# Copyright (c) 2012-2015 International Business Machines # Corporation and others. All Rights Reserved. # # This file should be in UTF-8 with a signature byte sequence ("BOM"). # # collationtest.txt: Collation test data. # # created on: 2012apr13 # created by: Markus W. Scherer # A line with "** test: description" is used for verbose and error output. # A collator can be set with "@ root" or "@ locale language-tag", # for example "@ locale de-u-co-phonebk". # An old-style locale ID can also be used, for example "@ locale de@collation=phonebook". # A collator can be built with "@ rules". # An "@ rules" line is followed by one or more lines with the tailoring rules. # A collator can be modified with "% attribute=value". # "* compare" tests the order (= or <) of the following strings. # The relation can be "=" or "<" (the level of the difference is not specified) # or "<1", "<2", "<c", "<3", "<4" (indicating the level of the difference). # Test sections ("* compare") are terminated by # definitions of new collators, changing attributes, or new test sections. ** test: simple CEs & expansions # Many types of mappings are tested elsewhere, including via the UCA conformance tests. # Here we mostly cover a few unusual mappings. @ rules &\x01 # most control codes are ignorable <<<\u0300 # tertiary CE &9<\x00 # NUL not ignorable &\uA00A\uA00B=\uA002 # two long-primary CEs &\uA00A\uA00B\u00050005=\uA003 # three CEs, require 64 bits * compare = \x01 = \x02 <3 \u0300 <1 9 <1 \x00 = \x01\x00\x02 <1 a <3 a\u0300 <2 a\u0308 = ä <1 b <1 か # Hiragana Ka (U+304B) <2 か\u3099 # plus voiced sound mark = が # Hiragana Ga (U+304C) <1 \uA00A\uA00B = \uA002 <1 \uA00A\uA00B\u00050004 <1 \uA00A\uA00B\u00050005 = \uA003 <1 \uA00A\uA00B\u00050006 ** test: contractions # Create some interesting mappings, and map some normalization-inert characters # (which are not subject to canonical reordering) # to some of the same CEs to check the sequence of CEs. @ rules # Contractions starting with 'a' should not continue with any character < U+0300 # so that we can test a shortcut for that. &a=ⓐ &b<bz=ⓑ &d<dz\u0301=ⓓ # d+z+acute &z <a\u0301=Ⓐ # a+acute sorts after z <a\u0301\u0301=Ⓑ # a+acute+acute <a\u0301\u0301\u0358=Ⓒ # a+acute+acute+dot above right <a\u030a=Ⓓ # a+ring <a\u0323=Ⓔ # a+dot below <a\u0323\u0358=Ⓕ # a+dot below+dot above right <a\u0327\u0323\u030a=Ⓖ # a+cedilla+dot below+ring <a\u0327\u0323bz=Ⓗ # a+cedilla+dot below+b+z &\U0001D158=⁰ # musical notehead black (has a symbol primary) <\U0001D158\U0001D165=¼ # musical quarter note # deliberately missing prefix contractions: # dz # a\u0327 # a\u0327\u0323 # a\u0327\u0323b &\x01 <<<\U0001D165=¹ # musical stem (ccc=216) <<<\U0001D16D=² # musical augmentation dot (ccc=226) <<<\U0001D165\U0001D16D=³ # stem+dot (ccc=216 226) &\u0301=❶ # acute (ccc=230) &\u030a=❷ # ring (ccc=230) &\u0308=❸ # diaeresis (ccc=230) <<\u0308\u0301=❹ # diaeresis+acute (=dialytika tonos) (ccc=230 230) &\u0327=❺ # cedilla (ccc=202) &\u0323=❻ # dot below (ccc=220) &\u0331=❼ # macron below (ccc=220) <<\u0331\u0358=❽ # macron below+dot above right (ccc=220 232) &\u0334=❾ # tilde overlay (ccc=1) &\u0358=❿ # dot above right (ccc=232) &\u0f71=① # tibetan vowel sign aa &\u0f72=② # tibetan vowel sign i # \u0f71\u0f72 # tibetan vowel sign aa + i = ii = U+0F73 &\u0f73=③ # tibetan vowel sign ii (ccc=0 but lccc=129) ** test: simple contractions # Some strings are chosen to cause incremental contiguous contraction matching to # go into partial matches for prefixes of contractions # (where the prefixes are deliberately not also contractions). # When there is no complete match, then the matching code must back out of those # so that discontiguous contractions work as specified. * compare # contraction starter with no following text, or mismatch, or blocked <1 a = ⓐ <1 aa = ⓐⓐ <1 ab = ⓐb <1 az = ⓐz * compare <1 a <2 a\u0308\u030a # ring blocked by diaeresis = ⓐ❸❷ <2 a\u0327 = ⓐ❺ * compare <2 \u0308 = ❸ <2 \u0308\u030a\u0301 # acute blocked by ring = ❸❷❶ * compare <1 \U0001D158 = ⁰ <1 \U0001D158\U0001D165 = ¼ # no discontiguous contraction because of missing prefix contraction d+z, # and a starter ('z') after the 'd' * compare <1 dz\u0323\u0301 = dz❻❶ # contiguous contractions * compare <1 abz = ⓐⓑ <1 abzz = ⓐⓑz * compare <1 a <1 z <1 a\u0301 = Ⓐ <1 a\u0301\u0301 = Ⓑ <1 a\u0301\u0301\u0358 = Ⓒ <1 a\u030a = Ⓓ <1 a\u0323\u0358 = Ⓕ <1 a\u0327\u0323\u030a # match despite missing prefix = Ⓖ <1 a\u0327\u0323bz = Ⓗ * compare <2 \u0308\u0308\u0301 # acute blocked from first diaeresis, contracts with second = ❸❹ * compare <1 \U0001D158\U0001D165 = ¼ * compare <3 \U0001D165\U0001D16D = ³ ** test: discontiguous contractions * compare <1 a\u0327\u030a # a+ring skips cedilla = Ⓓ❺ <2 a\u0327\u0327\u030a # a+ring skips 2 cedillas = Ⓓ❺❺ <2 a\u0327\u0327\u0327\u030a # a+ring skips 3 cedillas = Ⓓ❺❺❺ <2 a\u0334\u0327\u0327\u030a # a+ring skips tilde overlay & 2 cedillas = Ⓓ❾❺❺ <1 a\u0327\u0323 # a+dot below skips cedilla = Ⓔ❺ <1 a\u0323\u0301\u0358 # a+dot below+dot ab.r.: 2-char match, then skips acute = Ⓕ❶ <2 a\u0334\u0323\u0358 # a+dot below skips tilde overlay = Ⓕ❾ * compare <2 \u0331\u0331\u0358 # macron below+dot ab.r. skips the second macron below = ❽❼ * compare <1 a\u0327\u0331\u0323\u030a # a+ring skips cedilla, macron below, dot