[OpenSPARC-T2-SAM] / sam-t2 / devtools / v8plus / man / mann / scan.n

'\"
'\" Copyright (c) 1993 The Regents of the University of California.
'\" Copyright (c) 1994-1996 Sun Microsystems, Inc.
'\" Copyright (c) 2000 Scriptics Corporation.
'\"
'\" See the file "license.terms" for information on usage and redistribution
'\" of this file, and for a DISCLAIMER OF ALL WARRANTIES.
'\" 
'\" RCS: @(#) $Id: scan.n,v 1.9.2.1 2004/10/27 14:23:58 dkf Exp $
'\" 
'\" The definitions below are for supplemental macros used in Tcl/Tk
'\" manual entries.
'\"
'\" .AP type name in/out ?indent?
'\"	Start paragraph describing an argument to a library procedure.
'\"	type is type of argument (int, etc.), in/out is either "in", "out",
'\"	or "in/out" to describe whether procedure reads or modifies arg,
'\"	and indent is equivalent to second arg of .IP (shouldn't ever be
'\"	needed;  use .AS below instead)
'\"
'\" .AS ?type? ?name?
'\"	Give maximum sizes of arguments for setting tab stops.  Type and
'\"	name are examples of largest possible arguments that will be passed
'\"	to .AP later.  If args are omitted, default tab stops are used.
'\"
'\" .BS
'\"	Start box enclosure.  From here until next .BE, everything will be
'\"	enclosed in one large box.
'\"
'\" .BE
'\"	End of box enclosure.
'\"
'\" .CS
'\"	Begin code excerpt.
'\"
'\" .CE
'\"	End code excerpt.
'\"
'\" .VS ?version? ?br?
'\"	Begin vertical sidebar, for use in marking newly-changed parts
'\"	of man pages.  The first argument is ignored and used for recording
'\"	the version when the .VS was added, so that the sidebars can be
'\"	found and removed when they reach a certain age.  If another argument
'\"	is present, then a line break is forced before starting the sidebar.
'\"
'\" .VE
'\"	End of vertical sidebar.
'\"
'\" .DS
'\"	Begin an indented unfilled display.
'\"
'\" .DE
'\"	End of indented unfilled display.
'\"
'\" .SO
'\"	Start of list of standard options for a Tk widget.  The
'\"	options follow on successive lines, in four columns separated
'\"	by tabs.
'\"
'\" .SE
'\"	End of list of standard options for a Tk widget.
'\"
'\" .OP cmdName dbName dbClass
'\"	Start of description of a specific option.  cmdName gives the
'\"	option's name as specified in the class command, dbName gives
'\"	the option's name in the option database, and dbClass gives
'\"	the option's class in the option database.
'\"
'\" .UL arg1 arg2
'\"	Print arg1 underlined, then print arg2 normally.
'\"
'\" RCS: @(#) $Id: man.macros,v 1.4 2000/08/25 06:18:32 ericm Exp $
'\"
'\"	# Set up traps and other miscellaneous stuff for Tcl/Tk man pages.
.if t .wh -1.3i ^B
.nr ^l \n(.l
.ad b
'\"	# Start an argument description
.de AP
.ie !"\\$4"" .TP \\$4
.el \{\
.   ie !"\\$2"" .TP \\n()Cu
.   el          .TP 15
.\}
.ta \\n()Au \\n()Bu
.ie !"\\$3"" \{\
\&\\$1	\\fI\\$2\\fP	(\\$3)
.\".b
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\&\\$1	\\fI\\$2\\fP
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\&\\fI\\$1\\fP
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'\"	# define tabbing values for .AP
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.nr )A 10n
.if !"\\$1"" .nr )A \\w'\\$1'u+3n
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.\"
.if !"\\$2"" .nr )B \\w'\\$2'u+\\n()Au+3n
.nr )C \\n()Bu+\\w'(in/out)'u+2n
..
.AS Tcl_Interp Tcl_CreateInterp in/out
'\"	# BS - start boxed text
'\"	# ^y = starting y location
'\"	# ^b = 1
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.ie n \l'\\n(^lu\(ul'
.el \{\
.\"	Draw four-sided box normally, but don't draw top of
.\"	box if the box started on an earlier page.
.ie !\\n(^b-1 \{\
\h'-1.5n'\L'|\\n(^yu-1v'\l'\\n(^lu+3n\(ul'\L'\\n(^tu+1v-\\n(^yu'\l'|0u-1.5n\(ul'
.\}
.el \}\
\h'-1.5n'\L'|\\n(^yu-1v'\h'\\n(^lu+3n'\L'\\n(^tu+1v-\\n(^yu'\l'|0u-1.5n\(ul'
.\}
.\}
.fi
.br
.nr ^b 0
..
