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# $FreeBSD: release/9.1.0/share/i18n/csmapper/APPLE/GURMUKHI%25UCS.src 219019 2011-02-25 00:04:39Z gabor $
TYPE ROWCOL
NAME GURMUKHI/UCS
SRC_ZONE 0x00-0xFA
OOB_MODE ILSEQ
DST_ILSEQ 0xFFFE
DST_UNIT_BITS 16
#=======================================================================
# File name: GURMUKHI.TXT
#
# Contents: Map (external version) from Mac OS Gurmukhi
# encoding to Unicode 2.1 and later.
#
# Copyright: (c) 1997-2002, 2005 by Apple Computer, Inc., all rights
# reserved.
#
# Contact: charsets@apple.com
#
# Changes:
#
# c02 2005-Apr-05 Update header comments. Matches internal xml
# <c1.1> and Text Encoding Converter 2.0.
# b3,c1 2002-Dec-19 Change mappings for 0x91, 0xD5 based on
# new decomposition rules. Update URLs,
# notes. Matches internal utom<b2>.
# b02 1999-Sep-22 Update contact e-mail address. Matches
# internal utom<b1>, ufrm<b1>, and Text
# Encoding Converter version 1.5.
# n02 1998-Feb-05 First version; matches internal utom<n5>,
# ufrm<n6>.
#
# Standard header:
# ----------------
#
# Apple, the Apple logo, and Macintosh are trademarks of Apple
# Computer, Inc., registered in the United States and other countries.
# Unicode is a trademark of Unicode Inc. For the sake of brevity,
# throughout this document, "Macintosh" can be used to refer to
# Macintosh computers and "Unicode" can be used to refer to the
# Unicode standard.
#
# Apple Computer, Inc. ("Apple") makes no warranty or representation,
# either express or implied, with respect to this document and the
# included data, its quality, accuracy, or fitness for a particular
# purpose. In no event will Apple be liable for direct, indirect,
# special, incidental, or consequential damages resulting from any
# defect or inaccuracy in this document or the included data.
#
# These mapping tables and character lists are subject to change.
# The latest tables should be available from the following:
#
# <http://www.unicode.org/Public/MAPPINGS/VENDORS/APPLE/>
#
# For general information about Mac OS encodings and these mapping
# tables, see the file "README.TXT".
#
# Format:
# -------
#
# Three tab-separated columns;
# '#' begins a comment which continues to the end of the line.
# Column #1 is the Mac OS Gurmukhi code or code sequence
# (in hex as 0xNN or 0xNN+0xNN)
# Column #2 is the corresponding Unicode or Unicode sequence
# (in hex as 0xNNNN or 0xNNNN+0xNNNN).
# Column #3 is a comment containing the Unicode name or sequence
# of names. In some cases an additional comment follows the
# Unicode name(s).
#
# The entries are in two sections. The first section is for pairs of
# Mac OS Gurmukhi code points that must be mapped in a special way.
# The second section maps individual code points.
#
# Within each section, the entries are in Mac OS Gurmukhi code order.
#
# Control character mappings are not shown in this table, following
# the conventions of the standard UTC mapping tables. However, the
# Mac OS Gurmukhi character set uses the standard control characters
# at 0x00-0x1F and 0x7F.
#
# Notes on Mac OS Gurmukhi:
# -------------------------
#
# This is a legacy Mac OS encoding; in the Mac OS X Carbon and Cocoa
# environments, it is only supported via transcoding to and from
# Unicode.
#
# Mac OS Gurmukhi is based on IS 13194:1991 (ISCII-91), with the
# addition of several punctuation and symbol characters. However,
# Mac OS Gurmukhi does not support the ATR (attribute) mechanism of
# ISCII-91.
#
# 1. ISCII-91 features in Mac OS Gurmukhi include:
#
# a) Explicit halant and soft halant
#
# A double halant (0xE8 + 0xE8) constitutes an "explicit halant",
# which will always appear as a halant instead of causing formation
# of a ligature or half-form consonant.
