1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
5 -- G N A T . P E R F E C T _ H A S H _ G E N E R A T O R S --
9 -- Copyright (C) 2002-2005, AdaCore --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 2, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING. If not, write --
19 -- to the Free Software Foundation, 51 Franklin Street, Fifth Floor, --
20 -- Boston, MA 02110-1301, USA. --
22 -- As a special exception, if other files instantiate generics from this --
23 -- unit, or you link this unit with other files to produce an executable, --
24 -- this unit does not by itself cause the resulting executable to be --
25 -- covered by the GNU General Public License. This exception does not --
26 -- however invalidate any other reasons why the executable file might be --
27 -- covered by the GNU Public License. --
29 -- GNAT was originally developed by the GNAT team at New York University. --
30 -- Extensive contributions were provided by Ada Core Technologies Inc. --
32 ------------------------------------------------------------------------------
34 -- This package provides a generator of static minimal perfect hash functions.
35 -- To understand what a perfect hash function is, we define several notions.
36 -- These definitions are inspired from the following paper:
38 -- Zbigniew J. Czech, George Havas, and Bohdan S. Majewski ``An Optimal
39 -- Algorithm for Generating Minimal Perfect Hash Functions'', Information
40 -- Processing Letters, 43(1992) pp.257-264, Oct.1992
42 -- Let W be a set of m words. A hash function h is a function that maps the
43 -- set of words W into some given interval of integers [0, k-1], where k is an
44 -- integer, usually k >= m. h (w) where is a word computes an address or an
45 -- integer from I for the storage or the retrieval of that item. The storage
46 -- area used to store items is known as a hash table. Words for which the same
47 -- address is computed are called synonyms. Due to the existence of synonyms a
48 -- situation called collision may arise in which two items w1 and w2 have the
49 -- same address. Several schemes for resolving known. A perfect hash function
50 -- is an injection from the word set W to the integer interval I with k >= m.
51 -- If k = m, then h is a minimal perfect hash function. A hash function is
52 -- order preserving if it puts entries into the hash table in prespecified
55 -- A minimal perfect hash function is defined by two properties:
57 -- Since no collisions occur each item can be retrieved from the table in
58 -- *one* probe. This represents the "perfect" property.
60 -- The hash table size corresponds to the exact size of W and *no larger*.
61 -- This represents the "minimal" property.
63 -- The functions generated by this package require the key set to be known in
64 -- advance (they are "static" hash functions). The hash functions are also
65 -- order preserving. If w2 is inserted after w1 in the generator, then (w1)
66 -- < f (w2). These hashing functions are convenient for use with realtime
69 package GNAT
.Perfect_Hash_Generators
is
71 Default_K_To_V
: constant Float := 2.05;
72 -- Default ratio for the algorithm. When K is the number of keys, V =
73 -- (K_To_V) * K is the size of the main table of the hash function. To
74 -- converge, the algorithm requires K_To_V to be strictly greater than 2.0.
76 Default_Pkg_Name
: constant String := "Perfect_Hash";
77 -- Default package name in which the hash function is defined
79 Default_Position
: constant String := "";
80 -- The generator allows selection of the character positions used in the
81 -- hash function. By default, all positions are selected.
83 Default_Tries
: constant Positive := 20;
84 -- This algorithm may not succeed to find a possible mapping on the first
85 -- try and may have to iterate a number of times. This constant bounds the
88 type Optimization
is (Memory_Space
, CPU_Time
);
89 Default_Optimization
: constant Optimization
:= CPU_Time
;
90 -- Optimize either the memory space or the execution time
92 Verbose
: Boolean := False;
93 -- Output the status of the algorithm. For instance, the tables, the random
94 -- graph (edges, vertices) and selected char positions are output between
99 K_To_V
: Float := Default_K_To_V
;
100 Optim
: Optimization
:= CPU_Time
;
101 Tries
: Positive := Default_Tries
);
102 -- Initialize the generator and its internal structures. Set the ratio of
103 -- vertices over keys in the random graphs. This value has to be greater
104 -- than 2.0 in order for the algorithm to succeed. The key set is not
105 -- modified (in particular when it is already set). For instance, it is
106 -- possible to run several times the generator with different settings on
110 -- Deallocate the internal structures and the key table
112 procedure Insert
(Value
: String);
113 -- Insert a new key in the table
115 Too_Many_Tries
: exception;
116 -- Raised after Tries unsuccessful runs
118 procedure Compute
(Position
: String := Default_Position
);
119 -- Compute the hash function. Position allows to define selection of
120 -- character positions used in the keywords hash function. Positions can be
121 -- separated by commas and range like x-y may be used. Character '$'
122 -- represents the final character of a key. With an empty position, the
123 -- generator automatically produces positions to reduce the memory usage.
