'\"
'\" Copyright (c) 1993 The Regents of the University of California.
'\" Copyright (c) 1994-1996 Sun Microsystems, Inc.
'\"
'\" See the file "license.terms" for information on usage and redistribution
'\" of this file, and for a DISCLAIMER OF ALL WARRANTIES.
'\" 
'\" RCS: @(#) $Id: format.n,v 1.20 2007/12/13 15:22:32 dgp Exp $
'\" 
.so man.macros
.TH format n 8.1 Tcl "Tcl Built-In Commands"
.BS
'\" Note:  do not modify the .SH NAME line immediately below!
.SH NAME
format \- Format a string in the style of sprintf
.SH SYNOPSIS
\fBformat \fIformatString \fR?\fIarg arg ...\fR?
.BE

.SH INTRODUCTION
.PP
This command generates a formatted string in a fashion similar to the
ANSI C \fBsprintf\fR procedure.
\fIFormatString\fR indicates how to format the result, using
\fB%\fR conversion specifiers as in \fBsprintf\fR, and the additional
arguments, if any, provide values to be substituted into the result.
The return value from \fBformat\fR is the formatted string.
.SH "DETAILS ON FORMATTING"
.PP
The command operates by scanning \fIformatString\fR from left to right. 
Each character from the format string is appended to the result
string unless it is a percent sign.
If the character is a \fB%\fR then it is not copied to the result string.
Instead, the characters following the \fB%\fR character are treated as
a conversion specifier.
The conversion specifier controls the conversion of the next successive
\fIarg\fR to a particular format and the result is appended to 
the result string in place of the conversion specifier.
If there are multiple conversion specifiers in the format string,
then each one controls the conversion of one additional \fIarg\fR.
The \fBformat\fR command must be given enough \fIarg\fRs to meet the needs
of all of the conversion specifiers in \fIformatString\fR.
.PP
Each conversion specifier may contain up to six different parts:
an XPG3 position specifier,
a set of flags, a minimum field width, a precision, a size modifier,
and a conversion character.
Any of these fields may be omitted except for the conversion character.
The fields that are present must appear in the order given above.
The paragraphs below discuss each of these fields in turn.
.PP
If the \fB%\fR is followed by a decimal number and a \fB$\fR, as in
.QW \fB%2$d\fR ,
then the value to convert is not taken from the next sequential argument.
Instead, it is taken from the argument indicated by the number,
where 1 corresponds to the first \fIarg\fR.
If the conversion specifier requires multiple arguments because
of \fB*\fR characters in the specifier then
successive arguments are used, starting with the argument
given by the number.
This follows the XPG3 conventions for positional specifiers.
If there are any positional specifiers in \fIformatString\fR
then all of the specifiers must be positional.
.PP
The second portion of a conversion specifier may contain any of the
following flag characters, in any order:
.TP 10
\fB\-\fR
Specifies that the converted argument should be left-justified 
in its field (numbers are normally right-justified with leading 
spaces if needed).
.TP 10
\fB+\fR
Specifies that a number should always be printed with a sign, 
even if positive.
.TP 10
\fIspace\fR
Specifies that a space should be added to the beginning of the
number if the first character is not a sign.
.TP 10
\fB0\fR
Specifies that the number should be padded on the left with 
zeroes instead of spaces.
.TP 10
\fB#\fR
Requests an alternate output form. For \fBo\fR and \fBO\fR
conversions it guarantees that the first digit is always \fB0\fR.
For \fBx\fR or \fBX\fR conversions, \fB0x\fR or \fB0X\fR (respectively)
will be added to the beginning of the result unless it is zero.
For all floating-point conversions (\fBe\fR, \fBE\fR, \fBf\fR,
\fBg\fR, and \fBG\fR) it guarantees that the result always 
has a decimal point.
For \fBg\fR and \fBG\fR conversions it specifies that 
trailing zeroes should not be removed.
.PP
The third portion of a conversion specifier is a decimal number giving a
minimum field width for this conversion.
It is typically used to make columns line up in tabular printouts.
If the converted argument contains fewer characters than the
minimum field width then it will be padded so that it is as wide
as the minimum field width.
Padding normally occurs by adding extra spaces on the left of the
converted argument, but the \fB0\fR and \fB\-\fR flags 
may be used to specify padding with zeroes on the left or with
spaces on the right, respectively.
If the minimum field width is specified as \fB*\fR rather than
a number, then the next argument to the \fBformat\fR command
determines the minimum field width; it must be an integer value.
.PP
The fourth portion of a conversion specifier is a precision,
which consists of a period followed by a number.
The number is used in different ways for different conversions.
For \fBe\fR, \fBE\fR, and \fBf\fR conversions it specifies the number
of digits to appear to the right of the decimal point.
For \fBg\fR and \fBG\fR conversions it specifies the total number
