[CUP Logo Image]

CUP User's Manual

Scott E. Hudson
Graphics Visualization and Usability Center
Georgia Institute of Technology
July 1996 (v0.9.1)


Table of Contents

i.
About CUP Version 0.10a
1.
Introduction and Example
2.
Specification Syntax
3.
Running CUP
4.
Customizing the Parser
5.
Error Recovery
6.
Conclusion
References
A.
Grammar for CUP Specification Files
B.
A Very Simple Example Scanner
C.
Changes to CUP Version 0.10a

i. About CUP Version 0.10a

Version 0.10a of CUP adds many new changes and features over the previous releases of version 0.9. These changes attempt to make CUP more like its predecessor, YACC. As a result, the old parser specifications for CUP are not compatible and a reading of appendix C of the new manual will be necessary to write new specifications. The new version, however, gives the user more power and options, making parser specifications easier to write.

1. Introduction and Example

This manual describes the basic operation and use of the Java(tm) Based Constructor of Useful Parsers (CUP for short). CUP is a system for generating LALR parsers from simple specifications. It serves the same role as the widely used program YACC [1] and in fact offers most of the features of YACC. However, CUP is written in Java, uses specifications including embedded Java code, and produces parsers which are implemented in Java.

Although this manual covers all aspects of the CUP system, it is relatively brief, and assumes you have at least a little bit of knowledge of LR parsing. A working knowledge of YACC is also very helpful in understanding how CUP specifications work. A number of compiler construction textbooks (such as [2,3]) cover this material, and discuss the YACC system (which is quite similar to this one) as a specific example.

Using CUP involves creating a simple specification based on the grammar for which a parser is needed, along with construction of a scanner capable of breaking characters up into meaningful tokens (such as keywords, numbers, and special symbols).

As a simple example, consider a system for evaluating simple arithmetic expressions over integers. This system would read expressions from standard input (each terminated with a semicolon), evaluate them, and print the result on standard output. A grammar for the input to such a system might look like:

  expr_list ::= expr_list expr_part | expr_part
  expr_part ::= expr ';'
  expr      ::= expr '+' expr | expr '-' expr | expr '*' expr 
	      | expr '/' expr | expr '%' expr | '(' expr ')'  
              | '-' expr | number 
To specify a parser based on this grammar, our first step is to identify and name the set of terminal symbols that will appear on input, and the set of non terminal symbols. In this case, the non terminals are:
  expr_list, expr_part  and  expr .
For terminal names we might choose:
  SEMI, PLUS, MINUS, TIMES, DIVIDE, MOD, NUMBER, LPAREN,
and RPAREN
The experienced user will note a problem with the above grammar. It is ambiguous. An ambiguous grammar is a grammar which, given a certain input, can reduce the parts of the input in two different ways such as to give two different answers. Take the above grammar, for example. given the following input:
3 + 4 * 6
The grammar can either evaluate the 3 + 4 and then multiply seven by six, or it can evaluate 4 * 6 and then add three. Older versions of CUP forced the user to write unambiguous grammars, but now there is a construct allowing the user to specify precedences and associativities for terminals. This means that the above ambiguous grammar can be used, after specifying precedences and associativities. There is more explanation later. Based on these namings we can construct a small CUP specification as follows:

// CUP specification for a simple expression evaluator (no actions)

import java_cup.runtime.*;

/* Preliminaries to set up and use the scanner.  */
init with {: scanner.init();              :};
scan with {: return scanner.next_token(); :};

/* Terminals (tokens returned by the scanner). */
terminal            SEMI, PLUS, MINUS, TIMES, DIVIDE, MOD;
terminal            UMINUS, LPAREN, RPAREN;
terminal Integer    NUMBER;

/* Non terminals */
non terminal            expr_list, expr_part;
non terminal Integer    expr, term, factor;

/* Precedences */
precedence left PLUS, MINUS;
precedence left TIMES, DIVIDE, MOD;
precedence left UMINUS;

/* The grammar */
expr_list ::= expr_list expr_part | 
              expr_part;
expr_part ::= expr SEMI;
expr      ::= expr PLUS expr 
            | expr MINUS expr  
            | expr TIMES expr  
            | expr DIVIDE expr  
            | expr MOD expr 
	    | MINUS expr %prec UMINUS
            | LPAREN expr RPAREN
	    | NUMBER
	    ;


We will consider each part of the specification syntax in detail later. However, here we can quickly see that the specification contains four main parts. The first part provides preliminary and miscellaneous declarations to specify how the parser is to be generated, and supply parts of the runtime code. In this case we indicate that the java_cup.runtime classes should be imported, then supply a small bit of initialization code, and some code for invoking the scanner to retrieve the next input token. The second part of the specification declares terminals and non terminals, and associates object classes with each. In this case, the terminals are declared as either with no type, or of type Integer. The specified type of the terminal or non-terminal is the type of the value of those terminals or non-terminals. If no type is specified, the terminal or non-terminal carries no value. Here, no type indicates that these terminals and non-terminals hold no value. The third part specifies the precedence and associativity of terminals. The last precedence declaration give its terminals the highest precedence. The final part of the specification contains the grammar.

