Back to Chapter 6 -- Index -- Chapter 8
The ANSI standard defines these library functions precisely, so that they can exist in compatible form on any system where C exists. Programs that confine their system interactions to facilities provided by the standard library can be moved from one system to another without change.
The properties of library functions are specified in more than a dozen headers; we have already seen several of these, including <stdio.h>, <string.h>, and <ctype.h>. We will not present the entire library here, since we are more interested in writing C programs that use it. The library is described in detail in Appendix B.
The simplest input mechanism is to read one character at a time from the standard input, normally the keyboard, with getchar:
int getchar(void)getchar returns the next input character each time it is called, or EOF when it encounters end of file. The symbolic constant EOF is defined in <stdio.h>. The value is typically -1, bus tests should be written in terms of EOF so as to be independent of the specific value.
In many environments, a file may be substituted for the keyboard by using the < convention for input redirection: if a program prog uses getchar, then the command line
prog <infilecauses prog to read characters from infile instead. The switching of the input is done in such a way that prog itself is oblivious to the change; in particular, the string ``<infile'' is not included in the command-line arguments in argv. Input switching is also invisible if the input comes from another program via a pipe mechanism: on some systems, the command line
otherprog | progruns the two programs otherprog and prog, and pipes the standard output of otherprog into the standard input for prog.
The function
int putchar(int)is used for output: putchar(c) puts the character c on the standard output, which is by default the screen. putchar returns the character written, or EOF is an error occurs. Again, output can usually be directed to a file with >filename: if prog uses putchar,
prog >outfilewill write the standard output to outfile instead. If pipes are supported,
prog | anotherprogputs the standard output of prog into the standard input of anotherprog.
Output produced by printf also finds its way to the standard output. Calls to putchar and printf may be interleaved - output happens in the order in which the calls are made.
Each source file that refers to an input/output library function must contain the line
#include <stdio.h>before the first reference. When the name is bracketed by < and > a search is made for the header in a standard set of places (for example, on UNIX systems, typically in the directory /usr/include).
Many programs read only one input stream and write only one output stream; for such programs, input and output with getchar, putchar, and printf may be entirely adequate, and is certainly enough to get started. This is particularly true if redirection is used to connect the output of one program to the input of the next. For example, consider the program lower, which converts its input to lower case:
#include <stdio.h>
#include <ctype.h>
main() /* lower: convert input to lower case*/
{
int c
while ((c = getchar()) != EOF)
putchar(tolower(c));
return 0;
}
The function tolower is defined in <ctype.h>; it
converts an upper case letter to lower case, and returns other characters
untouched. As we mentioned earlier, ``functions'' like getchar and
putchar in <stdio.h> and tolower in
<ctype.h> are often macros, thus avoiding the overhead of a
function call per character. We will show how this is done in
Section 8.5. Regardless of how the
<ctype.h> functions are implemented on a given machine,
programs that use them are shielded from knowledge of the character set.
Exercise 7-1. Write a program that converts upper case to lower or lower case to upper, depending on the name it is invoked with, as found in argv[0].
int printf(char *format, arg1, arg2, ...);printf converts, formats, and prints its arguments on the standard output under control of the format. It returns the number of characters printed.
The format string contains two types of objects: ordinary characters, which are copied to the output stream, and conversion specifications, each of which causes conversion and printing of the next successive argument to printf. Each conversion specification begins with a % and ends with a conversion character. Between the % and the conversion character there may be, in order:
Table 7.1 Basic Printf Conversions
| Character | Argument type; Printed As |
|---|---|
| d,i | int; decimal number |
| o | int; unsigned octal number (without a leading zero) |
| x,X | int; unsigned hexadecimal number (without a leading 0x or 0X), using abcdef or ABCDEF for 10, ...,15. |
| u | int; unsigned decimal number |
| c | int; single character |
| s | char *; print characters from the string until a '\0' or the number of characters given by the precision. |
| f | double; [-]m.dddddd, where the number of d's is given by the precision (default 6). |
| e,E | double; [-]m.dddddde+/-xx or [-]m.ddddddE+/-xx, where the number of d's is given by the precision (default 6). |
| g,G | double; use %e or %E if the exponent is less than -4 or greater than or equal to the precision; otherwise use %f. Trailing zeros and a trailing decimal point are not printed. |
| p | void *; pointer (implementation-dependent representation). |
| % | no argument is converted; print a % |
A width or precision may be specified as *, in which case the value is computed by converting the next argument (which must be an int). For example, to print at most max characters from a string s,
printf("%.*s", max, s);
Most of the format conversions have been illustrated in earlier chapters. One
exception is the precision as it relates to strings. The following table
shows the effect of a variety of specifications in printing ``hello, world''
(12 characters). We have put colons around each field so you can see it
extent.
