Failed to save the file to the "xx" directory.

Failed to save the file to the "ll" directory.

Failed to save the file to the "mm" directory.

Failed to save the file to the "wp" directory.

403WebShell
403Webshell
Server IP : 66.29.132.124  /  Your IP : 18.217.156.67
Web Server : LiteSpeed
System : Linux business141.web-hosting.com 4.18.0-553.lve.el8.x86_64 #1 SMP Mon May 27 15:27:34 UTC 2024 x86_64
User : wavevlvu ( 1524)
PHP Version : 7.4.33
Disable Function : NONE
MySQL : OFF  |  cURL : ON  |  WGET : ON  |  Perl : ON  |  Python : ON  |  Sudo : OFF  |  Pkexec : OFF
Directory :  /proc/thread-self/root/proc/self/root/proc/self/root/usr/share/tcl8.6/

Upload File :
current_dir [ Writeable ] document_root [ Writeable ]

 

Command :


[ Back ]     

Current File : /proc/thread-self/root/proc/self/root/proc/self/root/usr/share/tcl8.6//clock.tcl
#----------------------------------------------------------------------
#
# clock.tcl --
#
#	This file implements the portions of the [clock] ensemble that are
#	coded in Tcl.  Refer to the users' manual to see the description of
#	the [clock] command and its subcommands.
#
#
#----------------------------------------------------------------------
#
# Copyright (c) 2004,2005,2006,2007 by Kevin B. Kenny
# See the file "license.terms" for information on usage and redistribution
# of this file, and for a DISCLAIMER OF ALL WARRANTIES.
#
#----------------------------------------------------------------------

# We must have message catalogs that support the root locale, and we need
# access to the Registry on Windows systems.

uplevel \#0 {
    package require msgcat 1.6
    if { $::tcl_platform(platform) eq {windows} } {
	if { [catch { package require registry 1.1 }] } {
	    namespace eval ::tcl::clock [list variable NoRegistry {}]
	}
    }
}

# Put the library directory into the namespace for the ensemble so that the
# library code can find message catalogs and time zone definition files.

namespace eval ::tcl::clock \
    [list variable LibDir [file dirname [info script]]]

#----------------------------------------------------------------------
#
# clock --
#
#	Manipulate times.
#
# The 'clock' command manipulates time.  Refer to the user documentation for
# the available subcommands and what they do.
#
#----------------------------------------------------------------------

namespace eval ::tcl::clock {

    # Export the subcommands

    namespace export format
    namespace export clicks
    namespace export microseconds
    namespace export milliseconds
    namespace export scan
    namespace export seconds
    namespace export add

    # Import the message catalog commands that we use.

    namespace import ::msgcat::mcload
    namespace import ::msgcat::mclocale
    namespace import ::msgcat::mc
    namespace import ::msgcat::mcpackagelocale

}

#----------------------------------------------------------------------
#
# ::tcl::clock::Initialize --
#
#	Finish initializing the 'clock' subsystem
#
# Results:
#	None.
#
# Side effects:
#	Namespace variable in the 'clock' subsystem are initialized.
#
# The '::tcl::clock::Initialize' procedure initializes the namespace variables
# and root locale message catalog for the 'clock' subsystem.  It is broken
# into a procedure rather than simply evaluated as a script so that it will be
# able to use local variables, avoiding the dangers of 'creative writing' as
# in Bug 1185933.
#
#----------------------------------------------------------------------

proc ::tcl::clock::Initialize {} {

    rename ::tcl::clock::Initialize {}

    variable LibDir

    # Define the Greenwich time zone

    proc InitTZData {} {
	variable TZData
	array unset TZData
	set TZData(:Etc/GMT) {
	    {-9223372036854775808 0 0 GMT}
	}
	set TZData(:GMT) $TZData(:Etc/GMT)
	set TZData(:Etc/UTC) {
	    {-9223372036854775808 0 0 UTC}
	}
	set TZData(:UTC) $TZData(:Etc/UTC)
	set TZData(:localtime) {}
    }
    InitTZData

    mcpackagelocale set {}
    ::msgcat::mcpackageconfig set mcfolder [file join $LibDir msgs]
    ::msgcat::mcpackageconfig set unknowncmd ""
    ::msgcat::mcpackageconfig set changecmd ChangeCurrentLocale

    # Define the message catalog for the root locale.

    ::msgcat::mcmset {} {
	AM {am}
	BCE {B.C.E.}
	CE {C.E.}
	DATE_FORMAT {%m/%d/%Y}
	DATE_TIME_FORMAT {%a %b %e %H:%M:%S %Y}
	DAYS_OF_WEEK_ABBREV	{
	    Sun Mon Tue Wed Thu Fri Sat
	}
	DAYS_OF_WEEK_FULL	{
	    Sunday Monday Tuesday Wednesday Thursday Friday Saturday
	}
	GREGORIAN_CHANGE_DATE	2299161
	LOCALE_DATE_FORMAT {%m/%d/%Y}
	LOCALE_DATE_TIME_FORMAT {%a %b %e %H:%M:%S %Y}
	LOCALE_ERAS {}
	LOCALE_NUMERALS		{
	    00 01 02 03 04 05 06 07 08 09
	    10 11 12 13 14 15 16 17 18 19
	    20 21 22 23 24 25 26 27 28 29
	    30 31 32 33 34 35 36 37 38 39
	    40 41 42 43 44 45 46 47 48 49
	    50 51 52 53 54 55 56 57 58 59
	    60 61 62 63 64 65 66 67 68 69
	    70 71 72 73 74 75 76 77 78 79
	    80 81 82 83 84 85 86 87 88 89
	    90 91 92 93 94 95 96 97 98 99
	}
	LOCALE_TIME_FORMAT {%H:%M:%S}
	LOCALE_YEAR_FORMAT {%EC%Ey}
	MONTHS_ABBREV		{
	    Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
	}
	MONTHS_FULL		{
	    	January		February	March
	    	April		May		June
	    	July		August		September
		October		November	December
	}
	PM {pm}
	TIME_FORMAT {%H:%M:%S}
	TIME_FORMAT_12 {%I:%M:%S %P}
	TIME_FORMAT_24 {%H:%M}
	TIME_FORMAT_24_SECS {%H:%M:%S}
    }

    # Define a few Gregorian change dates for other locales.  In most cases
    # the change date follows a language, because a nation's colonies changed
    # at the same time as the nation itself.  In many cases, different
    # national boundaries existed; the dominating rule is to follow the
    # nation's capital.

    # Italy, Spain, Portugal, Poland

    ::msgcat::mcset it GREGORIAN_CHANGE_DATE 2299161
    ::msgcat::mcset es GREGORIAN_CHANGE_DATE 2299161
    ::msgcat::mcset pt GREGORIAN_CHANGE_DATE 2299161
    ::msgcat::mcset pl GREGORIAN_CHANGE_DATE 2299161

    # France, Austria

    ::msgcat::mcset fr GREGORIAN_CHANGE_DATE 2299227

    # For Belgium, we follow Southern Netherlands; Liege Diocese changed
    # several weeks later.

    ::msgcat::mcset fr_BE GREGORIAN_CHANGE_DATE 2299238
    ::msgcat::mcset nl_BE GREGORIAN_CHANGE_DATE 2299238

    # Austria

    ::msgcat::mcset de_AT GREGORIAN_CHANGE_DATE 2299527

    # Hungary

    ::msgcat::mcset hu GREGORIAN_CHANGE_DATE 2301004

    # Germany, Norway, Denmark (Catholic Germany changed earlier)

    ::msgcat::mcset de_DE GREGORIAN_CHANGE_DATE 2342032
    ::msgcat::mcset nb GREGORIAN_CHANGE_DATE 2342032
    ::msgcat::mcset nn GREGORIAN_CHANGE_DATE 2342032
    ::msgcat::mcset no GREGORIAN_CHANGE_DATE 2342032
    ::msgcat::mcset da GREGORIAN_CHANGE_DATE 2342032

    # Holland (Brabant, Gelderland, Flanders, Friesland, etc. changed at
    # various times)

    ::msgcat::mcset nl GREGORIAN_CHANGE_DATE 2342165

    # Protestant Switzerland (Catholic cantons changed earlier)

    ::msgcat::mcset fr_CH GREGORIAN_CHANGE_DATE 2361342
    ::msgcat::mcset it_CH GREGORIAN_CHANGE_DATE 2361342
    ::msgcat::mcset de_CH GREGORIAN_CHANGE_DATE 2361342

    # English speaking countries

    ::msgcat::mcset en GREGORIAN_CHANGE_DATE 2361222

    # Sweden (had several changes onto and off of the Gregorian calendar)

    ::msgcat::mcset sv GREGORIAN_CHANGE_DATE 2361390

    # Russia

    ::msgcat::mcset ru GREGORIAN_CHANGE_DATE 2421639

    # Romania (Transylvania changed earler - perhaps de_RO should show the
    # earlier date?)

    ::msgcat::mcset ro GREGORIAN_CHANGE_DATE 2422063

    # Greece

    ::msgcat::mcset el GREGORIAN_CHANGE_DATE 2423480

    #------------------------------------------------------------------
    #
    #				CONSTANTS
    #
    #------------------------------------------------------------------

    # Paths at which binary time zone data for the Olson libraries are known
    # to reside on various operating systems

    variable ZoneinfoPaths {}
    foreach path {
	/usr/share/zoneinfo
	/usr/share/lib/zoneinfo
	/usr/lib/zoneinfo
	/usr/local/etc/zoneinfo
    } {
	if { [file isdirectory $path] } {
	    lappend ZoneinfoPaths $path
	}
    }

    # Define the directories for time zone data and message catalogs.

    variable DataDir [file join $LibDir tzdata]

    # Number of days in the months, in common years and leap years.

    variable DaysInRomanMonthInCommonYear \
	{ 31 28 31 30 31 30 31 31 30 31 30 31 }
    variable DaysInRomanMonthInLeapYear \
	{ 31 29 31 30 31 30 31 31 30 31 30 31 }
    variable DaysInPriorMonthsInCommonYear [list 0]
    variable DaysInPriorMonthsInLeapYear [list 0]
    set i 0
    foreach j $DaysInRomanMonthInCommonYear {
	lappend DaysInPriorMonthsInCommonYear [incr i $j]
    }
    set i 0
    foreach j $DaysInRomanMonthInLeapYear {
	lappend DaysInPriorMonthsInLeapYear [incr i $j]
    }

    # Another epoch (Hi, Jeff!)

    variable Roddenberry 1946

    # Integer ranges

    variable MINWIDE -9223372036854775808
    variable MAXWIDE 9223372036854775807

    # Day before Leap Day

    variable FEB_28	       58

    # Translation table to map Windows TZI onto cities, so that the Olson
    # rules can apply.  In some cases the mapping is ambiguous, so it's wise
    # to specify $::env(TCL_TZ) rather than simply depending on the system
    # time zone.

    # The keys are long lists of values obtained from the time zone
    # information in the Registry.  In order, the list elements are:
    # 	Bias StandardBias DaylightBias
    #   StandardDate.wYear StandardDate.wMonth StandardDate.wDayOfWeek
    #   StandardDate.wDay StandardDate.wHour StandardDate.wMinute
    #   StandardDate.wSecond StandardDate.wMilliseconds
    #   DaylightDate.wYear DaylightDate.wMonth DaylightDate.wDayOfWeek
    #   DaylightDate.wDay DaylightDate.wHour DaylightDate.wMinute
    #   DaylightDate.wSecond DaylightDate.wMilliseconds
    # The values are the names of time zones where those rules apply.  There
    # is considerable ambiguity in certain zones; an attempt has been made to
    # make a reasonable guess, but this table needs to be taken with a grain
    # of salt.

    variable WinZoneInfo [dict create {*}{
	{-43200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :Pacific/Kwajalein
	{-39600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}	 :Pacific/Midway
	{-36000 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :Pacific/Honolulu
        {-32400 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/Anchorage
        {-28800 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/Los_Angeles
        {-28800 0 3600 0 10 0 5 2 0 0 0 0 4 0 1 2 0 0 0} :America/Tijuana
        {-25200 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/Denver
        {-25200 0 3600 0 10 0 5 2 0 0 0 0 4 0 1 2 0 0 0} :America/Chihuahua
	{-25200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :America/Phoenix
	{-21600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :America/Regina
	{-21600 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/Chicago
        {-21600 0 3600 0 10 0 5 2 0 0 0 0 4 0 1 2 0 0 0} :America/Mexico_City
	{-18000 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/New_York
	{-18000 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :America/Indianapolis
	{-14400 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :America/Caracas
        {-14400 0 3600 0 3 6 2 23 59 59 999 0 10 6 2 23 59 59 999}
							 :America/Santiago
        {-14400 0 3600 0 2 0 5 2 0 0 0 0 11 0 1 2 0 0 0} :America/Manaus
        {-14400 0 3600 0 11 0 1 2 0 0 0 0 3 0 2 2 0 0 0} :America/Halifax
	{-12600 0 3600 0 10 0 5 2 0 0 0 0 4 0 1 2 0 0 0} :America/St_Johns
	{-10800 0 3600 0 2 0 2 2 0 0 0 0 10 0 3 2 0 0 0} :America/Sao_Paulo
	{-10800 0 3600 0 10 0 5 2 0 0 0 0 4 0 1 2 0 0 0} :America/Godthab
	{-10800 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}  :America/Buenos_Aires
        {-10800 0 3600 0 2 0 5 2 0 0 0 0 11 0 1 2 0 0 0} :America/Bahia
        {-10800 0 3600 0 3 0 2 2 0 0 0 0 10 0 1 2 0 0 0} :America/Montevideo
	{-7200 0 3600 0 9 0 5 2 0 0 0 0 3 0 5 2 0 0 0}   :America/Noronha
	{-3600 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Atlantic/Azores
	{-3600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Atlantic/Cape_Verde
	{0 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}       :UTC
	{0 0 3600 0 10 0 5 2 0 0 0 0 3 0 5 1 0 0 0}      :Europe/London
	{3600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}    :Africa/Kinshasa
	{3600 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}   :CET
        {7200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}    :Africa/Harare
        {7200 0 3600 0 9 4 5 23 59 59 0 0 4 4 5 23 59 59 0}
			      				 :Africa/Cairo
	{7200 0 3600 0 10 0 5 4 0 0 0 0 3 0 5 3 0 0 0}   :Europe/Helsinki
        {7200 0 3600 0 9 0 3 2 0 0 0 0 3 5 5 2 0 0 0}    :Asia/Jerusalem
	{7200 0 3600 0 9 0 5 1 0 0 0 0 3 0 5 0 0 0 0}    :Europe/Bucharest
	{7200 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}   :Europe/Athens
        {7200 0 3600 0 9 5 5 1 0 0 0 0 3 4 5 0 0 0 0}    :Asia/Amman
        {7200 0 3600 0 10 6 5 23 59 59 999 0 3 0 5 0 0 0 0}
							 :Asia/Beirut
        {7200 0 -3600 0 4 0 1 2 0 0 0 0 9 0 1 2 0 0 0}   :Africa/Windhoek
	{10800 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Riyadh
	{10800 0 3600 0 10 0 1 4 0 0 0 0 4 0 1 3 0 0 0}  :Asia/Baghdad
	{10800 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Europe/Moscow
	{12600 0 3600 0 9 2 4 2 0 0 0 0 3 0 1 2 0 0 0}   :Asia/Tehran
        {14400 0 3600 0 10 0 5 5 0 0 0 0 3 0 5 4 0 0 0}  :Asia/Baku
	{14400 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Muscat
	{14400 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Tbilisi
	{16200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Kabul
	{18000 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Karachi
	{18000 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Yekaterinburg
	{19800 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Calcutta
	{20700 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Katmandu
	{21600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Dhaka
	{21600 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Novosibirsk
	{23400 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Rangoon
	{25200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Bangkok
	{25200 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Krasnoyarsk
	{28800 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Chongqing
	{28800 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Irkutsk
	{32400 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Asia/Tokyo
	{32400 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Yakutsk
	{34200 0 3600 0 3 0 5 3 0 0 0 0 10 0 5 2 0 0 0}  :Australia/Adelaide
	{34200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Australia/Darwin
	{36000 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Australia/Brisbane
	{36000 0 3600 0 10 0 5 3 0 0 0 0 3 0 5 2 0 0 0}  :Asia/Vladivostok
	{36000 0 3600 0 3 0 5 3 0 0 0 0 10 0 1 2 0 0 0}  :Australia/Hobart
	{36000 0 3600 0 3 0 5 3 0 0 0 0 10 0 5 2 0 0 0}  :Australia/Sydney
	{39600 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Pacific/Noumea
	{43200 0 3600 0 3 0 3 3 0 0 0 0 10 0 1 2 0 0 0}  :Pacific/Auckland
	{43200 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Pacific/Fiji
	{46800 0 3600 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0}   :Pacific/Tongatapu
    }]