To produce a parser from this specification we use the CUP generator. If this specification were stored in a file parser.cup, then (on a Unix system at least) we might invoke CUP using a command like:

 java java_cup.Main < parser.cup 
In this case, the system will produce two Java source files containing parts of the generated parser: sym.java and parser.java. As you might expect, these two files contain declarations for the classes sym and parser. The sym class contains a series of constant declarations, one for each terminal symbol. This is typically used by the scanner to refer to symbols (e.g. with code such as "return new Symbol(sym.SEMI);" ). The parser class implements the parser itself.

The specification above, while constructing a full parser, does not perform any semantic actions -- it will only indicate success or failure of a parse. To calculate and print values of each expression, we must embed Java code within the parser to carry out actions at various points. In CUP, actions are contained in code strings which are surrounded by delimiters of the form {: and :} (we can see examples of this in the init with and scan with clauses above). In general, the system records all characters within the delimiters, but does not try to check that it contains valid Java code.

A more complete CUP specification for our example system (with actions embedded at various points in the grammar) is shown below:


// CUP specification for a simple expression evaluator (w/ actions)

import java_cup.runtime.*;

/* Preliminaries to set up and use the scanner.  */
init with {: scanner.init();              :};
scan with {: return scanner.next_token(); :};

/* Terminals (tokens returned by the scanner). */
terminal           SEMI, PLUS, MINUS, TIMES, DIVIDE, MOD;
terminal           UMINUS, LPAREN, RPAREN;
terminal Integer   NUMBER;

/* Non terminals */
non terminal            expr_list, expr_part;
non terminal Integer    expr;

/* Precedences */
precedence left PLUS, MINUS;
precedence left TIMES, DIVIDE, MOD;
precedence left UMINUS;

/* The grammar */
expr_list ::= expr_list expr_part 
	      | 
              expr_part;

expr_part ::= expr:e 
	      {: System.out.println("= " + e); :} 
              SEMI              
	      ;

expr      ::= expr:e1 PLUS expr:e2    
	      {: RESULT = new Integer(e1.intValue() + e2.intValue()); :} 
	      | 
              expr:e1 MINUS expr:e2    
              {: RESULT = new Integer(e1.intValue() - e2.intValue()); :} 
	      | 
              expr:e1 TIMES expr:e2 
	      {: RESULT = new Integer(e1.intValue() * e2.intValue()); :} 
	      | 
              expr:e1 DIVIDE expr:e2 
	      {: RESULT = new Integer(e1.intValue() / e2.intValue()); :} 
	      | 
              expr:e1 MOD expr:e2 
	      {: RESULT = new Integer(e1.intValue() % e2.intValue()); :} 
	      | 
              NUMBER:n                 
	      {: RESULT = n; :} 
	      | 
              MINUS expr:e             
	      {: RESULT = new Integer(0 - e.intValue()); :} 
	      %prec UMINUS
	      | 
              LPAREN expr:e RPAREN     
	      {: RESULT = e; :} 
	      ;


Here we can see several changes. Most importantly, code to be executed at various points in the parse is included inside code strings delimited by {: and :}. In addition, labels have been placed on various symbols in the right hand side of productions. For example in:
  expr:e1 PLUS expr:e2    
	{: RESULT = new Integer(e1.intValue() + e2.intValue()); :} 
the first non-terminal expr has been labeled with e1, and the second with e2. The left hand side value of each production is always implicitly labeled as RESULT.

Each symbol appearing in a production is represented at runtime by an object of type Symbol on the parse stack. The labels refer to the instance variable value in those objects. In the expression expr:e1 PLUS expr:e2, e1 and e2 refer to objects of type Integer. These objects are in the value fields of the objects of type Symbol representing those non-terminals on the parse stack. RESULT is of type Integer as well, since the resulting non-terminal expr was declared as of type Integer. This object becomes the value instance variable of a new Symbol object.

For each label, two more variables accessible to the user are declared. A left and right value labels are passed to the code string, so that the user can find out where the left and right side of each terminal or nonterminal is in the input stream. The name of these variables is the label name, plus left or right. for example, given the right hand side of a production expr:e1 PLUS expr:e2 the user could not only access variables e1 and e2, but also e1left, e1right, e2left and e2right. these variables are of type int.

