Perfect Hash Function Generator

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Introduction

This manual documents the GNU gperf perfect hash function generator utility, focusing on its features and how to use them, and how to report bugs.

High-Level Description of GNU gperf

Input Format to gperf

Declarations

Invoking gperf


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Contributors to GNU gperf Utility


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1 Introduction

gperf is a perfect hash function generator written in C++. It transforms an n element user-specified keyword set W into a perfect hash function F. F uniquely maps keywords in W onto the range 0..k, where k >= n-1. If k = n-1 then F is a minimal perfect hash function. gperf generates a 0..k element static lookup table and a pair of C functions. These functions determine whether a given character string s occurs in W, using at most one probe into the lookup table.

gperf currently generates the reserved keyword recognizer for lexical analyzers in several production and research compilers and language processing tools, including GNU C, GNU C++, GNU Java, GNU Pascal, GNU Modula 3, and GNU indent. Complete C++ source code for gperf is available from http://ftp.gnu.org/pub/gnu/gperf/. A paper describing gperf's design and implementation in greater detail is available in the Second USENIX C++ Conference proceedings or from http://www.cs.wustl.edu/~schmidt/resume.html.


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2 Static search structures and GNU gperf

A static search structure is an Abstract Data Type with certain fundamental operations, e.g., initialize, insert, and retrieve. Conceptually, all insertions occur before any retrievals. In practice, gperf generates a static array containing search set keywords and any associated attributes specified by the user. Thus, there is essentially no execution-time cost for the insertions. It is a useful data structure for representing static search sets. Static search sets occur frequently in software system applications. Typical static search sets include compiler reserved words, assembler instruction opcodes, and built-in shell interpreter commands. Search set members, called keywords, are inserted into the structure only once, usually during program initialization, and are not generally modified at run-time.

Numerous static search structure implementations exist, e.g., arrays, linked lists, binary search trees, digital search tries, and hash tables. Different approaches offer trade-offs between space utilization and search time efficiency. For example, an n element sorted array is space efficient, though the average-case time complexity for retrieval operations using binary search is proportional to log n. Conversely, hash table implementations often locate a table entry in constant time, but typically impose additional memory overhead and exhibit poor worst case performance.

Minimal perfect hash functions provide an optimal solution for a particular class of static search sets. A minimal perfect hash function is defined by two properties:

For most applications it is far easier to generate perfect hash functions than minimal perfect hash functions. Moreover, non-minimal perfect hash functions frequently execute faster than minimal ones in practice. This phenomena occurs since searching a sparse keyword table increases the probability of locating a “null” entry, thereby reducing string comparisons. gperf's default behavior generates near-minimal perfect hash functions for keyword sets. However, gperf provides many options that permit user control over the degree of minimality and perfection.

Static search sets often exhibit relative stability over time. For example, Ada's 63 reserved words have remained constant for nearly a decade. It is therefore frequently worthwhile to expend concerted effort building an optimal search structure once, if it subsequently receives heavy use multiple times. gperf removes the drudgery associated with constructing time- and space-efficient search structures by hand. It has proven a useful and practical tool for serious programming projects. Output from gperf is currently used in several production and research compilers, including GNU C, GNU C++, GNU Java, GNU Pascal, and GNU Modula 3. The latter two compilers are not yet part of the official GNU distribution. Each compiler utilizes gperf to automatically generate static search structures that efficiently identify their respective reserved keywords.


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3 High-Level Description of GNU gperf

The perfect hash function generator gperf reads a set of “keywords” from an input file (or from the standard input by default). It attempts to derive a perfect hashing function that recognizes a member of the static keyword set with at most a single probe into the lookup table. If gperf succeeds in generating such a function it produces a pair of C source code routines that perform hashing and table lookup recognition. All generated C code is directed to the standard output. Command-line options described below allow you to modify the input and output format to gperf.

By default, gperf attempts to produce time-efficient code, with less emphasis on efficient space utilization. However, several options exist that permit trading-off execution time for storage space and vice versa. In particular, expanding the generated table size produces a sparse search structure, generally yielding faster searches. Conversely, you can direct gperf to utilize a C switch statement scheme that minimizes data space storage size. Furthermore, using a C switch may actually speed up the keyword retrieval time somewhat. Actual results depend on your C compiler, of course.