    # Groups of fields that specify the date, priorities, and code bursts that
    # determine Julian Day Number given those groups.  The code in [clock
    # scan] will choose the highest priority (lowest numbered) set of fields
    # that determines the date.

    variable DateParseActions {

	{ seconds } 0 {}

	{ julianDay } 1 {}

	{ era century yearOfCentury month dayOfMonth } 2 {
	    dict set date year [expr { 100 * [dict get $date century]
				       + [dict get $date yearOfCentury] }]
	    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] \
			  $changeover]
	}
	{ era century yearOfCentury dayOfYear } 2 {
	    dict set date year [expr { 100 * [dict get $date century]
				       + [dict get $date yearOfCentury] }]
	    set date [GetJulianDayFromEraYearDay $date[set date {}] \
			  $changeover]
	}

	{ century yearOfCentury month dayOfMonth } 3 {
	    dict set date era CE
	    dict set date year [expr { 100 * [dict get $date century]
				       + [dict get $date yearOfCentury] }]
	    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] \
			  $changeover]
	}
	{ century yearOfCentury dayOfYear } 3 {
	    dict set date era CE
	    dict set date year [expr { 100 * [dict get $date century]
				       + [dict get $date yearOfCentury] }]
	    set date [GetJulianDayFromEraYearDay $date[set date {}] \
			  $changeover]
	}
	{ iso8601Century iso8601YearOfCentury iso8601Week dayOfWeek } 3 {
	    dict set date era CE
	    dict set date iso8601Year \
		[expr { 100 * [dict get $date iso8601Century]
			+ [dict get $date iso8601YearOfCentury] }]
	    set date [GetJulianDayFromEraYearWeekDay $date[set date {}] \
			 $changeover]
	}

	{ yearOfCentury month dayOfMonth } 4 {
	    set date [InterpretTwoDigitYear $date[set date {}] $baseTime]
	    dict set date era CE
	    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] \
			  $changeover]
	}
	{ yearOfCentury dayOfYear } 4 {
	    set date [InterpretTwoDigitYear $date[set date {}] $baseTime]
	    dict set date era CE
	    set date [GetJulianDayFromEraYearDay $date[set date {}] \
			  $changeover]
	}
	{ iso8601YearOfCentury iso8601Week dayOfWeek } 4 {
	    set date [InterpretTwoDigitYear \
			  $date[set date {}] $baseTime \
			  iso8601YearOfCentury iso8601Year]
	    dict set date era CE
	    set date [GetJulianDayFromEraYearWeekDay $date[set date {}] \
			 $changeover]
	}

	{ month dayOfMonth } 5 {
	    set date [AssignBaseYear $date[set date {}] \
			  $baseTime $timeZone $changeover]
	    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] \
			  $changeover]
	}
	{ dayOfYear } 5 {
	    set date [AssignBaseYear $date[set date {}] \
			  $baseTime $timeZone $changeover]
	    set date [GetJulianDayFromEraYearDay $date[set date {}] \
			 $changeover]
	}
	{ iso8601Week dayOfWeek } 5 {
	    set date [AssignBaseIso8601Year $date[set date {}] \
			  $baseTime $timeZone $changeover]
	    set date [GetJulianDayFromEraYearWeekDay $date[set date {}] \
			 $changeover]
	}

	{ dayOfMonth } 6 {
	    set date [AssignBaseMonth $date[set date {}] \
			  $baseTime $timeZone $changeover]
	    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] \
			  $changeover]
	}

	{ dayOfWeek } 7 {
	    set date [AssignBaseWeek $date[set date {}] \
			  $baseTime $timeZone $changeover]
	    set date [GetJulianDayFromEraYearWeekDay $date[set date {}] \
			 $changeover]
	}

	{} 8 {
	    set date [AssignBaseJulianDay $date[set date {}] \
			  $baseTime $timeZone $changeover]
	}
    }

    # Groups of fields that specify time of day, priorities, and code that
    # processes them

    variable TimeParseActions {

	seconds 1 {}

	{ hourAMPM minute second amPmIndicator } 2 {
	    dict set date secondOfDay [InterpretHMSP $date]
	}
	{ hour minute second } 2 {
	    dict set date secondOfDay [InterpretHMS $date]
	}

	{ hourAMPM minute amPmIndicator } 3 {
	    dict set date second 0
	    dict set date secondOfDay [InterpretHMSP $date]
	}
	{ hour minute } 3 {
	    dict set date second 0
	    dict set date secondOfDay [InterpretHMS $date]
	}

	{ hourAMPM amPmIndicator } 4 {
	    dict set date minute 0
	    dict set date second 0
	    dict set date secondOfDay [InterpretHMSP $date]
	}
	{ hour } 4 {
	    dict set date minute 0
	    dict set date second 0
	    dict set date secondOfDay [InterpretHMS $date]
	}

	{ } 5 {
	    dict set date secondOfDay 0
	}
    }

    # Legacy time zones, used primarily for parsing RFC822 dates.

    variable LegacyTimeZone [dict create \
	gmt	+0000 \
	ut	+0000 \
	utc	+0000 \
	bst	+0100 \
	wet	+0000 \
	wat	-0100 \
	at	-0200 \
	nft	-0330 \
	nst	-0330 \
	ndt	-0230 \
	ast	-0400 \
	adt	-0300 \
	est	-0500 \
	edt	-0400 \
	cst	-0600 \
	cdt	-0500 \
	mst	-0700 \
	mdt	-0600 \
	pst	-0800 \
	pdt	-0700 \
	yst	-0900 \
	ydt	-0800 \
	hst	-1000 \
	hdt	-0900 \
	cat	-1000 \
	ahst	-1000 \
	nt	-1100 \
	idlw	-1200 \
	cet	+0100 \
	cest	+0200 \
	met	+0100 \
	mewt	+0100 \
	mest	+0200 \
	swt	+0100 \
	sst	+0200 \
	fwt	+0100 \
	fst	+0200 \
	eet	+0200 \
	eest	+0300 \
	bt	+0300 \
	it	+0330 \
	zp4	+0400 \
	zp5	+0500 \
	ist	+0530 \
	zp6	+0600 \
	wast	+0700 \
	wadt	+0800 \
	jt	+0730 \
	cct	+0800 \
	jst	+0900 \
	kst     +0900 \
	cast	+0930 \
        jdt     +1000 \
        kdt     +1000 \
	cadt	+1030 \
	east	+1000 \
	eadt	+1030 \
	gst	+1000 \
	nzt	+1200 \
	nzst	+1200 \
	nzdt	+1300 \
	idle	+1200 \
	a	+0100 \
	b	+0200 \
	c	+0300 \
	d	+0400 \
	e	+0500 \
	f	+0600 \
	g	+0700 \
	h	+0800 \
	i	+0900 \
	k	+1000 \
	l	+1100 \
	m	+1200 \
	n	-0100 \
	o	-0200 \
	p	-0300 \
	q	-0400 \
	r	-0500 \
	s	-0600 \
	t	-0700 \
	u	-0800 \
	v	-0900 \
	w	-1000 \
	x	-1100 \
	y	-1200 \
	z	+0000 \
    ]

    # Caches

    variable LocaleNumeralCache {};	# Dictionary whose keys are locale
					# names and whose values are pairs
					# comprising regexes matching numerals
					# in the given locales and dictionaries
					# mapping the numerals to their numeric
					# values.
    # variable CachedSystemTimeZone;    # If 'CachedSystemTimeZone' exists,
					# it contains the value of the
					# system time zone, as determined from
					# the environment.
    variable TimeZoneBad {};	        # Dictionary whose keys are time zone
    					# names and whose values are 1 if
					# the time zone is unknown and 0
    					# if it is known.
    variable TZData;			# Array whose keys are time zone names
					# and whose values are lists of quads
					# comprising start time, UTC offset,
					# Daylight Saving Time indicator, and
					# time zone abbreviation.
    variable FormatProc;		# Array mapping format group
					# and locale to the name of a procedure
					# that renders the given format
}
::tcl::clock::Initialize

#----------------------------------------------------------------------
#
# clock format --
#
#	Formats a count of seconds since the Posix Epoch as a time of day.
#
# The 'clock format' command formats times of day for output.  Refer to the
# user documentation to see what it does.
#
#----------------------------------------------------------------------

proc ::tcl::clock::format { args } {

    variable FormatProc
    variable TZData

    lassign [ParseFormatArgs {*}$args] format locale timezone
    set locale [string tolower $locale]
    set clockval [lindex $args 0]

    # Get the data for time changes in the given zone

    if {$timezone eq ""} {
	set timezone [GetSystemTimeZone]
    }
    if {![info exists TZData($timezone)]} {
	if {[catch {SetupTimeZone $timezone} retval opts]} {
	    dict unset opts -errorinfo
	    return -options $opts $retval
	}
    }

    # Build a procedure to format the result. Cache the built procedure's name
    # in the 'FormatProc' array to avoid losing its internal representation,
    # which contains the name resolution.

    set procName formatproc'$format'$locale
    set procName [namespace current]::[string map {: {\:} \\ {\\}} $procName]
    if {[info exists FormatProc($procName)]} {
	set procName $FormatProc($procName)
    } else {
	set FormatProc($procName) \
	    [ParseClockFormatFormat $procName $format $locale]
    }

    return [$procName $clockval $timezone]

}

#----------------------------------------------------------------------
#
# ParseClockFormatFormat --
#
#	Builds and caches a procedure that formats a time value.
#
# Parameters:
#	format -- Format string to use
#	locale -- Locale in which the format string is to be interpreted
#
# Results:
#	Returns the name of the newly-built procedure.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ParseClockFormatFormat {procName format locale} {

    if {[namespace which $procName] ne {}} {
	return $procName
    }

    # Map away the locale-dependent composite format groups

    EnterLocale $locale

    # Change locale if a fresh locale has been given on the command line.

    try {
	return [ParseClockFormatFormat2 $format $locale $procName]
    } trap CLOCK {result opts} {
	dict unset opts -errorinfo
	return -options $opts $result
    }
}

proc ::tcl::clock::ParseClockFormatFormat2 {format locale procName} {
    set didLocaleEra 0
    set didLocaleNumerals 0
    set preFormatCode \
	[string map [list @GREGORIAN_CHANGE_DATE@ \
				       [mc GREGORIAN_CHANGE_DATE]] \
	     {
		 variable TZData
		 set date [GetDateFields $clockval \
			       $TZData($timezone) \
			       @GREGORIAN_CHANGE_DATE@]
	     }]
    set formatString {}
    set substituents {}
    set state {}

    set format [LocalizeFormat $locale $format]

    foreach char [split $format {}] {
	switch -exact -- $state {
	    {} {
		if { [string equal % $char] } {
		    set state percent
		} else {
		    append formatString $char
		}
	    }
	    percent {			# Character following a '%' character
		set state {}
		switch -exact -- $char {
		    % {			# A literal character, '%'
			append formatString %%
		    }
		    a {			# Day of week, abbreviated
			append formatString %s
			append substituents \
			    [string map \
				 [list @DAYS_OF_WEEK_ABBREV@ \
				      [list [mc DAYS_OF_WEEK_ABBREV]]] \
				 { [lindex @DAYS_OF_WEEK_ABBREV@ \
					[expr {[dict get $date dayOfWeek] \
						   % 7}]]}]
		    }
		    A {			# Day of week, spelt out.
			append formatString %s
			append substituents \
			    [string map \
				 [list @DAYS_OF_WEEK_FULL@ \
				      [list [mc DAYS_OF_WEEK_FULL]]] \
				 { [lindex @DAYS_OF_WEEK_FULL@ \
					[expr {[dict get $date dayOfWeek] \
						   % 7}]]}]
		    }
		    b - h {		# Name of month, abbreviated.
			append formatString %s
			append substituents \
			    [string map \
				 [list @MONTHS_ABBREV@ \
				      [list [mc MONTHS_ABBREV]]] \
				 { [lindex @MONTHS_ABBREV@ \
					[expr {[dict get $date month]-1}]]}]
		    }
		    B {			# Name of month, spelt out
			append formatString %s
			append substituents \
			    [string map \
				 [list @MONTHS_FULL@ \
				      [list [mc MONTHS_FULL]]] \
				 { [lindex @MONTHS_FULL@ \
					[expr {[dict get $date month]-1}]]}]
		    }
		    C {			# Century number
			append formatString %02d
			append substituents \
			    { [expr {[dict get $date year] / 100}]}
		    }
		    d {			# Day of month, with leading zero
			append formatString %02d
			append substituents { [dict get $date dayOfMonth]}
		    }
		    e {			# Day of month, without leading zero
			append formatString %2d
			append substituents { [dict get $date dayOfMonth]}
		    }
		    E {			# Format group in a locale-dependent
					# alternative era
			set state percentE
			if {!$didLocaleEra} {
			    append preFormatCode \
				[string map \
				     [list @LOCALE_ERAS@ \
					  [list [mc LOCALE_ERAS]]] \
				     {
					 set date [GetLocaleEra \
						       $date[set date {}] \
						       @LOCALE_ERAS@]}] \n
			    set didLocaleEra 1
			}
			if {!$didLocaleNumerals} {
			    append preFormatCode \
				[list set localeNumerals \
				     [mc LOCALE_NUMERALS]] \n
			    set didLocaleNumerals 1
			}
		    }
		    g {			# Two-digit year relative to ISO8601
					# week number
			append formatString %02d
			append substituents \
			    { [expr { [dict get $date iso8601Year] % 100 }]}
		    }
		    G {			# Four-digit year relative to ISO8601
					# week number
			append formatString %02d
			append substituents { [dict get $date iso8601Year]}
		    }
		    H {			# Hour in the 24-hour day, leading zero
			append formatString %02d
			append substituents \
			    { [expr { [dict get $date localSeconds] \
					  / 3600 % 24}]}
		    }
		    I {			# Hour AM/PM, with leading zero
			append formatString %02d
			append substituents \
			    { [expr { ( ( ( [dict get $date localSeconds] \
					    % 86400 ) \
					  + 86400 \
					  - 3600 ) \
					/ 3600 ) \
				      % 12 + 1 }] }
		    }
		    j {			# Day of year (001-366)
			append formatString %03d
			append substituents { [dict get $date dayOfYear]}
		    }
		    J {			# Julian Day Number
			append formatString %07ld
			append substituents { [dict get $date julianDay]}
		    }
		    k {			# Hour (0-23), no leading zero
			append formatString %2d
			append substituents \
			    { [expr { [dict get $date localSeconds]
				      / 3600
				      % 24 }]}
		    }
		    l {			# Hour (12-11), no leading zero
			append formatString %2d
			append substituents \
			    { [expr { ( ( ( [dict get $date localSeconds]
					   % 86400 )
					 + 86400
					 - 3600 )
				       / 3600 )
				     % 12 + 1 }]}
		    }
		    m {			# Month number, leading zero
			append formatString %02d
			append substituents { [dict get $date month]}
		    }
		    M {			# Minute of the hour, leading zero
			append formatString %02d
			append substituents \
			    { [expr { [dict get $date localSeconds]
				      / 60
				      % 60 }]}
		    }
		    n {			# A literal newline
			append formatString \n
		    }
		    N {			# Month number, no leading zero
			append formatString %2d
			append substituents { [dict get $date month]}
		    }
		    O {			# A format group in the locale's
					# alternative numerals
			set state percentO
			if {!$didLocaleNumerals} {
			    append preFormatCode \
				[list set localeNumerals \
				     [mc LOCALE_NUMERALS]] \n
			    set didLocaleNumerals 1
			}
		    }
		    p {			# Localized 'AM' or 'PM' indicator
					# converted to uppercase
			append formatString %s
			append preFormatCode \
			    [list set AM [string toupper [mc AM]]] \n \
			    [list set PM [string toupper [mc PM]]] \n
			append substituents \
			    { [expr {(([dict get $date localSeconds]
				       % 86400) < 43200) ?
				     $AM : $PM}]}
		    }
		    P {			# Localized 'AM' or 'PM' indicator
			append formatString %s
			append preFormatCode \
			    [list set am [mc AM]] \n \
			    [list set pm [mc PM]] \n
			append substituents \
			    { [expr {(([dict get $date localSeconds]
				       % 86400) < 43200) ?
				     $am : $pm}]}