'\"	# VS - start vertical sidebar
'\"	# ^Y = starting y location
'\"	# ^v = 1 (for troff;  for nroff this doesn't matter)
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.if !"\\$2"" .br
.mk ^Y
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.el .nr ^v 1u
..
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.sp -1
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'\"	# box/sidebar if in box/sidebar mode, then invoked standard
'\"	# page bottom macro.
.de ^B
.ev 2
'ti 0
'nf
.mk ^t
.if \\n(^b \{\
.\"	Draw three-sided box if this is the box's first page,
.\"	draw two sides but no top otherwise.
.ie !\\n(^b-1 \h'-1.5n'\L'|\\n(^yu-1v'\l'\\n(^lu+3n\(ul'\L'\\n(^tu+1v-\\n(^yu'\h'|0u'\c
.el \h'-1.5n'\L'|\\n(^yu-1v'\h'\\n(^lu+3n'\L'\\n(^tu+1v-\\n(^yu'\h'|0u'\c
.\}
.if \\n(^v \{\
.nr ^x \\n(^tu+1v-\\n(^Yu
\kx\h'-\\nxu'\h'|\\n(^lu+3n'\ky\L'-\\n(^xu'\v'\\n(^xu'\h'|0u'\c
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'\"	# DS - begin display
.de DS
.RS
.nf
.sp
..
'\"	# DE - end display
.de DE
.fi
.RE
.sp
..
'\"	# SO - start of list of standard options
.de SO
.SH "STANDARD OPTIONS"
.LP
.nf
.ta 5.5c 11c
.ft B
..
'\"	# SE - end of list of standard options
.de SE
.fi
.ft R
.LP
See the \\fBoptions\\fR manual entry for details on the standard options.
..
'\"	# OP - start of full description for a single option
.de OP
.LP
.nf
.ta 4c
Command-Line Name:	\\fB\\$1\\fR
Database Name:	\\fB\\$2\\fR
Database Class:	\\fB\\$3\\fR
.fi
.IP
..
'\"	# CS - begin code excerpt
.de CS
.RS
.nf
.ta .25i .5i .75i 1i
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.de CE
.fi
.RE
..
.de UL
\\$1\l'|0\(ul'\\$2
..
.TH scan n 8.4 Tcl "Tcl Built-In Commands"
.BS
'\" Note:  do not modify the .SH NAME line immediately below!
.SH NAME
scan \- Parse string using conversion specifiers in the style of sscanf
.SH SYNOPSIS
\fBscan \fIstring format \fR?\fIvarName varName ...\fR?
.BE

.SH INTRODUCTION
.PP
This command parses fields from an input string in the same fashion as the
ANSI C \fBsscanf\fR procedure and returns a count of the number of
conversions performed, or -1 if the end of the input string is reached
before any conversions have been performed.  \fIString\fR gives the input
to be parsed and \fIformat\fR indicates how to parse it, using \fB%\fR
conversion specifiers as in \fBsscanf\fR.  Each \fIvarName\fR gives the
name of a variable; when a field is scanned from \fIstring\fR the result is
converted back into a string and assigned to the corresponding variable.
If no \fIvarName\fR variables are specified, then \fBscan\fR works in an
inline manner, returning the data that would otherwise be stored in the
variables as a list.  In the inline case, an empty string is returned when
the end of the input string is reached before any conversions have been
performed.
.SH "DETAILS ON SCANNING"
.PP
\fBScan\fR operates by scanning \fIstring\fR and \fIformat\fR together.
If the next character in \fIformat\fR is a blank or tab then it
matches any number of white space characters in \fIstring\fR (including
zero).
Otherwise, if it isn't a \fB%\fR character then it 
must match the next character of \fIstring\fR.
When a \fB%\fR is encountered in \fIformat\fR, it indicates
the start of a conversion specifier.
.VS 8.4
A conversion specifier contains up to four fields after the \fB%\fR:
a \fB*\fR, which indicates that the converted value is to be discarded 
instead of assigned to a variable; a XPG3 position specifier; a number
indicating a maximum field width; a field size modifier; and a
conversion character.
.VE 8.4
All of these fields are optional except for the conversion character.
The fields that are present must appear in the order given above.
.PP
When \fBscan\fR finds a conversion specifier in \fIformat\fR, it
first skips any white-space characters in \fIstring\fR (unless the
specifier is \fB[\fR or \fBc\fR).