below (dot blocked by macron) = Ⓓ❺❼❻ <1 a\u0327\u0323\U0001D16D\u030a # a+dot below skips cedilla = Ⓔ❺²❷ <2 a\u0327\u0327\u0323\u030a # a+dot below skips 2 cedillas = Ⓔ❺❺❷ <2 a\u0327\u0323\u0323\u030a # a+dot below skips cedilla = Ⓔ❺❻❷ <2 a\u0334\u0327\u0323\u030a # a+dot below skips tilde overlay & cedilla = Ⓔ❾❺❷ * compare <1 \U0001D158\u0327\U0001D165 # quarter note skips cedilla = ¼❺ <1 a\U0001D165\u0323 # a+dot below skips stem = Ⓔ¹ # partial contiguous match, backs up, matches discontiguous contraction <1 a\u0327\u0323b = Ⓔ❺b <1 a\u0327\u0323ba = Ⓔ❺bⓐ # a+acute+acute+dot above right skips cedilla, continues matching 2 same-ccc combining marks * compare <1 a\u0327\u0301\u0301\u0358 = Ⓒ❺ # FCD but not NFD * compare <1 a\u0f73\u0301 # a+acute skips tibetan ii = Ⓐ③ # FCD but the 0f71 inside the 0f73 must be skipped # to match the discontiguous contraction of the first 0f71 with the trailing 0f72 inside the 0f73 * compare <1 \u0f71\u0f73 # == \u0f73\u0f71 == \u0f71\u0f71\u0f72 = ③① ** test: discontiguous contractions with nested contractions * compare <1 a\u0323\u0308\u0301\u0358 = Ⓕ❹ <2 a\u0323\u0308\u0301\u0308\u0301\u0358 = Ⓕ❹❹ ** test: discontiguous contractions with interleaved contractions * compare # a+ring & cedilla & macron below+dot above right <1 a\u0327\u0331\u030a\u0358 = Ⓓ❺❽ # a+ring & 1x..3x macron below+dot above right <2 a\u0331\u030a\u0358 = Ⓓ❽ <2 a\u0331\u0331\u030a\u0358\u0358 = Ⓓ❽❽ # also skips acute <2 a\u0331\u0331\u0331\u030a\u0301\u0358\u0358\u0358 = Ⓓ❽❽❽❶ # a+dot below & stem+augmentation dot, followed by contiguous d+z+acute <1 a\U0001D165\u0323\U0001D16Ddz\u0301 = Ⓔ³ⓓ ** test: some simple string comparisons @ root * compare # first string compares against "" = \u0000 < a <1 b <3 B = \u0000B\u0000 ** test: compare with strength=primary % strength=primary * compare <1 a <1 b = B ** test: compare with strength=secondary % strength=secondary * compare <1 a <1 b = B ** test: compare with strength=tertiary % strength=tertiary * compare <1 a <1 b <3 B ** test: compare with strength=quaternary % strength=quaternary * compare <1 a <1 b <3 B ** test: compare with strength=identical % strength=identical * compare <1 a <1 b <3 B ** test: côté with forwards secondary @ root * compare <1 cote <2 coté <2 côte <2 côté ** test: côté with forwards secondary vs. U+FFFE merge separator # Merged sort keys: On each level, any difference in the first segment # must trump any further difference. * compare <1 cote\uFFFEcôté <2 coté\uFFFEcôte <2 côte\uFFFEcoté <2 côté\uFFFEcote ** test: côté with backwards secondary % backwards=on * compare <1 cote <2 côte <2 coté <2 côté ** test: côté with backwards secondary vs. U+FFFE merge separator # Merged sort keys: On each level, any difference in the first segment # must trump any further difference. * compare <1 cote\uFFFEcôté <2 côte\uFFFEcoté <2 coté\uFFFEcôte <2 côté\uFFFEcote ** test: U+FFFE on identical level @ root % strength=identical * compare # All of these control codes are completely-ignorable, so that # their low code points are compared with the merge separator. # The merge separator must compare less than any other character. <1 \uFFFE\u0001\u0002\u0003 <i \u0001\uFFFE\u0002\u0003 <i \u0001\u0002\uFFFE\u0003 <i \u0001\u0002\u0003\uFFFE * compare # The merge separator must even compare less than U+0000. <1 \uFFFE\u0000\u0000 <i \u0000\uFFFE\u0000 <i \u0000\u0000\uFFFE ** test: Hani < surrogates < U+FFFD # Note: compareUTF8() treats unpaired surrogates like U+FFFD, # so with that the strings with surrogates will compare equal to each other # and equal to the string with U+FFFD. @ root % strength=identical * compare <1 abz <1 a\u4e00z <1 a\U00020000z <1 a\ud800z <1 a\udbffz <1 a\udc00z <1 a\udfffz <1 a\ufffdz ** test: script reordering @ root % reorder Hani Zzzz digit * compare <1 ? <1 + <1 丂 <1 a <1 α <1 5 % reorder default * compare <1 ? <1 + <1 5 <1 a <1 α <1 丂 ** test: empty rules @ rules * compare <1 a <2 ä <3 Ä <1 b ** test: very simple rules @ rules &a=e<<<<q<<<<r<x<<<X<<y<<<Y;z,Z % strength=quaternary * compare <1 a = e <4 q <4 r <1 x <3 X <2 y <3 Y <2 z <3 Z ** test: tailoring twice before a root position: primary @ rules &[before 1]b<p &[before 1]b<q * compare <1 a <1 p <1 q <1 b ** test: tailoring twice before a root position: secondary @ rules &[before 2]ſ<<p &[before 2]ſ<<q * compare <1 s <2 p <2 q <2 ſ # secondary-before common weight @ rules &[before 2]b<<p &[before 2]b<<q * compare <1 a <1 p <2 q <2 b ** test: tailoring twice before a root position: tertiary @ rules &[before 3]B<<<p &[before 3]B<<<q * compare <1 b <3 p <3 q <3 B # tertiary-before common weight @ rules &[before 3]b<<<p &[before 3]b<<<q * compare <1 a <1 p <3 q <3 b @ rules &[before 2]b<<s &[before 3]s<<<p &[before 3]s<<<q * compare <1 a <1 p <3 q <3 s <2 b ** test: tailor after completely ignorable @ rules &\x00<<<x<<y * compare = \x00 = \x1F <3 x <2 y ** test: secondary tailoring gaps, ICU ticket 9362 @ rules &[before 2]s<<'_' &s<<r # secondary between s and ſ (long s) &ſ<<*a-q # more than 15 between ſ and secondary CE boundary &[before 2][first primary ignorable]<<u<<v # between secondary CE boundary & lowest secondary CE &[last primary ignorable]<<y<<z * compare <2 u <2 v <2 \u0332 # lowest secondary CE <2 \u0308 <2 y <2 z <1 s_ <2 ss <2 sr <2 