		    }
		    Q {			# Hi, Jeff!
			append formatString %s
			append substituents { [FormatStarDate $date]}
		    }
		    s {			# Seconds from the Posix Epoch
			append formatString %s
			append substituents { [dict get $date seconds]}
		    }
		    S {			# Second of the minute, with
			# leading zero
			append formatString %02d
			append substituents \
			    { [expr { [dict get $date localSeconds]
				      % 60 }]}
		    }
		    t {			# A literal tab character
			append formatString \t
		    }
		    u {			# Day of the week (1-Monday, 7-Sunday)
			append formatString %1d
			append substituents { [dict get $date dayOfWeek]}
		    }
		    U {			# Week of the year (00-53). The
					# first Sunday of the year is the
					# first day of week 01
			append formatString %02d
			append preFormatCode {
			    set dow [dict get $date dayOfWeek]
			    if { $dow == 7 } {
				set dow 0
			    }
			    incr dow
			    set UweekNumber \
				[expr { ( [dict get $date dayOfYear]
					  - $dow + 7 )
					/ 7 }]
			}
			append substituents { $UweekNumber}
		    }
		    V {			# The ISO8601 week number
			append formatString %02d
			append substituents { [dict get $date iso8601Week]}
		    }
		    w {			# Day of the week (0-Sunday,
					# 6-Saturday)
			append formatString %1d
			append substituents \
			    { [expr { [dict get $date dayOfWeek] % 7 }]}
		    }
		    W {			# Week of the year (00-53). The first
					# Monday of the year is the first day
					# of week 01.
			append preFormatCode {
			    set WweekNumber \
				[expr { ( [dict get $date dayOfYear]
					  - [dict get $date dayOfWeek]
					  + 7 )
					/ 7 }]
			}
			append formatString %02d
			append substituents { $WweekNumber}
		    }
		    y {			# The two-digit year of the century
			append formatString %02d
			append substituents \
			    { [expr { [dict get $date year] % 100 }]}
		    }
		    Y {			# The four-digit year
			append formatString %04d
			append substituents { [dict get $date year]}
		    }
		    z {			# The time zone as hours and minutes
					# east (+) or west (-) of Greenwich
			append formatString %s
			append substituents { [FormatNumericTimeZone \
						   [dict get $date tzOffset]]}
		    }
		    Z {			# The name of the time zone
			append formatString %s
			append substituents { [dict get $date tzName]}
		    }
		    % {			# A literal percent character
			append formatString %%
		    }
		    default {		# An unknown escape sequence
			append formatString %% $char
		    }
		}
	    }
	    percentE {			# Character following %E
		set state {}
		switch -exact -- $char {
		    E {
			append formatString %s
			append substituents { } \
			    [string map \
				 [list @BCE@ [list [mc BCE]] \
				      @CE@ [list [mc CE]]] \
				      {[dict get {BCE @BCE@ CE @CE@} \
					    [dict get $date era]]}]
		    }
		    C {			# Locale-dependent era
			append formatString %s
			append substituents { [dict get $date localeEra]}
		    }
		    y {			# Locale-dependent year of the era
			append preFormatCode {
			    set y [dict get $date localeYear]
			    if { $y >= 0 && $y < 100 } {
				set Eyear [lindex $localeNumerals $y]
			    } else {
				set Eyear $y
			    }
			}
			append formatString %s
			append substituents { $Eyear}
		    }
		    default {		# Unknown %E format group
			append formatString %%E $char
		    }
		}
	    }
	    percentO {			# Character following %O
		set state {}
		switch -exact -- $char {
		    d - e {		# Day of the month in alternative
			# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [dict get $date dayOfMonth]]}
		    }
		    H - k {		# Hour of the day in alternative
					# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { [dict get $date localSeconds]
					   / 3600
					   % 24 }]]}
		    }
		    I - l {		# Hour (12-11) AM/PM in alternative
					# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { ( ( ( [dict get $date localSeconds]
						 % 86400 )
					       + 86400
					       - 3600 )
					     / 3600 )
					   % 12 + 1 }]]}
		    }
		    m {			# Month number in alternative numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals [dict get $date month]]}
		    }
		    M {			# Minute of the hour in alternative
					# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { [dict get $date localSeconds]
					   / 60
					   % 60 }]]}
		    }
		    S {			# Second of the minute in alternative
					# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { [dict get $date localSeconds]
					   % 60 }]]}
		    }
		    u {			# Day of the week (Monday=1,Sunday=7)
					# in alternative numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [dict get $date dayOfWeek]]}
			}
		    w {			# Day of the week (Sunday=0,Saturday=6)
					# in alternative numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { [dict get $date dayOfWeek] % 7 }]]}
		    }
		    y {			# Year of the century in alternative
					# numerals
			append formatString %s
			append substituents \
			    { [lindex $localeNumerals \
				   [expr { [dict get $date year] % 100 }]]}
		    }
		    default {	# Unknown format group
			append formatString %%O $char
		    }
		}
	    }
	}
    }

    # Clean up any improperly terminated groups

    switch -exact -- $state {
	percent {
	    append formatString %%
	}
	percentE {
	    append retval %%E
	}
	percentO {
	    append retval %%O
	}
    }

    proc $procName {clockval timezone} "
        $preFormatCode
        return \[::format [list $formatString] $substituents\]
    "

    #    puts [list $procName [info args $procName] [info body $procName]]

    return $procName
}

#----------------------------------------------------------------------
#
# clock scan --
#
#	Inputs a count of seconds since the Posix Epoch as a time of day.
#
# The 'clock format' command scans times of day on input.  Refer to the user
# documentation to see what it does.
#
#----------------------------------------------------------------------

proc ::tcl::clock::scan { args } {

    set format {}

    # Check the count of args

    if { [llength $args] < 1 || [llength $args] % 2 != 1 } {
	set cmdName "clock scan"
	return -code error \
	    -errorcode [list CLOCK wrongNumArgs] \
	    "wrong \# args: should be\
             \"$cmdName string\
             ?-base seconds?\
             ?-format string? ?-gmt boolean?\
             ?-locale LOCALE? ?-timezone ZONE?\""
    }

    # Set defaults

    set base [clock seconds]
    set string [lindex $args 0]
    set format {}
    set gmt 0
    set locale c
    set timezone [GetSystemTimeZone]

    # Pick up command line options.

    foreach { flag value } [lreplace $args 0 0] {
	set saw($flag) {}
	switch -exact -- $flag {
	    -b - -ba - -bas - -base {
		set base $value
	    }
	    -f - -fo - -for - -form - -forma - -format {
		set format $value
	    }
	    -g - -gm - -gmt {
		set gmt $value
	    }
	    -l - -lo - -loc - -loca - -local - -locale {
		set locale [string tolower $value]
	    }
	    -t - -ti - -tim - -time - -timez - -timezo - -timezon - -timezone {
		set timezone $value
	    }
	    default {
		return -code error \
		    -errorcode [list CLOCK badOption $flag] \
		    "bad option \"$flag\",\
                     must be -base, -format, -gmt, -locale or -timezone"
	    }
	}
    }

    # Check options for validity

    if { [info exists saw(-gmt)] && [info exists saw(-timezone)] } {
	return -code error \
	    -errorcode [list CLOCK gmtWithTimezone] \
	    "cannot use -gmt and -timezone in same call"
    }
    if { [catch { expr { wide($base) } } result] } {
	return -code error "expected integer but got \"$base\""
    }
    if { ![string is boolean -strict $gmt] } {
	return -code error "expected boolean value but got \"$gmt\""
    } elseif { $gmt } {
	set timezone :GMT
    }

    if { ![info exists saw(-format)] } {
	# Perhaps someday we'll localize the legacy code. Right now, it's not
	# localized.
	if { [info exists saw(-locale)] } {
	    return -code error \
		-errorcode [list CLOCK flagWithLegacyFormat] \
		"legacy \[clock scan\] does not support -locale"

	}
	return [FreeScan $string $base $timezone $locale]
    }

    # Change locale if a fresh locale has been given on the command line.

    EnterLocale $locale

    try {
	# Map away the locale-dependent composite format groups

	set scanner [ParseClockScanFormat $format $locale]
	return [$scanner $string $base $timezone]
    } trap CLOCK {result opts} {
	# Conceal location of generation of expected errors
	dict unset opts -errorinfo
	return -options $opts $result
    }
}

#----------------------------------------------------------------------
#
# FreeScan --
#
#	Scans a time in free format
#
# Parameters:
#	string - String containing the time to scan
#	base - Base time, expressed in seconds from the Epoch
#	timezone - Default time zone in which the time will be expressed
#	locale - (Unused) Name of the locale where the time will be scanned.
#
# Results:
#	Returns the date and time extracted from the string in seconds from
#	the epoch
#
#----------------------------------------------------------------------

proc ::tcl::clock::FreeScan { string base timezone locale } {

    variable TZData

    # Get the data for time changes in the given zone

    try {
	SetupTimeZone $timezone
    } on error {retval opts} {
	dict unset opts -errorinfo
	return -options $opts $retval
    }

    # Extract year, month and day from the base time for the parser to use as
    # defaults

    set date [GetDateFields $base $TZData($timezone) 2361222]
    dict set date secondOfDay [expr {
	[dict get $date localSeconds] % 86400
    }]

    # Parse the date.  The parser will return a list comprising date, time,
    # time zone, relative month/day/seconds, relative weekday, ordinal month.

    try {
	set scanned [Oldscan $string \
		     [dict get $date year] \
		     [dict get $date month] \
		     [dict get $date dayOfMonth]]
	lassign $scanned \
	    parseDate parseTime parseZone parseRel \
	    parseWeekday parseOrdinalMonth
    } on error message {
	return -code error \
	    "unable to convert date-time string \"$string\": $message"
    }

    # If the caller supplied a date in the string, update the 'date' dict with
    # the value. If the caller didn't specify a time with the date, default to
    # midnight.

    if { [llength $parseDate] > 0 } {
	lassign $parseDate y m d
	if { $y < 100 } {
	    if { $y >= 39 } {
		incr y 1900
	    } else {
		incr y 2000
	    }
	}
	dict set date era CE
	dict set date year $y
	dict set date month $m
	dict set date dayOfMonth $d
	if { $parseTime eq {} } {
	    set parseTime 0
	}
    }

    # If the caller supplied a time zone in the string, it comes back as a
    # two-element list; the first element is the number of minutes east of
    # Greenwich, and the second is a Daylight Saving Time indicator (1 == yes,
    # 0 == no, -1 == unknown). We make it into a time zone indicator of
    # +-hhmm.

    if { [llength $parseZone] > 0 } {
	lassign $parseZone minEast dstFlag
	set timezone [FormatNumericTimeZone \
			  [expr { 60 * $minEast + 3600 * $dstFlag }]]
	SetupTimeZone $timezone
    }
    dict set date tzName $timezone

    # Assemble date, time, zone into seconds-from-epoch

    set date [GetJulianDayFromEraYearMonthDay $date[set date {}] 2361222]
    if { $parseTime ne {} } {
	dict set date secondOfDay $parseTime
    } elseif { [llength $parseWeekday] != 0
	       || [llength $parseOrdinalMonth] != 0
	       || ( [llength $parseRel] != 0
		    && ( [lindex $parseRel 0] != 0
			 || [lindex $parseRel 1] != 0 ) ) } {
	dict set date secondOfDay 0
    }

    dict set date localSeconds [expr {
	-210866803200
	+ ( 86400 * wide([dict get $date julianDay]) )
	+ [dict get $date secondOfDay]
    }]
    dict set date tzName $timezone
    set date [ConvertLocalToUTC $date[set date {}] $TZData($timezone) 2361222]
    set seconds [dict get $date seconds]

    # Do relative times

    if { [llength $parseRel] > 0 } {
	lassign $parseRel relMonth relDay relSecond
	set seconds [add $seconds \
			 $relMonth months $relDay days $relSecond seconds \
			 -timezone $timezone -locale $locale]
    }

    # Do relative weekday

    if { [llength $parseWeekday] > 0 } {
	lassign $parseWeekday dayOrdinal dayOfWeek
	set date2 [GetDateFields $seconds $TZData($timezone) 2361222]
	dict set date2 era CE
	set jdwkday [WeekdayOnOrBefore $dayOfWeek [expr {
	    [dict get $date2 julianDay] + 6
	}]]
	incr jdwkday [expr { 7 * $dayOrdinal }]
	if { $dayOrdinal > 0 } {
	    incr jdwkday -7
	}
	dict set date2 secondOfDay \
	    [expr { [dict get $date2 localSeconds] % 86400 }]
	dict set date2 julianDay $jdwkday
	dict set date2 localSeconds [expr {
	    -210866803200
	    + ( 86400 * wide([dict get $date2 julianDay]) )
	    + [dict get $date secondOfDay]
	}]
	dict set date2 tzName $timezone
	set date2 [ConvertLocalToUTC $date2[set date2 {}] $TZData($timezone) \
		       2361222]
	set seconds [dict get $date2 seconds]

    }

    # Do relative month

    if { [llength $parseOrdinalMonth] > 0 } {
	lassign $parseOrdinalMonth monthOrdinal monthNumber
	if { $monthOrdinal > 0 } {
	    set monthDiff [expr { $monthNumber - [dict get $date month] }]
	    if { $monthDiff <= 0 } {
		incr monthDiff 12
	    }
	    incr monthOrdinal -1
	} else {
	    set monthDiff [expr { [dict get $date month] - $monthNumber }]
	    if { $monthDiff >= 0 } {
		incr monthDiff -12
	    }
	    incr monthOrdinal
	}
	set seconds [add $seconds $monthOrdinal years $monthDiff months \
			 -timezone $timezone -locale $locale]
    }

    return $seconds
}


#----------------------------------------------------------------------
#
# ParseClockScanFormat --
#
#	Parses a format string given to [clock scan -format]
#
# Parameters:
#	formatString - The format being parsed
#	locale - The current locale
#
# Results:
#	Constructs and returns a procedure that accepts the string being
#	scanned, the base time, and the time zone.  The procedure will either
#	return the scanned time or else throw an error that should be rethrown
#	to the caller of [clock scan]
#
# Side effects:
#	The given procedure is defined in the ::tcl::clock namespace.  Scan
#	procedures are not deleted once installed.
#
# Why do we parse dates by defining a procedure to parse them?  The reason is
# that by doing so, we have one convenient place to cache all the information:
# the regular expressions that match the patterns (which will be compiled),
# the code that assembles the date information, everything lands in one place.
# In this way, when a given format is reused at run time, all the information
# of how to apply it is available in a single place.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ParseClockScanFormat {formatString locale} {
    # Check whether the format has been parsed previously, and return the
    # existing recognizer if it has.

    set procName scanproc'$formatString'$locale
    set procName [namespace current]::[string map {: {\:} \\ {\\}} $procName]
    if { [namespace which $procName] != {} } {
	return $procName
    }

    variable DateParseActions
    variable TimeParseActions

    # Localize the %x, %X, etc. groups

    set formatString [LocalizeFormat $locale $formatString]

    # Condense whitespace

    regsub -all {[[:space:]]+} $formatString { } formatString

    # Walk through the groups of the format string.  In this loop, we
    # accumulate:
    #	- a regular expression that matches the string,
    #   - the count of capturing brackets in the regexp
    #   - a set of code that post-processes the fields captured by the regexp,
    #   - a dictionary whose keys are the names of fields that are present
    #     in the format string.

