample orthography change table --------------------------------- We include here the entire orthography input change table for Caquinte (a language of Peru). There are basically four changes that need to be made: (1) nasals, which in the practical orthography reflect their assimilation to the point of articulation of a following noncontinuant, must be changed into an unspecified nasal, represented by N; (2) c and qu are changed to k; (3) j is changed to h; and (4) gu is changed to g before i and e. \ch "mp" "Np" | for unspecified nasals \ch "nch" "Nch" \ch "nc" "Nk" \ch "nqu" "Nk" \ch "nt" "Nt" \ch "ch" "@" | to protect ch \ch "c" "k" | other c's to k \ch "@" "ch" | to restore ch \ch "qu" "k" \ch "j" "h" \ch "gue" "ge" \ch "gui" "gi" This change table can be simplified by the judicious use of string environment constraints: \ch "m" > "N" / _p \ch "n" > "N" / _c / _t / _qu \ch "c" > "k" / _~h \ch "qu" > "k" \ch "j" > "h" \ch "gu" > "g" / _e /_i As suggested by the preceding examples, the text orthography change table is composed of all the `\ch' fields found in the text input control file. These may appear anywhere in the file relative to the other fields. It is recommended that all the orthography changes be placed together in one section of the text input control file, rather than being mixed in with other fields. Syntax of Orthography Changes ----------------------------- This section presents a grammatical description of the syntax of orthography changes in BNF notation. These changes are found either in the dictionary orthography change table file or in the text input control file (see `Dictionary Orthography Change: \ch' above). 1a. ::= 1b. 2a. ::= 2b. 2c. 3. ::= any printing character not used in either the ``from'' string or the ``to'' string 4. ::= one or more characters other than the quote character used by this orthography change 5a. ::= 5b. 6a. ::= 6b. 6c. 7a. ::= 7b. 7c. 8a. ::= 8b. 8c. 9a. ::= 9b. 9c. ... 10a. ::= 10b. ( ) 11a. ::= ~ 11b. 11c. [ ] 12. ::= / +/ 13. ::= _ ~_ 14. ::= # ~# 15. ::= one or more contiguous characters Comments on selected BNF rules .............................. 2. The same `' character must be used at both the beginning and the end of both the "from" string and the "to" string. 3. The double quote (`"') and single quote (`'') characters are most often used. 7-8. Note that what can appear to the left of the environment bar is a mirror image of what can appear to the right. 9c. An ellipsis (`...') indicates a possible break in contiguity. 10b. Something enclosed in parentheses is optional. 11a. A tilde (`~') reverses the desirability of an element, causing the constraint to fail if it is found rather than fail if it is not found. 11c. A literal enclosed in square brackets must be the name of a string class defined by a `\scl' field in the analysis data file, or earlier in the dictionary orthography change file. 12. A `+/' is usually used for morpheme environment constraints, but may used for change environment constraints in `\ch' fields in the dictionary orthography change table file. 13. A tilde attached to the environment bar (`~_') inverts the sense of the constraint as a whole. 14b. The boundary marker preceded by a tilde (`~#') indicates that it must not be a word boundary. 15. The special characters used by environment constraints can be included in a literal only if they are immediately preceded by a backslash: \+ \/ \# \~ \[ \] \( \) \. \_ \\ Decomposition Separation Character: \dsc ======================================== The `\dsc' field defines the character used to separate the morphemes in the decomposition field of the output analysis file. For example, to use the equal sign (`='), the text input control file would include: \dsc = This would cause a decomposition field to be output as follows: \d %3%kay%ka=y%ka=y% It makes sense to use the `\dsc' field only once in the text input control file. If multiple `\dsc' fields do occur in the file, the value given in the first one is used. If the text input control file does not have an `\dsc' field, a dash (`-') is used. The first printing character following the `\dsc' field code is used as the morpheme decomposition separator character. The same character cannot be used both for separating decomposed morphemes in the analysis output file and for marking comments in the input control files. Thus, one normally cannot use the vertical bar (`|') as the decomposition separation character. Logically, this field should be in the analysis data file rather than the text _input_ control file since it affects output instead of input. Nevertheless, compatibility demands that it stays this way. Fields to Exclude: \excl ======================== The `\excl' field excludes one or more fields from processing. For example, to have the program ignore everything in `\co' and `\id' fields, the following line is included in the text input control file: \excl \co \id | ignore these fields If more than one `\excl' field is found in the text input control file, the