In general, gperf assigns values to the bytes it is using for hashing until some set of values gives each keyword a unique value. A helpful heuristic is that the larger the hash value range, the easier it is for gperf to find and generate a perfect hash function. Experimentation is the key to getting the most from gperf.


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3.1 Input Format to gperf

You can control the input file format by varying certain command-line arguments, in particular the ‘-t’ option. The input's appearance is similar to GNU utilities flex and bison (or UNIX utilities lex and yacc). Here's an outline of the general format:

     declarations
     %%
     keywords
     %%
     functions

Unlike flex or bison, the declarations section and the functions section are optional. The following sections describe the input format for each section.

It is possible to omit the declaration section entirely, if the ‘-t’ option is not given. In this case the input file begins directly with the first keyword line, e.g.:

     january
     february
     march
     april
     ...


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3.1.1 Declarations

The keyword input file optionally contains a section for including arbitrary C declarations and definitions, gperf declarations that act like command-line options, as well as for providing a user-supplied struct.


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3.1.1.1 User-supplied struct

If the ‘-t’ option (or, equivalently, the ‘%struct-type’ declaration) is enabled, you must provide a C struct as the last component in the declaration section from the input file. The first field in this struct must be of type char * or const char * if the ‘-P’ option is not given, or of type int if the option ‘-P’ (or, equivalently, the ‘%pic’ declaration) is enabled. This first field must be called ‘name’, although it is possible to modify its name with the ‘-K’ option (or, equivalently, the ‘%define slot-name’ declaration) described below.

Here is a simple example, using months of the year and their attributes as input:

     struct month { char *name; int number; int days; int leap_days; };
     %%
     january,   1, 31, 31
     february,  2, 28, 29
     march,     3, 31, 31
     april,     4, 30, 30
     may,       5, 31, 31
     june,      6, 30, 30
     july,      7, 31, 31
     august,    8, 31, 31
     september, 9, 30, 30
     october,  10, 31, 31
     november, 11, 30, 30
     december, 12, 31, 31

Separating the struct declaration from the list of keywords and other fields are a pair of consecutive percent signs, ‘%%’, appearing left justified in the first column, as in the UNIX utility lex.

If the struct has already been declared in an include file, it can be mentioned in an abbreviated form, like this:

     struct month;
     %%
     january,   1, 31, 31
     ...


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3.1.1.2 Gperf Declarations

The declaration section can contain gperf declarations. They influence the way gperf works, like command line options do. In fact, every such declaration is equivalent to a command line option. There are three forms of declarations:

  1. Declarations without argument, like ‘%compare-lengths’.
  2. Declarations with an argument, like ‘%switch=count’.
  3. Declarations of names of entities in the output file, like ‘%define lookup-function-name name’.

When a declaration is given both in the input file and as a command line option, the command-line option's value prevails.

The following gperf declarations are available.

%delimiters=delimiter-list
Allows you to provide a string containing delimiters used to separate keywords from their attributes. The default is ",". This option is essential if you want to use keywords that have embedded commas or newlines.
%struct-type
Allows you to include a struct type declaration for generated code; see above for an example.
%ignore-case
Consider upper and lower case ASCII characters as equivalent. The string comparison will use a case insignificant character comparison. Note that locale dependent case mappings are ignored.
%language=language-name
Instructs gperf to generate code in the language specified by the option's argument. Languages handled are currently:
KR-C
Old-style K&R C. This language is understood by old-style C compilers and ANSI C compilers, but ANSI C compilers may flag warnings (or even errors) because of lacking ‘const’.
C
Common C. This language is understood by ANSI C compilers, and also by old-style C compilers, provided that you #define const to empty for compilers which don't know about this keyword.
ANSI-C
ANSI C. This language is understood by ANSI C (C89, ISO C90) compilers, ISO C99 compilers, and C++ compilers.
C++
C++. This language is understood by C++ compilers.

The default is ANSI-C.