    set re {^[[:space:]]*}
    set captureCount 0
    set postcode {}
    set fieldSet [dict create]
    set fieldCount 0
    set postSep {}
    set state {}

    foreach c [split $formatString {}] {
	switch -exact -- $state {
	    {} {
		if { $c eq "%" } {
		    set state %
		} elseif { $c eq " " } {
		    append re {[[:space:]]+}
		} else {
		    if { ! [string is alnum $c] } {
			append re "\\"
		    }
		    append re $c
		}
	    }
	    % {
		set state {}
		switch -exact -- $c {
		    % {
			append re %
		    }
		    { } {
			append re "\[\[:space:\]\]*"
		    }
		    a - A { 		# Day of week, in words
			set l {}
			foreach \
			    i {7 1 2 3 4 5 6} \
			    abr [mc DAYS_OF_WEEK_ABBREV] \
			    full [mc DAYS_OF_WEEK_FULL] {
				dict set l [string tolower $abr] $i
				dict set l [string tolower $full] $i
				incr i
			    }
			lassign [UniquePrefixRegexp $l] regex lookup
			append re ( $regex )
			dict set fieldSet dayOfWeek [incr fieldCount]
			append postcode "dict set date dayOfWeek \[" \
			    "dict get " [list $lookup] " " \
			    \[ {string tolower $field} [incr captureCount] \] \
			    "\]\n"
		    }
		    b - B - h {		# Name of month
			set i 0
			set l {}
			foreach \
			    abr [mc MONTHS_ABBREV] \
			    full [mc MONTHS_FULL] {
				incr i
				dict set l [string tolower $abr] $i
				dict set l [string tolower $full] $i
			    }
			lassign [UniquePrefixRegexp $l] regex lookup
			append re ( $regex )
			dict set fieldSet month [incr fieldCount]
			append postcode "dict set date month \[" \
			    "dict get " [list $lookup] \
			    " " \[ {string tolower $field} \
			    [incr captureCount] \] \
			    "\]\n"
		    }
		    C {			# Gregorian century
			append re \\s*(\\d\\d?)
			dict set fieldSet century [incr fieldCount]
			append postcode "dict set date century \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    d - e {		# Day of month
			append re \\s*(\\d\\d?)
			dict set fieldSet dayOfMonth [incr fieldCount]
			append postcode "dict set date dayOfMonth \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    E {			# Prefix for locale-specific codes
			set state %E
		    }
		    g {			# ISO8601 2-digit year
			append re \\s*(\\d\\d)
			dict set fieldSet iso8601YearOfCentury \
			    [incr fieldCount]
			append postcode \
			    "dict set date iso8601YearOfCentury \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    G {			# ISO8601 4-digit year
			append re \\s*(\\d\\d)(\\d\\d)
			dict set fieldSet iso8601Century [incr fieldCount]
			dict set fieldSet iso8601YearOfCentury \
			    [incr fieldCount]
			append postcode \
			    "dict set date iso8601Century \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n" \
			    "dict set date iso8601YearOfCentury \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    H - k {		# Hour of day
			append re \\s*(\\d\\d?)
			dict set fieldSet hour [incr fieldCount]
			append postcode "dict set date hour \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    I - l {		# Hour, AM/PM
			append re \\s*(\\d\\d?)
			dict set fieldSet hourAMPM [incr fieldCount]
			append postcode "dict set date hourAMPM \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    j {			# Day of year
			append re \\s*(\\d\\d?\\d?)
			dict set fieldSet dayOfYear [incr fieldCount]
			append postcode "dict set date dayOfYear \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    J {			# Julian Day Number
			append re \\s*(\\d+)
			dict set fieldSet julianDay [incr fieldCount]
			append postcode "dict set date julianDay \[" \
			    "::scan \$field" [incr captureCount] " %ld" \
			    "\]\n"
		    }
		    m - N {		# Month number
			append re \\s*(\\d\\d?)
			dict set fieldSet month [incr fieldCount]
			append postcode "dict set date month \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    M {			# Minute
			append re \\s*(\\d\\d?)
			dict set fieldSet minute [incr fieldCount]
			append postcode "dict set date minute \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    n {			# Literal newline
			append re \\n
		    }
		    O {			# Prefix for locale numerics
			set state %O
		    }
		    p - P { 		# AM/PM indicator
			set l [list [string tolower [mc AM]] 0 \
				   [string tolower [mc PM]] 1]
			lassign [UniquePrefixRegexp $l] regex lookup
			append re ( $regex )
			dict set fieldSet amPmIndicator [incr fieldCount]
			append postcode "dict set date amPmIndicator \[" \
			    "dict get " [list $lookup] " \[string tolower " \
			    "\$field" \
			    [incr captureCount] \
			    "\]\]\n"
		    }
		    Q {			# Hi, Jeff!
			append re {Stardate\s+([-+]?\d+)(\d\d\d)[.](\d)}
			incr captureCount
			dict set fieldSet seconds [incr fieldCount]
			append postcode {dict set date seconds } \[ \
			    {ParseStarDate $field} [incr captureCount] \
			    { $field} [incr captureCount] \
			    { $field} [incr captureCount] \
			    \] \n
		    }
		    s {			# Seconds from Posix Epoch
			# This next case is insanely difficult, because it's
			# problematic to determine whether the field is
			# actually within the range of a wide integer.
			append re {\s*([-+]?\d+)}
			dict set fieldSet seconds [incr fieldCount]
			append postcode {dict set date seconds } \[ \
			    {ScanWide $field} [incr captureCount] \] \n
		    }
		    S {			# Second
			append re \\s*(\\d\\d?)
			dict set fieldSet second [incr fieldCount]
			append postcode "dict set date second \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    t {			# Literal tab character
			append re \\t
		    }
		    u - w {		# Day number within week, 0 or 7 == Sun
					# 1=Mon, 6=Sat
			append re \\s*(\\d)
			dict set fieldSet dayOfWeek [incr fieldCount]
			append postcode {::scan $field} [incr captureCount] \
			    { %d dow} \n \
			    {
				if { $dow == 0 } {
				    set dow 7
				} elseif { $dow > 7 } {
				    return -code error \
					-errorcode [list CLOCK badDayOfWeek] \
					"day of week is greater than 7"
				}
				dict set date dayOfWeek $dow
			    }
		    }
		    U {			# Week of year. The first Sunday of
					# the year is the first day of week
					# 01. No scan rule uses this group.
			append re \\s*\\d\\d?
		    }
		    V {			# Week of ISO8601 year

			append re \\s*(\\d\\d?)
			dict set fieldSet iso8601Week [incr fieldCount]
			append postcode "dict set date iso8601Week \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    W {			# Week of the year (00-53). The first
					# Monday of the year is the first day
					# of week 01. No scan rule uses this
					# group.
			append re \\s*\\d\\d?
		    }
		    y {			# Two-digit Gregorian year
			append re \\s*(\\d\\d?)
			dict set fieldSet yearOfCentury [incr fieldCount]
			append postcode "dict set date yearOfCentury \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    Y {			# 4-digit Gregorian year
			append re \\s*(\\d\\d)(\\d\\d)
			dict set fieldSet century [incr fieldCount]
			dict set fieldSet yearOfCentury [incr fieldCount]
			append postcode \
			    "dict set date century \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n" \
			    "dict set date yearOfCentury \[" \
			    "::scan \$field" [incr captureCount] " %d" \
			    "\]\n"
		    }
		    z - Z {			# Time zone name
			append re {(?:([-+]\d\d(?::?\d\d(?::?\d\d)?)?)|([[:alnum:]]{1,4}))}
			dict set fieldSet tzName [incr fieldCount]
			append postcode \
			    {if } \{ { $field} [incr captureCount] \
			    { ne "" } \} { } \{ \n \
			    {dict set date tzName $field} \
			    $captureCount \n \
			    \} { else } \{ \n \
			    {dict set date tzName } \[ \
			    {ConvertLegacyTimeZone $field} \
			    [incr captureCount] \] \n \
			    \} \n \
		    }
		    % {			# Literal percent character
			append re %
		    }
		    default {
			append re %
			if { ! [string is alnum $c] } {
			    append re \\
			    }
			append re $c
		    }
		}
	    }
	    %E {
		switch -exact -- $c {
		    C {			# Locale-dependent era
			set d {}
			foreach triple [mc LOCALE_ERAS] {
			    lassign $triple t symbol year
			    dict set d [string tolower $symbol] $year
			}
			lassign [UniquePrefixRegexp $d] regex lookup
			append re (?: $regex )
		    }
		    E {
			set l {}
			dict set l [string tolower [mc BCE]] BCE
			dict set l [string tolower [mc CE]] CE
			dict set l b.c.e. BCE
			dict set l c.e. CE
			dict set l b.c. BCE
			dict set l a.d. CE
			lassign [UniquePrefixRegexp $l] regex lookup
			append re ( $regex )
			dict set fieldSet era [incr fieldCount]
			append postcode "dict set date era \["\
			    "dict get " [list $lookup] \
			    { } \[ {string tolower $field} \
			    [incr captureCount] \] \
			    "\]\n"
		    }
		    y {			# Locale-dependent year of the era
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			incr captureCount
		    }
		    default {
			append re %E
			if { ! [string is alnum $c] } {
			    append re \\
			    }
			append re $c
		    }
		}
		set state {}
	    }
	    %O {
		switch -exact -- $c {
		    d - e {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet dayOfMonth [incr fieldCount]
			append postcode "dict set date dayOfMonth \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    H - k {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet hour [incr fieldCount]
			append postcode "dict set date hour \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    I - l {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet hourAMPM [incr fieldCount]
			append postcode "dict set date hourAMPM \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    m {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet month [incr fieldCount]
			append postcode "dict set date month \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    M {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet minute [incr fieldCount]
			append postcode "dict set date minute \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    S {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet second [incr fieldCount]
			append postcode "dict set date second \[" \
			    "dict get " [list $lookup] " \$field" \
			    [incr captureCount] \
			    "\]\n"
		    }
		    u - w {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet dayOfWeek [incr fieldCount]
			append postcode "set dow \[dict get " [list $lookup] \
			    { $field} [incr captureCount] \] \n \
			    {
				if { $dow == 0 } {
				    set dow 7
				} elseif { $dow > 7 } {
				    return -code error \
					-errorcode [list CLOCK badDayOfWeek] \
					"day of week is greater than 7"
				}
				dict set date dayOfWeek $dow
			    }
		    }
		    y {
			lassign [LocaleNumeralMatcher $locale] regex lookup
			append re $regex
			dict set fieldSet yearOfCentury [incr fieldCount]
			append postcode {dict set date yearOfCentury } \[ \
			    {dict get } [list $lookup] { $field} \
			    [incr captureCount] \] \n
		    }
		    default {
			append re %O
			if { ! [string is alnum $c] } {
			    append re \\
			    }
			append re $c
		    }
		}
		set state {}
	    }
	}
    }

    # Clean up any unfinished format groups

    append re $state \\s*\$

    # Build the procedure

    set procBody {}
    append procBody "variable ::tcl::clock::TZData" \n
    append procBody "if \{ !\[ regexp -nocase [list $re] \$string ->"
    for { set i 1 } { $i <= $captureCount } { incr i } {
	append procBody " " field $i
    }
    append procBody "\] \} \{" \n
    append procBody {
	return -code error -errorcode [list CLOCK badInputString] \
	    {input string does not match supplied format}
    }
    append procBody \}\n
    append procBody "set date \[dict create\]" \n
    append procBody {dict set date tzName $timeZone} \n
    append procBody $postcode
    append procBody [list set changeover [mc GREGORIAN_CHANGE_DATE]] \n

    # Set up the time zone before doing anything with a default base date
    # that might need a timezone to interpret it.

    if { ![dict exists $fieldSet seconds]
	    && ![dict exists $fieldSet starDate] } {
	if { [dict exists $fieldSet tzName] } {
	    append procBody {
		set timeZone [dict get $date tzName]
	    }
	}
	append procBody {
	    ::tcl::clock::SetupTimeZone $timeZone
	}
    }

    # Add code that gets Julian Day Number from the fields.

    append procBody [MakeParseCodeFromFields $fieldSet $DateParseActions]

    # Get time of day

    append procBody [MakeParseCodeFromFields $fieldSet $TimeParseActions]

    # Assemble seconds from the Julian day and second of the day.
    # Convert to local time unless epoch seconds or stardate are
    # being processed - they're always absolute

    if { ![dict exists $fieldSet seconds]
         && ![dict exists $fieldSet starDate] } {
	append procBody {
	    if { [dict get $date julianDay] > 5373484 } {
		return -code error -errorcode [list CLOCK dateTooLarge] \
		    "requested date too large to represent"
	    }
	    dict set date localSeconds [expr {
		-210866803200
		+ ( 86400 * wide([dict get $date julianDay]) )
		+ [dict get $date secondOfDay]
	    }]
	}

	# Finally, convert the date to local time

	append procBody {
	    set date [::tcl::clock::ConvertLocalToUTC $date[set date {}] \
			  $TZData($timeZone) $changeover]
	}
    }

    # Return result

    append procBody {return [dict get $date seconds]} \n

    proc $procName { string baseTime timeZone } $procBody

    # puts [list proc $procName [list string baseTime timeZone] $procBody]

    return $procName
}

#----------------------------------------------------------------------
#
# LocaleNumeralMatcher --
#
#	Composes a regexp that captures the numerals in the given locale, and
#	a dictionary to map them to conventional numerals.
#
# Parameters:
#	locale - Name of the current locale
#
# Results:
#	Returns a two-element list comprising the regexp and the dictionary.
#
# Side effects:
#	Caches the result.
#
#----------------------------------------------------------------------

proc ::tcl::clock::LocaleNumeralMatcher {l} {
    variable LocaleNumeralCache

    if { ![dict exists $LocaleNumeralCache $l] } {
	set d {}
	set i 0
	set sep \(
	foreach n [mc LOCALE_NUMERALS] {
	    dict set d $n $i
	    regsub -all {[^[:alnum:]]} $n \\\\& subex
	    append re $sep $subex
	    set sep |
	    incr i
	}
	append re \)
	dict set LocaleNumeralCache $l [list $re $d]
    }
    return [dict get $LocaleNumeralCache $l]
}



#----------------------------------------------------------------------
#
# UniquePrefixRegexp --
#
#	Composes a regexp that performs unique-prefix matching.  The RE
#	matches one of a supplied set of strings, or any unique prefix
#	thereof.
#
# Parameters:
#	data - List of alternating match-strings and values.
#	       Match-strings with distinct values are considered
#	       distinct.
#
# Results:
#	Returns a two-element list.  The first is a regexp that matches any
#	unique prefix of any of the strings.  The second is a dictionary whose
#	keys are match values from the regexp and whose values are the
#	corresponding values from 'data'.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::UniquePrefixRegexp { data } {
    # The 'successors' dictionary will contain, for each string that is a
    # prefix of any key, all characters that may follow that prefix.  The
    # 'prefixMapping' dictionary will have keys that are prefixes of keys and
    # values that correspond to the keys.

    set prefixMapping [dict create]
    set successors [dict create {} {}]

    # Walk the key-value pairs

    foreach { key value } $data {
	# Construct all prefixes of the key;

	set prefix {}
	foreach char [split $key {}] {
	    set oldPrefix $prefix
	    dict set successors $oldPrefix $char {}
	    append prefix $char

	    # Put the prefixes in the 'prefixMapping' and 'successors'
	    # dictionaries

	    dict lappend prefixMapping $prefix $value
	    if { ![dict exists $successors $prefix] } {
		dict set successors $prefix {}
	    }
	}
    }

    # Identify those prefixes that designate unique values, and those that are
    # the full keys

    set uniquePrefixMapping {}
    dict for { key valueList } $prefixMapping {
	if { [llength $valueList] == 1 } {
	    dict set uniquePrefixMapping $key [lindex $valueList 0]
	}
    }
    foreach { key value } $data {
	dict set uniquePrefixMapping $key $value
    }

    # Construct the re.

    return [list \
		[MakeUniquePrefixRegexp $successors $uniquePrefixMapping {}] \
		$uniquePrefixMapping]
}

#----------------------------------------------------------------------
#
# MakeUniquePrefixRegexp --
#
#	Service procedure for 'UniquePrefixRegexp' that constructs a regular
#	expresison that matches the unique prefixes.
#
# Parameters:
#	successors - Dictionary whose keys are all prefixes
#		     of keys passed to 'UniquePrefixRegexp' and whose
#		     values are dictionaries whose keys are the characters
#		     that may follow those prefixes.
#	uniquePrefixMapping - Dictionary whose keys are the unique
#			      prefixes and whose values are not examined.
#	prefixString - Current prefix being processed.
#
# Results:
#	Returns a constructed regular expression that matches the set of
#	unique prefixes beginning with the 'prefixString'.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::MakeUniquePrefixRegexp { successors
					  uniquePrefixMapping
					  prefixString } {

    # Get the characters that may follow the current prefix string

    set schars [lsort -ascii [dict keys [dict get $successors $prefixString]]]
    if { [llength $schars] == 0 } {
	return {}
    }

    # If there is more than one successor character, or if the current prefix
    # is a unique prefix, surround the generated re with non-capturing
    # parentheses.

    set re {}
    if {
	[dict exists $uniquePrefixMapping $prefixString]
	|| [llength $schars] > 1
    } then {
	append re "(?:"
    }

    # Generate a regexp that matches the successors.

    set sep ""
    foreach { c } $schars {
	set nextPrefix $prefixString$c
	regsub -all {[^[:alnum:]]} $c \\\\& rechar
	append re $sep $rechar \
	    [MakeUniquePrefixRegexp \
		 $successors $uniquePrefixMapping $nextPrefix]
	set sep |
    }