sſ <2 sa <2 sb <2 sp <2 sq <2 sus <2 svs <2 rs ** test: tertiary tailoring gaps, ICU ticket 9362 @ rules &[before 3]t<<<'_' &t<<<r # tertiary between t and fullwidth t &ᵀ<<<*a-q # more than 15 between ᵀ (modifier letter T) and tertiary CE boundary &[before 3][first secondary ignorable]<<<u<<<v # between tertiary CE boundary & lowest tertiary CE &[last secondary ignorable]<<<y<<<z * compare <3 u <3 v # Note: The root collator currently does not map any characters to tertiary CEs. <3 y <3 z <1 t_ <3 tt <3 tr <3 tt <3 tᵀ <3 ta <3 tb <3 tp <3 tq <3 tut <3 tvt <3 rt ** test: secondary & tertiary around root character @ rules &[before 2]m<<r &m<<s &[before 3]m<<<u &m<<<v * compare <1 l <1 r <2 u <3 m <3 v <2 s <1 n ** test: secondary & tertiary around tailored item @ rules &m<x &[before 2]x<<r &x<<s &[before 3]x<<<u &x<<<v * compare <1 m <1 r <2 u <3 x <3 v <2 s <1 n ** test: more nesting of secondary & tertiary before @ rules &[before 3]m<<<u &[before 2]m<<r &[before 3]r<<<q &m<<<w &m<<t &[before 3]w<<<v &w<<<x &w<<s * compare <1 l <1 q <3 r <2 u <3 m <3 v <3 w <3 x <2 s <2 t <1 n ** test: case bits @ rules &w<x # tailored CE getting case bits =uv=uV=Uv=UV # 2 chars -> 1 CE &ae=ch=cH=Ch=CH # 2 chars -> 2 CEs &rst=yz=yZ=Yz=YZ # 2 chars -> 3 CEs % caseFirst=lower * compare <1 ae = ch <3 cH <3 Ch <3 CH <1 rst = yz <3 yZ <3 Yz <3 YZ <1 w <1 x = uv <3 uV = Uv # mixed case on single CE cannot distinguish variations <3 UV ** test: tertiary CEs, tertiary, caseLevel=off, caseFirst=lower @ rules &\u0001<<<t<<<T # tertiary CEs % caseFirst=lower * compare <1 aa <3 aat <3 aaT <3 aA <3 aAt <3 ata <3 aTa ** test: tertiary CEs, tertiary, caseLevel=off, caseFirst=upper % caseFirst=upper * compare <1 aA <3 aAt <3 aa <3 aat <3 aaT <3 ata <3 aTa ** test: reset on expansion, ICU tickets 9415 & 9593 @ rules &æ<x # tailor the last primary CE so that x sorts between ae and af &æb=bæ # copy all reset CEs to make bæ sort the same &각<h # copy/tailor 3 CEs to make h sort before the next Hangul syllable 갂 &⒀<<y # copy/tailor 4 CEs to make y sort with only a secondary difference &l·=z # handle the pre-context for · when fetching reset CEs <<u # copy/tailor 2 CEs * compare <1 ae <2 æ <1 x <1 af * compare <1 aeb <2 æb = bæ * compare <1 각 <1 h <1 갂 <1 갃 * compare <1 · # by itself: primary CE <1 l <2 l· # l+middle dot has only a secondary difference from l = z <2 u * compare <1 (13) <3 ⒀ # DUCET sets special tertiary weights in all CEs <2 y <1 (13[ % alternate=shifted * compare <1 (13) = 13 <3 ⒀ = y # alternate=shifted removes the tailoring difference on the last CE <1 14 ** test: contraction inside extension, ICU ticket 9378 @ rules &а<<х/й # all letters are Cyrillic * compare <1 ай <2 х ** test: no duplicate tailored CEs for different reset positions with same CEs, ICU ticket 10104 @ rules &t<x &ᵀ<y # same primary weights &q<u &[before 1]ꝗ<v # q and ꝗ are primary adjacent * compare <1 q <1 u <1 v <1 ꝗ <1 t <3 ᵀ <1 y <1 x # Principle: Each rule builds on the state of preceding rules and ignores following rules. ** test: later rule does not affect earlier reset position, ICU ticket 10105 @ rules &a < u < v < w &ov < x &b < v * compare <1 oa <1 ou <1 x # CE(o) followed by CE between u and w <1 ow <1 ob <1 ov ** test: later rule does not affect earlier extension (1), ICU ticket 10105 @ rules &a=x/b &v=b % strength=secondary * compare <1 B <1 c <1 v = b * compare <1 AB = x <1 ac <1 av = ab ** test: later rule does not affect earlier extension (2), ICU ticket 10105 @ rules &a <<< c / e &g <<< e / l % strength=secondary * compare <1 AE = c <2 æ <1 agl = ae ** test: later rule does not affect earlier extension (3), ICU ticket 10105 @ rules &a = b / c &d = c / e % strength=secondary * compare <1 AC # C is still only tertiary different from the original c = b <1 ade = ac ** test: extension contains tailored character, ICU ticket 10105 @ rules &a=e &b=u/e * compare <1 a = e <1 ba = be = u ** test: add simple mappings for characters with root context @ rules &z=· # middle dot has a prefix mapping in the CLDR root &n=и # и (U+0438) has contractions in the root * compare <1 l <2 l· # root mapping for l|· still works <1 z = · * compare <1 n = и <1 И <1 и\u0306 # root mapping for й=и\u0306 still works = й <3 Й ** test: add context mappings around characters with root context @ rules &z=·h # middle dot has a prefix mapping in the CLDR root &n=ә|и # и (U+0438) has contractions in the root * compare <1 l <2 l· # root mapping for l|· still works <1 z = ·h * compare <1 и <3 И <1 и\u0306 # root mapping for й=и\u0306 still works = й * compare <1 әn = әи <1 әo ** test: many secondary CEs at the top of their range @ rules &[last primary ignorable]<<*\u2801-\u28ff * compare <2 \u0308 <2 \u2801 <2 \u2802 <2 \u2803 <2 \u2804 <2 \u28fd <2 \u28fe <2 \u28ff <1 \x20 ** test: many tertiary CEs at the top of their range @ rules &[last secondary ignorable]<<<*a-z * compare <3 a <3 b <3 c <3 d # e..w <3 x <3 y <3 z <2 \u0308 ** test: tailor contraction together with nearly equivalent prefix, ICU ticket 10101 @ rules &a=p|x &b=px &c=op * compare <1 b = px <3 B <1 c = op <3 C * compare <1 ca = opx # first contraction op, then prefix p|x <3 cA <3 Ca ** test: reset position with prefix (pre-context), ICU ticket 10102 @ rules &a=p|x &px=y * compare <1 pa = px = y <3 