%define slot-name name
This declaration is only useful when option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) has been given. By default, the program assumes the structure component identifier for the keyword is ‘name’. This option allows an arbitrary choice of identifier for this component, although it still must occur as the first field in your supplied struct.
%define initializer-suffix initializers
This declaration is only useful when option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) has been given. It permits to specify initializers for the structure members following slot-name in empty hash table entries. The list of initializers should start with a comma. By default, the emitted code will zero-initialize structure members following slot-name.
%define hash-function-name name
Allows you to specify the name for the generated hash function. Default name is ‘hash’. This option permits the use of two hash tables in the same file.
%define lookup-function-name name
Allows you to specify the name for the generated lookup function. Default name is ‘in_word_set’. This option permits multiple generated hash functions to be used in the same application.
%define class-name name
This option is only useful when option ‘-L C++’ (or, equivalently, the ‘%language=C++’ declaration) has been given. It allows you to specify the name of generated C++ class. Default name is Perfect_Hash.
%7bit
This option specifies that all strings that will be passed as arguments to the generated hash function and the generated lookup function will solely consist of 7-bit ASCII characters (bytes in the range 0..127). (Note that the ANSI C functions isalnum and isgraph do not guarantee that a byte is in this range. Only an explicit test like ‘c >= 'A' && c <= 'Z'’ guarantees this.)
%compare-lengths
Compare keyword lengths before trying a string comparison. This option is mandatory for binary comparisons (see Binary Strings). It also might cut down on the number of string comparisons made during the lookup, since keywords with different lengths are never compared via strcmp. However, using ‘%compare-lengths’ might greatly increase the size of the generated C code if the lookup table range is large (which implies that the switch option ‘-S’ or ‘%switch’ is not enabled), since the length table contains as many elements as there are entries in the lookup table.
%compare-strncmp
Generates C code that uses the strncmp function to perform string comparisons. The default action is to use strcmp.
%readonly-tables
Makes the contents of all generated lookup tables constant, i.e., “readonly”. Many compilers can generate more efficient code for this by putting the tables in readonly memory.
%enum
Define constant values using an enum local to the lookup function rather than with #defines. This also means that different lookup functions can reside in the same file. Thanks to James Clark <jjc@ai.mit.edu>.
%includes
Include the necessary system include file, <string.h>, at the beginning of the code. By default, this is not done; the user must include this header file himself to allow compilation of the code.
%global-table
Generate the static table of keywords as a static global variable, rather than hiding it inside of the lookup function (which is the default behavior).
%pic
Optimize the generated table for inclusion in shared libraries. This reduces the startup time of programs using a shared library containing the generated code. If the ‘%struct-type’ declaration (or, equivalently, the option ‘-t’) is also given, the first field of the user-defined struct must be of type ‘int’, not ‘char *’, because it will contain offsets into the string pool instead of actual strings. To convert such an offset to a string, you can use the expression ‘stringpool + o’, where o is the offset. The string pool name can be changed through the ‘%define string-pool-name’ declaration.
%define string-pool-name name
Allows you to specify the name of the generated string pool created by the declaration ‘%pic’ (or, equivalently, the option ‘-P’). The default name is ‘stringpool’. This declaration permits the use of two hash tables in the same file, with ‘%pic’ and even when the ‘%global-table’ declaration (or, equivalently, the option ‘-G’) is given.
%null-strings
Use NULL strings instead of empty strings for empty keyword table entries. This reduces the startup time of programs using a shared library containing the generated code (but not as much as the declaration ‘%pic’), at the expense of one more test-and-branch instruction at run time.
%define constants-prefix prefix
Allows you to specify a prefix for the constants TOTAL_KEYWORDS, MIN_WORD_LENGTH, MAX_WORD_LENGTH, and so on. This option permits the use of two hash tables in the same file, even when the option ‘-E’ (or, equivalently, the ‘%enum’ declaration) is not given or the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
%define word-array-name name
Allows you to specify the name for the generated array containing the hash table. Default name is ‘wordlist’. This option permits the use of two hash tables in the same file, even when the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
%define length-table-name name
Allows you to specify the name for the generated array containing the length table. Default name is ‘lengthtable’. This option permits the use of two length tables in the same file, even when the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
%switch=count
Causes the generated C code to use a switch statement scheme, rather than an array lookup table. This can lead to a reduction in both time and space requirements for some input files. The argument to this option determines how many switch statements are generated. A value of 1 generates 1 switch containing all the elements, a value of 2 generates 2 tables with 1/2 the elements in each switch, etc. This is useful since many C compilers cannot correctly generate code for large switch statements. This option was inspired in part by Keith Bostic's original C program.
%omit-struct-type
Prevents the transfer of the type declaration to the output file. Use this option if the type is already defined elsewhere.