Then it converts the next input characters according to the 
conversion specifier and stores the result in the variable given
by the next argument to \fBscan\fR.
.PP
If the \fB%\fR is followed by a decimal number and a \fB$\fR, as in
``\fB%2$d\fR'', then the variable to use 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 \fIvarName\fR.  If
there are any positional specifiers in \fIformat\fR then all of the
specifiers must be positional.  Every \fIvarName\fR on the argument
list must correspond to exactly one conversion specifier or an error
is generated, or in the inline case, any position can be specified
at most once and the empty positions will be filled in with empty strings.
.PP
The following conversion characters are supported:
.TP 10
\fBd\fR
The input field must be a decimal integer.
It is read in and the value is stored in the variable as a decimal string.
.VS 8.4
If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
value will have an internal representation that is at least 64-bits in
size.
.VE 8.4
.TP 10
\fBo\fR
The input field must be an octal integer. It is read in and the 
value is stored in the variable as a decimal string.
.VS 8.4
If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
value will have an internal representation that is at least 64-bits in
size.
If the value exceeds MAX_INT (017777777777 on platforms using 32-bit
integers when the \fBl\fR and \fBL\fR modifiers are not given), it
will be truncated to a signed integer.  Hence, 037777777777 will
appear as -1 on a 32-bit machine by default.
.VE 8.4
.TP 10
\fBx\fR
The input field must be a hexadecimal integer. It is read in 
and the value is stored in the variable as a decimal string.
.VS 8.4
If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
value will have an internal representation that is at least 64-bits in
size.
If the value exceeds MAX_INT (0x7FFFFFFF on platforms using 32-bit
integers when the \fBl\fR and \fBL\fR modifiers are not given), it
will be truncated to a signed integer.  Hence, 0xFFFFFFFF will appear
as -1 on a 32-bit machine.
.VE 8.4
.TP 10
\fBu\fR
The input field must be a decimal integer.  The value is stored in the
variable as an unsigned decimal integer string.
.VS 8.4
If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
value will have an internal representation that is at least 64-bits in
size.
.VE 8.4
.TP 10
\fBi\fR 
The input field must be an integer.  The base (i.e. decimal, octal, or
hexadecimal) is determined in the same fashion as described in
\fBexpr\fR.  The value is stored in the variable as a decimal string.
.VS 8.4
If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
value will have an internal representation that is at least 64-bits in
size.
.VE 8.4
.TP 10
\fBc\fR
A single character is read in and its binary value is stored in 
the variable as a decimal string.
Initial white space is not skipped in this case, so the input
field may be a white-space character.
This conversion is different from the ANSI standard in that the
input field always consists of a single character and no field
width may be specified.
.TP 10
\fBs\fR
The input field consists of all the characters up to the next 
white-space character; the characters are copied to the variable.
.TP 10
\fBe\fR or \fBf\fR or \fBg\fR
The input field must be a floating-point number consisting 
of an optional sign, a string of decimal digits possibly
containing a decimal point, and an optional exponent consisting 
of an \fBe\fR or \fBE\fR followed by an optional sign and a string of 
decimal digits.
It is read in and stored in the variable as a floating-point string.
.TP 10
\fB[\fIchars\fB]\fR
The input field consists of any number of characters in 
\fIchars\fR.
The matching string is stored in the variable.
If the first character between the brackets is a \fB]\fR then
it is treated as part of \fIchars\fR rather than the closing
bracket for the set.
If \fIchars\fR
contains a sequence of the form \fIa\fB\-\fIb\fR then any
character between \fIa\fR and \fIb\fR (inclusive) will match.
If the first or last character between the brackets is a \fB\-\fR, then
it is treated as part of \fIchars\fR rather than indicating a range.
.TP 10
\fB[^\fIchars\fB]\fR
The input field consists of any number of characters not in 
\fIchars\fR.
The matching string is stored in the variable.
If the character immediately following the \fB^\fR is a \fB]\fR then it is 
treated as part of the set rather than the closing bracket for 
the set.
If \fIchars\fR
contains a sequence of the form \fIa\fB\-\fIb\fR then any
character between \fIa\fR and \fIb\fR (inclusive) will be excluded
from the set.
If the first or last character between the brackets is a \fB\-\fR, then
it is treated as part of \fIchars\fR rather than indicating a range.
.TP 10
\fBn\fR
No input is consumed from the input string.  Instead, the total number
of characters scanned from the input string so far is stored in the variable.
.LP
The number of characters read from the input for a conversion is the
largest number that makes sense for that particular conversion (e.g.
as many decimal digits as possible for \fB%d\fR, as 
many octal digits as possible for \fB%o\fR, and so on).
