FMTINSTALL(2)FMTINSTALL(2)NAME
fmtinstall, dofmt, dorfmt, fmtprint, fmtvprint, fmtrune, fmtstrcpy,
fmtrunestrcpy, fmtfdinit, fmtfdflush, fmtstrinit, fmtstrflush, runefmt‐
strinit, runefmtstrflush, errfmt - support for user-defined print for‐
mats and output routines
SYNOPSIS
#include <u.h>
#include <libc.h>
typedef struct Fmt Fmt;
struct Fmt{
uchar runes; /* output buffer is runes or chars? */
void *start; /* of buffer */
void *to; /* current place in the buffer */
void *stop; /* end of the buffer; overwritten if flush fails */
int (*flush)(Fmt*);/* called when to == stop */
void *farg; /* to make flush a closure */
int nfmt; /* num chars formatted so far */
va_list args; /* args passed to dofmt */
int r; /* % format Rune */
int width;
int prec;
ulong flags;
};
enum{
FmtWidth = 1,
FmtLeft = FmtWidth << 1,
FmtPrec = FmtLeft << 1,
FmtSharp = FmtPrec << 1,
FmtSpace = FmtSharp << 1,
FmtSign = FmtSpace << 1,
FmtZero = FmtSign << 1,
FmtUnsigned = FmtZero << 1,
FmtShort = FmtUnsigned << 1,
FmtLong = FmtShort << 1,
FmtVLong = FmtLong << 1,
FmtComma = FmtVLong << 1,
FmtFlag = FmtComma << 1
};
int fmtfdinit(Fmt *f, int fd, char *buf, int nbuf);
int fmtfdflush(Fmt *f);
int fmtstrinit(Fmt *f);
char* fmtstrflush(Fmt *f);
int runefmtstrinit(Fmt *f);
Rune* runefmtstrflush(Fmt *f);
int fmtinstall(int c, int (*fn)(Fmt*));
int dofmt(Fmt *f, char *fmt);
int dorfmt(Fmt*, Rune *fmt);
int fmtprint(Fmt *f, char *fmt, ...);
int fmtvprint(Fmt *f, char *fmt, va_list v);
int fmtrune(Fmt *f, int r);
int fmtstrcpy(Fmt *f, char *s);
int fmtrunestrcpy(Fmt *f, Rune *s);
int errfmt(Fmt *f);
DESCRIPTION
The interface described here allows the construction of custom print(2)
verbs and output routines. In essence, they provide access to the
workings of the formatted print code.
The print(2) suite maintains its state with a data structure called
Fmt. A typical call to print(2) or its relatives initializes a Fmt
structure, passes it to subsidiary routines to process the output, and
finishes by emitting any saved state recorded in the Fmt. The details
of the Fmt are unimportant to outside users, except insofar as the gen‐
eral design influences the interface. The Fmt records whether the out‐
put is in runes or bytes, the verb being processed, its precision and
width, and buffering parameters. Most important, it also records a
flush routine that the library will call if a buffer overflows. When
printing to a file descriptor, the flush routine will emit saved char‐
acters and reset the buffer; when printing to an allocated string, it
will resize the string to receive more output. The flush routine is
nil when printing to fixed-size buffers. User code need never provide
a flush routine; this is done internally by the library.
Custom output routines
To write a custom output routine, such as an error handler that formats
and prints custom error messages, the output sequence can be run from
outside the library using the routines described here. There are two
main cases: output to an open file descriptor and output to a string.
To write to a file descriptor, call fmtfdinit to initialize the local
Fmt structure f, giving the file descriptor fd, the buffer buf, and its
size nbuf. Then call fmtprint or fmtvprint to generate the output.
These behave like fprint (see print(2)) or vfprint except that the
characters are buffered until fmtfdflush is called and the return value
is either 0 or -1. A typical example of this sequence appears in the
Examples section.
The same basic sequence applies when outputting to an allocated string:
call fmtstrinit to initialize the Fmt, then call fmtprint and fmtvprint
to generate the output. Finally, fmtstrflush will return the allocated
string, which should be freed after use. To output to a rune string,
use runefmtstrinit and runefmtstrflush. Regardless of the output style
or type, fmtprint or fmtvprint generates the characters.
Custom format verbs
Fmtinstall is used to install custom verbs and flags labeled by charac‐
ter c, which may be any non-zero Unicode character. Fn should be
declared as
int fn(Fmt*)
Fp->r is the flag or verb character to cause fn to be called. In fn,
fp->width, fp->prec are the width and precision, and fp->flags the
decoded flags for the verb (see print(2) for a description of these
items). The standard flag values are: FmtSign (+), FmtLeft (-),
FmtSpace (' '), FmtSharp (#), FmtComma (,), FmtLong (l), FmtShort (h),
FmtUnsigned (u), and FmtVLong (ll). The flag bits FmtWidth and FmtPrec
identify whether a width and precision were specified.
Fn is passed a pointer to the Fmt structure recording the state of the
output. If fp->r is a verb (rather than a flag), fn should use
Fmt->args to fetch its argument from the list, then format it, and
return zero. If fp->r is a flag, fn should return one. All interpre‐
tation of fp->width, fp->prec, and fp->flags is left up to the conver‐
sion routine. Fmtinstall returns 0 if the installation succeeds, -1 if
it fails.
Fmtprint and fmtvprint may be called to help prepare output in custom
conversion routines. These functions will preserve width, precision,
and flags. Both functions return 0 for success and -1 for failure.
The functions dofmt and dorfmt are the underlying formatters; they use
the existing contents of Fmt and should be called only by sophisticated
conversion routines. These routines return the number of characters
(bytes of UTF or runes) produced.
Some internal functions may be useful to format primitive types. They
honor the width, precision and flags as described in print(2). Fmtrune
formats a single character r. Fmtstrcpy formats a string s;
fmtrunestrcpy formats a rune string s. Errfmt formats the system error
string. All these routines return zero for successful execution. Con‐
version routines that call these functions will work properly regard‐
less of whether the output is bytes or runes.
8c(1) describes the C directive #pragma varargck that can be used to
provide type-checking for custom print verbs and output routines.
EXAMPLES
This function prints an error message with a variable number of argu‐
ments and then quits. Compared to the corresponding example in
print(2), this version uses a smaller buffer, will never truncate the
output message, but might generate multiple write system calls to pro‐
duce its output.
#pragma varargck argpos fatal 1
void
fatal(char *fmt, ...)
{
Fmt f;
char buf[64];
va_list arg;
fmtfdinit(&f, 1, buf, sizeof buf);
fmtprint(&f, "fatal: ");
va_start(arg, fmt);
fmtvprint(&f, fmt, arg);
va_end(arg);
fmtprint(&f, "\n");
fmtfdflush(&f);
exits("fatal error");
}
This example adds a verb to print complex numbers.
typedef struct {
double r, i;
} Complex;
#pragma varargck type "X" Complex
int
Xfmt(Fmt *f)
{
Complex c;
c = va_arg(f->args, Complex);
return fmtprint(f, "(%g,%g)", c.r, c.i);
}
main(...)
{
Complex x = (Complex){ 1.5, -2.3 };
fmtinstall('X', Xfmt);
print("x = %X\n", x);
}
SOURCE
/sys/src/libc/fmt
SEE ALSOprint(2), utf(6), errstr(2)DIAGNOSTICS
These routines return negative numbers or nil for errors and set
errstr.
FMTINSTALL(2)