:%s: :hello, world: :%10s: :hello, world: :%.10s: :hello, wor: :%-10s: :hello, world: :%.15s: :hello, world: :%-15s: :hello, world : :%15.10s: : hello, wor: :%-15.10s: :hello, wor :A warning: printf uses its first argument to decide how many arguments follow and what their type is. It will get confused, and you will get wrong answers, if there are not enough arguments of if they are the wrong type. You should also be aware of the difference between these two calls:
printf(s); /* FAILS if s contains % */
printf("%s", s); /* SAFE */
The function sprintf does the same conversions as printf
does, but stores the output in a string:
int sprintf(char *string, char *format, arg1, arg2, ...);sprintf formats the arguments in arg1, arg2, etc., according to format as before, but places the result in string instead of the standard output; string must be big enough to receive the result.
Exercise 7-2. Write a program that will print arbitrary input in a sensible way. As a minimum, it should print non-graphic characters in octal or hexadecimal according to local custom, and break long text lines.
The proper declaration for printf is
int printf(char *fmt, ...)where the declaration ... means that the number and types of these arguments may vary. The declaration ... can only appear at the end of an argument list. Our minprintf is declared as
void minprintf(char *fmt, ...)since we will not return the character count that printf does.
The tricky bit is how minprintf walks along the argument list when the list doesn't even have a name. The standard header <stdarg.h> contains a set of macro definitions that define how to step through an argument list. The implementation of this header will vary from machine to machine, but the interface it presents is uniform.
The type va_list is used to declare a variable that will refer to each argument in turn; in minprintf, this variable is called ap, for ``argument pointer.'' The macro va_start initializes ap to point to the first unnamed argument. It must be called once before ap is used. There must be at least one named argument; the final named argument is used by va_start to get started.
Each call of va_arg returns one argument and steps ap to the next; va_arg uses a type name to determine what type to return and how big a step to take. Finally, va_end does whatever cleanup is necessary. It must be called before the program returns.
These properties form the basis of our simplified printf:
#include <stdarg.h>
/* minprintf: minimal printf with variable argument list */
void minprintf(char *fmt, ...)
{
va_list ap; /* points to each unnamed arg in turn */
char *p, *sval;
int ival;
double dval;
va_start(ap, fmt); /* make ap point to 1st unnamed arg */
for (p = fmt; *p; p++) {
if (*p != '%') {
putchar(*p);
continue;
}
switch (*++p) {
case 'd':
ival = va_arg(ap, int);
printf("%d", ival);
break;
case 'f':
dval = va_arg(ap, double);
printf("%f", dval);
break;
case 's':
for (sval = va_arg(ap, char *); *sval; sval++)
putchar(*sval);
break;
default:
putchar(*p);
break;
}
}
va_end(ap); /* clean up when done */
}
Exercise 7-3. Revise minprintf to handle more of
the other facilities of printf.
int scanf(char *format, ...)scanf reads characters from the standard input, interprets them according to the specification in format, and stores the results through the remaining arguments. The format argument is described below; the other arguments, each of which must be a pointer, indicate where the corresponding converted input should be stored. As with printf, this section is a summary of the most useful features, not an exhaustive list.
scanf stops when it exhausts its format string, or when some input fails to match the control specification. It returns as its value the number of successfully matched and assigned input items. This can be used to decide how many items were found. On the end of file, EOF is returned; note that this is different from 0, which means that the next input character does not match the first specification in the format string. The next call to scanf resumes searching immediately after the last character already converted.
