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1 Homework HW6 due class 22 K&R 6.6 K&R 5.7 – 5.9 (skipped earlier) Finishing up K&R Chapter 6.

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Presentation on theme: "1 Homework HW6 due class 22 K&R 6.6 K&R 5.7 – 5.9 (skipped earlier) Finishing up K&R Chapter 6."— Presentation transcript:

1 1 Homework HW6 due class 22 K&R 6.6 K&R 5.7 – 5.9 (skipped earlier) Finishing up K&R Chapter 6

2 2 Table Lookup, K&R 6.6 struct for a linked list of names/definitions struct nlist {/* table entry */ struct nlist *next;/* link to next */ char *name;/* word name */ char *defn;/* word definition */ };

3 3 Table Lookup / Linked Lists Array of pointers to null terminated linked lists of structs defining table entries 0 0 0 [0] [1] [2] [3] [4] 0 0 nlist array

4 4 Table Lookup / Linked List Hash function to select starting array element unsigned int hash (char *s) { for (hashval = 0; *s != ‘\0’; s++) hashval = *s + 31 * hashval; return hashval % HASHSIZE; } In lookup ( ), std code for following a linked list: for (ptr = head; ptr != NULL; ptr = ptr->next)

5 5 Multi-Dimensional Arrays Declare rectangular multi-dimensional array char a[2][3]; /* array [row] [column] */ NOTE: char a[2, 3] is INCORRECT! The rightmost subscript varies fastest as one looks at how data lies in memory: a[0][0], a[0][1], a[0][2], a[1][0], a[1][1],... It is the same as a one dimensional array [2] with each element being an array [3]

6 6 Multi-Dimensional Arrays Example of converting a month & day into a day of the year for either normal or leap years static char daytab[2][13] = { {0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31}, {0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31} }; Use a second row of day counts for leap year rather than perform a calculation for days in February daytab[1][1] is 31  same as daytab[0][1] daytab[1][2] is 29  not same as daytab[0][2]

7 7 Multi-Dimensional Arrays The array declared as char daytab[2][13] can be thought of as: char (daytab [2]) [13]; /* pg. 53 */ Each one dimensional array element ( daytab[0], daytab[1] ) is like array name - as if we declared: char daytab0 [13], daytab1 [13]; daytab[0] is in memory first, then daytab[1]

8 8 Multi-Dimensional Arrays daytab[0] and daytab[1] are arrays of 13 chars Now recall duality of pointers and arrays: (daytab [0])[n]  (*daytab)[n] (daytab [1])[n]  (*(daytab+1))[n] daytab is a pointer to an array of elements each of which is an array of size 13 chars

9 9 Multi-Dimensional Arrays But, these two declarations are not allocated memory the same way: char daytab[2][13];  26 char-sized locations char (*dp) [13];  1 pointer-sized location For the second declaration, code must set the pointer equal to an already defined array of [n] [13] dp = daytab; OR Use malloc to allocate memory for an array: dp = (char (*)[13]) malloc(2*13);

10 10 Multi-Dimensional Arrays static char daytab[2][13] = {... }; dp = daytab; daytab[0][2] == 28daytab[1][2] == 29 dp Array of 13 chars 1 char (*) [13] A pointer to an unspecified number of 13 char arrays dp = (char (*)[13]) malloc(2*13); Array of 13 chars (*dp)[2] == 28(*(dp + 1))[2] == 29 (*dp)[2] == ??(*(dp + 1))[2] == ??

11 11 Multi-Dimensional Arrays “Real” C programmers use pointers to pointers often and multidimensional arrays rarely Avoids worst case for memory allocation Example: In hw5, allocating lines array as a two dimensional array (compiler allocated): char lines [MAXLINE][MAXLEN]; Allocates 2000*1000 bytes = 2 Megabytes! However, code runs faster w/o malloc/free

12 12 Multi-Dimensional Arrays We could have declared lines and the pointers to lines in my hw5 solution as follows: static char lines[MAXLINE][MAXLEN]; static char (*first)[MAXLEN], /* size of the */ (*last)[MAXLEN], /* data type is */ (*end)[MAXLEN]; /* MAXLEN (1000) */ static int wrapped; We are using all compiler allocated memory We don’t malloc and free any memory!