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3.1.1.3 C Code Inclusion

Using a syntax similar to GNU utilities flex and bison, it is possible to directly include C source text and comments verbatim into the generated output file. This is accomplished by enclosing the region inside left-justified surrounding ‘%{’, ‘%}’ pairs. Here is an input fragment based on the previous example that illustrates this feature:

     %{
     #include <assert.h>
     /* This section of code is inserted directly into the output. */
     int return_month_days (struct month *months, int is_leap_year);
     %}
     struct month { char *name; int number; int days; int leap_days; };
     %%
     january,   1, 31, 31
     february,  2, 28, 29
     march,     3, 31, 31
     ...


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3.1.2 Format for Keyword Entries

The second input file format section contains lines of keywords and any associated attributes you might supply. A line beginning with ‘#’ in the first column is considered a comment. Everything following the ‘#’ is ignored, up to and including the following newline. A line beginning with ‘%’ in the first column is an option declaration and must not occur within the keywords section.

The first field of each non-comment line is always the keyword itself. It can be given in two ways: as a simple name, i.e., without surrounding string quotation marks, or as a string enclosed in double-quotes, in C syntax, possibly with backslash escapes like \" or \234 or \xa8. In either case, it must start right at the beginning of the line, without leading whitespace. In this context, a “field” is considered to extend up to, but not include, the first blank, comma, or newline. Here is a simple example taken from a partial list of C reserved words:

     # These are a few C reserved words, see the c.gperf file
     # for a complete list of ANSI C reserved words.
     unsigned
     sizeof
     switch
     signed
     if
     default
     for
     while
     return

Note that unlike flex or bison the first ‘%%’ marker may be elided if the declaration section is empty.

Additional fields may optionally follow the leading keyword. Fields should be separated by commas, and terminate at the end of line. What these fields mean is entirely up to you; they are used to initialize the elements of the user-defined struct provided by you in the declaration section. If the ‘-t’ option (or, equivalently, the ‘%struct-type’ declaration) is not enabled these fields are simply ignored. All previous examples except the last one contain keyword attributes.


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3.1.3 Including Additional C Functions

The optional third section also corresponds closely with conventions found in flex and bison. All text in this section, starting at the final ‘%%’ and extending to the end of the input file, is included verbatim into the generated output file. Naturally, it is your responsibility to ensure that the code contained in this section is valid C.


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3.1.4 Where to place directives for GNU indent.

If you want to invoke GNU indent on a gperf input file, you will see that GNU indent doesn't understand the ‘%%’, ‘%{’ and ‘%}’ directives that control gperf's interpretation of the input file. Therefore you have to insert some directives for GNU indent. More precisely, assuming the most general input file structure

     declarations part 1
     %{
     verbatim code
     %}
     declarations part 2
     %%
     keywords
     %%
     functions

you would insert ‘*INDENT-OFF*’ and ‘*INDENT-ON*’ comments as follows:

     /* *INDENT-OFF* */
     declarations part 1
     %{
     /* *INDENT-ON* */
     verbatim code
     /* *INDENT-OFF* */
     %}
     declarations part 2
     %%
     keywords
     %%
     /* *INDENT-ON* */
     functions


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3.2 Output Format for Generated C Code with gperf

Several options control how the generated C code appears on the standard output. Two C functions are generated. They are called hash and in_word_set, although you may modify their names with a command-line option. Both functions require two arguments, a string, char * str, and a length parameter, int len. Their default function prototypes are as follows:

— Function: unsigned int hash (const char * str, unsigned int len)

By default, the generated hash function returns an integer value created by adding len to several user-specified str byte positions indexed into an associated values table stored in a local static array. The associated values table is constructed internally by gperf and later output as a static local C array called ‘hash_table’. The relevant selected positions (i.e. indices into str) are specified via the ‘-k’ option when running gperf, as detailed in the Options section below (see Options).

— Function: in_word_set (const char * str, unsigned int len)

If str is in the keyword set, returns a pointer to that keyword. More exactly, if the option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) was given, it returns a pointer to the matching keyword's structure. Otherwise it returns NULL.

If the option ‘-c’ (or, equivalently, the ‘%compare-strncmp’ declaration) is not used, str must be a NUL terminated string of exactly length len. If ‘-c’ (or, equivalently, the ‘%compare-strncmp’ declaration) is used, str must simply be an array of len bytes and does not need to be NUL terminated.