#
# Halant followed by nukta (0xE8 + 0xE9) constitutes a "soft
# halant", which prevents formation of a ligature and instead
# retains the half-form of the first consonant.
#
# b) Invisible consonant
#
# The byte 0xD9 (called INV in ISCII-91) is an invisible consonant:
# It behaves like a consonant but has no visible appearance. It is
# intended to be used (often in combination with halant) to display
# dependent forms in isolation, such as the RA forms or consonant
# half-forms.
#
# c) Extensions for Vedic, etc.
#
# The byte 0xF0 (called EXT in ISCII-91) followed by any byte in
# the range 0xA1-0xEE constitutes a two-byte code point which can
# be used to represent additional characters for Vedic (or other
# extensions); 0xF0 followed by any other byte value constitutes
# malformed text. Mac OS Gurmukhi supports this mechanism, but
# does not currently map any of these two-byte code points to
# anything.
#
# 2. Mac OS Gurmukhi additions
#
# Mac OS Gurmukhi adds characters using the code points
# 0x80-0x8A and 0x90-0x94 (the latter are some Gurmukhi additions).
#
# 3. Unused code points
#
# The following code points are currently unused, and are not shown
# here: 0x8B-0x8F, 0x95-0xA1, 0xA3, 0xAA-0xAB, 0xAE-0xAF, 0xB2,
# 0xC7, 0xCE, 0xD0, 0xD2-0xD3, 0xD6, 0xDF-0xE0, 0xE3-0xE4, 0xE7,
# 0xEB-0xEF, 0xFB-0xFF. In addition, 0xF0 is not shown here, but it
# has a special function as described above.
#
# Unicode mapping issues and notes:
# ---------------------------------
#
# 1. Mapping the byte pairs
#
# If the byte value 0xE8 is encountered when mapping Mac OS
# Gurmukhi text, then the next byte (if there is one) should be
# examined. If the next byte is 0xE8 or 0xE9, then the byte pair
# should be mapped using the first section of the mapping table
# below. Otherwise, each byte should be mapped using the second
# section of the mapping table below.
#
# - The Unicode Standard, Version 2.0, specifies how explicit
# halant and soft halant should be represented in Unicode;
# these mappings are used below.
#
# If the byte value 0xF0 is encountered when mapping Mac OS
# Gurmukhi text, then the next byte should be examined. If there
# is no next byte (e.g. 0xF0 at end of buffer), the mapping
# process should indicate incomplete character. If there is a next
# byte but it is not in the range 0xA1-0xEE, the mapping process
# should indicate malformed text. Otherwise, the mapping process
# should treat the byte pair as a valid two-byte code point with no
# mapping (e.g. map it to QUESTION MARK, REPLACEMENT CHARACTER,
# etc.).
#
# 2. Mapping the invisible consonant
#
# It has been suggested that INV in ISCII-91 should map to ZERO
# WIDTH NON-JOINER in Unicode. However, this causes problems with
# roundtrip fidelity: The ISCII-91 sequences 0xE8+0xE8 and 0xE8+0xD9
# would map to the same sequence of Unicode characters. We have
# instead mapped INV to LEFT-TO-RIGHT MARK, which avoids these
# problems.
#
# 3. Mappings using corporate characters
#
# Mapping the GURMUKHI LETTER SHA 0xD5 presents an interesting
# problem. At first glance, we could map it to the single Unicode
# character 0x0A36.
#
# However, our goal is that the mappings provided here should also
# be able to generate the mappings to maximally decomposed Unicode
# by simple recursive substitution of the canonical decompositions
# in the Unicode database. We want mapping tables derived this way
# to retain full roundtrip fidelity.