contents of each field is added to the overall list of text fields to exclude. This list is initially empty, and stays empty unless the text input control file contains an `\excl' field. Thus, no text fields are excluded from processing by default. If the text input control file contains `\excl' fields, then only those text fields are not processed. Every word in every text field not mentioned explicitly in an `\excl' field will be processed. Note that every text field in the input text files is processed unless the text input control file contains either an `\excl' or an `\incl' field. One or the other is used to limit processing, but never both. Primary format marker character: \format ======================================== The `\format' field designates a single character to flag the beginning of a primary format marker. For example, if the format markers in the text files begin with the at sign (`@'), the following would be placed in the text input control file: \format @ This would be used, for example, if the text contained format markers like the following: @ @p @sp @make(Article) @very-long.and;muddled/format*marker,to#be$sure If a `\format' field occurs in the text input control file without a following character to serve for flagging format markers, then the program will not recognize any format markers and will try to parse everything other than punctuation characters. It makes sense to use the `\format' field only once in the text input control file. If multiple `\format' fields do occur in the file, the value given in the first one is used. The first printing character following the `\format' field code is used to flag format markers. The character currently used to mark comments cannot be assigned to also flag format markers. Thus, the vertical bar (`|') cannot normally be used to flag format markers. Fields to Include: \incl ======================== The `\incl' field explicitly includes one or more text fields for processing, excluding all other fields. For instance, to process everything in `\txt' and `\qt' fields, but ignore everything else, the following line is placed in the text input control file: \incl \txt \qt | process these fields If more than one `\incl' field is found in the text input control file, the contents of each field is added to the overall list of text fields to process. This list is initially empty, and stays empty unless the text input control file contains an `\incl' field. If the text input control file contains `\incl' fields, then only those text fields are processed. Every word in every text field not mentioned explicitly in an `\incl' field will not be processed. Note that every text field in the input text files is processed unless the text input control file contains either an `\excl' or an `\incl' field. One or the other is used to limit processing, but never both. Lowercase/uppercase character pairs: \luwfc =========================================== To break a text into words, the program needs to know which characters are used to form words. It always assumes that the letters `A' through `Z' and `a' through `z' are used as word formation characters. If the orthography of the language the user is working in uses any other characters that have lowercase and uppercase forms, these must given in a `\luwfc' field in the text input control file. The `\luwfc' field defines pairs of characters; the first member of each pair is a lowercase character and the second is the corresponding uppercase character. Several such pairs may be placed in the field or they may be placed on separate fields. Whitespace may be interspersed freely. For example, the following three examples are equivalent: \luwfc éÉ ñÑ or \luwfc éÉ | e with acute accent \luwfc ñÑ | enyee or \luwfc é É ñ Ñ Note that comments can be used as well (just as they can in any AMPLE control file). This means that the comment character cannot be designated as a word formation character. If the orthography includes the vertical bar (`|'), then a different comment character must be defined with the `-c' command line option when AMPLE is initiated; see `AMPLE Command Options' above. The `\luwfc' field can be entered anywhere in the text input control file, although a natural place would be before the `\wfc' (word formation character) field. Any standard alphabetic character (that is `a' through `z' or `A' through `Z') in the `\luwfc' field will override the standard lower- upper case pairing. For example, the following will treat `X' as the upper case equivalent of `z': \luwfc z X Note that `Z' will still have `z' as its lower-case equivalent in this case. The `\luwfc' field is allowed to map multiple lower case characters to the same upper case character, and vice versa. This is needed for languages that do not mark tone on upper case letters. Multibyte lowercase/uppercase character pairs: \luwfcs ====================================================== The `\luwfcs' field extends the character pair definitions of the `\luwfc' field to