The code generated for these two functions is affected by the following options:

-t
--struct-type
Make use of the user-defined struct.
-S total-switch-statements
--switch=total-switch-statements
Generate 1 or more C switch statement rather than use a large, (and potentially sparse) static array. Although the exact time and space savings of this approach vary according to your C compiler's degree of optimization, this method often results in smaller and faster code.

If the ‘-t’ and ‘-S’ options (or, equivalently, the ‘%struct-type’ and ‘%switch’ declarations) are omitted, the default action is to generate a char * array containing the keywords, together with additional empty strings used for padding the array. By experimenting with the various input and output options, and timing the resulting C code, you can determine the best option choices for different keyword set characteristics.


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3.3 Use of NUL bytes

By default, the code generated by gperf operates on zero terminated strings, the usual representation of strings in C. This means that the keywords in the input file must not contain NUL bytes, and the str argument passed to hash or in_word_set must be NUL terminated and have exactly length len.

If option ‘-c’ (or, equivalently, the ‘%compare-strncmp’ declaration) is used, then the str argument does not need to be NUL terminated. The code generated by gperf will only access the first len, not len+1, bytes starting at str. However, the keywords in the input file still must not contain NUL bytes.

If option ‘-l’ (or, equivalently, the ‘%compare-lengths’ declaration) is used, then the hash table performs binary comparison. The keywords in the input file may contain NUL bytes, written in string syntax as \000 or \x00, and the code generated by gperf will treat NUL like any other byte. Also, in this case the ‘-c’ option (or, equivalently, the ‘%compare-strncmp’ declaration) is ignored.


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3.4 Controlling Identifiers

The identifiers of the functions, tables, and constants defined by the code generated by gperf can be controlled through gperf declarations or the equivalent command-line options. This is useful for three purposes:


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3.5 The Copyright of the Output

gperf is under GPL, but that does not cause the output produced by gperf to be under GPL. The reason is that the output contains only small pieces of text that come directly from gperf's source code – only about 7 lines long, too small for being significant –, and therefore the output is not a “work based on gperf” (in the sense of the GPL version 3).

On the other hand, the output produced by gperf contains essentially all of the input file. Therefore the output is a “derivative work” of the input (in the sense of U.S. copyright law); and its copyright status depends on the copyright of the input. For most software licenses, the result is that the the output is under the same license, with the same copyright holder, as the input that was passed to gperf.


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4 Invoking gperf

There are many options to gperf. They were added to make the program more convenient for use with real applications. “On-line” help is readily available via the ‘--help’ option. Here is the complete list of options.


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4.1 Specifying the Location of the Output File

--output-file=file
Allows you to specify the name of the file to which the output is written to.

The results are written to standard output if no output file is specified or if it is ‘-’.


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4.2 Options that affect Interpretation of the Input File

These options are also available as declarations in the input file (see Gperf Declarations).

-e keyword-delimiter-list
--delimiters=keyword-delimiter-list
Allows you to provide a string containing delimiters used to separate keywords from their attributes. The default is ",". This option is essential if you want to use keywords that have embedded commas or newlines. One useful trick is to use -e'TAB', where TAB is the literal tab character.
-t
--struct-type
Allows you to include a struct type declaration for generated code. Any text before a pair of consecutive ‘%%’ is considered part of the type declaration. Keywords and additional fields may follow this, one group of fields per line. A set of examples for generating perfect hash tables and functions for Ada, C, C++, Pascal, Modula 2, Modula 3 and JavaScript reserved words are distributed with this release.
--ignore-case
Consider upper and lower case ASCII characters as equivalent. The string comparison will use a case insignificant character comparison. Note that locale dependent case mappings are ignored. This option is therefore not suitable if a properly internationalized or locale aware case mapping should be used. (For example, in a Turkish locale, the upper case equivalent of the lowercase ASCII letter ‘i’ is the non-ASCII character ‘capital i with dot above’.) For this case, it is better to apply an uppercase or lowercase conversion on the string before passing it to the gperf generated function.


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4.3 Options to specify the Language for the Output Code

These options are also available as declarations in the input file (see Gperf Declarations).