The input field for a given conversion terminates either when a
white-space character is encountered or when the maximum field 
width has been reached, whichever comes first.
If a \fB*\fR is present in the conversion specifier 
then no variable is assigned and the next scan argument is not consumed.
.SH "DIFFERENCES FROM ANSI SSCANF"
.PP
The behavior of the \fBscan\fR command is the same as the behavior of
the ANSI C \fBsscanf\fR procedure except for the following differences:
.IP [1]
\fB%p\fR conversion specifier is not currently supported.
.IP [2]
For \fB%c\fR conversions a single character value is
converted to a decimal string, which is then assigned to the
corresponding \fIvarName\fR;
no field width may be specified for this conversion.
.IP [3]
.VS 8.4
The \fBh\fR modifier is always ignored and the \fBl\fR and \fBL\fR
modifiers are ignored when converting real values (i.e. type
\fBdouble\fR is used for the internal representation).
.VE 8.4
.IP [4]
If the end of the input string is reached before any conversions have been
performed and no variables are given, an empty string is returned.
.SH EXAMPLES
Parse a simple color specification of the form \fI#RRGGBB\fR using
hexadecimal conversions with field sizes:
.CS
set string "#08D03F"
\fBscan\fR $string "#%2x%2x%2x" r g b
.CE
.PP
Parse a \fIHH:MM\fR time string, noting that this avoids problems with
octal numbers by forcing interpretation as decimals (if we did not
care, we would use the \fB%i\fR conversion instead):
.CS
set string "08:08"   ;# *Not* octal!
if {[\fBscan\fR $string "%d:%d" hours minutes] != 2} {
   error "not a valid time string"
}
# We have to understand numeric ranges ourselves...
if {$minutes < 0 || $minutes > 59} {
   error "invalid number of minutes"
}
.CE
.PP
Break a string up into sequences of non-whitespace characters (note
the use of the \fB%n\fR conversion so that we get skipping over
leading whitespace correct):
.CS
set string " a string {with braced words} + leading space "
set words {}
while {[\fBscan\fR $string %s%n word length] == 2} {
   lappend words $word
   set string [string range $string $length end]
}
.CE
.PP
Parse a simple coordinate string, checking that it is complete by
looking for the terminating character explicitly:
.CS
set string "(5.2,-4e-2)"
# Note that the spaces before the literal parts of
# the scan pattern are significant, and that ")" is
# the Unicode character \\u0029
if {
   [\fBscan\fR $string " (%f ,%f %c" x y last] != 3
   || $last != 0x0029
} then {
   error "invalid coordinate string"
}
puts "X=$x, Y=$y"
.CE

.SH "SEE ALSO"
format(n), sscanf(3)

.SH KEYWORDS
conversion specifier, parse, scan
Commit	Line	Data
920dae64 AT	1	'\"
	2	'\" Copyright (c) 1993 The Regents of the University of California.
	3	'\" Copyright (c) 1994-1996 Sun Microsystems, Inc.
	4	'\" Copyright (c) 2000 Scriptics Corporation.
	5	'\"
	6	'\" See the file "license.terms" for information on usage and redistribution
	7	'\" of this file, and for a DISCLAIMER OF ALL WARRANTIES.
	8	'\"
	9	'\" RCS: @(#) $Id: scan.n,v 1.9.2.1 2004/10/27 14:23:58 dkf Exp $
	10	'\"
	11	'\" The definitions below are for supplemental macros used in Tcl/Tk
	12	'\" manual entries.
	13	'\"
	14	'\" .AP type name in/out ?indent?
	15	'\" Start paragraph describing an argument to a library procedure.
	16	'\" type is type of argument (int, etc.), in/out is either "in", "out",
	17	'\" or "in/out" to describe whether procedure reads or modifies arg,
	18	'\" and indent is equivalent to second arg of .IP (shouldn't ever be
	19	'\" needed; use .AS below instead)
	20	'\"
	21	'\" .AS ?type? ?name?
	22	'\" Give maximum sizes of arguments for setting tab stops. Type and
	23	'\" name are examples of largest possible arguments that will be passed
	24	'\" to .AP later. If args are omitted, default tab stops are used.
	25	'\"
	26	'\" .BS
	27	'\" Start box enclosure. From here until next .BE, everything will be
	28	'\" enclosed in one large box.
	29	'\"
	30	'\" .BE
	31	'\" End of box enclosure.
	32	'\"
	33	'\" .CS
	34	'\" Begin code excerpt.
	35	'\"
	36	'\" .CE
	37	'\" End code excerpt.
	38	'\"
	39	'\" .VS ?version? ?br?