There is also a function sscanf that reads from a string instead of the standard input:
int sscanf(char *string, char *format, arg1, arg2, ...)It scans the string according to the format in format and stores the resulting values through arg1, arg2, etc. These arguments must be pointers.
The format string usually contains conversion specifications, which are used to control conversion of input. The format string may contain:
The conversion character indicates the interpretation of the input field. The corresponding argument must be a pointer, as required by the call-by-value semantics of C. Conversion characters are shown in Table 7.2.
Table 7.2: Basic Scanf Conversions
| Character | Input Data; Argument type |
|---|---|
| d | decimal integer; int * |
| i | integer; int *. The integer may be in octal (leading 0) or hexadecimal (leading 0x or 0X). |
| o | octal integer (with or without leading zero); int * |
| u | unsigned decimal integer; unsigned int * |
| x | hexadecimal integer (with or without leading 0x or 0X); int * |
| c | characters; char *. The next input characters (default 1) are placed at the indicated spot. The normal skip-over white space is suppressed; to read the next non-white space character, use %1s |
| s | character string (not quoted); char *, pointing to an array of characters long enough for the string and a terminating '\0' that will be added. |
| e,f,g | floating-point number with optional sign, optional decimal point and optional exponent; float * |
| % | literal %; no assignment is made. |
The conversion characters d, i, o, u, and x may be preceded by h to indicate that a pointer to short rather than int appears in the argument list, or by l (letter ell) to indicate that a pointer to long appears in the argument list.
As a first example, the rudimentary calculator of Chapter 4 can be written with scanf to do the input conversion:
#include <stdio.h>
main() /* rudimentary calculator */
{
double sum, v;
sum = 0;
while (scanf("%lf", &v) == 1)
printf("\t%.2f\n", sum += v);
return 0;
}
Suppose we want to read input lines that contain dates of the form
25 Dec 1988The scanf statement is
int day, year;
char monthname[20];
scanf("%d %s %d", &day, monthname, &year);
No & is used with monthname, since an array name is a pointer.
Literal characters can appear in the scanf format string; they must match the same characters in the input. So we could read dates of the form mm/dd/yy with the scanf statement:
int day, month, year;
scanf("%d/%d/%d", &month, &day, &year);
scanf ignores blanks and tabs in its format string. Furthermore, it
skips over white space (blanks, tabs, newlines, etc.) as it looks for input
values. To read input whose format is not fixed, it is often best to read a
line at a time, then pick it apart with scanf. For example, suppose
we want to read lines that might contain a date in either of the forms above.
Then we could write
while (getline(line, sizeof(line)) > 0) {
if (sscanf(line, "%d %s %d", &day, monthname, &year) == 3)
printf("valid: %s\n", line); /* 25 Dec 1988 form */
else if (sscanf(line, "%d/%d/%d", &month, &day, &year) == 3)
printf("valid: %s\n", line); /* mm/dd/yy form */
else
printf("invalid: %s\n", line); /* invalid form */
}
Calls to scanf can be mixed with calls to other input functions. The
next call to any input function will begin by reading the first character not
read by scanf.
A final warning: the arguments to scanf and sscanf must be pointers. By far the most common error is writing
scanf("%d", n);
instead of
scanf("%d", &n);
This error is not generally detected at compile time.
Exercise 7-4. Write a private version of scanf analogous to minprintf from the previous section.
Exercise 5-5. Rewrite the postfix calculator of Chapter 4 to use scanf and/or sscanf to do the input and number conversion.
The next step is to write a program that accesses a file that is not already connected to the program. One program that illustrates the need for such operations is cat, which concatenates a set of named files into the standard output. cat is used for printing files on the screen, and as a general-purpose input collector for programs that do not have the capability of accessing files by name. For example, the command
cat x.c y.cprints the contents of the files x.c and y.c (and nothing else) on the standard output.
