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| author | David A. Holland |
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| date | Sat, 22 Dec 2007 17:52:45 -0500 |
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| 1 <!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 3.2//EN"> | |
| 2 <HTML> | |
| 3 <HEAD> | |
| 4 <TITLE>String Dictionary Class Definition</TITLE> | |
| 5 </HEAD> | |
| 6 | |
| 7 | |
| 8 <BODY BGCOLOR="#ffffff" BACKGROUND="tilbl6h.gif" | |
| 9 TEXT="#000000" LINK="#0033CC" | |
| 10 VLINK="#CC0033" ALINK="#CC0099"> | |
| 11 | |
| 12 <P> | |
| 13 <IMG ALIGN="right" SRC="../images/agrsl6c.gif" ALT="AnaGram" | |
| 14 WIDTH=124 HEIGHT=30 > | |
| 15 <BR CLEAR="all"> | |
| 16 Back to : | |
| 17 <A HREF="../index.html">Index</A> | | |
| 18 <A HREF="index.html">Class libraries for examples</A> | |
| 19 <P> | |
| 20 | |
| 21 <IMG ALIGN="bottom" SRC="../images/rbline6j.gif" ALT="----------------------" | |
| 22 WIDTH=1010 HEIGHT=2 > | |
| 23 <P> | |
| 24 | |
| 25 <H1>String Dictionary Class Definition</H1> | |
| 26 <IMG ALIGN="bottom" SRC="../images/rbline6j.gif" ALT="----------------------" | |
| 27 WIDTH=1010 HEIGHT=2 > | |
| 28 <P> | |
| 29 <BR> | |
| 30 <H2>Introduction</H2> | |
| 31 <P> | |
| 32 | |
| 33 A string dictionary is a device for keeping track of character strings. | |
| 34 It associates a unique, non-zero, unsigned integer with each unique | |
| 35 string inserted in the dictionary. These indices are assigned in order | |
| 36 of insertion, so that the first string inserted has index 1, the second | |
| 37 index 2, and so on. These indices may be used to index auxiliary tables | |
| 38 containing information about the corresponding string. In particular, | |
| 39 these indices may be conveniently used to index a symbol table. A | |
| 40 hashing scheme is used to facilitate quick identification of a given | |
| 41 string. | |
| 42 <P> | |
| 43 <BR> | |
| 44 | |
| 45 <H2>Constructor </H2> | |
| 46 | |
| 47 The constructor for a string dictionary takes two unsigned integer | |
| 48 arguments: the maximum number of entries and the average number of | |
| 49 bytes per entry. The latter will default to ten if you don't specify | |
| 50 it. The product of size and length must be less than 65536. For | |
| 51 example: | |
| 52 <PRE> | |
| 53 string_dictionary td(5000); // 5000 entries, default size | |
| 54 string_dictionary xx(500,20); // 500 entries, average size = 20 | |
| 55 </PRE> | |
| 56 <P> | |
| 57 <BR> | |
| 58 | |
| 59 <H2>Entering Strings in a Dictionary </H2> | |
| 60 | |
| 61 To enter a string in a dictionary, use the overloaded operator " << ", | |
| 62 with the dictionary on the left, the string on the right. The result is | |
| 63 a nonzero, unsigned integer. For example: | |
| 64 <PRE> | |
| 65 unsigned hwx = td << "Hello, world!"; | |
| 66 </PRE> | |
| 67 <P> | |
| 68 <BR> | |
| 69 | |
| 70 <H2>Dictionary Lookups </H2> | |
| 71 | |
| 72 To look up a string in a dictionary, use the overloaded operator | |
| 73 "<CODE>[]</CODE>", | |
| 74 using the string to index the dictionary. The result is an unsigned | |
| 75 integer. It will be zero if the string is not found in the dictionary. | |
| 76 For example: | |
| 77 <PRE> | |
| 78 unsigned k = td["Hello, world!"]; | |
| 79 </PRE> | |
| 80 <BR> | |
| 81 | |
| 82 <H2>Recovering a String from a Dictionary </H2> | |
| 83 | |
| 84 The operator "<CODE>[]</CODE>" is also overloaded to allow you to get the pointer to | |
| 85 a particular string in the dictionary. Simply index the dictionary with | |