-L generated-language-name
--language=generated-language-name
Instructs gperf to generate code in the language specified by the option's argument. Languages handled are currently:
KR-C
Old-style K&R C. This language is understood by old-style C compilers and ANSI C compilers, but ANSI C compilers may flag warnings (or even errors) because of lacking ‘const’.
C
Common C. This language is understood by ANSI C compilers, and also by old-style C compilers, provided that you #define const to empty for compilers which don't know about this keyword.
ANSI-C
ANSI C. This language is understood by ANSI C compilers and C++ compilers.
C++
C++. This language is understood by C++ compilers.

The default is ANSI-C.

-a
This option is supported for compatibility with previous releases of gperf. It does not do anything.
-g
This option is supported for compatibility with previous releases of gperf. It does not do anything.


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4.4 Options for fine tuning Details in the Output Code

Most of these options are also available as declarations in the input file (see Gperf Declarations).

-K slot-name
--slot-name=slot-name
This option is only useful when option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) has been given. By default, the program assumes the structure component identifier for the keyword is ‘name’. This option allows an arbitrary choice of identifier for this component, although it still must occur as the first field in your supplied struct.
-F initializers
--initializer-suffix=initializers
This option is only useful when option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) has been given. It permits to specify initializers for the structure members following slot-name in empty hash table entries. The list of initializers should start with a comma. By default, the emitted code will zero-initialize structure members following slot-name.
-H hash-function-name
--hash-function-name=hash-function-name
Allows you to specify the name for the generated hash function. Default name is ‘hash’. This option permits the use of two hash tables in the same file.
-N lookup-function-name
--lookup-function-name=lookup-function-name
Allows you to specify the name for the generated lookup function. Default name is ‘in_word_set’. This option permits multiple generated hash functions to be used in the same application.
-Z class-name
--class-name=class-name
This option is only useful when option ‘-L C++’ (or, equivalently, the ‘%language=C++’ declaration) has been given. It allows you to specify the name of generated C++ class. Default name is Perfect_Hash.
-7
--seven-bit
This option specifies that all strings that will be passed as arguments to the generated hash function and the generated lookup function will solely consist of 7-bit ASCII characters (bytes in the range 0..127). (Note that the ANSI C functions isalnum and isgraph do not guarantee that a byte is in this range. Only an explicit test like ‘c >= 'A' && c <= 'Z'’ guarantees this.) This was the default in versions of gperf earlier than 2.7; now the default is to support 8-bit and multibyte characters.
-l
--compare-lengths
Compare keyword lengths before trying a string comparison. This option is mandatory for binary comparisons (see Binary Strings). It also might cut down on the number of string comparisons made during the lookup, since keywords with different lengths are never compared via strcmp. However, using ‘-l’ might greatly increase the size of the generated C code if the lookup table range is large (which implies that the switch option ‘-S’ or ‘%switch’ is not enabled), since the length table contains as many elements as there are entries in the lookup table.
-c
--compare-strncmp
Generates C code that uses the strncmp function to perform string comparisons. The default action is to use strcmp.
-C
--readonly-tables
Makes the contents of all generated lookup tables constant, i.e., “readonly”. Many compilers can generate more efficient code for this by putting the tables in readonly memory.
-E
--enum
Define constant values using an enum local to the lookup function rather than with #defines. This also means that different lookup functions can reside in the same file. Thanks to James Clark <jjc@ai.mit.edu>.
-I
--includes
Include the necessary system include file, <string.h>, at the beginning of the code. By default, this is not done; the user must include this header file himself to allow compilation of the code.
-G
--global-table
Generate the static table of keywords as a static global variable, rather than hiding it inside of the lookup function (which is the default behavior).
-P
--pic
Optimize the generated table for inclusion in shared libraries. This reduces the startup time of programs using a shared library containing the generated code. If the option ‘-t’ (or, equivalently, the ‘%struct-type’ declaration) is also given, the first field of the user-defined struct must be of type ‘int’, not ‘char *’, because it will contain offsets into the string pool instead of actual strings. To convert such an offset to a string, you can use the expression ‘stringpool + o’, where o is the offset. The string pool name can be changed through the option ‘--string-pool-name’.
-Q string-pool-name
--string-pool-name=string-pool-name
Allows you to specify the name of the generated string pool created by option ‘-P’. The default name is ‘stringpool’. This option permits the use of two hash tables in the same file, with ‘-P’ and even when the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
--null-strings
Use NULL strings instead of empty strings for empty keyword table entries. This reduces the startup time of programs using a shared library containing the generated code (but not as much as option ‘-P’), at the expense of one more test-and-branch instruction at run time.
--constants-prefix=prefix
Allows you to specify a prefix for the constants TOTAL_KEYWORDS, MIN_WORD_LENGTH, MAX_WORD_LENGTH, and so on. This option permits the use of two hash tables in the same file, even when the option ‘-E’ (or, equivalently, the ‘%enum’ declaration) is not given or the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
-W hash-table-array-name
--word-array-name=hash-table-array-name
Allows you to specify the name for the generated array containing the hash table. Default name is ‘wordlist’. This option permits the use of two hash tables in the same file, even when the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
--length-table-name=length-table-array-name
Allows you to specify the name for the generated array containing the length table. Default name is ‘lengthtable’. This option permits the use of two length tables in the same file, even when the option ‘-G’ (or, equivalently, the ‘%global-table’ declaration) is given.
-S total-switch-statements
--switch=total-switch-statements
Causes the generated C code to use a switch statement scheme, rather than an array lookup table. This can lead to a reduction in both time and space requirements for some input files. The argument to this option determines how many switch statements are generated. A value of 1 generates 1 switch containing all the elements, a value of 2 generates 2 tables with 1/2 the elements in each switch, etc. This is useful since many C compilers cannot correctly generate code for large switch statements. This option was inspired in part by Keith Bostic's original C program.
-T
--omit-struct-type
Prevents the transfer of the type declaration to the output file. Use this option if the type is already defined elsewhere.
-p
This option is supported for compatibility with previous releases of gperf. It does not do anything.