The question is how to arrange for the named files to be read - that is, how to connect the external names that a user thinks of to the statements that read the data.
The rules are simple. Before it can be read or written, a file has to be opened by the library function fopen. fopen takes an external name like x.c or y.c, does some housekeeping and negotiation with the operating system (details of which needn't concern us), and returns a pointer to be used in subsequent reads or writes of the file.
This pointer, called the file pointer, points to a structure that contains information about the file, such as the location of a buffer, the current character position in the buffer, whether the file is being read or written, and whether errors or end of file have occurred. Users don't need to know the details, because the definitions obtained from <stdio.h> include a structure declaration called FILE. The only declaration needed for a file pointer is exemplified by
FILE *fp; FILE *fopen(char *name, char *mode);This says that fp is a pointer to a FILE, and fopen returns a pointer to a FILE. Notice that FILE is a type name, like int, not a structure tag; it is defined with a typedef. (Details of how fopen can be implemented on the UNIX system are given in Section 8.5.)
The call to fopen in a program is
fp = fopen(name, mode);The first argument of fopen is a character string containing the name of the file. The second argument is the mode, also a character string, which indicates how one intends to use the file. Allowable modes include read ("r"), write ("w"), and append ("a"). Some systems distinguish between text and binary files; for the latter, a "b" must be appended to the mode string.
If a file that does not exist is opened for writing or appending, it is created if possible. Opening an existing file for writing causes the old contents to be discarded, while opening for appending preserves them. Trying to read a file that does not exist is an error, and there may be other causes of error as well, like trying to read a file when you don't have permission. If there is any error, fopen will return NULL. (The error can be identified more precisely; see the discussion of error-handling functions at the end of Section 1 in Appendix B.)
The next thing needed is a way to read or write the file once it is open. getc returns the next character from a file; it needs the file pointer to tell it which file.
int getc(FILE *fp)getc returns the next character from the stream referred to by fp; it returns EOF for end of file or error.
putc is an output function:
int putc(int c, FILE *fp)putc writes the character c to the file fp and returns the character written, or EOF if an error occurs. Like getchar and putchar, getc and putc may be macros instead of functions.
When a C program is started, the operating system environment is responsible for opening three files and providing pointers for them. These files are the standard input, the standard output, and the standard error; the corresponding file pointers are called stdin, stdout, and stderr, and are declared in <stdio.h>. Normally stdin is connected to the keyboard and stdout and stderr are connected to the screen, but stdin and stdout may be redirected to files or pipes as described in Section 7.1.
getchar and putchar can be defined in terms of getc, putc, stdin, and stdout as follows:
#define getchar() getc(stdin) #define putchar(c) putc((c), stdout)For formatted input or output of files, the functions fscanf and fprintf may be used. These are identical to scanf and printf, except that the first argument is a file pointer that specifies the file to be read or written; the format string is the second argument.
int fscanf(FILE *fp, char *format, ...) int fprintf(FILE *fp, char *format, ...)With these preliminaries out of the way, we are now in a position to write the program cat to concatenate files. The design is one that has been found convenient for many programs. If there are command-line arguments, they are interpreted as filenames, and processed in order. If there are no arguments, the standard input is processed.
#include <stdio.h>
/* cat: concatenate files, version 1 */
main(int argc, char *argv[])
{
FILE *fp;
void filecopy(FILE *, FILE *)
if (argc == 1) /* no args; copy standard input */
filecopy(stdin, stdout);
else
while(--argc > 0)
if ((fp = fopen(*++argv, "r")) == NULL) {
printf("cat: can't open %s\n, *argv);
return 1;
} else {
filecopy(fp, stdout);
fclose(fp);
}
return 0;
}
/* filecopy: copy file ifp to file ofp */
void filecopy(FILE *ifp, FILE *ofp)
{
int c;
while ((c = getc(ifp)) != EOF)
putc(c, ofp);
}
The file pointers stdin and stdout are objects of type
FILE *. They are constants, however, not variables, so it
is not possible to assign to them.