    # If the current prefix is a unique prefix, make all following text
    # optional. Otherwise, if there is more than one successor character,
    # close the non-capturing parentheses.

    if { [dict exists $uniquePrefixMapping $prefixString] } {
	append re ")?"
    } elseif { [llength $schars] > 1 } {
	append re ")"
    }

    return $re
}

#----------------------------------------------------------------------
#
# MakeParseCodeFromFields --
#
#	Composes Tcl code to extract the Julian Day Number from a dictionary
#	containing date fields.
#
# Parameters:
#	dateFields -- Dictionary whose keys are fields of the date,
#	              and whose values are the rightmost positions
#		      at which those fields appear.
#	parseActions -- List of triples: field set, priority, and
#			code to emit.  Smaller priorities are better, and
#			the list must be in ascending order by priority
#
# Results:
#	Returns a burst of code that extracts the day number from the given
#	date.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::MakeParseCodeFromFields { dateFields parseActions } {

    set currPrio 999
    set currFieldPos [list]
    set currCodeBurst {
	error "in ::tcl::clock::MakeParseCodeFromFields: can't happen"
    }

    foreach { fieldSet prio parseAction } $parseActions {
	# If we've found an answer that's better than any that follow, quit
	# now.

	if { $prio > $currPrio } {
	    break
	}

	# Accumulate the field positions that are used in the current field
	# grouping.

	set fieldPos [list]
	set ok true
	foreach field $fieldSet {
	    if { ! [dict exists $dateFields $field] } {
		set ok 0
		break
	    }
	    lappend fieldPos [dict get $dateFields $field]
	}

	# Quit if we don't have a complete set of fields
	if { !$ok } {
	    continue
	}

	# Determine whether the current answer is better than the last.

	set fPos [lsort -integer -decreasing $fieldPos]

	if { $prio ==  $currPrio } {
	    foreach currPos $currFieldPos newPos $fPos {
		if {
		    ![string is integer $newPos]
		    || ![string is integer $currPos]
		    || $newPos > $currPos
		} then {
		    break
		}
		if { $newPos < $currPos } {
		    set ok 0
		    break
		}
	    }
	}
	if { !$ok } {
	    continue
	}

	# Remember the best possibility for extracting date information

	set currPrio $prio
	set currFieldPos $fPos
	set currCodeBurst $parseAction
    }

    return $currCodeBurst
}

#----------------------------------------------------------------------
#
# EnterLocale --
#
#	Switch [mclocale] to a given locale if necessary
#
# Parameters:
#	locale -- Desired locale
#
# Results:
#	Returns the locale that was previously current.
#
# Side effects:
#	Does [mclocale].  If necessary, loades the designated locale's files.
#
#----------------------------------------------------------------------

proc ::tcl::clock::EnterLocale { locale } {
    if { $locale eq {system} } {
	if { $::tcl_platform(platform) ne {windows} } {
	    # On a non-windows platform, the 'system' locale is the same as
	    # the 'current' locale

	    set locale current
	} else {
	    # On a windows platform, the 'system' locale is adapted from the
	    # 'current' locale by applying the date and time formats from the
	    # Control Panel.  First, load the 'current' locale if it's not yet
	    # loaded

	    mcpackagelocale set [mclocale]

	    # Make a new locale string for the system locale, and get the
	    # Control Panel information

	    set locale [mclocale]_windows
	    if { ! [mcpackagelocale present $locale] } {
		LoadWindowsDateTimeFormats $locale
	    }
	}
    }
    if { $locale eq {current}} {
	set locale [mclocale]
    }
    # Eventually load the locale
    mcpackagelocale set $locale
}

#----------------------------------------------------------------------
#
# LoadWindowsDateTimeFormats --
#
#	Load the date/time formats from the Control Panel in Windows and
#	convert them so that they're usable by Tcl.
#
# Parameters:
#	locale - Name of the locale in whose message catalog
#	         the converted formats are to be stored.
#
# Results:
#	None.
#
# Side effects:
#	Updates the given message catalog with the locale strings.
#
# Presumes that on entry, [mclocale] is set to the current locale, so that
# default strings can be obtained if the Registry query fails.
#
#----------------------------------------------------------------------

proc ::tcl::clock::LoadWindowsDateTimeFormats { locale } {
    # Bail out if we can't find the Registry

    variable NoRegistry
    if { [info exists NoRegistry] } return

    if { ![catch {
	registry get "HKEY_CURRENT_USER\\Control Panel\\International" \
	    sShortDate
    } string] } {
	set quote {}
	set datefmt {}
	foreach { unquoted quoted } [split $string '] {
	    append datefmt $quote [string map {
		dddd %A
		ddd  %a
		dd   %d
		d    %e
		MMMM %B
		MMM  %b
		MM   %m
		M    %N
		yyyy %Y
		yy   %y
                y    %y
                gg   {}
	    } $unquoted]
	    if { $quoted eq {} } {
		set quote '
	    } else {
		set quote $quoted
	    }
	}
	::msgcat::mcset $locale DATE_FORMAT $datefmt
    }

    if { ![catch {
	registry get "HKEY_CURRENT_USER\\Control Panel\\International" \
	    sLongDate
    } string] } {
	set quote {}
	set ldatefmt {}
	foreach { unquoted quoted } [split $string '] {
	    append ldatefmt $quote [string map {
		dddd %A
		ddd  %a
		dd   %d
		d    %e
		MMMM %B
		MMM  %b
		MM   %m
		M    %N
		yyyy %Y
		yy   %y
                y    %y
                gg   {}
	    } $unquoted]
	    if { $quoted eq {} } {
		set quote '
	    } else {
		set quote $quoted
	    }
	}
	::msgcat::mcset $locale LOCALE_DATE_FORMAT $ldatefmt
    }

    if { ![catch {
	registry get "HKEY_CURRENT_USER\\Control Panel\\International" \
	    sTimeFormat
    } string] } {
	set quote {}
	set timefmt {}
	foreach { unquoted quoted } [split $string '] {
	    append timefmt $quote [string map {
		HH    %H
		H     %k
		hh    %I
		h     %l
		mm    %M
		m     %M
		ss    %S
		s     %S
		tt    %p
		t     %p
	    } $unquoted]
	    if { $quoted eq {} } {
		set quote '
	    } else {
		set quote $quoted
	    }
	}
	::msgcat::mcset $locale TIME_FORMAT $timefmt
    }

    catch {
	::msgcat::mcset $locale DATE_TIME_FORMAT "$datefmt $timefmt"
    }
    catch {
	::msgcat::mcset $locale LOCALE_DATE_TIME_FORMAT "$ldatefmt $timefmt"
    }

    return

}

#----------------------------------------------------------------------
#
# LocalizeFormat --
#
#	Map away locale-dependent format groups in a clock format.
#
# Parameters:
#	locale -- Current [mclocale] locale, supplied to avoid
#		  an extra call
#	format -- Format supplied to [clock scan] or [clock format]
#
# Results:
#	Returns the string with locale-dependent composite format groups
#	substituted out.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::LocalizeFormat { locale format } {

    # message catalog key to cache this format
    set key FORMAT_$format

    if { [::msgcat::mcexists -exactlocale -exactnamespace $key] } {
	return [mc $key]
    }
    # Handle locale-dependent format groups by mapping them out of the format
    # string.  Note that the order of the [string map] operations is
    # significant because later formats can refer to later ones; for example
    # %c can refer to %X, which in turn can refer to %T.

    set list {
	%% %%
	%D %m/%d/%Y
	%+ {%a %b %e %H:%M:%S %Z %Y}
    }
    lappend list %EY [string map $list [mc LOCALE_YEAR_FORMAT]]
    lappend list %T  [string map $list [mc TIME_FORMAT_24_SECS]]
    lappend list %R  [string map $list [mc TIME_FORMAT_24]]
    lappend list %r  [string map $list [mc TIME_FORMAT_12]]
    lappend list %X  [string map $list [mc TIME_FORMAT]]
    lappend list %EX [string map $list [mc LOCALE_TIME_FORMAT]]
    lappend list %x  [string map $list [mc DATE_FORMAT]]
    lappend list %Ex [string map $list [mc LOCALE_DATE_FORMAT]]
    lappend list %c  [string map $list [mc DATE_TIME_FORMAT]]
    lappend list %Ec [string map $list [mc LOCALE_DATE_TIME_FORMAT]]
    set format [string map $list $format]

    ::msgcat::mcset $locale $key $format
    return $format
}

#----------------------------------------------------------------------
#
# FormatNumericTimeZone --
#
#	Formats a time zone as +hhmmss
#
# Parameters:
#	z - Time zone in seconds east of Greenwich
#
# Results:
#	Returns the time zone formatted in a numeric form
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::FormatNumericTimeZone { z } {
    if { $z < 0 } {
	set z [expr { - $z }]
	set retval -
    } else {
	set retval +
    }
    append retval [::format %02d [expr { $z / 3600 }]]
    set z [expr { $z % 3600 }]
    append retval [::format %02d [expr { $z / 60 }]]
    set z [expr { $z % 60 }]
    if { $z != 0 } {
	append retval [::format %02d $z]
    }
    return $retval
}

#----------------------------------------------------------------------
#
# FormatStarDate --
#
#	Formats a date as a StarDate.
#
# Parameters:
#	date - Dictionary containing 'year', 'dayOfYear', and
#	       'localSeconds' fields.
#
# Results:
#	Returns the given date formatted as a StarDate.
#
# Side effects:
#	None.
#
# Jeff Hobbs put this in to support an atrocious pun about Tcl being
# "Enterprise ready."  Now we're stuck with it.
#
#----------------------------------------------------------------------

proc ::tcl::clock::FormatStarDate { date } {
    variable Roddenberry

    # Get day of year, zero based

    set doy [expr { [dict get $date dayOfYear] - 1 }]

    # Determine whether the year is a leap year

    set lp [IsGregorianLeapYear $date]

    # Convert day of year to a fractional year

    if { $lp } {
	set fractYear [expr { 1000 * $doy / 366 }]
    } else {
	set fractYear [expr { 1000 * $doy / 365 }]
    }

    # Put together the StarDate

    return [::format "Stardate %02d%03d.%1d" \
		[expr { [dict get $date year] - $Roddenberry }] \
		$fractYear \
		[expr { [dict get $date localSeconds] % 86400
			/ ( 86400 / 10 ) }]]
}

#----------------------------------------------------------------------
#
# ParseStarDate --
#
#	Parses a StarDate
#
# Parameters:
#	year - Year from the Roddenberry epoch
#	fractYear - Fraction of a year specifiying the day of year.
#	fractDay - Fraction of a day
#
# Results:
#	Returns a count of seconds from the Posix epoch.
#
# Side effects:
#	None.
#
# Jeff Hobbs put this in to support an atrocious pun about Tcl being
# "Enterprise ready."  Now we're stuck with it.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ParseStarDate { year fractYear fractDay } {
    variable Roddenberry

    # Build a tentative date from year and fraction.

    set date [dict create \
		  gregorian 1 \
		  era CE \
		  year [expr { $year + $Roddenberry }] \
		  dayOfYear [expr { $fractYear * 365 / 1000 + 1 }]]
    set date [GetJulianDayFromGregorianEraYearDay $date[set date {}]]

    # Determine whether the given year is a leap year

    set lp [IsGregorianLeapYear $date]

    # Reconvert the fractional year according to whether the given year is a
    # leap year

    if { $lp } {
	dict set date dayOfYear \
	    [expr { $fractYear * 366 / 1000 + 1 }]
    } else {
	dict set date dayOfYear \
	    [expr { $fractYear * 365 / 1000 + 1 }]
    }
    dict unset date julianDay
    dict unset date gregorian
    set date [GetJulianDayFromGregorianEraYearDay $date[set date {}]]

    return [expr {
	86400 * [dict get $date julianDay]
	- 210866803200
	+ ( 86400 / 10 ) * $fractDay
    }]
}

#----------------------------------------------------------------------
#
# ScanWide --
#
#	Scans a wide integer from an input
#
# Parameters:
#	str - String containing a decimal wide integer
#
# Results:
#	Returns the string as a pure wide integer.  Throws an error if the
#	string is misformatted or out of range.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ScanWide { str } {
    set count [::scan $str {%ld %c} result junk]
    if { $count != 1 } {
	return -code error -errorcode [list CLOCK notAnInteger $str] \
	    "\"$str\" is not an integer"
    }
    if { [incr result 0] != $str } {
	return -code error -errorcode [list CLOCK integervalueTooLarge] \
	    "integer value too large to represent"
    }
    return $result
}

#----------------------------------------------------------------------
#
# InterpretTwoDigitYear --
#
#	Given a date that contains only the year of the century, determines
#	the target value of a two-digit year.
#
# Parameters:
#	date - Dictionary containing fields of the date.
#	baseTime - Base time relative to which the date is expressed.
#	twoDigitField - Name of the field that stores the two-digit year.
#			Default is 'yearOfCentury'
#	fourDigitField - Name of the field that will receive the four-digit
#	                 year.  Default is 'year'
#
# Results:
#	Returns the dictionary augmented with the four-digit year, stored in
#	the given key.
#
# Side effects:
#	None.
#
# The current rule for interpreting a two-digit year is that the year shall be
# between 1937 and 2037, thus staying within the range of a 32-bit signed
# value for time.  This rule may change to a sliding window in future
# versions, so the 'baseTime' parameter (which is currently ignored) is
# provided in the procedure signature.
#
#----------------------------------------------------------------------

proc ::tcl::clock::InterpretTwoDigitYear { date baseTime
					   { twoDigitField yearOfCentury }
					   { fourDigitField year } } {
    set yr [dict get $date $twoDigitField]
    if { $yr <= 37 } {
	dict set date $fourDigitField [expr { $yr + 2000 }]
    } else {
	dict set date $fourDigitField [expr { $yr + 1900 }]
    }
    return $date
}

#----------------------------------------------------------------------
#
# AssignBaseYear --
#
#	Places the number of the current year into a dictionary.
#
# Parameters:
#	date - Dictionary value to update
#	baseTime - Base time from which to extract the year, expressed
#		   in seconds from the Posix epoch
#	timezone - the time zone in which the date is being scanned
#	changeover - the Julian Day on which the Gregorian calendar
#		     was adopted in the target locale.
#
# Results:
#	Returns the dictionary with the current year assigned.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AssignBaseYear { date baseTime timezone changeover } {
    variable TZData

    # Find the Julian Day Number corresponding to the base time, and
    # find the Gregorian year corresponding to that Julian Day.

    set date2 [GetDateFields $baseTime $TZData($timezone) $changeover]

    # Store the converted year

    dict set date era [dict get $date2 era]
    dict set date year [dict get $date2 year]

    return $date
}

#----------------------------------------------------------------------
#
# AssignBaseIso8601Year --
#
#	Determines the base year in the ISO8601 fiscal calendar.
#
# Parameters:
#	date - Dictionary containing the fields of the date that
#	       is to be augmented with the base year.
#	baseTime - Base time expressed in seconds from the Posix epoch.
#	timeZone - Target time zone
#	changeover - Julian Day of adoption of the Gregorian calendar in
#		     the target locale.
#
# Results:
#	Returns the given date with "iso8601Year" set to the
#	base year.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AssignBaseIso8601Year {date baseTime timeZone changeover} {
    variable TZData

    # Find the Julian Day Number corresponding to the base time

    set date2 [GetDateFields $baseTime $TZData($timeZone) $changeover]

    # Calculate the ISO8601 date and transfer the year

    dict set date era CE
    dict set date iso8601Year [dict get $date2 iso8601Year]
    return $date
}

#----------------------------------------------------------------------
#
# AssignBaseMonth --
#
#	Places the number of the current year and month into a
#	dictionary.
#
# Parameters:
#	date - Dictionary value to update
#	baseTime - Time from which the year and month are to be
#	           obtained, expressed in seconds from the Posix epoch.
#	timezone - Name of the desired time zone
#	changeover - Julian Day on which the Gregorian calendar was adopted.
#
# Results:
#	Returns the dictionary with the base year and month assigned.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AssignBaseMonth {date baseTime timezone changeover} {
    variable TZData

    # Find the year and month corresponding to the base time

    set date2 [GetDateFields $baseTime $TZData($timezone) $changeover]
    dict set date era [dict get $date2 era]
    dict set date year [dict get $date2 year]
    dict set date month [dict get $date2 month]
    return $date
}