pA <1 q <1 x ** test: prefix+contraction together (1), ICU ticket 10071 @ rules &x=a|bc * compare <1 ab <1 Abc <1 abd <1 ac <1 aw <1 ax = abc <3 aX <3 Ax <1 b <1 bb <1 bc <3 bC <3 Bc <1 bd ** test: prefix+contraction together (2), ICU ticket 10071 @ rules &w=bc &x=a|b * compare <1 w = bc <3 W * compare <1 aw <1 ax = ab <3 aX <1 axb <1 axc = abc # prefix match a|b takes precedence over contraction match bc <3 abC <1 abd <1 ay ** test: prefix+contraction together (3), ICU ticket 10071 @ rules &x=a|b &w=bc # reverse order of rules as previous test, order should not matter here * compare # same "compare" sequences as previous test <1 w = bc <3 W * compare <1 aw <1 ax = ab <3 aX <1 axb <1 axc = abc # prefix match a|b takes precedence over contraction match bc <3 abC <1 abd <1 ay ** test: no mapping p|c, falls back to contraction ch, CLDR ticket 5962 @ rules &d=ch &v=p|ci * compare <1 pc <3 pC <1 pcH <1 pcI <1 pd = pch # no-prefix contraction ch matches <3 pD <1 pv = pci # prefix+contraction p|ci matches <3 pV ** test: tailor in & around compact ranges of root primaries # The Ogham characters U+1681..U+169A are in simple ascending order of primary CEs # which should be reliably encoded as one range in the root elements data. @ rules &[before 1]ᚁ<a &ᚁ<b &[before 1]ᚂ<c &ᚂ<d &[before 1]ᚚ<y &ᚚ<z &[before 2]ᚁ<<r &ᚁ<<s &[before 3]ᚚ<<<t &ᚚ<<<u * compare <1 ᣵ # U+18F5 last Canadian Aboriginal <1 a <1 r <2 ᚁ <2 s <1 b <1 c <1 ᚂ <1 d <1 ᚃ <1 ᚙ <1 y <1 t <3 ᚚ <3 u <1 z <1 ᚠ # U+16A0 first Runic ** test: suppressContractions @ rules &z<ch<әж [suppressContractions [·cә]] * compare <1 ch <3 cH # ch was suppressed <1 l <1 l· # primary difference, not secondary, because l|· was suppressed <1 ә <2 ә\u0308 # secondary difference, not primary, because contractions for ә were suppressed <1 әж <3 әЖ ** test: Hangul & Jamo @ rules &L=\u1100 # first Jamo L &V=\u1161 # first Jamo V &T=\u11A8 # first Jamo T &\uAC01<<*\u4E00-\u4EFF # first Hangul LVT syllable & lots of secondary diffs * compare <1 Lv <3 LV = \u1100\u1161 = \uAC00 <1 LVt <3 LVT = \u1100\u1161\u11A8 = \uAC00\u11A8 = \uAC01 <2 LVT\u0308 <2 \u4E00 <2 \u4E01 <2 \u4E80 <2 \u4EFF <2 LV\u0308T <1 \uAC02 ** test: adjust special reset positions according to previous rules, CLDR ticket 6070 @ rules &[last variable]<x [maxVariable space] # has effect only after building, no effect on following rules &[last variable]<y &[before 1][first regular]<z * compare <1 ? # some punctuation <1 x <1 y <1 z <1 $ # some symbol @ rules &[last primary ignorable]<<x<<<y &[last primary ignorable]<<z * compare <2 \u0358 <2 x <3 y <2 z <1 \x20 @ rules &[last secondary ignorable]<<<x &[last secondary ignorable]<<<y * compare <3 x <3 y <2 \u0358 @ rules &[before 2][first variable]<<z &[before 2][first variable]<<y &[before 3][first variable]<<<x &[before 3][first variable]<<<w &[before 1][first variable]<v &[before 2][first variable]<<u &[before 3][first variable]<<<t &[before 2]\uFDD1\xA0<<s # FractionalUCA.txt: FDD1 00A0, SPACE first primary * compare <2 \u0358 <1 s <2 \uFDD1\xA0 <1 t <3 u <2 v <1 w <3 x <3 y <2 z <2 \t @ rules &[before 2][first regular]<<z &[before 3][first regular]<<<y &[before 1][first regular]<x &[before 3][first regular]<<<w &[before 2]\uFDD1\u263A<<v # FractionalUCA.txt: FDD1 263A, SYMBOL first primary &[before 3][first regular]<<<u &[before 1][first regular]<p # primary before the boundary: becomes variable &[before 3][first regular]<<<t # not affected by p &[last variable]<q # after p! * compare <1 ? <1 p <1 q <1 t <3 u <3 v <1 w <3 x <1 y <3 z <1 $ # check that p & q are indeed variable % alternate=shifted * compare = ? = p = q <1 t <3 u <3 v <1 w <3 x <1 y <3 z <1 $ @ rules &[before 2][first trailing]<<z &[before 1][first trailing]<y &[before 3][first trailing]<<<x * compare <1 \u4E00 # first Han, first implicit <1 \uFDD1\uFDD0 # FractionalUCA.txt: unassigned first primary # Note: The root collator currently does not map any characters to the trailing first boundary primary. <1 x <3 y <1 z <2 \uFFFD # The root collator currently maps U+FFFD to the first real trailing primary. @ rules &[before 2][first primary ignorable]<<z &[before 2][first primary ignorable]<<y &[before 3][first primary ignorable]<<<x &[before 3][first primary ignorable]<<<w * compare = \x01 <2 w <3 x <3 y <2 z <2 \u0301 @ rules &[before 3][first secondary ignorable]<<<y &[before 3][first secondary ignorable]<<<x * compare = \x01 <3 x <3 y <2 \u0301 ** test: canonical closure @ rules &X=A &U= * compare <1 U =  = A\u0302 <2 Ú # U with acute = U\u0301 = Ấ # A with circumflex & acute = Â\u0301 = A\u0302\u0301 <1 X = A <2 X\u030A # with ring above = Å = A\u030A = \u212B # Angstrom sign @ rules &x=\u5140\u55C0 * compare <1 x = \u5140\u55C0 = \u5140\uFA0D = \uFA0C\u55C0 = \uFA0C\uFA0D # CJK compatibility characters <3 X # canonical closure on prefix rules, ICU ticket 9444 @ rules &x=ä|ŝ * compare <1 äs # not tailored <1 äx = äŝ = a\u0308s\u0302 = a\u0308ŝ = äs\u0302 <3 äX ** test: conjoining Jamo map to expansions @ rules &gg=\u1101 # Jamo Lead consonant GG &nj=\u11AC # Jamo Trail consonant NJ * compare <1 gg\u1161nj = \u1101\u1161\u11AC = \uAE4C\u11AC = \uAE51 <3 gg\u1161nJ <1 \u1100\u1100 ** test: canonical tail closure, ICU ticket 5913 @ rules &a<â * compare <1 a <1 â # tailored = a\u0302 <2 