of digits to appear, including those on both sides of the decimal
point (however, trailing zeroes after the decimal point will still
be omitted unless the \fB#\fR flag has been specified).
For integer conversions, it specifies a minimum number of digits
to print (leading zeroes will be added if necessary).
For \fBs\fR conversions it specifies the maximum number of characters to be 
printed; if the string is longer than this then the trailing characters will be dropped.
If the precision is specified with \fB*\fR rather than a number
then the next argument to the \fBformat\fR command determines the precision;
it must be a numeric string.
.PP
The fifth part of a conversion specifier is a size modifier,
which must be \fBll\fR, \fBh\fR, or \fBl\fR.
If it is \fBll\fR it specifies that an integer value is taken
without truncation for conversion to a formatted substring.
If it is \fBh\fR it specifies that an integer value is
truncated to a 16-bit range before converting.  This option is rarely useful.
If it is \fBl\fR it specifies that the integer value is 
truncated to the same range as that produced by the \fBwide()\fR
function of the \fBexpr\fR command (at least a 64-bit range).
If neither \fBh\fR nor \fBl\fR are present, the integer value is
truncated to the same range as that produced by the \fBint()\fR
function of the \fBexpr\fR command (at least a 32-bit range, but
determined by the value of \fBtcl_platform(wordSize)\fR).
.PP
The last thing in a conversion specifier is an alphabetic character
that determines what kind of conversion to perform.
The following conversion characters are currently supported:
.TP 10
\fBd\fR
Convert integer to signed decimal string.
.TP 10
\fBu\fR
Convert integer to unsigned decimal string.
.TP 10
\fBi\fR
Convert integer to signed decimal string (equivalent to \fBd\fR).
.TP 10
\fBo\fR
Convert integer to unsigned octal string.
.TP 10
\fBx\fR or \fBX\fR
Convert integer to unsigned hexadecimal string, using digits
.QW 0123456789abcdef
for \fBx\fR and
.QW 0123456789ABCDEF
for \fBX\fR).
.TP 10
\fBc\fR
Convert integer to the Unicode character it represents.
.TP 10
\fBs\fR
No conversion; just insert string.
.TP 10
\fBf\fR
Convert number to signed decimal string of 
the form \fIxx.yyy\fR, where the number of \fIy\fR's is determined by 
the precision (default: 6).
If the precision is 0 then no decimal point is output.
.TP 10
\fBe\fR or \fBE\fR
Convert number to scientific notation in the 
form \fIx.yyy\fBe\(+-\fIzz\fR, where the number of \fIy\fR's is determined 
by the precision (default: 6).
If the precision is 0 then no decimal point is output.
If the \fBE\fR form is used then \fBE\fR is 
printed instead of \fBe\fR.
.TP 10
\fBg\fR or \fBG\fR
If the exponent is less than \-4 or greater than or equal to the 
precision, then convert number as for \fB%e\fR or 
\fB%E\fR.
Otherwise convert as for \fB%f\fR.
Trailing zeroes and a trailing decimal point are omitted.
.TP 10
\fB%\fR
No conversion: just insert \fB%\fR.
.SH "DIFFERENCES FROM ANSI SPRINTF"
.PP
The behavior of the format command is the same as the
ANSI C \fBsprintf\fR procedure except for the following
differences:
.IP [1]
\fB%p\fR and \fB%n\fR specifiers are not supported.
.IP [2]
For \fB%c\fR conversions the argument must be an integer value,
which will then be converted to the corresponding character value.
.IP [3]
The size modifiers are ignored when formatting floating-point values.
The \fBll\fR modifier has no \fBsprintf\fR counterpart.
.SH EXAMPLES
Convert the numeric value of a UNICODE character to the character
itself:
.CS
set value 120
set char [\fBformat\fR %c $value]
.CE
.PP
Convert the output of \fBtime\fR into seconds to an accuracy of
hundredths of a second:
.CS
set us [lindex [time $someTclCode] 0]
puts [\fBformat\fR "%.2f seconds to execute" [expr {$us / 1e6}]]
.CE
.PP
Create a packed X11 literal color specification:
.CS
# Each color-component should be in range (0..255)
set color [\fBformat\fR "#%02x%02x%02x" $r $g $b]
.CE
.PP
Use XPG3 format codes to allow reordering of fields (a technique that
is often used in localized message catalogs; see \fBmsgcat\fR) without
reordering the data values passed to \fBformat\fR:
.CS
set fmt1 "Today, %d shares in %s were bought at $%.2f each"
puts [\fBformat\fR $fmt1 123 "Global BigCorp" 19.37]

set fmt2 "Bought %2\e$s equity ($%3$.2f x %1\e$d) today"
puts [\fBformat\fR $fmt2 123 "Global BigCorp" 19.37]
.CE
.PP
Print a small table of powers of three:
.CS
# Set up the column widths
set w1 5
set w2 10

# Make a nice header (with separator) for the table first
set sep +-[string repeat - $w1]-+-[string repeat - $w2]-+
puts $sep
puts [\fBformat\fR "| %-*s | %-*s |" $w1 "Index" $w2 "Power"]
puts $sep

# Print the contents of the table
set p 1
for {set i 0} {$i<=20} {incr i} {
   puts [\fBformat\fR "| %*d | %*ld |" $w1 $i $w2 $p]
   set p [expr {wide($p) * 3}]
}

# Finish off by printing the separator again
puts $sep
.CE
.SH "SEE ALSO"
scan(n), sprintf(3), string(n)
.SH KEYWORDS
conversion specifier, format, sprintf, string, substitution