The final step in creating a working parser is to create a scanner (also known as a lexical analyzer or simply a lexer). This routine is responsible for reading individual characters, removing things things like white space and comments, recognizing which terminal symbols from the grammar each group of characters represents, then returning token objects representing these symbols to the parser. The terminals will be retrieved with a call to the scanner function. In the example, the parser will call scanner.next_token(). The scanner should return objects of type java_cup.runtime.Symbol. This type is very different than older versions of CUP's java_cup.runtime.symbol. These Symbol objects contains the instance variable value of type Object, which should be set by the lexer. This variable refers to the value of that symbol, and the type of object in value should be of the same type as declared in the terminal and non terminal declarations. In the above example, if the lexer wished to pass a NUMBER token, it should create a Symbol with the value instance variable filled with an object of type Integer. terminals and non-terminals with no value have a null value field.

. The code contained in the init with clause of the specification will be executed before any tokens are requested. Each token will be requested using whatever code is found in the scan with clause. Beyond this, the exact form the scanner takes is up to you.

In the next section a more detailed and formal explanation of all parts of a CUP specification will be given. Section 3 describes options for running the CUP system. Section 4 discusses the details of how to customize a CUP parser, while Section 5 considers error recovery. Finally, Section 6 provides a conclusion.

2. Specification Syntax

Now that we have seen a small example, we present a complete description of all parts of a CUP specification. A specification has four sections with a total of eight specific parts (however, most of these are optional). A specification consists of: Each of these parts must appear in the order presented here. (A complete grammar for the specification language is given in Appendix A.) The particulars of each part of the specification are described in the subsections below.

Package and Import Specifications
A specification begins with optional package and import declarations. These have the same syntax, and play the same role, as the package and import declarations found in a normal Java program. A package declaration is of the form:
    package name;
where name name is a Java package identifier, possibly in several parts separated by ".". In general, CUP employs Java lexical conventions. So for example, both styles of Java comments are supported, and identifiers are constructed beginning with a letter, dollar sign ($), or underscore (_), which can then be followed by zero or more letters, numbers, dollar signs, and underscores.

After an optional package declaration, there can be zero or more import declarations. As in a Java program these have the form:

    import package_name.class_name;
or
    import package_name.*;
The package declaration indicates what package the sym and parser classes that are generated by the system will be in. Any import declarations that appear in the specification will also appear in the source file for the parser class allowing various names from that package to be used directly in user supplied action code.
User Code Components
Following the optional package and import declarations are a series of optional declarations that allow user code to be included as part of the generated parser (see Section 4 for a full description of how the parser uses this code). As a part of the parser file, a separate non-public class to contain all embedded user actions is produced. The first action code declaration section allows code to be included in this class. Routines and variables for use by the code embedded in the grammar would normally be placed in this section (a typical example might be symbol table manipulation routines). This declaration takes the form:
    action code {: ... :};
where {: ... :} is a code string whose contents will be placed directly within the action class class declaration.

After the action code declaration is an optional parser code declaration. This declaration allows methods and variable to be placed directly within the generated parser class. Although this is less common, it can be helpful when customizing the parser -- it is possible for example, to include scanning methods inside the parser and/or override the default error reporting routines. This declaration is very similar to the action code declaration and takes the form:

    parser code {: ... :};
Again, code from the code string is placed directly into the generated parser class definition.

Next in the specification is the optional init declaration which has the form:

    init with {: ... :};
This declaration provides code that will be executed by the parser before it asks for the first token. Typically, this is used to initialize the scanner as well as various tables and other data structures that might be needed by semantic actions. In this case, the code given in the code string forms the body of a void method inside the parser class.

The final (optional) user code section of the specification indicates how the parser should ask for the next token from the scanner. This has the form:

    scan with {: ... :};
As with the init clause, the contents of the code string forms the body of a method in the generated parser. However, in this case the method returns an object of type java_cup.runtime.Symbol. Consequently the code found in the scan with clause should return such a value.

Symbol Lists
Following user supplied code comes the first required part of the specification: the symbol lists. These declarations are responsible for naming and supplying a type for each terminal and non-terminal symbol that appears in the grammar. As indicated above, each terminal and non-terminal symbol is represented at runtime with a Symbol object. In the case of terminals, these are returned by the scanner and placed on the parse stack. The lexer should put the value of the terminal in the value instance variable. In the case of non terminals these replace a series of Symbol objects on the parse stack whenever the right hand side of some production is recognized. In order to tell the parser which object types should be used for which symbol, terminal and non terminal declarations are used. These take the forms:
    terminal classname name1, name2, ...;
    non terminal classname name1, name2, ...;
    terminal name1, name2, ...;
and
    non terminal name1, name2, ...;
where classname can be a multiple part name separated with "."s. The classname specified represents the type of the value of that terminal or non-terminal. When accessing these values through labels, the users uses the type declared. the classname can be of any type. If no classname is given, then the terminal or non-terminal holds no value. a label referring to such a symbol with have a null value.
Precedence and Associativity declarations
The third section, which is optional, specifies the precedences and associativity of terminals. This is useful for parsing with ambiguous grammars, as done in the example above. There are three type of precedence/associativity declarations:

	precedence left     terminal[, terminal...];
	precedence right    terminal[, terminal...];
	precedence nonassoc terminal[, terminal...];
The comma separated list indicates that those terminals should have the associativity specified at that precedence level and the precedence of that declaration. The order of precedence, from highest to lowest, is bottom to top. Hence, this declares that multiplication and division have higher precedence than addition and subtraction:

	precedence left  ADD, SUBTRACT;
	precedence left  TIMES, DIVIDE;
Precedence resolves shift reduce problems. For example, given the input to the above example parser 3 + 4 * 8, the parser doesn't know whether to reduce 3 + 4 or shift the '*' onto the stack. However, since '*' has a higher precedence than '+', it will be shifted and the multiplication will be performed before the addition.

CUP assigns each one of its terminals a precedence according to these declarations. Any terminals not in this declaration have lowest precedence. CUP also assigns each of its productions a precedence. That precedence is equal to the precedence of the last terminal in that production. If the production has no terminals, then it has lowest precedence. For example, expr ::= expr TIMES expr would have the same precedence as TIMES. When there is a shift/reduce conflict, the parser determines whether the terminal to be shifted has a higher precedence, or if the production to reduce by does. If the terminal has higher precedence, it it shifted, if the production has higher precedence, a reduce is performed. If they have equal precedence, associativity of the terminal determine what happens.

An associativity is assigned to each terminal used in the precedence/associativity declarations. The three associativities are left, right and nonassoc Associativities are also used to resolve shift/reduce conflicts, but only in the case of equal precedences. If the associativity of the terminal that can be shifted is left, then a reduce is performed. This means, if the input is a string of additions, like 3 + 4 + 5 + 6 + 7, the parser will always reduce them from left to right, in this case, starting with 3 + 4. If the associativity of the terminal is right, it is shifted onto the stack. hence, the reductions will take place from right to left. So, if PLUS were declared with associativity of right, the 6 + 7 would be reduced first in the above string. If a terminal is declared as nonassoc, then two consecutive occurrences of equal precedence non-associative terminals generates an error. This is useful for comparison operations. For example, if the input string is 6 == 7 == 8 == 9, the parser should generate an error. If '==' is declared as nonassoc then an error will be generated.

All terminals not used in the precedence/associativity declarations are treated as lowest precedence. If a shift/reduce error results, involving two such terminals, it cannot be resolved, as the above conflicts are, so it will be reported.

The Grammar
The final section of a CUP declaration provides the grammar. This section optionally starts with a declaration of the form:
    start with non-terminal;
This indicates which non-terminal is the start or goal non-terminal for parsing. If a start non-terminal is not explicitly declared, then the non terminal on the left hand side of the first production will be used. At the end of a successful parse, CUP returns an object of type java_cup.runtime.Symbol. This Symbol's value instance variable contains the final reduction result.

The grammar itself follows the optional start declaration. Each production in the grammar has a left hand side non terminal followed by the symbol "::=", which is then followed by a series of zero or more actions, terminal, or non terminal symbols, followed by an optional contextual precedence assignment, and terminated with a semicolon (;).

Each symbol on the right hand side can optionally be labeled with a name. Label names appear after the symbol name separated by a colon (:). Label names must be unique within the production, and can be used within action code to refer to the value of the symbol. Along with the label, two more variables are created, which are the label plus left and the label plus right. These are int values that contain the right and left locations of what the terminal or non-terminal covers in the input file. These values must be properly initialized in the terminals by the lexer. The left and right values then propagate to non-terminals to which productions reduce.

If there are several productions for the same non terminal they may be declared together. In this case the productions start with the non terminal and "::=". This is followed by multiple right hand sides each separated by a bar (|). The full set of productions is then terminated by a semicolon.

Actions appear in the right hand side as code strings (e.g., Java code inside {: ... :} delimiters). These are executed by the parser at the point when the portion of the production to the left of the action has been recognized. (Note that the scanner will have returned the token one past the point of the action since the parser needs this extra lookahead token for recognition.)

Contextual precedence assignments follow all the symbols and actions of the right hand side of the production whose precedence it is assigning. Contextual precedence assignment allows a production to be assigned a precedence not based on the last terminal in it. A good example is shown in the above sample parser specification:


	precedence left PLUS, MINUS;
	precedence left TIMES, DIVIDE, MOD;
	precedence left UMINUS;

	expr ::=  MINUS expr:e             
	          {: RESULT = new Integer(0 - e.intValue()); :} 
	          %prec UMINUS
Here, there production is declared as having the precedence of UMINUS. Hence, the parser can give the MINUS sign two different precedences, depending on whether it is a unary minus or a subtraction operation.