#
# Since the canonical decomposition of 0x0A36 is 0x0A38+0x0A3C,
# the decomposition mapping for 0xD5 would be identical with the
# decomposition mapping for 0xD7+0xE9, and roundtrip fidelity would
# be lost.
#
# We solve this problem by using a grouping hint (one of the set of
# transcoding hints defined by Apple).
#
# Apple has defined a block of 32 corporate characters as "transcoding
# hints." These are used in combination with standard Unicode characters
# to force them to be treated in a special way for mapping to other
# encodings; they have no other effect. Sixteen of these transcoding
# hints are "grouping hints" - they indicate that the next 2-4 Unicode
# characters should be treated as a single entity for transcoding. The
# other sixteen transcoding hints are "variant tags" - they are like
# combining characters, and can follow a standard Unicode (or a sequence
# consisting of a base character and other combining characters) to
# cause it to be treated in a special way for transcoding. These always
# terminate a combining-character sequence.
#
# The transcoding coding hint used in this mapping table is:
# 0xF860 group next 2 characters
#
# Then we can map 0x91 as follows:
# 0xD5 -> 0xF860+0x0A38+0x0A3C
#
# We could also have used a variant tag such as 0xF87F and mapped it
# this way:
# 0xD5 -> 0x0A36+0xF87F
#
# 4. Additional loose mappings from Unicode
#
# These are not preserved in roundtrip mappings.
#
# 0A59 -> 0xB4+0xE9 # GURMUKHI LETTER KHHA
# 0A5A -> 0xB5+0xE9 # GURMUKHI LETTER GHHA
# 0A5B -> 0xBA+0xE9 # GURMUKHI LETTER ZA
# 0A5E -> 0xC9+0xE9 # GURMUKHI LETTER FA
#
# 0A70 -> 0xA2 # GURMUKHI TIPPI
#
# Loose mappings from Unicode should also map U+0A71 (GURMUKHI ADDAK)
# followed by any Gurmukhi consonant to the equivalent ISCII-91
# consonant plus halant plus the consonant again. For example:
#
# 0A71+0A15 -> 0xB3+0xE8+0xB3
# 0A71+0A16 -> 0xB4+0xE8+0xB4
# ...
#
# Details of mapping changes in each version:
# -------------------------------------------
#
# Changes from version b02 to version b03/c01:
#
# - Change mapping of 0x91 from 0xF860+0x0A21+0x0A3C to 0x0A5C GURMUKHI
# LETTER RRA, now that the canonical decomposition of 0x0A5C to
# 0x0A21+0x0A3C has been deleted
#
# - Change mapping of 0xD5 from 0x0A36 GURMUKHI LETTER SHA to
# 0xF860+0x0A38+0x0A3C, now that a canonical decomposition of 0x0A36
# to 0x0A38+0x0A3C has been added.
#
##################
BEGIN_MAP
0x00 - 0x7F = 0x0000 -
0x80 = 0x00D7
0x81 = 0x2212
0x82 = 0x2013
0x83 = 0x2014
0x84 = 0x2018
0x85 = 0x2019
0x86 = 0x2026
0x87 = 0x2022
0x88 = 0x00A9
0x89 = 0x00AE
0x8A = 0x2122
0x90 = 0x0A71
0x91 = 0x0A5C
0x92 = 0x0A73
0x93 = 0x0A72
0x94 = 0x0A74
0xA2 = 0x0A02
0xA4 = 0x0A05
0xA5 = 0x0A06
0xA6 = 0x0A07
0xA7 = 0x0A08
0xA8 = 0x0A09
0xA9 = 0x0A0A
0xAC = 0x0A0F
0xAD = 0x0A10
0xB0 = 0x0A13
0xB1 = 0x0A14
0xB3 = 0x0A15
0xB4 = 0x0A16
0xB5 = 0x0A17
0xB6 = 0x0A18
0xB7 = 0x0A19
0xB8 = 0x0A1A
0xB9 = 0x0A1B
0xBA = 0x0A1C
0xBB = 0x0A1D
0xBC = 0x0A1E
0xBD = 0x0A1F
0xBE = 0x0A20
0xBF = 0x0A21
0xC0 = 0x0A22
0xC1 = 0x0A23
0xC2 = 0x0A24
0xC3 = 0x0A25
0xC4 = 0x0A26
0xC5 = 0x0A27
0xC6 = 0x0A28
0xC8 = 0x0A2A
0xC9 = 0x0A2B
0xCA = 0x0A2C
0xCB = 0x0A2D
0xCC = 0x0A2E
0xCD = 0x0A2F
0xCF = 0x0A30
0xD1 = 0x0A32
0xD4 = 0x0A35
#0xD5 = 0xF860+0x0A38+0x0A3C
0xD7 = 0x0A38
0xD8 = 0x0A39
0xD9 = 0x200E
0xDA = 0x0A3E
0xDB = 0x0A3F
0xDC = 0x0A40
0xDD = 0x0A41
0xDE = 0x0A42
0xE1 = 0x0A47
0xE2 = 0x0A48
0xE5 = 0x0A4B
0xE6 = 0x0A4C
0xE8 = 0x0A4D
#0xE8+0xE8 = 0x0A4D+0x200C
#0xE8+0xE9 = 0x0A4D+0x200D
0xE9 = 0x0A3C
0xEA = 0x0964
0xF1 = 0x0A66
0xF2 = 0x0A67
0xF3 = 0x0A68
0xF4 = 0x0A69
0xF5 = 0x0A6A
0xF6 = 0x0A6B
0xF7 = 0x0A6C
0xF8 = 0x0A6D
0xF9 = 0x0A6E
0xFA = 0x0A6F
END_MAP