multibyte character sequences. Like the `\luwfc' field, the `\luwfcs' field defines pairs of characters; the first member of each pair is a multibyte lowercase character and the second is the corresponding multibyte uppercase character. Several such pairs may be placed in the field or they may be placed on separate fields. Whitespace separates the members of each pair, and the pairs from each other. For example, the following three examples are equivalent: \luwfcs e' E` n~ N^ ç C& or \luwfcs e' E` | e with acute accent \luwfcs n~ N^ | enyee \luwfcs ç C& | c cedilla or \luwfcs e' E` n~ N^ ç C& Note that comments can be used as well (just as they can in any AMPLE control file). This means that the comment character cannot be designated as a word formation character. If the orthography includes the vertical bar (`|'), then a different comment character must be defined with the `-c' command line option when AMPLE is initiated; see `AMPLE Command Options' above. Also note that there is no requirement that the lowercase form be the same length (number of bytes) as the uppercase form. The examples shown above are only one or two bytes (character codes) in length, but there is no limit placed on the length of a multibyte character. The `\luwfcs' field can be entered anywhere in the text input control file. `\luwfcs' fields may be mixed with `\luwfc' fields in the same file. Any standard alphabetic character (that is `a' through `z' or `A' through `Z') in the `\luwfcs' field will override the standard lower- upper case pairing. For example, the following will treat `X' as the upper case equivalent of `z': \luwfcs z X Note that `Z' will still have `z' as its lowercase equivalent in this case. The `\luwfcs' field is allowed to map multiple multibyte lowercase characters to the same multibyte uppercase character, and vice versa. This may be useful in some situations, but it introduces an element of ambiguity into the decapitalization and recapitalization processes. If ambiguous capitalization is supported, then for the previous example, `z' will have both `X' and `Z' as uppercase equivalents, and `X' will have both `x' and `Z' as lowercase equivalents. Maximum number of decapitalizations: \maxdecap ============================================== The `\maxdecap' field sets the maximum number of different decapitalizations allowed. Since the `\luwfc' field can map several lowercase characters onto a single uppercase character, a word with uppercase characters can (logically) generate a number of alternatives when decapitalized. This is especially true of words that are entirely capitalized to begin with. The default limit is 100. Prevent Any Decapitalization: \nocap ==================================== The usual behavior is to normalize input words to lowercase. The program remembers the case of the word as one of four possibilities: 1. all uppercase 2. all lowercase 3. only the first letter uppercase 4. mixed uppercase and lowercase However, not all orthographies use the concept of capitalization. To help deal with these, the field code `\nocap' disables all case normalization if it appears anywhere in the text input control file. Prevent Decapitalization of Individual Characters: \noincap =========================================================== The handling of mixed uppercase and lowercase is limited in utility, and sometimes causes more problems than it solves. For this reason, the `\noincap' field code turns off mixed case decapitalization. The program would still decapitalize words that are entirely capitalized and words that begin with a capital letter. String class: \scl ================== A string class is defined by the `\scl' field code followed by the class name, which is followed in turn by one or more contiguous character strings or (previously defined) string class names. A string class name used as part of the class definition must be enclosed in square brackets. The class name must be a single, contiguous sequence of printing characters. Characters and words which have special meanings in tests should not be used. The actual character strings have no such restrictions. The individual members of the class are separated by spaces, tabs, or newlines. Each `\scl' field defines a single string class. Any number of `\scl' fields may appear in the file. The only restriction is that a string class must be defined before it is used. String classes must be defined before being used. For example, the first two lines of the simpler Caquinte example above could be given as follows: \scl -bilabial c t qu \ch "m" > "N" / _ p \ch "n" > "N" / _ [-bilabial] The string class definition could be in another control file: string classes defined elsewhere can be used in the text input control file as well. If no `\scl' fields appear in the text input control file, then AMPLE does not allow any string classes in text input orthography change environment constraints unless they are defined in the analysis data file or the dictionary orthography changes