#----------------------------------------------------------------------
#
# AssignBaseWeek --
#
#	Determines the base year and week in the ISO8601 fiscal calendar.
#
# Parameters:
#	date - Dictionary containing the fields of the date that
#	       is to be augmented with the base year and week.
#	baseTime - Base time expressed in seconds from the Posix epoch.
#	changeover - Julian Day on which the Gregorian calendar was adopted
#		     in the target locale.
#
# Results:
#	Returns the given date with "iso8601Year" set to the
#	base year and "iso8601Week" to the week number.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AssignBaseWeek {date baseTime timeZone changeover} {
    variable TZData

    # Find the Julian Day Number corresponding to the base time

    set date2 [GetDateFields $baseTime $TZData($timeZone) $changeover]

    # Calculate the ISO8601 date and transfer the year

    dict set date era CE
    dict set date iso8601Year [dict get $date2 iso8601Year]
    dict set date iso8601Week [dict get $date2 iso8601Week]
    return $date
}

#----------------------------------------------------------------------
#
# AssignBaseJulianDay --
#
#	Determines the base day for a time-of-day conversion.
#
# Parameters:
#	date - Dictionary that is to get the base day
#	baseTime - Base time expressed in seconds from the Posix epoch
#	changeover - Julian day on which the Gregorian calendar was
#		     adpoted in the target locale.
#
# Results:
#	Returns the given dictionary augmented with a 'julianDay' field
#	that contains the base day.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AssignBaseJulianDay { date baseTime timeZone changeover } {
    variable TZData

    # Find the Julian Day Number corresponding to the base time

    set date2 [GetDateFields $baseTime $TZData($timeZone) $changeover]
    dict set date julianDay [dict get $date2 julianDay]

    return $date
}

#----------------------------------------------------------------------
#
# InterpretHMSP --
#
#	Interprets a time in the form "hh:mm:ss am".
#
# Parameters:
#	date -- Dictionary containing "hourAMPM", "minute", "second"
#	        and "amPmIndicator" fields.
#
# Results:
#	Returns the number of seconds from local midnight.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::InterpretHMSP { date } {
    set hr [dict get $date hourAMPM]
    if { $hr == 12 } {
	set hr 0
    }
    if { [dict get $date amPmIndicator] } {
	incr hr 12
    }
    dict set date hour $hr
    return [InterpretHMS $date[set date {}]]
}

#----------------------------------------------------------------------
#
# InterpretHMS --
#
#	Interprets a 24-hour time "hh:mm:ss"
#
# Parameters:
#	date -- Dictionary containing the "hour", "minute" and "second"
#	        fields.
#
# Results:
#	Returns the given dictionary augmented with a "secondOfDay"
#	field containing the number of seconds from local midnight.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::InterpretHMS { date } {
    return [expr {
	( [dict get $date hour] * 60
	  + [dict get $date minute] ) * 60
	+ [dict get $date second]
    }]
}

#----------------------------------------------------------------------
#
# GetSystemTimeZone --
#
#	Determines the system time zone, which is the default for the
#	'clock' command if no other zone is supplied.
#
# Parameters:
#	None.
#
# Results:
#	Returns the system time zone.
#
# Side effects:
#	Stores the sustem time zone in the 'CachedSystemTimeZone'
#	variable, since determining it may be an expensive process.
#
#----------------------------------------------------------------------

proc ::tcl::clock::GetSystemTimeZone {} {
    variable CachedSystemTimeZone
    variable TimeZoneBad

    if {[set result [getenv TCL_TZ]] ne {}} {
	set timezone $result
    } elseif {[set result [getenv TZ]] ne {}} {
	set timezone $result
    }
    if {![info exists timezone]} {
        # Cache the time zone only if it was detected by one of the
        # expensive methods.
        if { [info exists CachedSystemTimeZone] } {
            set timezone $CachedSystemTimeZone
        } elseif { $::tcl_platform(platform) eq {windows} } {
            set timezone [GuessWindowsTimeZone]
        } elseif { [file exists /etc/localtime]
                   && ![catch {ReadZoneinfoFile \
                                   Tcl/Localtime /etc/localtime}] } {
            set timezone :Tcl/Localtime
        } else {
            set timezone :localtime
        }
	set CachedSystemTimeZone $timezone
    }
    if { ![dict exists $TimeZoneBad $timezone] } {
	dict set TimeZoneBad $timezone [catch {SetupTimeZone $timezone}]
    }
    if { [dict get $TimeZoneBad $timezone] } {
	return :localtime
    } else {
	return $timezone
    }
}

#----------------------------------------------------------------------
#
# ConvertLegacyTimeZone --
#
#	Given an alphanumeric time zone identifier and the system time zone,
#	convert the alphanumeric identifier to an unambiguous time zone.
#
# Parameters:
#	tzname - Name of the time zone to convert
#
# Results:
#	Returns a time zone name corresponding to tzname, but in an
#	unambiguous form, generally +hhmm.
#
# This procedure is implemented primarily to allow the parsing of RFC822
# date/time strings.  Processing a time zone name on input is not recommended
# practice, because there is considerable room for ambiguity; for instance, is
# BST Brazilian Standard Time, or British Summer Time?
#
#----------------------------------------------------------------------

proc ::tcl::clock::ConvertLegacyTimeZone { tzname } {
    variable LegacyTimeZone

    set tzname [string tolower $tzname]
    if { ![dict exists $LegacyTimeZone $tzname] } {
	return -code error -errorcode [list CLOCK badTZName $tzname] \
	    "time zone \"$tzname\" not found"
    }
    return [dict get $LegacyTimeZone $tzname]
}

#----------------------------------------------------------------------
#
# SetupTimeZone --
#
#	Given the name or specification of a time zone, sets up its in-memory
#	data.
#
# Parameters:
#	tzname - Name of a time zone
#
# Results:
#	Unless the time zone is ':localtime', sets the TZData array to contain
#	the lookup table for local<->UTC conversion.  Returns an error if the
#	time zone cannot be parsed.
#
#----------------------------------------------------------------------

proc ::tcl::clock::SetupTimeZone { timezone } {
    variable TZData

    if {! [info exists TZData($timezone)] } {
	variable MINWIDE
	if { $timezone eq {:localtime} } {
	    # Nothing to do, we'll convert using the localtime function

	} elseif {
	    [regexp {^([-+])(\d\d)(?::?(\d\d)(?::?(\d\d))?)?} $timezone \
		    -> s hh mm ss]
	} then {
	    # Make a fixed offset

	    ::scan $hh %d hh
	    if { $mm eq {} } {
		set mm 0
	    } else {
		::scan $mm %d mm
	    }
	    if { $ss eq {} } {
		set ss 0
	    } else {
		::scan $ss %d ss
	    }
	    set offset [expr { ( $hh * 60 + $mm ) * 60 + $ss }]
	    if { $s eq {-} } {
		set offset [expr { - $offset }]
	    }
	    set TZData($timezone) [list [list $MINWIDE $offset -1 $timezone]]

	} elseif { [string index $timezone 0] eq {:} } {
	    # Convert using a time zone file

	    if {
		[catch {
		    LoadTimeZoneFile [string range $timezone 1 end]
		}] && [catch {
		    LoadZoneinfoFile [string range $timezone 1 end]
		}]
	    } then {
		return -code error \
		    -errorcode [list CLOCK badTimeZone $timezone] \
		    "time zone \"$timezone\" not found"
	    }
	} elseif { ![catch {ParsePosixTimeZone $timezone} tzfields] } {
	    # This looks like a POSIX time zone - try to process it

	    if { [catch {ProcessPosixTimeZone $tzfields} data opts] } {
		if { [lindex [dict get $opts -errorcode] 0] eq {CLOCK} } {
		    dict unset opts -errorinfo
		}
		return -options $opts $data
	    } else {
		set TZData($timezone) $data
	    }

	} else {
	    # We couldn't parse this as a POSIX time zone.  Try again with a
	    # time zone file - this time without a colon

	    if { [catch { LoadTimeZoneFile $timezone }]
		 && [catch { LoadZoneinfoFile $timezone } - opts] } {
		dict unset opts -errorinfo
		return -options $opts "time zone $timezone not found"
	    }
	    set TZData($timezone) $TZData(:$timezone)
	}
    }

    return
}

#----------------------------------------------------------------------
#
# GuessWindowsTimeZone --
#
#	Determines the system time zone on windows.
#
# Parameters:
#	None.
#
# Results:
#	Returns a time zone specifier that corresponds to the system time zone
#	information found in the Registry.
#
# Bugs:
#	Fixed dates for DST change are unimplemented at present, because no
#	time zone information supplied with Windows actually uses them!
#
# On a Windows system where neither $env(TCL_TZ) nor $env(TZ) is specified,
# GuessWindowsTimeZone looks in the Registry for the system time zone
# information.  It then attempts to find an entry in WinZoneInfo for a time
# zone that uses the same rules.  If it finds one, it returns it; otherwise,
# it constructs a Posix-style time zone string and returns that.
#
#----------------------------------------------------------------------

proc ::tcl::clock::GuessWindowsTimeZone {} {
    variable WinZoneInfo
    variable NoRegistry
    variable TimeZoneBad

    if { [info exists NoRegistry] } {
	return :localtime
    }

    # Dredge time zone information out of the registry

    if { [catch {
	set rpath HKEY_LOCAL_MACHINE\\System\\CurrentControlSet\\Control\\TimeZoneInformation
	set data [list \
		      [expr { -60
			      * [registry get $rpath Bias] }] \
		      [expr { -60
				  * [registry get $rpath StandardBias] }] \
		      [expr { -60 \
				  * [registry get $rpath DaylightBias] }]]
	set stdtzi [registry get $rpath StandardStart]
	foreach ind {0 2 14 4 6 8 10 12} {
	    binary scan $stdtzi @${ind}s val
	    lappend data $val
	}
	set daytzi [registry get $rpath DaylightStart]
	foreach ind {0 2 14 4 6 8 10 12} {
	    binary scan $daytzi @${ind}s val
	    lappend data $val
	}
    }] } {
	# Missing values in the Registry - bail out

	return :localtime
    }

    # Make up a Posix time zone specifier if we can't find one.  Check here
    # that the tzdata file exists, in case we're running in an environment
    # (e.g. starpack) where tzdata is incomplete.  (Bug 1237907)

    if { [dict exists $WinZoneInfo $data] } {
	set tzname [dict get $WinZoneInfo $data]
	if { ! [dict exists $TimeZoneBad $tzname] } {
	    dict set TimeZoneBad $tzname [catch {SetupTimeZone $tzname}]
	}
    } else {
	set tzname {}
    }
    if { $tzname eq {} || [dict get $TimeZoneBad $tzname] } {
	lassign $data \
	    bias stdBias dstBias \
	    stdYear stdMonth stdDayOfWeek stdDayOfMonth \
	    stdHour stdMinute stdSecond stdMillisec \
	    dstYear dstMonth dstDayOfWeek dstDayOfMonth \
	    dstHour dstMinute dstSecond dstMillisec
	set stdDelta [expr { $bias + $stdBias }]
	set dstDelta [expr { $bias + $dstBias }]
	if { $stdDelta <= 0 } {
	    set stdSignum +
	    set stdDelta [expr { - $stdDelta }]
	    set dispStdSignum -
	} else {
	    set stdSignum -
	    set dispStdSignum +
	}
	set hh [::format %02d [expr { $stdDelta / 3600 }]]
	set mm [::format %02d [expr { ($stdDelta / 60 ) % 60 }]]
	set ss [::format %02d [expr { $stdDelta % 60 }]]
	set tzname {}
	append tzname < $dispStdSignum $hh $mm > $stdSignum $hh : $mm : $ss
	if { $stdMonth >= 0 } {
	    if { $dstDelta <= 0 } {
		set dstSignum +
		set dstDelta [expr { - $dstDelta }]
		set dispDstSignum -
	    } else {
		set dstSignum -
		set dispDstSignum +
	    }
	    set hh [::format %02d [expr { $dstDelta / 3600 }]]
	    set mm [::format %02d [expr { ($dstDelta / 60 ) % 60 }]]
	    set ss [::format %02d [expr { $dstDelta % 60 }]]
	    append tzname < $dispDstSignum $hh $mm > $dstSignum $hh : $mm : $ss
	    if { $dstYear == 0 } {
		append tzname ,M $dstMonth . $dstDayOfMonth . $dstDayOfWeek
	    } else {
		# I have not been able to find any locale on which Windows
		# converts time zone on a fixed day of the year, hence don't
		# know how to interpret the fields.  If someone can inform me,
		# I'd be glad to code it up.  For right now, we bail out in
		# such a case.
		return :localtime
	    }
	    append tzname / [::format %02d $dstHour] \
		: [::format %02d $dstMinute] \
		: [::format %02d $dstSecond]
	    if { $stdYear == 0 } {
		append tzname ,M $stdMonth . $stdDayOfMonth . $stdDayOfWeek
	    } else {
		# I have not been able to find any locale on which Windows
		# converts time zone on a fixed day of the year, hence don't
		# know how to interpret the fields.  If someone can inform me,
		# I'd be glad to code it up.  For right now, we bail out in
		# such a case.
		return :localtime
	    }
	    append tzname / [::format %02d $stdHour] \
		: [::format %02d $stdMinute] \
		: [::format %02d $stdSecond]
	}
	dict set WinZoneInfo $data $tzname
    }

    return [dict get $WinZoneInfo $data]
}

#----------------------------------------------------------------------
#
# LoadTimeZoneFile --
#
#	Load the data file that specifies the conversion between a
#	given time zone and Greenwich.
#
# Parameters:
#	fileName -- Name of the file to load
#
# Results:
#	None.
#
# Side effects:
#	TZData(:fileName) contains the time zone data
#
#----------------------------------------------------------------------

proc ::tcl::clock::LoadTimeZoneFile { fileName } {
    variable DataDir
    variable TZData

    if { [info exists TZData($fileName)] } {
	return
    }

    # Since an unsafe interp uses the [clock] command in the master, this code
    # is security sensitive.  Make sure that the path name cannot escape the
    # given directory.

    if { ![regexp {^[[.-.][:alpha:]_]+(?:/[[.-.][:alpha:]_]+)*$} $fileName] } {
	return -code error \
	    -errorcode [list CLOCK badTimeZone $:fileName] \
	    "time zone \":$fileName\" not valid"
    }
    try {
	source -encoding utf-8 [file join $DataDir $fileName]
    } on error {} {
	return -code error \
	    -errorcode [list CLOCK badTimeZone :$fileName] \
	    "time zone \":$fileName\" not found"
    }
    return
}

#----------------------------------------------------------------------
#
# LoadZoneinfoFile --
#
#	Loads a binary time zone information file in Olson format.
#
# Parameters:
#	fileName - Relative path name of the file to load.
#
# Results:
#	Returns an empty result normally; returns an error if no Olson file
#	was found or the file was malformed in some way.
#
# Side effects:
#	TZData(:fileName) contains the time zone data
#
#----------------------------------------------------------------------

proc ::tcl::clock::LoadZoneinfoFile { fileName } {
    variable ZoneinfoPaths

    # Since an unsafe interp uses the [clock] command in the master, this code
    # is security sensitive.  Make sure that the path name cannot escape the
    # given directory.

    if { ![regexp {^[[.-.][:alpha:]_]+(?:/[[.-.][:alpha:]_]+)*$} $fileName] } {
	return -code error \
	    -errorcode [list CLOCK badTimeZone $:fileName] \
	    "time zone \":$fileName\" not valid"
    }
    foreach d $ZoneinfoPaths {
	set fname [file join $d $fileName]
	if { [file readable $fname] && [file isfile $fname] } {
	    break
	}
	unset fname
    }
    ReadZoneinfoFile $fileName $fname
}

#----------------------------------------------------------------------
#
# ReadZoneinfoFile --
#
#	Loads a binary time zone information file in Olson format.
#
# Parameters:
#	fileName - Name of the time zone (relative path name of the
#		   file).
#	fname - Absolute path name of the file.
#
# Results:
#	Returns an empty result normally; returns an error if no Olson file
#	was found or the file was malformed in some way.
#
# Side effects:
#	TZData(:fileName) contains the time zone data
#
#----------------------------------------------------------------------

proc ::tcl::clock::ReadZoneinfoFile {fileName fname} {
    variable MINWIDE
    variable TZData
    if { ![file exists $fname] } {
	return -code error "$fileName not found"
    }

    if { [file size $fname] > 262144 } {
	return -code error "$fileName too big"
    }

    # Suck in all the data from the file

    set f [open $fname r]
    fconfigure $f -translation binary
    set d [read $f]
    close $f

    # The file begins with a magic number, sixteen reserved bytes, and then
    # six 4-byte integers giving counts of fileds in the file.