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4.5 Options for changing the Algorithms employed by gperf

-k selected-byte-positions
--key-positions=selected-byte-positions
Allows selection of the byte positions used in the keywords' hash function. The allowable choices range between 1-255, inclusive. The positions are separated by commas, e.g., ‘-k 9,4,13,14’; ranges may be used, e.g., ‘-k 2-7’; and positions may occur in any order. Furthermore, the wildcard '*' causes the generated hash function to consider all byte positions in each keyword, whereas '$' instructs the hash function to use the “final byte” of a keyword (this is the only way to use a byte position greater than 255, incidentally).

For instance, the option ‘-k 1,2,4,6-10,'$'’ generates a hash function that considers positions 1,2,4,6,7,8,9,10, plus the last byte in each keyword (which may be at a different position for each keyword, obviously). Keywords with length less than the indicated byte positions work properly, since selected byte positions exceeding the keyword length are simply not referenced in the hash function.

This option is not normally needed since version 2.8 of gperf; the default byte positions are computed depending on the keyword set, through a search that minimizes the number of byte positions.

-D
--duplicates
Handle keywords whose selected byte sets hash to duplicate values. Duplicate hash values can occur if a set of keywords has the same names, but possesses different attributes, or if the selected byte positions are not well chosen. With the -D option gperf treats all these keywords as part of an equivalence class and generates a perfect hash function with multiple comparisons for duplicate keywords. It is up to you to completely disambiguate the keywords by modifying the generated C code. However, gperf helps you out by organizing the output.

Using this option usually means that the generated hash function is no longer perfect. On the other hand, it permits gperf to work on keyword sets that it otherwise could not handle.

-m iterations
--multiple-iterations=iterations
Perform multiple choices of the ‘-i’ and ‘-j’ values, and choose the best results. This increases the running time by a factor of iterations but does a good job minimizing the generated table size.
-i initial-value
--initial-asso=initial-value
Provides an initial value for the associate values array. Default is 0. Increasing the initial value helps inflate the final table size, possibly leading to more time efficient keyword lookups. Note that this option is not particularly useful when ‘-S’ (or, equivalently, ‘%switch’) is used. Also, ‘-i’ is overridden when the ‘-r’ option is used.
-j jump-value
--jump=jump-value
Affects the “jump value”, i.e., how far to advance the associated byte value upon collisions. Jump-value is rounded up to an odd number, the default is 5. If the jump-value is 0 gperf jumps by random amounts.
-n
--no-strlen
Instructs the generator not to include the length of a keyword when computing its hash value. This may save a few assembly instructions in the generated lookup table.
-r
--random
Utilizes randomness to initialize the associated values table. This frequently generates solutions faster than using deterministic initialization (which starts all associated values at 0). Furthermore, using the randomization option generally increases the size of the table.
-s size-multiple
--size-multiple=size-multiple
Affects the size of the generated hash table. The numeric argument for this option indicates “how many times larger or smaller” the maximum associated value range should be, in relationship to the number of keywords. It can be written as an integer, a floating-point number or a fraction. For example, a value of 3 means “allow the maximum associated value to be about 3 times larger than the number of input keywords”. Conversely, a value of 1/3 means “allow the maximum associated value to be about 3 times smaller than the number of input keywords”. Values smaller than 1 are useful for limiting the overall size of the generated hash table, though the option ‘-m’ is better at this purpose.