3. Running CUP

As mentioned above, CUP is written in Java. To invoke it, one needs to use the Java interpreter to invoke the static method java_cup.Main(), passing an array of strings containing options. Assuming a Unix machine, the simplest way to do this is typically to invoke it directly from the command line with a command such as:
    java java_cup.Main options < inputfile
Once running, CUP expects to find a specification file on standard input and produces two Java source files as output.

In addition to the specification file, CUP's behavior can also be changed by passing various options to it. Legal options include:

-package name
Specify that the parser and sym classes are to be placed in the named package. By default, no package specification is put in the generated code (hence the classes default to the special "unnamed" package).
-parser name
Output parser and action code into a file (and class) with the given name instead of the default of "parser".
-symbols name
Output the symbol constant code into a class with the given name instead of the default of "sym".
-nonterms
Place constants for non terminals into the symbol constant class. The parser does not need these symbol constants, so they are not normally output. However, it can be very helpful to refer to these constants when debugging a generated parser.
-expect number
During parser construction the system may detect that an ambiguous situation would occur at runtime. This is called a conflict. In general, the parser may be unable to decide whether to shift (read another symbol) or reduce (replace the recognized right hand side of a production with its left hand side). This is called a shift/reduce conflict. Similarly, the parser may not be able to decide between reduction with two different productions. This is called a reduce/reduce conflict. Normally, if one or more of these conflicts occur, parser generation is aborted. However, in certain carefully considered cases it may be advantageous to arbitrarily break such a conflict. In this case CUP uses YACC convention and resolves shift/reduce conflicts by shifting, and reduce/reduce conflicts using the "highest priority" production (the one declared first in the specification). In order to enable automatic breaking of conflicts the -expect option must be given indicating exactly how many conflicts are expected. Conflicts resolved by precedences and associativities are not reported.
-compact_red
Including this option enables a table compaction optimization involving reductions. In particular, it allows the most common reduce entry in each row of the parse action table to be used as the default for that row. This typically saves considerable room in the tables, which can grow to be very large. This optimization has the effect of replacing all error entries in a row with the default reduce entry. While this may sound dangerous, if not down right incorrect, it turns out that this does not affect the correctness of the parser. In particular, some changes of this type are inherent in LALR parsers (when compared to canonical LR parsers), and the resulting parsers will still never read past the first token at which the error could be detected. The parser can, however, make extra erroneous reduces before detecting the error, so this can degrade the parser's ability to do error recovery. (Refer to reference [2] pp. 244-247 or reference [3] pp. 190-194 for a complete explanation of this compaction technique.)

Special note: at the time of this writing the standard javac compiler had a bug which caused it to produce corrupted class files when very large statically initialized arrays (i.e., large parse tables) are used. Consequently, if you have a large grammar, you may be forced to use this option in order to create tables that are small enough to compile correctly.
-nowarn
This options causes all warning messages (as opposed to error messages) produced by the system to be suppressed.
-nosummary
Normally, the system prints a summary listing such things as the number of terminals, non terminals, parse states, etc. at the end of its run. This option suppresses that summary.
-progress
This option causes the system to print short messages indicating its progress through various parts of the parser generation process.
-dump_grammar
-dump_states
-dump_tables
-dump
These options cause the system to produce a human readable dump of the grammar, the constructed parse states (often needed to resolve parse conflicts), and the parse tables (rarely needed), respectively. The -dump option can be used to produce all of these dumps.
-time
This option adds detailed timing statistics to the normal summary of results. This is normally of great interest only to maintainers of the system itself.
-debug
This option produces voluminous internal debugging information about the system as it runs. This is normally of interest only to maintainers of the system itself.
-nopositions
This option keeps CUP from generating code to propagate the left and right hand values of terminals to non-terminals, and then from non-terminals to other terminals. If the left and right values aren't going to be used by the parser, then it will save some runtime computation to not generate these position propagations. This option also keeps the left and right label variables from being generated, so any reference to these will cause an error.

4. Customizing the Parser

Each generated parser consists of three generated classes. The sym class (which can be renamed using the -symbols option) simply contains a series of int constants, one for each terminal. Non terminals are also include if the -nonterms option is given. The source file for the parser class (which can be renamed using the -parser option) actually contains two class definitions, the public parser class that implements the actual parser, and another non-public class (called CUP$action) which encapsulates all user actions contained in the grammar, as well as code from the action code declaration. In addition to user supplied code, this class contains one method: CUP$do_action which consists of a large switch statement for selecting and executing various fragments of user supplied action code. In general, all names beginning with the prefix of CUP$ are reserved for internal uses by CUP generated code.