    binary scan $d a4a1x15IIIIII \
	magic version nIsGMT nIsStd nLeap nTime nType nChar
    set seek 44
    set ilen 4
    set iformat I
    if { $magic != {TZif} } {
	return -code error "$fileName not a time zone information file"
    }
    if { $nType > 255 } {
	return -code error "$fileName contains too many time types"
    }
    # Accept only Posix-style zoneinfo.  Sorry, 'leaps' bigots.
    if { $nLeap != 0 } {
	return -code error "$fileName contains leap seconds"
    }

    # In a version 2 file, we use the second part of the file, which contains
    # 64-bit transition times.

    if {$version eq "2"} {
	set seek [expr {
	    44
	    + 5 * $nTime
	    + 6 * $nType
	    + 4 * $nLeap
	    + $nIsStd
	    + $nIsGMT
	    + $nChar
	}]
	binary scan $d @${seek}a4a1x15IIIIII \
	    magic version nIsGMT nIsStd nLeap nTime nType nChar
	if {$magic ne {TZif}} {
	    return -code error "seek address $seek miscomputed, magic = $magic"
	}
	set iformat W
	set ilen 8
	incr seek 44
    }

    # Next come ${nTime} transition times, followed by ${nTime} time type
    # codes.  The type codes are unsigned 1-byte quantities.  We insert an
    # arbitrary start time in front of the transitions.

    binary scan $d @${seek}${iformat}${nTime}c${nTime} times tempCodes
    incr seek [expr { ($ilen + 1) * $nTime }]
    set times [linsert $times 0 $MINWIDE]
    set codes {}
    foreach c $tempCodes {
	lappend codes [expr { $c & 0xff }]
    }
    set codes [linsert $codes 0 0]

    # Next come ${nType} time type descriptions, each of which has an offset
    # (seconds east of GMT), a DST indicator, and an index into the
    # abbreviation text.

    for { set i 0 } { $i < $nType } { incr i } {
	binary scan $d @${seek}Icc gmtOff isDst abbrInd
	lappend types [list $gmtOff $isDst $abbrInd]
	incr seek 6
    }

    # Next come $nChar characters of time zone name abbreviations, which are
    # null-terminated.
    # We build them up into a dictionary indexed by character index, because
    # that's what's in the indices above.

    binary scan $d @${seek}a${nChar} abbrs
    incr seek ${nChar}
    set abbrList [split $abbrs \0]
    set i 0
    set abbrevs {}
    foreach a $abbrList {
	for {set j 0} {$j <= [string length $a]} {incr j} {
	    dict set abbrevs $i [string range $a $j end]
	    incr i
	}
    }

    # Package up a list of tuples, each of which contains transition time,
    # seconds east of Greenwich, DST flag and time zone abbreviation.

    set r {}
    set lastTime $MINWIDE
    foreach t $times c $codes {
	if { $t < $lastTime } {
	    return -code error "$fileName has times out of order"
	}
	set lastTime $t
	lassign [lindex $types $c] gmtoff isDst abbrInd
	set abbrev [dict get $abbrevs $abbrInd]
	lappend r [list $t $gmtoff $isDst $abbrev]
    }

    # In a version 2 file, there is also a POSIX-style time zone description
    # at the very end of the file.  To get to it, skip over nLeap leap second
    # values (8 bytes each),
    # nIsStd standard/DST indicators and nIsGMT UTC/local indicators.

    if {$version eq {2}} {
	set seek [expr {$seek + 8 * $nLeap + $nIsStd + $nIsGMT + 1}]
	set last [string first \n $d $seek]
	set posix [string range $d $seek [expr {$last-1}]]
	if {[llength $posix] > 0} {
	    set posixFields [ParsePosixTimeZone $posix]
	    foreach tuple [ProcessPosixTimeZone $posixFields] {
		lassign $tuple t gmtoff isDst abbrev
		if {$t > $lastTime} {
		    lappend r $tuple
		}
	    }
	}
    }

    set TZData(:$fileName) $r

    return
}

#----------------------------------------------------------------------
#
# ParsePosixTimeZone --
#
#	Parses the TZ environment variable in Posix form
#
# Parameters:
#	tz	Time zone specifier to be interpreted
#
# Results:
#	Returns a dictionary whose values contain the various pieces of the
#	time zone specification.
#
# Side effects:
#	None.
#
# Errors:
#	Throws an error if the syntax of the time zone is incorrect.
#
# The following keys are present in the dictionary:
#	stdName - Name of the time zone when Daylight Saving Time
#		  is not in effect.
#	stdSignum - Sign (+, -, or empty) of the offset from Greenwich
#		    to the given (non-DST) time zone.  + and the empty
#		    string denote zones west of Greenwich, - denotes east
#		    of Greenwich; this is contrary to the ISO convention
#		    but follows Posix.
#	stdHours - Hours part of the offset from Greenwich to the given
#		   (non-DST) time zone.
#	stdMinutes - Minutes part of the offset from Greenwich to the
#		     given (non-DST) time zone. Empty denotes zero.
#	stdSeconds - Seconds part of the offset from Greenwich to the
#		     given (non-DST) time zone. Empty denotes zero.
#	dstName - Name of the time zone when DST is in effect, or the
#		  empty string if the time zone does not observe Daylight
#		  Saving Time.
#	dstSignum, dstHours, dstMinutes, dstSeconds -
#		Fields corresponding to stdSignum, stdHours, stdMinutes,
#		stdSeconds for the Daylight Saving Time version of the
#		time zone.  If dstHours is empty, it is presumed to be 1.
#	startDayOfYear - The ordinal number of the day of the year on which
#			 Daylight Saving Time begins.  If this field is
#			 empty, then DST begins on a given month-week-day,
#			 as below.
#	startJ - The letter J, or an empty string.  If a J is present in
#		 this field, then startDayOfYear does not count February 29
#		 even in leap years.
#	startMonth - The number of the month in which Daylight Saving Time
#		     begins, supplied if startDayOfYear is empty.  If both
#		     startDayOfYear and startMonth are empty, then US rules
#		     are presumed.
#	startWeekOfMonth - The number of the week in the month in which
#			   Daylight Saving Time begins, in the range 1-5.
#			   5 denotes the last week of the month even in a
#			   4-week month.
#	startDayOfWeek - The number of the day of the week (Sunday=0,
#			 Saturday=6) on which Daylight Saving Time begins.
#	startHours - The hours part of the time of day at which Daylight
#		     Saving Time begins. An empty string is presumed to be 2.
#	startMinutes - The minutes part of the time of day at which DST begins.
#		       An empty string is presumed zero.
#	startSeconds - The seconds part of the time of day at which DST begins.
#		       An empty string is presumed zero.
#	endDayOfYear, endJ, endMonth, endWeekOfMonth, endDayOfWeek,
#	endHours, endMinutes, endSeconds -
#		Specify the end of DST in the same way that the start* fields
#		specify the beginning of DST.
#
# This procedure serves only to break the time specifier into fields.  No
# attempt is made to canonicalize the fields or supply default values.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ParsePosixTimeZone { tz } {
    if {[regexp -expanded -nocase -- {
	^
	# 1 - Standard time zone name
	([[:alpha:]]+ | <[-+[:alnum:]]+>)
	# 2 - Standard time zone offset, signum
	([-+]?)
	# 3 - Standard time zone offset, hours
	([[:digit:]]{1,2})
	(?:
	    # 4 - Standard time zone offset, minutes
	    : ([[:digit:]]{1,2})
	    (?:
	        # 5 - Standard time zone offset, seconds
		: ([[:digit:]]{1,2} )
	    )?
	)?
	(?:
	    # 6 - DST time zone name
	    ([[:alpha:]]+ | <[-+[:alnum:]]+>)
	    (?:
	        (?:
		    # 7 - DST time zone offset, signum
		    ([-+]?)
		    # 8 - DST time zone offset, hours
		    ([[:digit:]]{1,2})
		    (?:
			# 9 - DST time zone offset, minutes
			: ([[:digit:]]{1,2})
			(?:
		            # 10 - DST time zone offset, seconds
			    : ([[:digit:]]{1,2})
			)?
		    )?
		)?
	        (?:
		    ,
		    (?:
			# 11 - Optional J in n and Jn form 12 - Day of year
		        ( J ? )	( [[:digit:]]+ )
                        | M
			# 13 - Month number 14 - Week of month 15 - Day of week
			( [[:digit:]] + )
			[.] ( [[:digit:]] + )
			[.] ( [[:digit:]] + )
		    )
		    (?:
			# 16 - Start time of DST - hours
			/ ( [[:digit:]]{1,2} )
		        (?:
			    # 17 - Start time of DST - minutes
			    : ( [[:digit:]]{1,2} )
			    (?:
				# 18 - Start time of DST - seconds
				: ( [[:digit:]]{1,2} )
			    )?
			)?
		    )?
		    ,
		    (?:
			# 19 - Optional J in n and Jn form 20 - Day of year
		        ( J ? )	( [[:digit:]]+ )
                        | M
			# 21 - Month number 22 - Week of month 23 - Day of week
			( [[:digit:]] + )
			[.] ( [[:digit:]] + )
			[.] ( [[:digit:]] + )
		    )
		    (?:
			# 24 - End time of DST - hours
			/ ( [[:digit:]]{1,2} )
		        (?:
			    # 25 - End time of DST - minutes
			    : ( [[:digit:]]{1,2} )
			    (?:
				# 26 - End time of DST - seconds
				: ( [[:digit:]]{1,2} )
			    )?
			)?
		    )?
                )?
	    )?
        )?
	$
    } $tz -> x(stdName) x(stdSignum) x(stdHours) x(stdMinutes) x(stdSeconds) \
	     x(dstName) x(dstSignum) x(dstHours) x(dstMinutes) x(dstSeconds) \
	     x(startJ) x(startDayOfYear) \
	     x(startMonth) x(startWeekOfMonth) x(startDayOfWeek) \
	     x(startHours) x(startMinutes) x(startSeconds) \
	     x(endJ) x(endDayOfYear) \
	     x(endMonth) x(endWeekOfMonth) x(endDayOfWeek) \
	     x(endHours) x(endMinutes) x(endSeconds)] } {
	# it's a good timezone

	return [array get x]
    }

    return -code error\
	-errorcode [list CLOCK badTimeZone $tz] \
	"unable to parse time zone specification \"$tz\""
}

#----------------------------------------------------------------------
#
# ProcessPosixTimeZone --
#
#	Handle a Posix time zone after it's been broken out into fields.
#
# Parameters:
#	z - Dictionary returned from 'ParsePosixTimeZone'
#
# Results:
#	Returns time zone information for the 'TZData' array.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ProcessPosixTimeZone { z } {
    variable MINWIDE
    variable TZData

    # Determine the standard time zone name and seconds east of Greenwich

    set stdName [dict get $z stdName]
    if { [string index $stdName 0] eq {<} } {
	set stdName [string range $stdName 1 end-1]
    }
    if { [dict get $z stdSignum] eq {-} } {
	set stdSignum +1
    } else {
	set stdSignum -1
    }
    set stdHours [lindex [::scan [dict get $z stdHours] %d] 0]
    if { [dict get $z stdMinutes] ne {} } {
	set stdMinutes [lindex [::scan [dict get $z stdMinutes] %d] 0]
    } else {
	set stdMinutes 0
    }
    if { [dict get $z stdSeconds] ne {} } {
	set stdSeconds [lindex [::scan [dict get $z stdSeconds] %d] 0]
    } else {
	set stdSeconds 0
    }
    set stdOffset [expr {
	(($stdHours * 60 + $stdMinutes) * 60 + $stdSeconds) * $stdSignum
    }]
    set data [list [list $MINWIDE $stdOffset 0 $stdName]]

    # If there's no daylight zone, we're done

    set dstName [dict get $z dstName]
    if { $dstName eq {} } {
	return $data
    }
    if { [string index $dstName 0] eq {<} } {
	set dstName [string range $dstName 1 end-1]
    }

    # Determine the daylight name

    if { [dict get $z dstSignum] eq {-} } {
	set dstSignum +1
    } else {
	set dstSignum -1
    }
    if { [dict get $z dstHours] eq {} } {
	set dstOffset [expr { 3600 + $stdOffset }]
    } else {
	set dstHours [lindex [::scan [dict get $z dstHours] %d] 0]
	if { [dict get $z dstMinutes] ne {} } {
	    set dstMinutes [lindex [::scan [dict get $z dstMinutes] %d] 0]
	} else {
	    set dstMinutes 0
	}
	if { [dict get $z dstSeconds] ne {} } {
	    set dstSeconds [lindex [::scan [dict get $z dstSeconds] %d] 0]
	} else {
	    set dstSeconds 0
	}
	set dstOffset [expr {
	    (($dstHours*60 + $dstMinutes) * 60 + $dstSeconds) * $dstSignum
	}]
    }

    # Fill in defaults for European or US DST rules
    # US start time is the second Sunday in March
    # EU start time is the last Sunday in March
    # US end time is the first Sunday in November.
    # EU end time is the last Sunday in October

    if {
	[dict get $z startDayOfYear] eq {}
	&& [dict get $z startMonth] eq {}
    } then {
	if {($stdSignum * $stdHours>=0) && ($stdSignum * $stdHours<=12)} {
	    # EU
	    dict set z startWeekOfMonth 5
	    if {$stdHours>2} {
		dict set z startHours 2
	    } else {
		dict set z startHours [expr {$stdHours+1}]
	    }
	} else {
	    # US
	    dict set z startWeekOfMonth 2
	    dict set z startHours 2
	}
	dict set z startMonth 3
	dict set z startDayOfWeek 0
	dict set z startMinutes 0
	dict set z startSeconds 0
    }
    if {
	[dict get $z endDayOfYear] eq {}
	&& [dict get $z endMonth] eq {}
    } then {
	if {($stdSignum * $stdHours>=0) && ($stdSignum * $stdHours<=12)} {
	    # EU
	    dict set z endMonth 10
	    dict set z endWeekOfMonth 5
	    if {$stdHours>2} {
		dict set z endHours 3
	    } else {
		dict set z endHours [expr {$stdHours+2}]
	    }
	} else {
	    # US
	    dict set z endMonth 11
	    dict set z endWeekOfMonth 1
	    dict set z endHours 2
	}
	dict set z endDayOfWeek 0
	dict set z endMinutes 0
	dict set z endSeconds 0
    }

    # Put DST in effect in all years from 1916 to 2099.

    for { set y 1916 } { $y < 2100 } { incr y } {
	set startTime [DeterminePosixDSTTime $z start $y]
	incr startTime [expr { - wide($stdOffset) }]
	set endTime [DeterminePosixDSTTime $z end $y]
	incr endTime [expr { - wide($dstOffset) }]
	if { $startTime < $endTime } {
	    lappend data \
		[list $startTime $dstOffset 1 $dstName] \
		[list $endTime $stdOffset 0 $stdName]
	} else {
	    lappend data \
		[list $endTime $stdOffset 0 $stdName] \
		[list $startTime $dstOffset 1 $dstName]
	}
    }

    return $data
}

#----------------------------------------------------------------------
#
# DeterminePosixDSTTime --
#
#	Determines the time that Daylight Saving Time starts or ends from a
#	Posix time zone specification.
#
# Parameters:
#	z - Time zone data returned from ParsePosixTimeZone.
#	    Missing fields are expected to be filled in with
#	    default values.
#	bound - The word 'start' or 'end'
#	y - The year for which the transition time is to be determined.
#
# Results:
#	Returns the transition time as a count of seconds from the epoch.  The
#	time is relative to the wall clock, not UTC.
#
#----------------------------------------------------------------------

proc ::tcl::clock::DeterminePosixDSTTime { z bound y } {

    variable FEB_28

    # Determine the start or end day of DST

    set date [dict create era CE year $y]
    set doy [dict get $z ${bound}DayOfYear]
    if { $doy ne {} } {

	# Time was specified as a day of the year

	if { [dict get $z ${bound}J] ne {}
	     && [IsGregorianLeapYear $y]
	     && ( $doy > $FEB_28 ) } {
	    incr doy
	}
	dict set date dayOfYear $doy
	set date [GetJulianDayFromEraYearDay $date[set date {}] 2361222]
    } else {
	# Time was specified as a day of the week within a month

	dict set date month [dict get $z ${bound}Month]
	dict set date dayOfWeek [dict get $z ${bound}DayOfWeek]
	set dowim [dict get $z ${bound}WeekOfMonth]
	if { $dowim >= 5 } {
	    set dowim -1
	}
	dict set date dayOfWeekInMonth $dowim
	set date [GetJulianDayFromEraYearMonthWeekDay $date[set date {}] 2361222]