	40	'\" Begin vertical sidebar, for use in marking newly-changed parts
	41	'\" of man pages. The first argument is ignored and used for recording
	42	'\" the version when the .VS was added, so that the sidebars can be
	43	'\" found and removed when they reach a certain age. If another argument
	44	'\" is present, then a line break is forced before starting the sidebar.
	45	'\"
	46	'\" .VE
	47	'\" End of vertical sidebar.
	48	'\"
	49	'\" .DS
	50	'\" Begin an indented unfilled display.
	51	'\"
	52	'\" .DE
	53	'\" End of indented unfilled display.
	54	'\"
	55	'\" .SO
	56	'\" Start of list of standard options for a Tk widget. The
	57	'\" options follow on successive lines, in four columns separated
	58	'\" by tabs.
	59	'\"
	60	'\" .SE
	61	'\" End of list of standard options for a Tk widget.
	62	'\"
	63	'\" .OP cmdName dbName dbClass
	64	'\" Start of description of a specific option. cmdName gives the
65	'\" option's name as specified in the class command, dbName gives
66	'\" the option's name in the option database, and dbClass gives
67	'\" the option's class in the option database.
68	'\"
69	'\" .UL arg1 arg2
70	'\" Print arg1 underlined, then print arg2 normally.
71	'\"
72	'\" RCS: @(#) $Id: man.macros,v 1.4 2000/08/25 06:18:32 ericm Exp $
73	'\"
74	'\" # Set up traps and other miscellaneous stuff for Tcl/Tk man pages.
75	.if t .wh -1.3i ^B
76	.nr ^l \n(.l
77	.ad b
78	'\" # Start an argument description
79	.de AP
80	.ie !"\\$4"" .TP \\$4
81	.el \{\
82	. ie !"\\$2"" .TP \\n()Cu
83	. el .TP 15
84	.\}
85	.ta \\n()Au \\n()Bu
86	.ie !"\\$3"" \{\
87	\&\\$1 \\fI\\$2\\fP (\\$3)
88	.\".b
89	.\}
90	.el \{\
91	.br
92	.ie !"\\$2"" \{\
93	\&\\$1 \\fI\\$2\\fP
94	.\}
95	.el \{\
96	\&\\fI\\$1\\fP
97	.\}
98	.\}
99	..
100	'\" # define tabbing values for .AP
101	.de AS
102	.nr )A 10n
103	.if !"\\$1"" .nr )A \\w'\\$1'u+3n
104	.nr )B \\n()Au+15n
105	.\"
106	.if !"\\$2"" .nr )B \\w'\\$2'u+\\n()Au+3n
107	.nr )C \\n()Bu+\\w'(in/out)'u+2n
108	..
109	.AS Tcl_Interp Tcl_CreateInterp in/out
110	'\" # BS - start boxed text
111	'\" # ^y = starting y location
112	'\" # ^b = 1
113	.de BS
114	.br
115	.mk ^y
116	.nr ^b 1u
117	.if n .nf
118	.if n .ti 0
119	.if n \l'\\n(.lu\(ul'
120	.if n .fi
121	..
122	'\" # BE - end boxed text (draw box now)
123	.de BE
124	.nf
125	.ti 0
126	.mk ^t
127	.ie n \l'\\n(^lu\(ul'
128	.el \{\
129	.\" Draw four-sided box normally, but don't draw top of
130	.\" box if the box started on an earlier page.
131	.ie !\\n(^b-1 \{\
132	\h'-1.5n'\L'\|\\n(^yu-1v'\l'\\n(^lu+3n\(ul'\L'\\n(^tu+1v-\\n(^yu'\l'\|0u-1.5n\(ul'
133	.\}
134	.el \}\
135	\h'-1.5n'\L'\|\\n(^yu-1v'\h'\\n(^lu+3n'\L'\\n(^tu+1v-\\n(^yu'\l'\|0u-1.5n\(ul'
136	.\}
137	.\}
138	.fi
139	.br
140	.nr ^b 0
141	..
142	'\" # VS - start vertical sidebar
143	'\" # ^Y = starting y location
144	'\" # ^v = 1 (for troff; for nroff this doesn't matter)
145	.de VS
146	.if !"\\$2"" .br
147	.mk ^Y
148	.ie n 'mc \s12\(br\s0
149	.el .nr ^v 1u
150	..