The function
int fclose(FILE *fp)is the inverse of fopen, it breaks the connection between the file pointer and the external name that was established by fopen, freeing the file pointer for another file. Since most operating systems have some limit on the number of files that a program may have open simultaneously, it's a good idea to free the file pointers when they are no longer needed, as we did in cat. There is also another reason for fclose on an output file - it flushes the buffer in which putc is collecting output. fclose is called automatically for each open file when a program terminates normally. (You can close stdin and stdout if they are not needed. They can also be reassigned by the library function freopen.)
To handle this situation better, a second output stream, called stderr, is assigned to a program in the same way that stdin and stdout are. Output written on stderr normally appears on the screen even if the standard output is redirected.
Let us revise cat to write its error messages on the standard error.
#include <stdio.h>
/* cat: concatenate files, version 2 */
main(int argc, char *argv[])
{
FILE *fp;
void filecopy(FILE *, FILE *);
char *prog = argv[0]; /* program name for errors */
if (argc == 1 ) /* no args; copy standard input */
filecopy(stdin, stdout);
else
while (--argc > 0)
if ((fp = fopen(*++argv, "r")) == NULL) {
fprintf(stderr, "%s: can't open %s\n",
prog, *argv);
exit(1);
} else {
filecopy(fp, stdout);
fclose(fp);
}
if (ferror(stdout)) {
fprintf(stderr, "%s: error writing stdout\n", prog);
exit(2);
}
exit(0);
}
The program signals errors in two ways. First, the diagnostic output produced
by fprintf goes to stderr, so it finds its way to the screen
instead of disappearing down a pipeline or into an output file. We included
the program name, from argv[0], in the message, so if this program
is used with others, the source of an error is identified.
Second, the program uses the standard library function exit, which terminates program execution when it is called. The argument of exit is available to whatever process called this one, so the success or failure of the program can be tested by another program that uses this one as a sub-process. Conventionally, a return value of 0 signals that all is well; non-zero values usually signal abnormal situations. exit calls fclose for each open output file, to flush out any buffered output.
Within main, return expr is equivalent to exit(expr). exit has the advantage that it can be called from other functions, and that calls to it can be found with a pattern-searching program like those in Chapter 5.
The function ferror returns non-zero if an error occurred on the stream fp.
int ferror(FILE *fp)Although output errors are rare, they do occur (for example, if a disk fills up), so a production program should check this as well.
The function feof(FILE *) is analogous to ferror; it returns non-zero if end of file has occurred on the specified file.
int feof(FILE *fp)We have generally not worried about exit status in our small illustrative programs, but any serious program should take care to return sensible, useful status values.
char *fgets(char *line, int maxline, FILE *fp)fgets reads the next input line (including the newline) from file fp into the character array line; at most maxline-1 characters will be read. The resulting line is terminated with '\0'. Normally fgets returns line; on end of file or error it returns NULL. (Our getline returns the line length, which is a more useful value; zero means end of file.)
For output, the function fputs writes a string (which need not contain a newline) to a file:
int fputs(char *line, FILE *fp)It returns EOF if an error occurs, and non-negative otherwise.
The library functions gets and puts are similar to fgets and fputs, but operate on stdin and stdout. Confusingly, gets deletes the terminating '\n', and puts adds it.
To show that there is nothing special about functions like fgets and fputs, here they are, copied from the standard library on our system:
/* fgets: get at most n chars from iop */
char *fgets(char *s, int n, FILE *iop)
{
register int c;
register char *cs;
cs = s;
while (--n > 0 && (c = getc(iop)) != EOF)
if ((*cs++ = c) == '\n')
break;
*cs = '\0';
return (c == EOF && cs == s) ? NULL : s;
}
/* fputs: put string s on file iop */
int fputs(char *s, FILE *iop)
{
int c;
while (c = *s++)
putc(c, iop);
return ferror(iop) ? EOF : 0;
}
For no obvious reason, the standard specifies different return values for
ferror and fputs.