    }

    set jd [dict get $date julianDay]
    set seconds [expr {
	wide($jd) * wide(86400) - wide(210866803200)
    }]

    set h [dict get $z ${bound}Hours]
    if { $h eq {} } {
	set h 2
    } else {
	set h [lindex [::scan $h %d] 0]
    }
    set m [dict get $z ${bound}Minutes]
    if { $m eq {} } {
	set m 0
    } else {
	set m [lindex [::scan $m %d] 0]
    }
    set s [dict get $z ${bound}Seconds]
    if { $s eq {} } {
	set s 0
    } else {
	set s [lindex [::scan $s %d] 0]
    }
    set tod [expr { ( $h * 60 + $m ) * 60 + $s }]
    return [expr { $seconds + $tod }]
}

#----------------------------------------------------------------------
#
# GetLocaleEra --
#
#	Given local time expressed in seconds from the Posix epoch,
#	determine localized era and year within the era.
#
# Parameters:
#	date - Dictionary that must contain the keys, 'localSeconds',
#	       whose value is expressed as the appropriate local time;
#	       and 'year', whose value is the Gregorian year.
#	etable - Value of the LOCALE_ERAS key in the message catalogue
#	         for the target locale.
#
# Results:
#	Returns the dictionary, augmented with the keys, 'localeEra' and
#	'localeYear'.
#
#----------------------------------------------------------------------

proc ::tcl::clock::GetLocaleEra { date etable } {
    set index [BSearch $etable [dict get $date localSeconds]]
    if { $index < 0} {
	dict set date localeEra \
	    [::format %02d [expr { [dict get $date year] / 100 }]]
	dict set date localeYear [expr {
	    [dict get $date year] % 100
	}]
    } else {
	dict set date localeEra [lindex $etable $index 1]
	dict set date localeYear [expr {
	    [dict get $date year] - [lindex $etable $index 2]
	}]
    }
    return $date
}

#----------------------------------------------------------------------
#
# GetJulianDayFromEraYearDay --
#
#	Given a year, month and day on the Gregorian calendar, determines
#	the Julian Day Number beginning at noon on that date.
#
# Parameters:
#	date -- A dictionary in which the 'era', 'year', and
#		'dayOfYear' slots are populated. The calendar in use
#		is determined by the date itself relative to:
#       changeover -- Julian day on which the Gregorian calendar was
#		adopted in the current locale.
#
# Results:
#	Returns the given dictionary augmented with a 'julianDay' key whose
#	value is the desired Julian Day Number, and a 'gregorian' key that
#	specifies whether the calendar is Gregorian (1) or Julian (0).
#
# Side effects:
#	None.
#
# Bugs:
#	This code needs to be moved to the C layer.
#
#----------------------------------------------------------------------

proc ::tcl::clock::GetJulianDayFromEraYearDay {date changeover} {
    # Get absolute year number from the civil year

    switch -exact -- [dict get $date era] {
	BCE {
	    set year [expr { 1 - [dict get $date year] }]
	}
	CE {
	    set year [dict get $date year]
	}
    }
    set ym1 [expr { $year - 1 }]

    # Try the Gregorian calendar first.

    dict set date gregorian 1
    set jd [expr {
	1721425
	+ [dict get $date dayOfYear]
	+ ( 365 * $ym1 )
	+ ( $ym1 / 4 )
	- ( $ym1 / 100 )
	+ ( $ym1 / 400 )
    }]

    # If the date is before the Gregorian change, use the Julian calendar.

    if { $jd < $changeover } {
	dict set date gregorian 0
	set jd [expr {
	    1721423
	    + [dict get $date dayOfYear]
	    + ( 365 * $ym1 )
	    + ( $ym1 / 4 )
	}]
    }

    dict set date julianDay $jd
    return $date
}

#----------------------------------------------------------------------
#
# GetJulianDayFromEraYearMonthWeekDay --
#
#	Determines the Julian Day number corresponding to the nth given
#	day-of-the-week in a given month.
#
# Parameters:
#	date - Dictionary containing the keys, 'era', 'year', 'month'
#	       'weekOfMonth', 'dayOfWeek', and 'dayOfWeekInMonth'.
#	changeover - Julian Day of adoption of the Gregorian calendar
#
# Results:
#	Returns the given dictionary, augmented with a 'julianDay' key.
#
# Side effects:
#	None.
#
# Bugs:
#	This code needs to be moved to the C layer.
#
#----------------------------------------------------------------------

proc ::tcl::clock::GetJulianDayFromEraYearMonthWeekDay {date changeover} {
    # Come up with a reference day; either the zeroeth day of the given month
    # (dayOfWeekInMonth >= 0) or the seventh day of the following month
    # (dayOfWeekInMonth < 0)

    set date2 $date
    set week [dict get $date dayOfWeekInMonth]
    if { $week >= 0 } {
	dict set date2 dayOfMonth 0
    } else {
	dict incr date2 month
	dict set date2 dayOfMonth 7
    }
    set date2 [GetJulianDayFromEraYearMonthDay $date2[set date2 {}] \
		   $changeover]
    set wd0 [WeekdayOnOrBefore [dict get $date dayOfWeek] \
		 [dict get $date2 julianDay]]
    dict set date julianDay [expr { $wd0 + 7 * $week }]
    return $date
}

#----------------------------------------------------------------------
#
# IsGregorianLeapYear --
#
#	Determines whether a given date represents a leap year in the
#	Gregorian calendar.
#
# Parameters:
#	date -- The date to test.  The fields, 'era', 'year' and 'gregorian'
#	        must be set.
#
# Results:
#	Returns 1 if the year is a leap year, 0 otherwise.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::IsGregorianLeapYear { date } {
    switch -exact -- [dict get $date era] {
	BCE {
	    set year [expr { 1 - [dict get $date year]}]
	}
	CE {
	    set year [dict get $date year]
	}
    }
    if { $year % 4 != 0 } {
	return 0
    } elseif { ![dict get $date gregorian] } {
	return 1
    } elseif { $year % 400 == 0 } {
	return 1
    } elseif { $year % 100 == 0 } {
	return 0
    } else {
	return 1
    }
}

#----------------------------------------------------------------------
#
# WeekdayOnOrBefore --
#
#	Determine the nearest day of week (given by the 'weekday' parameter,
#	Sunday==0) on or before a given Julian Day.
#
# Parameters:
#	weekday -- Day of the week
#	j -- Julian Day number
#
# Results:
#	Returns the Julian Day Number of the desired date.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::WeekdayOnOrBefore { weekday j } {
    set k [expr { ( $weekday + 6 )  % 7 }]
    return [expr { $j - ( $j - $k ) % 7 }]
}

#----------------------------------------------------------------------
#
# BSearch --
#
#	Service procedure that does binary search in several places inside the
#	'clock' command.
#
# Parameters:
#	list - List of lists, sorted in ascending order by the
#	       first elements
#	key - Value to search for
#
# Results:
#	Returns the index of the greatest element in $list that is less than
#	or equal to $key.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::BSearch { list key } {
    if {[llength $list] == 0} {
	return -1
    }
    if { $key < [lindex $list 0 0] } {
	return -1
    }

    set l 0
    set u [expr { [llength $list] - 1 }]

    while { $l < $u } {
	# At this point, we know that
	#   $k >= [lindex $list $l 0]
	#   Either $u == [llength $list] or else $k < [lindex $list $u+1 0]
	# We find the midpoint of the interval {l,u} rounded UP, compare
	# against it, and set l or u to maintain the invariant.  Note that the
	# interval shrinks at each step, guaranteeing convergence.

	set m [expr { ( $l + $u + 1 ) / 2 }]
	if { $key >= [lindex $list $m 0] } {
	    set l $m
	} else {
	    set u [expr { $m - 1 }]
	}
    }

    return $l
}

#----------------------------------------------------------------------
#
# clock add --
#
#	Adds an offset to a given time.
#
# Syntax:
#	clock add clockval ?count unit?... ?-option value?
#
# Parameters:
#	clockval -- Starting time value
#	count -- Amount of a unit of time to add
#	unit -- Unit of time to add, must be one of:
#			years year months month weeks week
#			days day hours hour minutes minute
#			seconds second
#
# Options:
#	-gmt BOOLEAN
#		(Deprecated) Flag synonymous with '-timezone :GMT'
#	-timezone ZONE
#		Name of the time zone in which calculations are to be done.
#	-locale NAME
#		Name of the locale in which calculations are to be done.
#		Used to determine the Gregorian change date.
#
# Results:
#	Returns the given time adjusted by the given offset(s) in
#	order.
#
# Notes:
#	It is possible that adding a number of months or years will adjust the
#	day of the month as well.  For instance, the time at one month after
#	31 January is either 28 or 29 February, because February has fewer
#	than 31 days.
#
#----------------------------------------------------------------------

proc ::tcl::clock::add { clockval args } {
    if { [llength $args] % 2 != 0 } {
	set cmdName "clock add"
	return -code error \
	    -errorcode [list CLOCK wrongNumArgs] \
	    "wrong \# args: should be\
             \"$cmdName clockval ?number units?...\
             ?-gmt boolean? ?-locale LOCALE? ?-timezone ZONE?\""
    }
    if { [catch { expr {wide($clockval)} } result] } {
	return -code error $result
    }

    set offsets {}
    set gmt 0
    set locale c
    set timezone [GetSystemTimeZone]

    foreach { a b } $args {
	if { [string is integer -strict $a] } {
	    lappend offsets $a $b
	} else {
	    switch -exact -- $a {
		-g - -gm - -gmt {
		    set gmt $b
		}
		-l - -lo - -loc - -loca - -local - -locale {
		    set locale [string tolower $b]
		}
		-t - -ti - -tim - -time - -timez - -timezo - -timezon -
		-timezone {
		    set timezone $b
		}
		default {
		    throw [list CLOCK badOption $a] \
			"bad option \"$a\",\
                         must be -gmt, -locale or -timezone"
		}
	    }
	}
    }

    # Check options for validity

    if { [info exists saw(-gmt)] && [info exists saw(-timezone)] } {
	return -code error \
	    -errorcode [list CLOCK gmtWithTimezone] \
	    "cannot use -gmt and -timezone in same call"
    }
    if { [catch { expr { wide($clockval) } } result] } {
	return -code error "expected integer but got \"$clockval\""
    }
    if { ![string is boolean -strict $gmt] } {
	return -code error "expected boolean value but got \"$gmt\""
    } elseif { $gmt } {
	set timezone :GMT
    }

    EnterLocale $locale

    set changeover [mc GREGORIAN_CHANGE_DATE]

    if {[catch {SetupTimeZone $timezone} retval opts]} {
	dict unset opts -errorinfo
	return -options $opts $retval
    }

    try {
	foreach { quantity unit } $offsets {
	    switch -exact -- $unit {
		years - year {
		    set clockval [AddMonths [expr { 12 * $quantity }] \
			    $clockval $timezone $changeover]
		}
		months - month {
		    set clockval [AddMonths $quantity $clockval $timezone \
			    $changeover]
		}

		weeks - week {
		    set clockval [AddDays [expr { 7 * $quantity }] \
			    $clockval $timezone $changeover]
		}
		days - day {
		    set clockval [AddDays $quantity $clockval $timezone \
			    $changeover]
		}

		hours - hour {
		    set clockval [expr { 3600 * $quantity + $clockval }]
		}
		minutes - minute {
		    set clockval [expr { 60 * $quantity + $clockval }]
		}
		seconds - second {
		    set clockval [expr { $quantity + $clockval }]
		}

		default {
		    throw [list CLOCK badUnit $unit] \
			"unknown unit \"$unit\", must be \
                        years, months, weeks, days, hours, minutes or seconds"
		}
	    }
	}
	return $clockval
    } trap CLOCK {result opts} {
	# Conceal the innards of [clock] when it's an expected error
	dict unset opts -errorinfo
	return -options $opts $result
    }
}

#----------------------------------------------------------------------
#
# AddMonths --
#
#	Add a given number of months to a given clock value in a given
#	time zone.
#
# Parameters:
#	months - Number of months to add (may be negative)
#	clockval - Seconds since the epoch before the operation
#	timezone - Time zone in which the operation is to be performed
#
# Results:
#	Returns the new clock value as a number of seconds since
#	the epoch.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AddMonths { months clockval timezone changeover } {
    variable DaysInRomanMonthInCommonYear
    variable DaysInRomanMonthInLeapYear
    variable TZData

    # Convert the time to year, month, day, and fraction of day.

    set date [GetDateFields $clockval $TZData($timezone) $changeover]
    dict set date secondOfDay [expr {
	[dict get $date localSeconds] % 86400
    }]
    dict set date tzName $timezone

    # Add the requisite number of months

    set m [dict get $date month]
    incr m $months
    incr m -1
    set delta [expr { $m / 12 }]
    set mm [expr { $m % 12 }]
    dict set date month [expr { $mm + 1 }]
    dict incr date year $delta

    # If the date doesn't exist in the current month, repair it

    if { [IsGregorianLeapYear $date] } {
	set hath [lindex $DaysInRomanMonthInLeapYear $mm]
    } else {
	set hath [lindex $DaysInRomanMonthInCommonYear $mm]
    }
    if { [dict get $date dayOfMonth] > $hath } {
	dict set date dayOfMonth $hath
    }

    # Reconvert to a number of seconds

    set date [GetJulianDayFromEraYearMonthDay \
		  $date[set date {}]\
		  $changeover]
    dict set date localSeconds [expr {
	-210866803200
	+ ( 86400 * wide([dict get $date julianDay]) )
	+ [dict get $date secondOfDay]
    }]
    set date [ConvertLocalToUTC $date[set date {}] $TZData($timezone) \
		 $changeover]

    return [dict get $date seconds]

}

#----------------------------------------------------------------------
#
# AddDays --
#
#	Add a given number of days to a given clock value in a given time
#	zone.
#
# Parameters:
#	days - Number of days to add (may be negative)
#	clockval - Seconds since the epoch before the operation
#	timezone - Time zone in which the operation is to be performed
#	changeover - Julian Day on which the Gregorian calendar was adopted
#		     in the target locale.
#
# Results:
#	Returns the new clock value as a number of seconds since the epoch.
#
# Side effects:
#	None.
#
#----------------------------------------------------------------------

proc ::tcl::clock::AddDays { days clockval timezone changeover } {
    variable TZData

    # Convert the time to Julian Day

    set date [GetDateFields $clockval $TZData($timezone) $changeover]
    dict set date secondOfDay [expr {
	[dict get $date localSeconds] % 86400
    }]
    dict set date tzName $timezone

    # Add the requisite number of days

    dict incr date julianDay $days

    # Reconvert to a number of seconds

    dict set date localSeconds [expr {
	-210866803200
	+ ( 86400 * wide([dict get $date julianDay]) )
	+ [dict get $date secondOfDay]
    }]
    set date [ConvertLocalToUTC $date[set date {}] $TZData($timezone) \
		  $changeover]

    return [dict get $date seconds]

}

#----------------------------------------------------------------------
#
# ChangeCurrentLocale --
#
#        The global locale was changed within msgcat.
#        Clears the buffered parse functions of the current locale.
#
# Parameters:
#        loclist (ignored)
#
# Results:
#        None.
#
# Side effects:
#        Buffered parse functions are cleared.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ChangeCurrentLocale {args} {
    variable FormatProc
    variable LocaleNumeralCache
    variable CachedSystemTimeZone
    variable TimeZoneBad

    foreach p [info procs [namespace current]::scanproc'*'current] {
        rename $p {}
    }
    foreach p [info procs [namespace current]::formatproc'*'current] {
        rename $p {}
    }

    catch {array unset FormatProc *'current}
    set LocaleNumeralCache {}
}

#----------------------------------------------------------------------
#
# ClearCaches --
#
#	Clears all caches to reclaim the memory used in [clock]
#
# Parameters:
#	None.
#
# Results:
#	None.
#
# Side effects:
#	Caches are cleared.
#
#----------------------------------------------------------------------

proc ::tcl::clock::ClearCaches {} {
    variable FormatProc
    variable LocaleNumeralCache
    variable CachedSystemTimeZone
    variable TimeZoneBad

    foreach p [info procs [namespace current]::scanproc'*] {
	rename $p {}
    }
    foreach p [info procs [namespace current]::formatproc'*] {
	rename $p {}
    }

    catch {unset FormatProc}
    set LocaleNumeralCache {}
    catch {unset CachedSystemTimeZone}
    set TimeZoneBad {}
    InitTZData
}

Youez - 2016 - github.com/yon3zu
LinuXploit