file. Caseless word formation characters: \wfc ======================================== To break a text into words, the program needs to know which characters are used to form words. It always assumes that the letters `A' through `Z' and `a' through `z' are used as word formation characters. If the orthography of the language the user is working in uses any characters that do not have different lowercase and uppercase forms, these must given in a `\wfc' field in the text input control file. For example, English uses an apostrophe character (`'') that could be considered a word formation character. This information is provided by the following example: \wfc ' | needed for words like don't Notice that the characters in the `\wfc' field may be separated by spaces, although it is not required to do so. If more than one `\wfc' field occurs in the text input control file, the program uses the combination of all characters defined in all such fields as word formation characters. The comment character cannot be designated as a word formation character. If the orthography includes the vertical bar (`|'), then a different comment character must be defined with the `-c' command line option when AMPLE is initiated; see `AMPLE Command Options' above. Multibyte caseless word formation characters: \wfcs =================================================== The `\wfcs' field allows multibyte characters to be defined as "caseless" word formation characters. It has the same relationship to `\wfc' that `\luwfcs' has to `\luwfc'. The multibyte word formation characters are separated from each other by whitespace. A sample text input control file ================================ The following is the complete text input control file for Huallaga Quechua (a language of Peru): \id HGTEXT.CTL - for Huallaga Quechua, 25-May-88 \co WORD FORMATION CHARACTERS \wfc ' ~ \co FIELDS TO EXCLUDE \excl \id | identification fields \co ORTHOGRAPHY CHANGES \ch "aa" > "a:" | for long vowels \ch "ee" > "i:" \ch "ii" > "i:" \ch "oo" > "u:" \ch "uu" > "u:" \ch "qeki" > "qiki" | for cases like wawqeki \ch "~n" > "n~" | for typos | for Spanish loans like hwista \scl sib s c | sibilants \ch "hw" > "f" / ~[sib]_ Output Analysis Files ********************* Analysis files are "record oriented standard format files". This means that the files are divided into records, each representing a single word in the original input text file, and records are divided into fields. An analysis file contains at least one record, and may contain a large number of records. Each record contains one or more fields. Each field occupies at least one line, and is marked by a "field code" at the beginning of the line. A field code begins with a backslash character (`\'), and contains 1 or more letters in addition. Analysis file fields ==================== This section describes the possible fields in an analysis file. The only field that is guaranteed to exist is the analysis (`\a') field. All other fields are either data dependent or optional. Analysis field: \a ------------------ The analysis field (`\a') starts each record of an analysis file. It has the following form: \a PFX IFX PFX < CAT root CAT root > SFX IFX SFX where `PFX' is a prefix morphname, `IFX' is an infix morphname, `SFX' is a suffix morphname, `CAT' is a root category, and `root' is a root gloss or etymology. In the simplest case, an analysis field would look like this: \a < CAT root > where `CAT' is a root category and `root' is a root gloss or etymology. The `\rd' field in the analysis data file can replace the characters used to bracket the root category and gloss/etymology; see `Root Delimiter Characters: \rd' above. The dictionary field code mapped to `M' in the dictionary codes file controls the affix and default root morphnames; see `Morphname (internal code M)'. If the `-g' command line option is given, the output analysis file contains glosses from the root dictionary marked by the field code mapped to `G' in the dictionary codes file; see `AMPLE Command Options' and `Root Gloss (internal code G)' above. Decomposition field: \d ----------------------- The morpheme decomposition field (`\d') follows the analysis field. It has the following form: \d anti-dis-establish-ment-arian-ism-s where the hyphens separate the individual morphemes in the surface form of the word. The `\dsc' field in the text input control file can replace the hyphen with another character for separating the morphemes; see `Decomposition Separation Character: \dsc' above. The morpheme decomposition field is optional. It is enabled either by a `-w d' command line option (see `AMPLE Command Options' above), or by an interactive query. Category field: \cat -------------------- The category field (`\cat') provides rudimentary category information. This may be useful for sentence level parsing. It has the following form: \cat CAT where `CAT' is the word category. A more complex example is \cat C0 C1/C0=C2=C2/C1=C1/C1 where `C0' is the proposed word category, `C1/C0' is a prefix