The parser class contains the actual generated parser. It is a subclass of java_cup.runtime.lr_parser which implements a general table driven framework for an LR parser. The generated parser class provides a series of tables for use by the general framework. Three tables are provided:

the production table
provides the symbol number of the left hand side non terminal, along with the length of the right hand side, for each production in the grammar,
the action table
indicates what action (shift, reduce, or error) is to be taken on each lookahead symbol when encountered in each state, and
the reduce-goto table
indicates which state to shift to after reduces (under each non-terminal from each state).
(Note that the action and reduce-goto tables are not stored as simple arrays, but use a compacted "list" structure to save a significant amount of space. See comments the runtime system source code for details.)

Beyond the parse tables, generated (or inherited) code provides a series of methods that can be used to customize the generated parser. Some of these methods are supplied by code found in part of the specification and can be customized directly in that fashion. The others are provided by the lr_parser base class and can be overridden with new versions (via the parser code declaration) to customize the system. Methods available for customization include:

public void user_init()
This method is called by the parser prior to asking for the first token from the scanner. The body of this method contains the code from the init with clause of the the specification.
public java_cup.runtime.Symbol scan()
This method encapsulates the scanner and is called each time a new terminal is needed by the parser. The body of this method is supplied by the scan with clause of the specification.
public void report_error(String message, Object info)
This method should be called whenever an error message is to be issued. In the default implementation of this method, the first parameter provides the text of a message which is printed on System.err and the second parameter is simply ignored. It is very typical to override this method in order to provide a more sophisticated error reporting mechanism.
public void report_fatal_error(String message, Object info)
This method should be called whenever a non-recoverable error occurs. It responds by calling report_error(), then aborts parsing by calling the parser method done_parsing(), and finally throws an exception. (In general done_parsing() should be called at any point that parsing needs to be terminated early).
public void syntax_error(token cur_token)
This method is called by the parser as soon as a syntax error is detected (but before error recovery is attempted). In the default implementation it calls: report_error("Syntax error", null);.
public void unrecovered_syntax_error(token cur_token)
This method is called by the parser if it is unable to recover from a syntax error. In the default implementation it calls: report_fatal_error("Couldn't repair and continue parse", null);.
protected int error_sync_size()
This method is called by the parser to determine how many tokens it must successfully parse in order to consider an error recovery successful. The default implementation returns 3. Values below 2 are not recommended. See the section on error recovery for details.
Parsing itself is performed by the method public Symbol parse(). This method starts by getting references to each of the parse tables, then initializes a CUP$action object (by calling protected void init_actions()). Next it calls user_init(), then fetches the first lookahead token with a call to scan(). Finally, it begins parsing. Parsing continues until done_parsing() is called (this is done automatically, for example, when the parser accepts). It then returns a Symbol with the value instance variable containing the RESULT of the start production, or null, if there is no value.

In addition to the normal parser, the runtime system also provides a debugging version of the parser. This operates in exactly the same way as the normal parser, but prints debugging messages (by calling public void debug_message(String mess) whose default implementation prints a message to System.err).

Based on these routines, invocation of a CUP parser is typically done with code such as:

      /* create a parsing object */
      parser parser_obj = new parser();

      /* open input files, etc. here */
      Symbol parse_tree = null;

      try {
        if (do_debug_parse)
          parse_tree = parser_obj.debug_parse();
        else
          parse_tree = parser_obj.parse();
      } catch (Exception e) {
        /* do cleanup here -- possibly rethrow e */
      } finally {
	/* do close out here */
      }

5. Error Recovery

A final important aspect of building parsers with CUP is support for syntactic error recovery. CUP uses the same error recovery mechanisms as YACC. In particular, it supports a special error symbol (denoted simply as error). This symbol plays the role of a special non terminal which, instead of being defined by productions, instead matches an erroneous input sequence.

The error symbol only comes into play if a syntax error is detected. If a syntax error is detected then the parser tries to replace some portion of the input token stream with error and then continue parsing. For example, we might have productions such as:

    stmt ::= expr SEMI | while_stmt SEMI | if_stmt SEMI | ... |
	     error SEMI
	     ;
This indicates that if none of the normal productions for stmt can be matched by the input, then a syntax error should be declared, and recovery should be made by skipping erroneous tokens (equivalent to matching and replacing them with error) up to a point at which the parse can be continued with a semicolon (and additional context that legally follows a statement). An error is considered to be recovered from if and only if a sufficient number of tokens past the error symbol can be successfully parsed. (The number of tokens required is determined by the error_sync_size() method of the parser and defaults to 3).