124 -- Raise Too_Many_Tries in case that the algorithm does not succeed in less
125 -- than Tries attempts (see Initialize).
127 procedure Produce
(Pkg_Name
: String := Default_Pkg_Name
);
128 -- Generate the hash function package Pkg_Name. This package includes the
129 -- minimal perfect Hash function.
131 -- The routines and structures defined below allow producing the hash
132 -- function using a different way from the procedure above. The procedure
133 -- Define returns the lengths of an internal table and its item type size.
134 -- The function Value returns the value of each item in the table.
136 -- The hash function has the following form:
138 -- h (w) = (g (f1 (w)) + g (f2 (w))) mod m
140 -- G is a function based on a graph table [0,n-1] -> [0,m-1]. m is the
141 -- number of keys. n is an internally computed value and it can be obtained
142 -- as the length of vector G.
144 -- F1 and F2 are two functions based on two function tables T1 and T2.
145 -- Their definition depends on the chosen optimization mode.
147 -- Only some character positions are used in the keys because they are
148 -- significant. They are listed in a character position table (P in the
149 -- pseudo-code below). For instance, in {"jan", "feb", "mar", "apr", "jun",
150 -- "jul", "aug", "sep", "oct", "nov", "dec"}, only positions 2 and 3 are
151 -- significant (the first character can be ignored). In this example, P =
154 -- When Optimization is CPU_Time, the first dimension of T1 and T2
155 -- corresponds to the character position in the key and the second to the
156 -- character set. As all the character set is not used, we define a used
157 -- character table which associates a distinct index to each used character
158 -- (unused characters are mapped to zero). In this case, the second
159 -- dimension of T1 and T2 is reduced to the used character set (C in the
160 -- pseudo-code below). Therefore, the hash function has the following:
162 -- function Hash (S : String) return Natural is
163 -- F : constant Natural := S'First - 1;
164 -- L : constant Natural := S'Length;
165 -- F1, F2 : Natural := 0;
169 -- for K in P'Range loop
170 -- exit when L < P (K);
171 -- J := C (S (P (K) + F));
172 -- F1 := (F1 + Natural (T1 (K, J))) mod <n>;
173 -- F2 := (F2 + Natural (T2 (K, J))) mod <n>;
176 -- return (Natural (G (F1)) + Natural (G (F2))) mod <m>;
179 -- When Optimization is Memory_Space, the first dimension of T1 and T2
180 -- corresponds to the character position in the key and the second
181 -- dimension is ignored. T1 and T2 are no longer matrices but vectors.
182 -- Therefore, the used character table is not available. The hash function
183 -- has the following form:
185 -- function Hash (S : String) return Natural is
186 -- F : constant Natural := S'First - 1;
187 -- L : constant Natural := S'Length;
188 -- F1, F2 : Natural := 0;
192 -- for K in P'Range loop
193 -- exit when L < P (K);
194 -- J := Character'Pos (S (P (K) + F));
195 -- F1 := (F1 + Natural (T1 (K) * J)) mod <n>;
196 -- F2 := (F2 + Natural (T2 (K) * J)) mod <n>;
199 -- return (Natural (G (F1)) + Natural (G (F2))) mod <m>;
211 Item_Size
: out Natural;
212 Length_1
: out Natural;
213 Length_2
: out Natural);
214 -- Return the definition of the table Name. This includes the length of
215 -- dimensions 1 and 2 and the size of an unsigned integer item. When
216 -- Length_2 is zero, the table has only one dimension. All the ranges start
222 K
: Natural := 0) return Natural;
223 -- Return the value of the component (I, J) of the table Name. When the
224 -- table has only one dimension, J is ignored.
226 end GNAT
.Perfect_Hash_Generators
;