category pair, `C2' is a root category, and `C2/C1' and `C1/C1' are suffix category pairs. The equal signs (`=') serve to separate the category information of the individual morphemes. The `\cat' field of the analysis data file controls whether the category field is written to the output analysis file; see `Category output control: \cat' above. If there are multiple analyses, there will be multiple categories in the output, separated by ambiguity markers. Properties field: \p -------------------- The properties field (`\p') contains the names of any allomorph or morpheme properties found in the analysis of the word. It has the form: \p ==prop1 prop2=prop3= where `prop1', `prop2', and `prop3' are property names. The equal signs (`=') serve to separate the property information of the individual morphemes. Note that morphemes may have more than one property, with the names separated by spaces, or no properties at all. By default, the properties field is written to the output analysis file. The `-w 0' command option, or any `-w' option that does not include `p' in its argument disables the properties field. Feature Descriptors field: \fd ------------------------------ The feature descriptor field (`\fd') contains the feature names associated with each morpheme in the analysis. It has the following form: \fd ==feat1 feat2=feat3= where `feat1', `feat2', and `feat3' are feature descriptors. The equal signs (`=') serve to separate the feature descriptors of the individual morphemes. Note that morphemes may have more than one feature descriptor, with the names separated by spaces, or no feature descriptors at all. The dictionary field code mapped to `F' in the dictionary code table file controls whether feature descriptors are written to the output analysis file; if this mapping is not defined, then the `\fd' field is not written. See `Feature Descriptor (internal code F)' above. If there are multiple analyses, there will be multiple feature sets in the output, separated by ambiguity markers. Underlying form field: \u ------------------------- The underlying form field (`\u') is similar to the decomposition field except that it shows underlying forms instead of surface forms. It looks like this: \u a-para-a-i-ri-me where the hyphens separate the individual morphemes. The `\dsc' field in the text input control file can replace the hyphen with another character for separating the morphemes; see `Decomposition Separation Character: \dsc' above. The dictionary field code mapped to `U' in the dictionary code table file controls whether underlying forms are written to the output analysis file; if this mapping is not defined, then the `\u' field is not written. See `Underlying Form (internal code U)' above. Word field: \w -------------- The original word field (`\w') contains the original input word as it looks before decapitalization and orthography changes. It looks like this: \w The Note that this is a gratuitous change from earlier versions of AMPLE and KTEXT, which wrote the decapitalized form. The original word field is optional. It is enabled either by a `-w w' command line option (see `AMPLE Command Options' above), or by an interactive query. Formatting field: \f -------------------- The format information field (`\f') records any formatting codes or punctuation that appeared in the input text file before the word. It looks like this: \f \\id MAT 5 HGMT05.SFM, 14-feb-84 D. Weber, Huallaga Quechua\n \\c 5\n\n \\s where backslashes (`\') in the input text are doubled, newlines are represented by `\n', and additional lines in the field start with a tab character. The format information field is written to the output analysis file whenever it is needed, that is, whenever formatting codes or punctuation exist before words. Capitalization field: \c ------------------------ The capitalization field (`\c') records any capitalization of the input word. It looks like this: \c 1 where the number following the field code has one of these values: `1' the first (or only) letter of the word is capitalized `2' all letters of the word are capitalized `4-32767' some letters of the word are capitalized and some are not Note that the third form is of limited utility, but still exists because of words like the author's last name. The capitalization field is written to the output analysis file whenever any of the letters in the word are capitalized; see `Prevent Any Decapitalization: \nocap' and `Prevent Decapitalization of Individual Characters: \noincap' above. Nonalphabetic field: \n ----------------------- The nonalphabetic field (`\n') records any trailing punctuation, bar code (see `Bar Code Format Code Characters: \barcodes' above), or whitespace characters. It looks like this: \n |r.