151	'\" # VE - end of vertical sidebar
152	.de VE
153	.ie n 'mc
154	.el \{\
155	.ev 2
156	.nf
157	.ti 0
158	.mk ^t
159	\h'\|\\n(^lu+3n'\L'\|\\n(^Yu-1v\(bv'\v'\\n(^tu+1v-\\n(^Yu'\h'-\|\\n(^lu+3n'
160	.sp -1
161	.fi
162	.ev
163	.\}
164	.nr ^v 0
165	..
166	'\" # Special macro to handle page bottom: finish off current
167	'\" # box/sidebar if in box/sidebar mode, then invoked standard
168	'\" # page bottom macro.
169	.de ^B
170	.ev 2
171	'ti 0
172	'nf
173	.mk ^t
174	.if \\n(^b \{\
175	.\" Draw three-sided box if this is the box's first page,
176	.\" draw two sides but no top otherwise.
177	.ie !\\n(^b-1 \h'-1.5n'\L'\|\\n(^yu-1v'\l'\\n(^lu+3n\(ul'\L'\\n(^tu+1v-\\n(^yu'\h'\|0u'\c
178	.el \h'-1.5n'\L'\|\\n(^yu-1v'\h'\\n(^lu+3n'\L'\\n(^tu+1v-\\n(^yu'\h'\|0u'\c
179	.\}
180	.if \\n(^v \{\
181	.nr ^x \\n(^tu+1v-\\n(^Yu
182	\kx\h'-\\nxu'\h'\|\\n(^lu+3n'\ky\L'-\\n(^xu'\v'\\n(^xu'\h'\|0u'\c
183	.\}
184	.bp
185	'fi
186	.ev
187	.if \\n(^b \{\
188	.mk ^y
189	.nr ^b 2
190	.\}
191	.if \\n(^v \{\
192	.mk ^Y
193	.\}
194	..
195	'\" # DS - begin display
196	.de DS
197	.RS
198	.nf
199	.sp
200	..
201	'\" # DE - end display
202	.de DE
203	.fi
204	.RE
205	.sp
206	..
207	'\" # SO - start of list of standard options
208	.de SO
209	.SH "STANDARD OPTIONS"
210	.LP
211	.nf
212	.ta 5.5c 11c
213	.ft B
214	..
215	'\" # SE - end of list of standard options
216	.de SE
217	.fi
218	.ft R
219	.LP
220	See the \\fBoptions\\fR manual entry for details on the standard options.
221	..
222	'\" # OP - start of full description for a single option
223	.de OP
224	.LP
225	.nf
226	.ta 4c
227	Command-Line Name: \\fB\\$1\\fR
228	Database Name: \\fB\\$2\\fR
229	Database Class: \\fB\\$3\\fR
230	.fi
231	.IP
232	..
233	'\" # CS - begin code excerpt
234	.de CS
235	.RS
236	.nf
237	.ta .25i .5i .75i 1i
238	..
239	'\" # CE - end code excerpt
240	.de CE
241	.fi
242	.RE
243	..
244	.de UL
245	\\$1\l'\|0\(ul'\\$2
246	..
247	.TH scan n 8.4 Tcl "Tcl Built-In Commands"
248	.BS
249	'\" Note: do not modify the .SH NAME line immediately below!
250	.SH NAME
251	scan \- Parse string using conversion specifiers in the style of sscanf
252	.SH SYNOPSIS
253	\fBscan \fIstring format \fR?\fIvarName varName ...\fR?
254	.BE
255
256	.SH INTRODUCTION
257	.PP
258	This command parses fields from an input string in the same fashion as the
259	ANSI C \fBsscanf\fR procedure and returns a count of the number of
260	conversions performed, or -1 if the end of the input string is reached
261	before any conversions have been performed. \fIString\fR gives the input
262	to be parsed and \fIformat\fR indicates how to parse it, using \fB%\fR
263	conversion specifiers as in \fBsscanf\fR. Each \fIvarName\fR gives the
264	name of a variable; when a field is scanned from \fIstring\fR the result is
265	converted back into a string and assigned to the corresponding variable.
266	If no \fIvarName\fR variables are specified, then \fBscan\fR works in an
267	inline manner, returning the data that would otherwise be stored in the
268	variables as a list. In the inline case, an empty string is returned when
269	the end of the input string is reached before any conversions have been
270	performed.
271	.SH "DETAILS ON SCANNING"
272	.PP
273	\fBScan\fR operates by scanning \fIstring\fR and \fIformat\fR together.
274	If the next character in \fIformat\fR is a blank or tab then it
275	matches any number of white space characters in \fIstring\fR (including
276	zero).
277	Otherwise, if it isn't a \fB%\fR character then it
278	must match the next character of \fIstring\fR.
279	When a \fB%\fR is encountered in \fIformat\fR, it indicates
280	the start of a conversion specifier.