If `generate switch' option ‘-S’ (or, equivalently, ‘%switch’) is not enabled, the maximum associated value influences the static array table size, and a larger table should decrease the time required for an unsuccessful search, at the expense of extra table space.

The default value is 1, thus the default maximum associated value about the same size as the number of keywords (for efficiency, the maximum associated value is always rounded up to a power of 2). The actual table size may vary somewhat, since this technique is essentially a heuristic.


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4.6 Informative Output

-h
--help
Prints a short summary on the meaning of each program option. Aborts further program execution.
-v
--version
Prints out the current version number.
-d
--debug
Enables the debugging option. This produces verbose diagnostics to “standard error” when gperf is executing. It is useful both for maintaining the program and for determining whether a given set of options is actually speeding up the search for a solution. Some useful information is dumped at the end of the program when the ‘-d’ option is enabled.


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5 Known Bugs and Limitations with gperf

The following are some limitations with the current release of gperf:


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6 Things Still Left to Do

It should be “relatively” easy to replace the current perfect hash function algorithm with a more exhaustive approach; the perfect hash module is essential independent from other program modules. Additional worthwhile improvements include:


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7 Bibliography

[1] Chang, C.C.: A Scheme for Constructing Ordered Minimal Perfect Hashing Functions Information Sciences 39(1986), 187-195.

[2] Cichelli, Richard J. Author's Response to “On Cichelli's Minimal Perfect Hash Functions Method” Communications of the ACM, 23, 12(December 1980), 729.

[3] Cichelli, Richard J. Minimal Perfect Hash Functions Made Simple Communications of the ACM, 23, 1(January 1980), 17-19.

[4] Cook, C. R. and Oldehoeft, R.R. A Letter Oriented Minimal Perfect Hashing Function SIGPLAN Notices, 17, 9(September 1982), 18-27.

[5] Cormack, G. V. and Horspool, R. N. S. and Kaiserwerth, M. Practical Perfect Hashing Computer Journal, 28, 1(January 1985), 54-58.

[6] Jaeschke, G. Reciprocal Hashing: A Method for Generating Minimal Perfect Hashing Functions Communications of the ACM, 24, 12(December 1981), 829-833.

[7] Jaeschke, G. and Osterburg, G. On Cichelli's Minimal Perfect Hash Functions Method Communications of the ACM, 23, 12(December 1980), 728-729.

[8] Sager, Thomas J. A Polynomial Time Generator for Minimal Perfect Hash Functions Communications of the ACM, 28, 5(December 1985), 523-532

[9] Schmidt, Douglas C. GPERF: A Perfect Hash Function Generator Second USENIX C++ Conference Proceedings, April 1990.

[10] Schmidt, Douglas C. GPERF: A Perfect Hash Function Generator C++ Report, SIGS 10 10 (November/December 1998).

[11] Sebesta, R.W. and Taylor, M.A. Minimal Perfect Hash Functions for Reserved Word Lists SIGPLAN Notices, 20, 12(September 1985), 47-53.

[12] Sprugnoli, R. Perfect Hashing Functions: A Single Probe Retrieving Method for Static Sets Communications of the ACM, 20 11(November 1977), 841-850.

[13] Stallman, Richard M. Using and Porting GNU CC Free Software Foundation, 1988.

[14] Stroustrup, Bjarne The C++ Programming Language. Addison-Wesley, 1986.

[15] Tiemann, Michael D. User's Guide to GNU C++ Free Software Foundation, 1989.


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