\n where newlines are represented by `\n'. The nonalphabetic field ends with the last whitespace character immediately following the word. The nonalphabetic field is written to the output analysis file whenever the word is followed by anything other than a single space character. This includes the case when a word ends a file with nothing following it. Ambiguous analyses ================== The previous section assumed that only one analysis is produced for each word. This is not always possible since words in isolation are frequently ambiguous. Multiple analyses are handled by writing each analysis field in parallel, with the number of analyses at the beginning of each output field. For example, \a %2%< A0 imaika > CNJT AUG%< A0 imaika > ADVS% \d %2%imaika-Npa-ni%imaika-Npani% \cat %2%A0 A0=A0/A0=A0/A0%A0 A0=A0/A0% \p %2%==%=% \fd %2%==%=% \u %2%imaika-Npa-ni%imaika-Npani% \w Imaicampani \f \\v124 \c 1 \n \n where the percent sign (`%') separates the different analyses in each field. Note that only those fields which contain analysis information are marked for ambiguity. The other fields (`\w', `\f', `\c', and `\n') are the same regardless of the number of analyses. The `\ambig' field in the text input control file can replace the percent sign with another character for separating the analyses; see `Ambiguity Marker Character: \ambig' above. Analysis failures ================= The previous sections assumed that words are successfully analyzed. This does not always happen. Analysis failures are marked the same way as multiple analyses, but with zero (`0') for the ambiguity count. For example, \a %0%ta% \d %0%ta% \cat %0%% \p %0%% \fd %0%% \u %0%% \w TA \f \\v 12 |b \c 2 \n |r\n Note that only the `\a' and `\d' fields contain any information, and those both have the original word as a place holder. The other analysis fields (`\cat', `\p', `\fd', and `\u') are marked for failure, but otherwise left empty. The `\ambig' field in the text input control file can replace the percent sign with another character for marking analysis failures and ambiguities; see `Ambiguity Marker Character: \ambig' above. Bibliography ************ 1. Weber, David J., H. Andrew Black, and Stephen R. McConnel. 1988. `AMPLE: a tool for exploring morphology'. Occasional Publications in Academic Computing No. 12. Dallas, TX: Summer Institute of Linguistics. 2. Weber, David J., H. Andrew Black, Stephen R. McConnel, and Alan Buseman. 1990. `STAMP: a tool for dialect adaptation'. Occasional Publications in Academic Computing No. 15. Dallas, TX: Summer Institute of Linguistics. Index ***** -/: See ``AMPLE Command Options''. -a: See ``AMPLE Command Options''. -b: See ``AMPLE Command Options''. -c character: See ``AMPLE Command Options''. -d number: See ``AMPLE Command Options''. -e filename: See ``AMPLE Command Options''. -f filename: See ``AMPLE Command Options''. -g: See ``AMPLE Command Options''. -i filename: See ``AMPLE Command Options''. -m: See ``AMPLE Command Options''. -n number: See ``AMPLE Command Options''. -o filename: See ``AMPLE Command Options''. -p: See ``AMPLE Command Options''. -q: See ``AMPLE Command Options''. -r: See ``AMPLE Command Options''. -s filename: See ``AMPLE Command Options''. -t: See ``AMPLE Command Options''. -u: See ``AMPLE Command Options''. -v: See ``AMPLE Command Options''. -w fields: See ``AMPLE Command Options''. -x fields: See ``AMPLE Command Options''. -Z address,count: See ``AMPLE Command Options''. -z filename: See ``AMPLE Command Options''. \a: See ``Analysis field: \a''. \ambig: See ``Ambiguity Marker Character: \ambig''. \ancc: See ``Allomorphs Never Co-occur Constraint: \ancc''. \ap: See ``Allomorph properties: \ap''. \barchar: See ``Bar code format marker character: \barchar''. \barcodes: See ``Bar Code Format Code Characters: \barcodes''. \c: See ``Capitalization field: \c''. \ca: See ``Categories: \ca''. \cat <1>: See ``Category field: \cat''. \cat: See ``Category output control: \cat''. \catcr: See ``Category output control for compound roots: \catcr''. \ccl: See ``Category class: \ccl''. \ch <1>: See ``Text Orthography Change: \ch''. \ch <2>: See ``Dictionary Orthography Change: \ch''. \ch: See ``Change standard format marker to internal code: \ch''. \cr: See ``Compound root category pair: \cr''. \d: See ``Decomposition field: \d''. \dicdecap: See ``Dictionary decapitalization control: \dicdecap''. \dsc: See ``Decomposition Separation Character: \dsc''. \excl: See ``Fields to Exclude: \excl''. \f: See ``Formatting field: \f''. \fd: See ``Feature Descriptors field: \fd''. \format: See ``Primary format marker character: \format''. \ft: See ``Final test: \ft''. \iah: See ``Infix ad hoc pair: \iah''. \incl: See ``Fields to Include: \incl''. \infix: See ``Infix dictionary fields: \infix''. \it: See ``Infix successor test: \it''. \luwfc: See ``Lowercase/uppercase character pairs: \luwfc''. \luwfcs: See ``Multibyte lowercase/uppercase character pairs: \luwfcs''. \maxdecap: See ``Maximum number of decapitalizations: \maxdecap''. \maxi: See ``Maximum number of infixes: \maxi''. \maxnull: See ``Maximum number of null allomorphs: \maxnull''. \maxp: See ``Maximum number of prefixes: \maxp''. \maxprops: See ``Maximum number of properties: \maxprops''. \maxr: See ``Maximum number of roots: \maxr''. \maxs: See ``Maximum number of suffixes: \maxs''. \mcc: See ``Morpheme Co-occurrence Constraint: \mcc''. \mcl: See ``Morpheme class: \mcl''. \mp: See ``Morpheme properties: \mp''. \n: See ``Nonalphabetic field: \n''. \nocap: See ``Prevent Any Decapitalization: \nocap''. \noincap: See ``Prevent Decapitalization of Individual Characters: \noincap''. \p: See ``Properties field: \p''. \pah: See ``Prefix ad hoc pair: \pah''. \patr: See ``Word parser parameter settings: \patr''. \pcl: See ``Punctuation class: \pcl''. \prefix: See ``Prefix dictionary fields: \prefix''. \pt: See ``Prefix successor test: \pt''. \rah: See ``Root ad hoc pair: \rah''. \rd: See ``Root Delimiter Characters: \rd''. \root: See ``Root dictionary fields: \root''. \rt: See ``Root successor test: \rt''. \sah: See ``Suffix ad hoc pair: \sah''. \scl <1>: See ``String class: \scl''. \scl <2>: See ``String class: \scl''. \scl: See ``String class: \scl''. \st: See ``Suffix successor test: \st''. \strcheck: See ``Valid allomorph and string environment characters: \strcheck''. \suffix: See ``Suffix dictionary fields: \suffix''. \u: See ``Underlying form field: \u''. \unified: See ``Unified dictionary fields: \unified''. \w: See ``Word field: \w''. \wfc: See ``Caseless word formation characters: \wfc''. \wfcs: See ``Multibyte caseless word formation characters: \wfcs''. analysis data file: See ``Analysis Data File''. analysis output file: See ``Output Analysis Files''. dictionary code table: See ``Dictionary Code Table File''. dictionary files: See ``Dictionary Files''. dictionary orthography change table: See ``Dictionary Orthography Change Table File''. output analysis file: See ``Output Analysis Files''. standard format: See ``Standard format''. text input control: See ``Text Input Control File''. Table of Contents ***************** Introduction to the AMPLE program Running AMPLE AMPLE Command Options Program Interaction Standard format Analysis Data File Analysis Data File Fields Allomorphs Never Co-occur Constraint: \ancc Allomorph properties: \ap Categories: \ca Category output control: \cat Category output control for compound roots: \catcr Category class: \ccl Compound root category pair: \cr Dictionary decapitalization control: \dicdecap Final test: \ft Infix ad hoc pair: \iah Infix successor test: \it Maximum number of infixes: \maxi Maximum number of null allomorphs: \maxnull Maximum number of prefixes: \maxp Maximum number of properties: \maxprops Maximum number of roots: \maxr Maximum number of suffixes: \maxs Morpheme Co-occurrence Constraint: \mcc Morpheme class: \mcl Morpheme properties: \mp Prefix ad hoc pair: \pah Word parser parameter settings: \patr Punctuation class: \pcl Prefix successor test: \pt Root ad hoc pair: \rah Root Delimiter Characters: \rd Root successor test: \rt Suffix ad hoc pair: \sah String class: \scl Suffix successor test: \st Valid allomorph and string environment characters: \strcheck Test Syntax Morpheme Co-occurrence Constraint Syntax Allomorphs Never Co-occur Constraint Syntax Dictionary Code Table File Change standard format marker to internal code: \ch Infix dictionary fields: \infix Prefix dictionary fields: \prefix Root dictionary fields: \root Suffix dictionary fields: \suffix Unified dictionary fields: \unified Dictionary Orthography Change Table File Dictionary Orthography Change: \ch String class: \scl Dictionary Files Allomorph (internal code A) Category (internal code C) Elsewhere Allomorph (internal code E) Feature Descriptor (internal code F) Root Gloss (internal code G) Infix location (internal code L) Morphname (internal code M) Order class (internal code O) Morpheme property (internal code P) Morpheme type (internal code T) Underlying Form (internal code U) Morpheme Co-occurrence Constraint (internal code Z) Do not load (internal code !) Text Input Control File Input text files Ambiguity Marker Character: \ambig Bar code format marker character: \barchar Bar Code Format Code Characters: \barcodes Text Orthography Change: \ch Basic changes Environmentally constrained changes Using text orthography changes Where orthography changes apply A sample orthography change table Syntax of Orthography Changes Decomposition Separation Character: \dsc Fields to Exclude: \excl Primary format marker character: \format Fields to Include: \incl Lowercase/uppercase character pairs: \luwfc Multibyte lowercase/uppercase character pairs: \luwfcs Maximum number of decapitalizations: \maxdecap Prevent Any Decapitalization: \nocap Prevent Decapitalization of Individual Characters: \noincap String class: \scl Caseless word formation characters: \wfc Multibyte caseless word formation characters: \wfcs A sample text input control file Output Analysis Files Analysis file fields Analysis field: \a Decomposition field: \d Category field: \cat Properties field: \p Feature Descriptors field: \fd Underlying form field: \u Word field: \w Formatting field: \f Capitalization field: \c Nonalphabetic field: \n Ambiguous analyses Analysis failures Bibliography Index