281	.VS 8.4
282	A conversion specifier contains up to four fields after the \fB%\fR:
283	a \fB*\fR, which indicates that the converted value is to be discarded
284	instead of assigned to a variable; a XPG3 position specifier; a number
285	indicating a maximum field width; a field size modifier; and a
286	conversion character.
287	.VE 8.4
288	All of these fields are optional except for the conversion character.
289	The fields that are present must appear in the order given above.
290	.PP
291	When \fBscan\fR finds a conversion specifier in \fIformat\fR, it
292	first skips any white-space characters in \fIstring\fR (unless the
293	specifier is \fB[\fR or \fBc\fR).
294	Then it converts the next input characters according to the
295	conversion specifier and stores the result in the variable given
296	by the next argument to \fBscan\fR.
297	.PP
298	If the \fB%\fR is followed by a decimal number and a \fB$\fR, as in
299	``\fB%2$d\fR'', then the variable to use is not taken from the next
300	sequential argument. Instead, it is taken from the argument indicated
301	by the number, where 1 corresponds to the first \fIvarName\fR. If
302	there are any positional specifiers in \fIformat\fR then all of the
303	specifiers must be positional. Every \fIvarName\fR on the argument
304	list must correspond to exactly one conversion specifier or an error
305	is generated, or in the inline case, any position can be specified
306	at most once and the empty positions will be filled in with empty strings.
307	.PP
308	The following conversion characters are supported:
309	.TP 10
310	\fBd\fR
311	The input field must be a decimal integer.
312	It is read in and the value is stored in the variable as a decimal string.
313	.VS 8.4
314	If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
315	value will have an internal representation that is at least 64-bits in
316	size.
317	.VE 8.4
318	.TP 10
319	\fBo\fR
320	The input field must be an octal integer. It is read in and the
321	value is stored in the variable as a decimal string.
322	.VS 8.4
323	If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
324	value will have an internal representation that is at least 64-bits in
325	size.
326	If the value exceeds MAX_INT (017777777777 on platforms using 32-bit
327	integers when the \fBl\fR and \fBL\fR modifiers are not given), it
328	will be truncated to a signed integer. Hence, 037777777777 will
329	appear as -1 on a 32-bit machine by default.
330	.VE 8.4
331	.TP 10
332	\fBx\fR
333	The input field must be a hexadecimal integer. It is read in
334	and the value is stored in the variable as a decimal string.
335	.VS 8.4
336	If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
337	value will have an internal representation that is at least 64-bits in
338	size.
339	If the value exceeds MAX_INT (0x7FFFFFFF on platforms using 32-bit
340	integers when the \fBl\fR and \fBL\fR modifiers are not given), it
341	will be truncated to a signed integer. Hence, 0xFFFFFFFF will appear
342	as -1 on a 32-bit machine.
343	.VE 8.4
344	.TP 10
345	\fBu\fR
346	The input field must be a decimal integer. The value is stored in the
347	variable as an unsigned decimal integer string.
348	.VS 8.4
349	If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
350	value will have an internal representation that is at least 64-bits in
351	size.
352	.VE 8.4
353	.TP 10
354	\fBi\fR
355	The input field must be an integer. The base (i.e. decimal, octal, or
356	hexadecimal) is determined in the same fashion as described in
357	\fBexpr\fR. The value is stored in the variable as a decimal string.
358	.VS 8.4
359	If the \fBl\fR or \fBL\fR field size modifier is given, the scanned
360	value will have an internal representation that is at least 64-bits in
361	size.
362	.VE 8.4
363	.TP 10
364	\fBc\fR
365	A single character is read in and its binary value is stored in
366	the variable as a decimal string.
367	Initial white space is not skipped in this case, so the input
368	field may be a white-space character.
369	This conversion is different from the ANSI standard in that the
370	input field always consists of a single character and no field
371	width may be specified.
372	.TP 10
373	\fBs\fR
374	The input field consists of all the characters up to the next
375	white-space character; the characters are copied to the variable.
376	.TP 10
377	\fBe\fR or \fBf\fR or \fBg\fR
378	The input field must be a floating-point number consisting
379	of an optional sign, a string of decimal digits possibly
380	containing a decimal point, and an optional exponent consisting
381	of an \fBe\fR or \fBE\fR followed by an optional sign and a string of
382	decimal digits.
383	It is read in and stored in the variable as a floating-point string.
384	.TP 10
385	\fB[\fIchars\fB]\fR
386	The input field consists of any number of characters in
387	\fIchars\fR.