13 13 Multi-Dimensional Arrays Function init_lineholder void init_lineholder(int nlines) { if (nlines > MAXLINE) nlines = MAXLINE; first = last = lines; end = lines + nlines; /* lines + 2Meg */ wrapped = 0; }

14 14 Multi-Dimensional Arrays Function insert_lines void insert_line(char *line) { strcpy(*last++, line); /* incr by 1K bytes */ if (wrapped) first = (++first >= end)? /* incr by 1K bytes */ lines : first; /* reset if needed */ if (last >= end) { last = lines; wrapped = 1; }

15 15 Multi-Dimensional Arrays Function print_lines void print_lines(void) { do { if (*first != NULL) printf("%s", *first); first = (++first >= end)? lines : first; } while (first != last); }

16 16 Multi-Dimensional Arrays ‘n’ ‘o’ ‘w’ ‘ ’ ‘i’ ‘s’ … ‘\0’ ‘f’ ‘o’ ‘r’ ‘ ’ ‘a’ ‘l’ ‘l’ ‘ ’… ‘\0’ MAXLINE MAXLEN Wasted Memory Space

17 17 typedef, K&R 6.7 typedef creates a new name for existing type typedef int Boolean; typedef char *String; Does not create a new type in any real sense No new semantics for the new type name! Variables declared using new type name have same properties as variables of original type

18 18 typedef Could have used typedef in section 6.5 like this: typedef struct tnode { char *word; int count; treeptr left; treeptr right; } treenode; typedef struct tnode *treeptr;

19 19 typedef Then, could have coded talloc ( ) as follows: treeptr talloc(void) { return (treeptr) malloc(sizeof(treenode)); }

20 20 typedef Used to provide clearer documentation: treeptr root; versus struct tnode *root; Used to create machine independent variable types: typedef int size_t;/* size of types */ typedef int ptrdiff_t; /* difference of pointers */

21 21 Unions, K&R 6.8 A Union is a variable that may hold objects of different types (at different times or for different instances of use) union u_tag { int ival; float fval; char *sval; } u;

22 22 Unions A union will be allocated enough space for the largest type in the list of possible types Same as a struct except all members have a zero offset from the base address of union u ivalfval*sval

23 23 Unions The operations allowed on unions are the same as operations allowed on structs: –Access a member of a union union u_tag x; x.ival = … ; –Assign to union of the same type union u_tag y; x = y;

24 24 Unions –Create a pointer to / take the address of a union union u_tag x; union u_tag *px = &x; –Access a member of a union via a pointer px->ival = … ;

25 25 Unions Program code must know which type of value has been stored in a union variable and process using correct member type DON’T store data in a union using one type and read it back via another type in attempt to get the value converted between types x.ival = 12;/* put an int in union */ float z = x.fval; /* don’t read as float! */

26 26 Bit-Fields, K&R 6.9 Bit fields are used to get a field size other than 8 bits (char), 16 bits (short on some machines) or 32 bits (long on most machines) Allows us to “pack” data one or more bits at a time into a larger data item in memory to save space, e.g. 32 single bit fields to an int Can use bit fields instead of using masks, shifts, and or’s to manipulate groups of bits

27 27 Bit-Fields Uses struct form: struct { unsigned int flg1 : 1; /* called a “bit field“ */ unsigned int flg2 : 1; /* ": 1"  "1 bit in length " */ unsigned int flg3 : 2; /* ": 2"  "2 bits in length" */ } flag; /* variable */ Field lengths must be an integral number of bits

28 28 Bit-Fields Access bit fields by member name same as any struct – just limited number of values flag.flg1 = 0; /* or = 1; */ flag.flg3 = 0; /* or = 1; = 2; =3; */

29 29 Bit-Fields Minimum size data item is implementation dependent, as is order of fields in memory Don’t make any assumptions about order!! Sample memory allocation: flags flags.flg1flags.flg2 flags.flg3 112

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