a\u0323\u0302 # discontiguous contraction = ạ\u0302 # equivalent = ậ # equivalent <1 b @ rules &a<ạ * compare <1 a <1 ạ # tailored = a\u0323 <2 a\u0323\u0302 # contiguous contraction plus extra diacritic = ạ\u0302 # equivalent = ậ # equivalent <1 b # Tail closure should work even if there is a prefix and/or contraction. @ rules &a<\u5140|câ # In order to find discontiguous contractions for \u5140|câ # there must exist a mapping for \u5140|ca, regardless of what it maps to. # (This follows from the UCA spec.) &x=\u5140|ca * compare <1 \u5140a = \uFA0Ca <1 \u5140câ # tailored = \uFA0Ccâ = \u5140ca\u0302 = \uFA0Cca\u0302 <2 \u5140ca\u0323\u0302 # discontiguous contraction = \uFA0Cca\u0323\u0302 = \u5140cạ\u0302 = \uFA0Ccạ\u0302 = \u5140cậ = \uFA0Ccậ <1 \u5140b = \uFA0Cb <1 \u5140x = \u5140ca # Double-check that without the extra mapping there will be no discontiguous match. @ rules &a<\u5140|câ * compare <1 \u5140a = \uFA0Ca <1 \u5140câ # tailored = \uFA0Ccâ = \u5140ca\u0302 = \uFA0Cca\u0302 <1 \u5140b = \uFA0Cb <1 \u5140ca\u0323\u0302 # no discontiguous contraction = \uFA0Cca\u0323\u0302 = \u5140cạ\u0302 = \uFA0Ccạ\u0302 = \u5140cậ = \uFA0Ccậ @ rules &a<cạ * compare <1 a <1 cạ # tailored = ca\u0323 <2 ca\u0323\u0302 # contiguous contraction plus extra diacritic = cạ\u0302 # equivalent = cậ # equivalent <1 b # ᾢ = U+1FA2 GREEK SMALL LETTER OMEGA WITH PSILI AND VARIA AND YPOGEGRAMMENI # = 03C9 0313 0300 0345 # ccc = 0, 230, 230, 240 @ rules &δ=αῳ # In order to find discontiguous contractions for αῳ # there must exist a mapping for αω, regardless of what it maps to. # (This follows from the UCA spec.) &ε=αω * compare <1 δ = αῳ = αω\u0345 <2 αω\u0313\u0300\u0345 # discontiguous contraction = αὠ\u0300\u0345 = αὢ\u0345 = αᾢ <2 αω\u0300\u0313\u0345 = αὼ\u0313\u0345 = αῲ\u0313 # not FCD <1 ε = αω # Double-check that without the extra mapping there will be no discontiguous match. @ rules &δ=αῳ * compare <1 αω\u0313\u0300\u0345 # no discontiguous contraction = αὠ\u0300\u0345 = αὢ\u0345 = αᾢ <2 αω\u0300\u0313\u0345 = αὼ\u0313\u0345 = αῲ\u0313 # not FCD <1 δ = αῳ = αω\u0345 # Add U+0315 COMBINING COMMA ABOVE RIGHT which has ccc=232. # Tests code paths where the tailored string has a combining mark # that does not occur in any composite's decomposition. @ rules &δ=αὼ\u0315 * compare <1 αω\u0313\u0300\u0315 # Not tailored: The grave accent blocks the comma above. = αὠ\u0300\u0315 = αὢ\u0315 <1 δ = αὼ\u0315 = αω\u0300\u0315 <2 αω\u0300\u0315\u0345 = αὼ\u0315\u0345 = αῲ\u0315 # not FCD ** test: danish a+a vs. a-umlaut, ICU ticket 9319 @ rules &z<aa * compare <1 z <1 aa <2 aa\u0308 = aä ** test: Jamo L with and in prefix # Useful for the Korean "searchjl" tailoring (instead of contractions of pairs of Jamo L). @ rules # Jamo Lead consonant G after G or GG &[last primary ignorable]<<\u1100|\u1100=\u1101|\u1100 # Jamo Lead consonant GG sorts like G+G &\u1100\u1100=\u1101 # Note: Making G|GG and GG|GG sort the same as G|G+G # would require the ability to reset on G|G+G, # or we could make G-after-G equal to some secondary-CE character, # and reset on a pair of those. # (It does not matter much if there are at most two G in a row in real text.) * compare <1 \u1100 <2 \u1100\u1100 # only one primary from a sequence of G lead consonants = \u1101 <2 \u1100\u1100\u1100 = \u1101\u1100 # but not = \u1100\u1101, see above <1 \u1100\u1161 = \uAC00 <2 \u1100\u1100\u1161 = \u1100\uAC00 # prefix match from the L of the LV syllable = \u1101\u1161 = \uAE4C ** test: proposed Korean "searchjl" tailoring with prefixes, CLDR ticket 6546 @ rules # Low secondary CEs for Jamo V & T. # Note: T should sort before V for proper syllable order. &\u0332 # COMBINING LOW LINE (first primary ignorable) <<\u1161<<\u1162 # Korean Jamo lead consonant search rules, part 2: # Make modern compound L jamo primary equivalent to non-compound forms. # Secondary CEs for Jamo L-after-L, greater than Jamo V & T. &\u0313 # COMBINING COMMA ABOVE (second primary ignorable) =\u1100|\u1100 =\u1103|\u1103 =\u1107|\u1107 =\u1109|\u1109 =\u110C|\u110C # Compound L Jamo map to equivalent expansions of primary+secondary CE. &\u1100\u0313=\u1101<<<\u3132 # HANGUL CHOSEONG SSANGKIYEOK, HANGUL LETTER SSANGKIYEOK &\u1103\u0313=\u1104<<<\u3138 # HANGUL CHOSEONG SSANGTIKEUT, HANGUL LETTER SSANGTIKEUT &\u1107\u0313=\u1108<<<\u3143 # HANGUL CHOSEONG SSANGPIEUP, HANGUL LETTER SSANGPIEUP &\u1109\u0313=\u110A<<<\u3146 # HANGUL CHOSEONG SSANGSIOS, HANGUL LETTER SSANGSIOS &\u110C\u0313=\u110D<<<\u3149 # HANGUL CHOSEONG SSANGCIEUC, HANGUL LETTER SSANGCIEUC * compare <1 \u1100\u1161 = \uAC00 <2 \u1100\u1162 = \uAC1C <2 \u1100\u1100\u1161 = \u1100\uAC00 = \u1101\u1161 = \uAE4C <3 \u3132\u1161 ** test: Hangul syllables in prefix & in the interior of a contraction @ rules &x=\u1100\u1161|a\u1102\u1162z * compare <1 \u1100\u1161x = \u1100\u1161a\u1102\u1162z = \u1100\u1161a\uB0B4z = \uAC00a\u1102\u1162z = \uAC00a\uB0B4z ** test: digits are unsafe-backwards when numeric=on @ root % numeric=on * compare # If digits are not unsafe, then numeric collation sees "1"=="01" and "b">"a". # We need to back up before the identical prefix "1" and compare the full numbers. <1 11b <1 101a ** test: simple locale data test @ locale de * compare <1 a <2 ä <1 ae <2 æ @ locale de-u-co-phonebk * compare <1 a <1 ae <2 ä <2 æ # The following test cases were moved here from ICU 52's DataDrivenCollationTest.txt. ** test: DataDrivenCollationTest/TestMorePinyin # Testing the primary strength. @ locale zh % strength=primary * compare < lā = lĀ = Lā = LĀ < lān = lĀn < lē = lĒ = Lē = LĒ < lēn = lĒn ** test: DataDrivenCollationTest/TestLithuanian # Lithuanian sort order. @ locale lt * compare < cz < č < d < iz < j < sz < š < t < zz < ž ** test: DataDrivenCollationTest/TestLatvian # Latvian sort order. @ locale lv * compare < cz < č < d < gz < ģ < h < iz < j < kz < ķ < l < lz < ļ < m < nz < ņ < o < rz < ŗ < s < sz < š < t < zz < ž ** test: DataDrivenCollationTest/TestEstonian # Estonian sort order. @ locale et * compare < sy < š < šy < z < zy < ž < v < va < w < õ < õy < ä < äy < ö < öy < ü < üy < x ** test: DataDrivenCollationTest/TestAlbanian # Albanian sort order. @ locale sq * compare < cz < ç < d < dz < dh < e < ez < ë < f < gz < gj < h < lz < ll < m < nz < nj < o < rz < rr < s < sz < sh < t < tz < th < u < xz < xh < y < zz < zh ** test: DataDrivenCollationTest/TestSimplifiedChineseOrder # Sorted file has different order. @ root # normalization=on turned on & off automatically. * compare < \u5F20 < \u5F20\u4E00\u8E3F ** test: DataDrivenCollationTest/TestTibetanNormalizedIterativeCrash # This pretty much crashes. @ root * compare < \u0f71\u0f72\u0f80\u0f71\u0f72 < \u0f80 ** test: DataDrivenCollationTest/TestThaiPartialSortKeyProblems # These are examples of strings that caused trouble in partial sort key testing. @ locale th-TH * compare < \u0E01\u0E01\u0E38\u0E18\u0E20\u0E31\u0E13\u0E11\u0E4C < \u0E01\u0E01\u0E38\u0E2A\u0E31\u0E19\u0E42\u0E18 * compare < \u0E01\u0E07\u0E01\u0E32\u0E23 < \u0E01\u0E07\u0E42\u0E01\u0E49 * compare < \u0E01\u0E23\u0E19\u0E17\u0E32 < \u0E01\u0E23\u0E19\u0E19\u0E40\u0E0A\u0E49\u0E32 * compare < \u0E01\u0E23\u0E30\u0E40\u0E08\u0E35\u0E22\u0E27 < \u0E01\u0E23\u0E30\u0E40\u0E08\u0E35\u0E4A\u0E22\u0E27 * compare < \u0E01\u0E23\u0E23\u0E40\u0E0A\u0E2D < \u0E01\u0E23\u0E23\u0E40\u0E0A\u0E49\u0E32 ** test: DataDrivenCollationTest/TestJavaStyleRule # java.text allows rules to start as '<<<x<<<y...' # we emulate this by assuming a &[first tertiary ignorable] in this case. @ rules &\u0001=equal<<<z<<x<<<w &[first tertiary ignorable]=a &[first primary ignorable]=b * compare = a = equal < z < x = b # x had become the new first primary ignorable < w ** test: DataDrivenCollationTest/TestShiftedIgnorable # The UCA states that primary ignorables should be completely # ignorable when following a shifted code point. @ root % alternate=shifted % strength=quaternary * compare < a\u0020b = a\u0020\u0300b = a\u0020\u0301b < a_b = a_\u0300b = a_\u0301b < A\u0020b = A\u0020\u0300b = A\u0020\u0301b < A_b = A_\u0300b = A_\u0301b < a\u0301b < A\u0301b < a\u0300b < A\u0300b ** test: DataDrivenCollationTest/TestNShiftedIgnorable # The UCA states that primary ignorables should be completely # ignorable when following a shifted code point. @ root % alternate=non-ignorable % strength=tertiary * compare < a\u0020b < A\u0020b < a\u0020\u0301b < A\u0020\u0301b < a\u0020\u0300b < A\u0020\u0300b < a_b < A_b < a_\u0301b < A_\u0301b < a_\u0300b < A_\u0300b < a\u0301b < A\u0301b < a\u0300b < A\u0300b ** test: DataDrivenCollationTest/TestSafeSurrogates # It turned out that surrogates were not skipped properly # when iterating backwards if they were in the middle of a # contraction. This test assures that this is fixed. @ rules &a < x\ud800\udc00b * compare < a < x\ud800\udc00b ** test: DataDrivenCollationTest/da_TestPrimary # This test goes through primary strength cases @ locale da % strength=primary * compare < Lvi < Lwi * compare < L\u00e4vi < L\u00f6wi * compare < L\u00fcbeck = Lybeck ** test: DataDrivenCollationTest/da_TestTertiary # This test goes through tertiary strength cases @ locale da % strength=tertiary * compare < Luc < luck * compare < luck < L\u00fcbeck * compare < lybeck < L\u00fcbeck * compare < L\u00e4vi < L\u00f6we * compare < L\u00f6ww < mast * compare < A/S < ANDRE < ANDR\u00c9 < ANDREAS < AS < CA < \u00c7A < CB < \u00c7C < D.S.B. < DA < \u00d0A < DB < \u00d0C < DSB < DSC < EKSTRA_ARBEJDE < EKSTRABUD0 < H\u00d8ST < HAAG < H\u00c5NDBOG < HAANDV\u00c6RKSBANKEN < Karl < karl < NIELS\u0020J\u00d8RGEN < NIELS-J\u00d8RGEN < NIELSEN < R\u00c9E,\u0020A < REE,\u0020B < R\u00c9E,\u0020L < REE,\u0020V < SCHYTT,\u0020B < SCHYTT,\u0020H < SCH\u00dcTT,\u0020H < SCHYTT,\u0020L < SCH\u00dcTT,\u0020M < SS < \u00df < SSA < STORE\u0020VILDMOSE < STOREK\u00c6R0 < STORM\u0020PETERSEN < STORMLY < THORVALD < THORVARDUR < \u00feORVAR\u00d0UR < THYGESEN < VESTERG\u00c5RD,\u0020A < VESTERGAARD,\u0020A < VESTERG\u00c5RD,\u0020B < \u00c6BLE < \u00c4BLE < \u00d8BERG < \u00d6BERG * compare < andere < chaque < chemin < cote < cot\u00e9 < c\u00f4te < c\u00f4t\u00e9 < \u010du\u010d\u0113t < Czech < hi\u0161a < irdisch < lie < lire < llama < l\u00f5ug < l\u00f2za < lu\u010d < luck < L\u00fcbeck < lye < l\u00e4vi < L\u00f6wen < m\u00e0\u0161ta < m\u00eer < myndig < M\u00e4nner < m\u00f6chten < pi\u00f1a < pint < pylon < \u0161\u00e0ran < savoir < \u0160erb\u016bra < Sietla < \u015blub < subtle < symbol < s\u00e4mtlich < verkehrt < vox < v\u00e4ga < waffle < wood < yen < yuan < yucca < \u017eal < \u017eena < \u017den\u0113va < zoo0 < Zviedrija < Z\u00fcrich < zysk0 < \u00e4ndere ** test: DataDrivenCollationTest/hi_TestNewRules # This test goes through new rules and tests against old rules @ locale hi * compare < कॐ < कं < कँ < कः ** test: DataDrivenCollationTest/ro_TestNewRules # This test goes through new rules and tests against old rules @ locale ro * compare < xAx < xă < xĂ < Xă < XĂ < xăx < xĂx < xâ < x < Xâ < X < xâx < xÂx < xb < xIx < xî < xÎ < Xî < XÎ < xîx < xÎx < xj < xSx < xș = xş < xȘ = xŞ < Xș = Xş < XȘ = XŞ < xșx = xşx < xȘx = xŞx < xT < xTx < xț = xţ < xȚ = xŢ < Xț = Xţ < XȚ = XŢ < xțx = xţx < xȚx = xŢx < xU ** test: DataDrivenCollationTest/testOffsets # This tests cases where forwards and backwards iteration get different offsets @ locale en % strength=tertiary * compare < a\uD800\uDC00\uDC00 < b\uD800\uDC00\uDC00 * compare < \u0301A\u0301\u0301 < \u0301B\u0301\u0301 * compare < abcd\r\u0301 < abce\r\u0301 # TODO: test offsets in new CollationTest # End of test cases moved here from ICU 52's DataDrivenCollationTest.txt. ** test: was ICU 52 cmsccoll/TestRedundantRules @ rules & a < b < c < d& [before 1] c < m * compare <1 a <1 b <1 m <1 c <1 d @ rules & a < b <<< c << d <<< e& [before 3] e <<< x * compare <1 a <1 b <3 c <2 d <3 x <3 e @ rules & a < b <<< c << d <<< e <<< f < g& [before 1] g < x * compare <1 a <1 b <3 c <2 d <3 e <3 f <1 x <1 g @ rules & a <<< b << c < d& a < m * compare <1 a <3 b <2 c <1 m <1 d @ rules &a<b<<b\u0301 &z<b * compare <1 a <1 b\u0301 <1 z <1 b @ rules &z<m<<<q<<<m * compare <1 z <1 q <3 m @ rules &z<<<m<q<<<m * compare <1 z <1 q <3 m @ rules & a < b < c < d& r < c * compare <1 a <1 b <1 d <1 r <1 c @ rules & a < b < c < d& c < m * compare <1 a <1 b <1 c <1 m <1 d @ rules & a < b < c < d& a < m * compare <1 a <1 m <1 b <1 c <1 d ** test: was ICU 52 cmsccoll/TestExpansionSyntax # The following two rules should sort the particular list of strings the same. @ rules &AE <<< a << b <<< c &d <<< f * compare <1 AE <3 a <2 b <3 c <1 d <3 f @ rules &A <<< a / E << b / E <<< c /E &d <<< f * compare <1 AE <3 a <2 b <3 c <1 d <3 f # The following two rules should sort the particular list of strings the same. @ rules &AE <<< a <<< b << c << d < e < f <<< g * compare <1 AE <3 a <3 b <2 c <2 d <1 e <1 f <3 g @ rules &A <<< a / E <<< b / E << c / E << d / E < e < f <<< g * compare <1 AE <3 a <3 b <2 c <2 d <1 e <1 f <3 g # The following two rules should sort the particular list of strings the same. @ rules &AE <<< B <<< C / D <<< F * compare <1 AE <3 B <3 F <1 AED <3 C @ rules &A <<< B / E <<< C / ED <<< F / E * compare <1 AE <3 B <3 F <1 AED <3 C ** test: never reorder trailing primaries @ root % reorder Zzzz Grek * compare <1 L <1 字 <1 Ω <1 \uFFFD <1 \uFFFF ** test: fall back to mappings with shorter prefixes, not immediately to ones with no prefixes @ rules &u=ab|cd &v=b|ce * compare <1 abc <1 abcc <1 abcf <1 abcd = abu <1 abce = abv # With the following rules, there is only one prefix per composite ĉ or ç, # but both prefixes apply to just c in NFD form. # We would get different results for composed vs. NFD input # if we fell back directly from longest-prefix mappings to no-prefix mappings. @ rules &x=op|ĉ &y=p|ç * compare <1 opc <2 opć <1 opcz <1 opd <1 opĉ = opc\u0302 = opx <1 opç = opc\u0327 = opy # The mapping is used which has the longest matching prefix for which # there is also a suffix match, with the longest suffix match among several for that prefix. @ rules &❶=d &❷=de &❸=def &①=c|d &②=c|de &③=c|def &④=bc|d &⑤=bc|de &⑥=bc|def &⑦=abc|d &⑧=abc|de &⑨=abc|def * compare <1 9aadzz = 9aa❶zz <1 9aadez = 9aa❷z <1 9aadef = 9aa❸ <1 9acdzz = 9ac①zz <1 9acdez = 9ac②z <1 9acdef = 9ac③ <1 9bcdzz = 9bc④zz <1 9bcdez = 9bc⑤z <1 9bcdef = 9bc⑥ <1 abcdzz = abc⑦zz <1 abcdez = abc⑧z <1 abcdef = abc⑨ ** test: prefix + discontiguous contraction with missing prefix contraction # Unfortunate terminology: The first "prefix" here is the pre-context, # the second "prefix" refers to the contraction/relation string that is # one shorter than the one being tested. @ rules &x=p|e &y=p|ê &z=op|ê # No mapping for op|e: # Discontiguous contraction matching should not match op|ê in opệ # because it would have to skip the dot below and extend a match on op|e by the circumflex, # but there is no match on op|e. * compare <1 oPe <1 ope = opx <1 opệ = opy\u0323 # y not z <1 opê = opz # We cannot test for fallback by whether the contraction default CE32 # is for another contraction. With the following rules, there is no mapping for op|e, # and the fallback to prefix p has no contractions. @ rules &x=p|e &z=op|ê * compare <1 oPe <1 ope = opx <2 opệ = opx\u0323\u0302 # x not z <1 opê = opz # One more variation: Fallback to the simple code point, no shorter non-empty prefix. @ rules &x=e &z=op|ê * compare <1 ope = opx <3 oPe = oPx <2 opệ = opx\u0323\u0302 # x not z <1 opê = opz ** test: maxVariable via rules @ rules [maxVariable space][alternate shifted] * compare = \u0020 = \u000A <1 . <1 ° # degree sign <1 $ <1 0 ** test: maxVariable via setting @ root % maxVariable=currency % alternate=shifted * compare = \u0020 = \u000A = . = ° # degree sign = $ <1 0 ** test: ICU4J CollationMiscTest/TestContractionClosure (ää) # This tests canonical closure, but it also tests that CollationFastLatin # bails out properly for