388	The matching string is stored in the variable.
389	If the first character between the brackets is a \fB]\fR then
390	it is treated as part of \fIchars\fR rather than the closing
391	bracket for the set.
392	If \fIchars\fR
393	contains a sequence of the form \fIa\fB\-\fIb\fR then any
394	character between \fIa\fR and \fIb\fR (inclusive) will match.
395	If the first or last character between the brackets is a \fB\-\fR, then
396	it is treated as part of \fIchars\fR rather than indicating a range.
397	.TP 10
398	\fB[^\fIchars\fB]\fR
399	The input field consists of any number of characters not in
400	\fIchars\fR.
401	The matching string is stored in the variable.
402	If the character immediately following the \fB^\fR is a \fB]\fR then it is
403	treated as part of the set rather than the closing bracket for
404	the set.
405	If \fIchars\fR
406	contains a sequence of the form \fIa\fB\-\fIb\fR then any
407	character between \fIa\fR and \fIb\fR (inclusive) will be excluded
408	from the set.
409	If the first or last character between the brackets is a \fB\-\fR, then
410	it is treated as part of \fIchars\fR rather than indicating a range.
411	.TP 10
412	\fBn\fR
413	No input is consumed from the input string. Instead, the total number
414	of characters scanned from the input string so far is stored in the variable.
415	.LP
416	The number of characters read from the input for a conversion is the
417	largest number that makes sense for that particular conversion (e.g.
418	as many decimal digits as possible for \fB%d\fR, as
419	many octal digits as possible for \fB%o\fR, and so on).
420	The input field for a given conversion terminates either when a
421	white-space character is encountered or when the maximum field
422	width has been reached, whichever comes first.
423	If a \fB*\fR is present in the conversion specifier
424	then no variable is assigned and the next scan argument is not consumed.
425	.SH "DIFFERENCES FROM ANSI SSCANF"
426	.PP
427	The behavior of the \fBscan\fR command is the same as the behavior of
428	the ANSI C \fBsscanf\fR procedure except for the following differences:
429	.IP [1]
430	\fB%p\fR conversion specifier is not currently supported.
431	.IP [2]
432	For \fB%c\fR conversions a single character value is
433	converted to a decimal string, which is then assigned to the
434	corresponding \fIvarName\fR;
435	no field width may be specified for this conversion.
436	.IP [3]
437	.VS 8.4
438	The \fBh\fR modifier is always ignored and the \fBl\fR and \fBL\fR
439	modifiers are ignored when converting real values (i.e. type
440	\fBdouble\fR is used for the internal representation).
441	.VE 8.4
442	.IP [4]
443	If the end of the input string is reached before any conversions have been
444	performed and no variables are given, an empty string is returned.
445	.SH EXAMPLES
446	Parse a simple color specification of the form \fI#RRGGBB\fR using
447	hexadecimal conversions with field sizes:
448	.CS
449	set string "#08D03F"
450	\fBscan\fR $string "#%2x%2x%2x" r g b
451	.CE
452	.PP
453	Parse a \fIHH:MM\fR time string, noting that this avoids problems with
454	octal numbers by forcing interpretation as decimals (if we did not
455	care, we would use the \fB%i\fR conversion instead):
456	.CS
457	set string "08:08" ;# Not octal!
458	if {[\fBscan\fR $string "%d:%d" hours minutes] != 2} {
459	error "not a valid time string"
460	}
461	# We have to understand numeric ranges ourselves...
462	if {$minutes < 0 \|\| $minutes > 59} {
463	error "invalid number of minutes"
464	}
465	.CE
466	.PP
467	Break a string up into sequences of non-whitespace characters (note
468	the use of the \fB%n\fR conversion so that we get skipping over
469	leading whitespace correct):
470	.CS
471	set string " a string {with braced words} + leading space "
472	set words {}
473	while {[\fBscan\fR $string %s%n word length] == 2} {
474	lappend words $word
475	set string [string range $string $length end]
476	}
477	.CE
478	.PP
479	Parse a simple coordinate string, checking that it is complete by
480	looking for the terminating character explicitly:
481	.CS
482	set string "(5.2,-4e-2)"
483	# Note that the spaces before the literal parts of
484	# the scan pattern are significant, and that ")" is
485	# the Unicode character \\u0029
486	if {
487	[\fBscan\fR $string " (%f ,%f %c" x y last] != 3
488	\|\| $last != 0x0029
489	} then {
490	error "invalid coordinate string"
491	}
492	puts "X=$x, Y=$y"
493	.CE
494
495	.SH "SEE ALSO"
496	format(n), sscanf(3)
497
498	.SH KEYWORDS
499	conversion specifier, parse, scan