Specifically, the parser first looks for the closest state to the top of the parse stack that has an outgoing transition under error. This generally corresponds to working from productions that represent more detailed constructs (such as a specific kind of statement) up to productions that represent more general or enclosing constructs (such as the general production for all statements or a production representing a whole section of declarations) until we get to a place where an error recovery production has been provided for. Once the parser is placed into a configuration that has an immediate error recovery (by popping the stack to the first such state), the parser begins skipping tokens to find a point at which the parse can be continued. After discarding each token, the parser attempts to parse ahead in the input (without executing any embedded semantic actions). If the parser can successfully parse past the required number of tokens, then the input is backed up to the point of recovery and the parse is resumed normally (executing all actions). If the parse cannot be continued far enough, then another token is discarded and the parser again tries to parse ahead. If the end of input is reached without making a successful recovery (or there was no suitable error recovery state found on the parse stack to begin with) then error recovery fails.

6. Conclusion

This manual has briefly described the CUP LALR parser generation system. CUP is designed to fill the same role as the well known YACC parser generator system, but is written in and operates entirely with Java code rather than C or C++. Additional details on the operation of the system can be found in the parser generator and runtime source code. See the CUP home page below for access to the API documentation for the system and its runtime.

This document covers the system as it stands at the time of its sixth alpha release (v0.9.1). Check the CUP home page: http://www.cc.gatech.edu/gvu/people/Faculty/hudson/java_cup/home.html for the latest release information, instructions for downloading the system, and additional news about the system. Bug reports and other comments for the developers can be sent to java-cup@cc.gatech.edu

CUP was originally written by Scott Hudson, in August of 1995.

It was most recently modified by Frank Flannery, in July of 1996.

References

[1]
S. C. Johnson, "YACC -- Yet Another Compiler Compiler", CS Technical Report #32, Bell Telephone Laboratories, Murray Hill, NJ, 1975.
[2]
A. Aho, R. Sethi, and J. Ullman, Compilers: Principles, Techniques, and Tools, Addison-Wesley Publishing, Reading, MA, 1986.
[3]
C. Fischer, and R. LeBlanc, Crafting a Compiler with C, Benjamin/Cummings Publishing, Redwood City, CA, 1991.

Appendix A. Grammar for CUP Specification Files



java_cup_spec ::= package_spec import_list code_part init_code 
		       scan_code symbol_list precedence_list start_spec 
		       production_list
package_spec       ::= PACKAGE multipart_id SEMI | empty
import_list        ::= import_list import_spec | empty
import_spec        ::= IMPORT import_id SEMI
code_part          ::= action_code_part parser_code_part 
action_code_part   ::= ACTION CODE CODE_STRING SEMI | empty
parser_code_part   ::= PARSER CODE CODE_STRING SEMI | empty
init_code          ::= INIT WITH CODE_STRING SEMI | empty
scan_code          ::= SCAN WITH CODE_STRING SEMI | empty
symbol_list        ::= symbol_list symbol | symbol
symbol             ::= TERMINAL type_id declares_term |
                       NON TERMINAL type_id declares_non_term |
		       TERMINAL declares_term |
		       NON TERMINAL declares_non_term
term_name_list     ::= term_name_list COMMA new_term_id | new_term_id
non_term_name_list ::= non_term_name_list COMMA new_non_term_id |
	               new_non_term_id
declares_term      ::= term_name_list SEMI
declares_non_term  ::= non_term_name_list SEMI
precedence_list    ::= precedence_l | empty
precedence_l       ::= precedence_l preced + preced;
preced             ::= PRECEDENCE LEFT terminal_list SEMI
	               | PRECEDENCE RIGHT terminal_list SEMI
	               | PRECEDENCE NONASSOC terminal_list SEMI
terminal_list      ::= terminal_list COMMA terminal_id | terminal_id 
start_spec         ::= START WITH nt_id SEMI | empty
production_list    ::= production_list production | production
production         ::= nt_id COLON_COLON_EQUALS rhs_list SEMI
rhs_list           ::= rhs_list BAR rhs | rhs
rhs                ::= prod_part_list PERCENT_PREC term_id |
                       prod_part_list
prod_part_list     ::= prod_part_list prod_part | empty
prod_part          ::= symbol_id opt_label | CODE_STRING
opt_label          ::= COLON label_id | empty
multipart_id       ::= multipart_id DOT ID | ID
import_id          ::= multipart_id DOT STAR | multipart_id
type_id            ::= multipart_id
terminal_id        ::= term_id
term_id            ::= symbol_id
new_term_id        ::= ID
new_non_term_id    ::= ID
nt_id              ::= ID
symbol_id          ::= ID
label_id           ::= ID


Appendix B. A Very Simple Example Scanner



// Simple Example Scanner Class

import java_cup.runtime.*;
import sym;

public class scanner {
  /* single lookahead character */
  protected static int next_char;

  /* advance input by one character */
  protected static void advance()
    throws java.io.IOException
    { next_char = System.in.read(); }