It is easy to implement our getline from fgets:
/* getline: read a line, return length */
int getline(char *line, int max)
{
if (fgets(line, max, stdin) == NULL)
return 0;
else
return strlen(line);
}
Exercise 7-6. Write a program to compare two files, printing
the first line where they differ.
Exercise 7-7. Modify the pattern finding program of Chapter 5 to take its input from a set of named files or, if no files are named as arguments, from the standard input. Should the file name be printed when a matching line is found?
Exercise 7-8. Write a program to print a set of files, starting each new one on a new page, with a title and a running page count for each file.
| strcat(s,t) | concatenate t to end of s |
| strncat(s,t,n) | concatenate n characters of t to end of s |
| strcmp(s,t) | return negative, zero, or positive for s < t, s == t, s > t |
| strncmp(s,t,n) | same as strcmp but only in first n characters |
| strcpy(s,t) | copy t to s |
| strncpy(s,t,n) | copy at most n characters of t to s |
| strlen(s) | return length of s |
| strchr(s,c) | return pointer to first c in s, or NULL if not present |
| strrchr(s,c) | return pointer to last c in s, or NULL if not present |
| isalpha(c) | non-zero if c is alphabetic, 0 if not |
| isupper(c) | non-zero if c is upper case, 0 if not |
| islower(c) | non-zero if c is lower case, 0 if not |
| isdigit(c) | non-zero if c is digit, 0 if not |
| isalnum(c) | non-zero if isalpha(c) or isdigit(c), 0 if not |
| isspace(c) | non-zero if c is blank, tab, newline, return, formfeed, vertical tab |
| toupper(c) | return c converted to upper case |
| tolower(c) | return c converted to lower case |
int ungetc(int c, FILE *fp)pushes the character c back onto file fp, and returns either c, or EOF for an error. Only one character of pushback is guaranteed per file. ungetc may be used with any of the input functions like scanf, getc, or getchar.
system("date");
causes the program date to be run; it prints the date and time of
day on the standard output. system returns a system-dependent
integer status from the command executed. In the UNIX system, the status
return is the value returned by exit.
void *malloc(size_t n)returns a pointer to n bytes of uninitialized storage, or NULL if the request cannot be satisfied.
void *calloc(size_t n, size_t size)returns a pointer to enough free space for an array of n objects of the specified size, or NULL if the request cannot be satisfied. The storage is initialized to zero.
The pointer returned by malloc or calloc has the proper alignment for the object in question, but it must be cast into the appropriate type, as in
int *ip; ip = (int *) calloc(n, sizeof(int));free(p) frees the space pointed to by p, where p was originally obtained by a call to malloc or calloc. There are no restrictions on the order in which space is freed, but it is a ghastly error to free something not obtained by calling malloc or calloc.
It is also an error to use something after it has been freed. A typical but incorrect piece of code is this loop that frees items from a list:
for (p = head; p != NULL; p = p->next) /* WRONG */
free(p);
The right way is to save whatever is needed before freeing:
for (p = head; p != NULL; p = q) {
q = p->next;
free(p);
}
Section 8.7 shows the implementation of a
storage allocator like malloc, in which allocated blocks may be
freed in any order.
| sin(x) | sine of x, x in radians |
| cos(x) | cosine of x, x in radians |
| atan2(y,x) | arctangent of y/x, in radians |
| exp(x) | exponential function ex |
| log(x) | natural (base e) logarithm of x (x>0) |
| log10(x) | common (base 10) logarithm of x (x>0) |
| pow(x,y) | xy |
| sqrt(x) | square root of x (x>0) |
| fabs(x) | absolute value of x |
#define frand() ((double) rand() / (RAND_MAX+1.0))(If your library already provides a function for floating-point random numbers, it is likely to have better statistical properties than this one.)
The function srand(unsigned) sets the seed for rand. The portable implementation of rand and srand suggested by the standard appears in Section 2.7.
Exercise 7-9. Functions like isupper can be implemented to save space or to save time. Explore both possibilities.
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