| 86 an unsigned integer. The result will be a pointer to the desired | |
| 87 string. If the index is zero, or larger than the number of strings in | |
| 88 the dictionary, the pointer will be null. For example: | |
| 89 <PRE> | |
| 90 unsigned k = td << "Hello"; | |
| 91 char *ptr = td[k]; //returns pointer to "Hello" | |
| 92 </PRE> | |
| 93 <BR> | |
| 94 | |
| 95 <H2>Number of Entries in the Dictionary </H2> | |
| 96 | |
| 97 To find the number of entries in a dictionary, use the function "size". | |
| 98 It returns an unsigned integer. Since the zero entry is unused, the | |
| 99 integer returned by size is the index of the last entry in the | |
| 100 dictionary. For example: | |
| 101 <PRE> | |
| 102 unsigned n = size(td); | |
| 103 </PRE> | |
| 104 <P> | |
| 105 <BR> | |
| 106 | |
| 107 <H2>Resetting a String Dictionary </H2> | |
| 108 | |
| 109 The overloaded function reset() may be used to restore a string | |
| 110 dictionary to its initial condition, deleting all entries: | |
| 111 <PRE> | |
| 112 reset(td); | |
| 113 </PRE> | |
| 114 <P> | |
| 115 <BR> | |
| 116 | |
| 117 <H2>Technical Notes </H2> | |
| 118 | |
| 119 The dictionary uses a hashing algorithm freely adapted from Fletcher's | |
| 120 checksum as described by John Kodis in Doctor Dobb's Journal, May, | |
| 121 1992. | |
| 122 <P> | |
| 123 The length of the hash table is the smallest power of two that is | |
| 124 greater than the specified size of the dictionary. Therefore, if you | |
| 125 are using a computer with 8086 architecture, you are limited to a | |
| 126 dictionary with fewer than 32768 entries. | |
| 127 <P> | |
| 128 The hash algorithm produces two unsigned integers, k1 and k2, which are | |
| 129 each less than 255. The hash code is then calculated as | |
| 130 <CODE> 255*k1 + k2</CODE>, | |
| 131 and masked to the length of the hash table. In case of collision, a | |
| 132 hash increment is calculated by using k1 and k2 in the opposite order: | |
| 133 <CODE> 255*k2 + k1</CODE>. | |
| 134 This is multiplied by two and one is added to guarantee an | |
| 135 increment which is relatively prime to the length of the hash table. | |
| 136 This process guarantees the entire table can be searched. | |
| 137 <P> | |
| 138 The number of calls and the number of collisions are recorded so you | |
| 139 can check the efficiency of the hash algorithm. | |
| 140 <P> | |
| 141 Because the dictionary allocates a single character array for all the | |
| 142 dictionary entries, the product of the max number of entries and the | |
| 143 average size must be less than 65536 when using 8086 architecture. If | |
| 144 this is inconvenient there are several alternatives. You can allocate | |
| 145 storage individually for each string and simply maintain a list of | |
| 146 pointers, or you can declare a "huge" array, and use longs to index it. | |
| 147 Remember that in this case the hash table would have to be declared as | |
| 148 an array of longs. | |
| 149 | |
| 150 | |
| 151 <P> | |
| 152 <BR> | |
| 153 | |
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| 161 | |
| 162 <P> | |
| 163 Back to : | |
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| 166 | |
| 167 <P> | |
| 168 <ADDRESS><FONT SIZE="-1"> | |
| 169 AnaGram parser generator - examples<BR> | |
| 170 Class libraries - String dictionary class definition<BR> | |
| 171 Copyright © 1993-1999, Parsifal Software. <BR> | |
| 172 All Rights Reserved.<BR> | |
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