  /* initialize the scanner */
  public static void init()
    throws java.io.IOException
    { advance(); }

  /* recognize and return the next complete token */
  public static Symbol next_token()
    throws java.io.IOException
    {
      for (;;)
        switch (next_char)
	  {
	    case '0': case '1': case '2': case '3': case '4': 
	    case '5': case '6': case '7': case '8': case '9': 
	      /* parse a decimal integer */
	      int i_val = 0;
	      do {
	        i_val = i_val * 10 + (next_char - '0');
	        advance();
	      } while (next_char >= '0' && next_char <= '9');
	    return new Symbol(sym.NUMBER, new Integer(i_val));

	    case ';': advance(); return new Symbol(sym.SEMI);
	    case '+': advance(); return new Symbol(sym.PLUS);
	    case '-': advance(); return new Symbol(sym.MINUS);
	    case '*': advance(); return new Symbol(sym.TIMES);
	    case '/': advance(); return new Symbol(sym.DIVIDE);
	    case '%': advance(); return new Symbol(sym.MOD);
	    case '(': advance(); return new Symbol(sym.LPAREN);
	    case ')': advance(); return new Symbol(sym.RPAREN);

	    case -1: return new Symbol(sym.EOF);

	    default: 
	      /* in this simple scanner we just ignore everything else */
	      advance();
	    break;
	  }
    }
};

Appendix C: Changes to CUP Version 0.10a

CUP version 0.10a is a major overhaul of CUP. The changes are severe, meaning no backwards compatibility to older versions. The changes consist of:
Lexical Interface
CUP now interfaces with the lexer in a completely different manner. In the previous releases, a new class was used for every distinct type of terminal. This release, however, uses only one class: The Symbol class. The Symbol class has three instance variables which are significant to the parser when passing information from the lexer. The first is the value instance variable. This variable contains the value of that terminal. It is of the type declared as the terminal type in the parser specification file. The second two are the instance variables left and right. They should be filled with the int value of where in the input file, character-wise, that terminal was found.

For more information, refer to the manual on scanners.

Terminal/Non-Terminal Declarations
Terminal and non-nonterminal declarations now can be declared in two different ways to indicate the values of the terminals or non-terminals. The previous declarations of the form

terminal classname terminal [, terminal ...];
still works. The classname, however indicates the type of the value of the terminal or non-terminal, and does not indicate the type of object placed on the parse stack. A declaration, such as:

terminal terminal [, terminal ...];
indicates the terminals in the list hold no value.

For more information, refer to the manual on declarations.

Label References
Label references do not refer to the object on the parse stack, as in the old CUP, but rather to the value of the value instance variable of the Symbol that represents that terminal or non-terminal. Hence, references to terminal and non-terminal values is direct, as opposed to the old CUP, where the labels referred to objects containing the value of the terminal or non-terminal.

For more information, refer to the manual on labels.

RESULT Value
The RESULT variable refers directly to the value of the non-terminal to which a rule reduces, rather than to the object on the parse stack. Hence, RESULT is of the same type the non-terminal to which it reduces, as declared in the non terminal declaration. Again, the reference is direct, rather than to something that will contain the data.

For more information, refer to the manual on RESULT.

Position Propagation
For every label, two more variables are declared, which are the label plus left or the label plus right. These correspond to the left and right locations in the input stream to which that terminal or non-terminal came from. These values are propagated from the input terminals, so that the starting non-terminal should have a left value of 0 and a right value of the location of the last character read.

For more information, refer to the manual on positions.

Return Value
A call to parse() or debug_parse() returns a Symbol. This Symbol is the start non-terminal, so the value instance variable contains the final RESULT assignment.
Precedence
CUP now has precedenced terminals. a new declaration section, occurring between the terminal and non-terminal declarations and the grammar specifies the precedence and associativity of rules. The declarations are of the form:

precedence {left| right | nonassoc} terminal[, terminal ...];
...

The terminals are assigned a precedence, where terminals on the same line have equal precedences, and the precedence declarations farther down the list of precedence declarations have higher precedence. left, right and nonassoc specify the associativity of these terminals. left associativity corresponds to a reduce on conflict, right to a shift on conflict, and nonassoc to an error on conflict. Hence, ambiguous grammars may now be used.

For more information, refer to the manual on precedence.

Contextual Precedence
Finally the new CUP adds contextual precedence. A production may be declare as followed:

lhs ::= {right hand side list of terminals, non-terminals and actions}
        %prec {terminal};
this production would then have a precedence equal to the terminal specified after the %prec. Hence, shift/reduce conflicts can be contextually resolved. Note that the %prec terminal part comes after all actions strings. It does not come before the last action string.

For more information, refer to the manual on contextual precedence. These changes implemented by:

Frank Flannery
Department of Computer Science
Princeton University


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