contractions with combining marks. # For that we need pairs of strings that remain in the Latin fastpath # long enough, hence the extra "= b" lines. @ rules &b=\u00e4\u00e4 * compare <1 b = \u00e4\u00e4 = b = a\u0308a\u0308 = b = \u00e4a\u0308 = b = a\u0308\u00e4 ** test: ICU4J CollationMiscTest/TestContractionClosure (Å) @ rules &b=\u00C5 * compare <1 b = \u00C5 = b = A\u030A = b = \u212B ** test: reset-before on already-tailored characters, ICU ticket 10108 @ rules &a<w<<x &[before 2]x<<y * compare <1 a <1 w <2 y <2 x @ rules &a<<w<<<x &[before 2]x<<y * compare <1 a <2 y <2 w <3 x @ rules &a<w<x &[before 2]x<<y * compare <1 a <1 w <1 y <2 x @ rules &a<w<<<x &[before 2]x<<y * compare <1 a <1 y <2 w <3 x ** test: numeric collation with other settings, ICU ticket 9092 @ root % strength=identical % caseFirst=upper % numeric=on * compare <1 100\u0020a <1 101 ** test: collation type fallback from unsupported type, ICU ticket 10149 @ locale fr-CA-u-co-phonebk # Expect the same result as with fr-CA, using backwards-secondary order. # That is, we should fall back from the unsupported collation type # to the locale's default collation type. * compare <1 cote <2 côte <2 coté <2 côté ** test: @ is equivalent to [backwards 2], ICU ticket 9956 @ rules &b<a @ &v<<w * compare <1 b <1 a <1 cote <2 côte <2 coté <2 côté <1 v <2 w <1 x ** test: shifted+reordering, ICU ticket 9507 @ root % reorder Grek punct space % alternate=shifted % strength=quaternary # Which primaries are "variable" should be determined without script reordering, # and then primaries should be reordered whether they are shifted to quaternary or not. * compare <4 ( # punctuation <4 ) <4 \u0020 # space <1 ` # symbol <1 ^ <1 $ # currency symbol <1 € <1 0 # numbers <1 ε # Greek <1 e # Latin <1 e(e <4 e)e <4 e\u0020e <4 ee <3 e(E <4 e)E <4 e\u0020E <4 eE ** test: "uppercase first" could sort a string before its prefix, ICU ticket 9351 @ rules &\u0001<<<b<<<B % caseFirst=upper * compare <1 aaa <3 aaaB ** test: secondary+case ignores secondary ignorables, ICU ticket 9355 @ rules &\u0001<<<b<<<B % strength=secondary % caseLevel=on * compare <1 a = ab = aB ** test: custom collation rules involving tail of a contraction in Malayalam, ICU ticket 6328 @ rules &[before 2] ൌ << ൗ # U+0D57 << U+0D4C == 0D46+0D57 * compare <1 ൗx <2 ൌx <1 ൗy <2 ൌy ** test: quoted apostrophe in compact syntax, ICU ticket 8204 @ rules &q<<*a''c * compare <1 d <1 p <1 q <2 a <2 \u0027 <2 c <1 r # ICU ticket #8260 "Support all collation-related keywords in Collator.getInstance()" ** test: locale -u- with collation keywords, ICU ticket 8260 @ locale de-u-kv-sPace-ka-shifTed-kn-kk-falsE-kf-Upper-kc-tRue-ks-leVel4 * compare <4 \u0020 # space is shifted, strength=quaternary <1 ! # punctuation is regular <1 2 <1 12 # numeric sorting <1 B <c b # uppercase first on case level <1 x\u0301\u0308 <2 x\u0308\u0301 # normalization off ** test: locale @ with collation keywords, ICU ticket 8260 @ locale fr@colbAckwards=yes;ColStrength=Quaternary;kv=currencY;colalternate=shifted * compare <4 $ # currency symbols are shifted, strength=quaternary <1 àla <2 alà # backwards secondary level ** test: locale -u- with script reordering, ICU ticket 8260 @ locale el-u-kr-kana-SYMBOL-Grek-hani-cyrl-latn-digit-armn-deva-ethi-thai * compare <1 \u0020 <1 あ <1 ☂ <1 Ω <1 丂 <1 ж <1 L <1 4 <1 Ձ <1 अ <1 ሄ <1 ฉ ** test: locale @collation=type should be case-insensitive @ locale de@coLLation=PhoneBook * compare <1 ae <2 ä <3 Ä ** test: import root search rules plus German phonebook rules, ICU ticket 8962 @ locale de-u-co-search * compare <1 = <1 ≠ <1 a <1 ae <2 ä # Once more, but with runtime builder. @ rules [import und-u-co-search][import de-u-co-phonebk] * compare <1 = <1 ≠ <1 a <1 ae <2 ä # Once again, with import from "root" not "und" (as in a proper language tag). @ rules [import root-u-co-search][import de-u-co-phonebk] * compare <1 = <1 ≠ <1 a <1 ae <2 ä ** test: import rules from a language with non-Latin native script, and reset the reordering, ICU ticket 10998 # Greek should sort Greek first. @ rules [import el] * compare <1 4 <1 Ω <1 L # Import Greek, and then reset the reordering. @ rules [import el][reorder Zzzz] * compare <1 4 <1 L <1 Ω # "others" is a synonym for Zzzz. @ rules [import el][reorder others] * compare <1 4 <1 L <1 Ω ** test: regression test for CollationFastLatinBuilder, ICU ticket 11388 @ rules &x<<aa<<<Aa<<<AA % strength=secondary * compare <1 AA <2 Aẩ <2 aą * compare <1 AA <2 aą ** test: tailor tertiary-after a common tertiary where there is a lower one # Assume that Hiragana small A has a below-common tertiary, and Hiragana A has a common one. # See ICU ticket 11448 & CLDR ticket 7222. @ rules &あ<<<x<<<y<<<z * compare <1 ぁ <3 あ <3 x <3 y <3 z <3 ァ <1 い ** test: tailor tertiary-after a below-common tertiary @ rules &ぁ<<<x<<<y<<<z * compare <1 ぁ <3 x <3 y <3 z <3 あ <3 ァ <1 い ** test: tailor tertiary-before a common tertiary where there is a lower one @ rules &[before 3]あ<<<x<<<y<<<z * compare <1 ぁ <3 x <3 y <3 z <3 あ <3 ァ <1 い ** test: tailor tertiary-before a below-common tertiary @ rules &[before 3]ぁ<<<x<<<y<<<z * compare <1 x <3 y <3 z <3 ぁ <3 あ <3 ァ <1 い ** test: reorder single scripts not groups, ICU ticket 11449 @ root % reorder Goth Latn * compare <1 4 <1 𐌰 # Gothic <1 L <1 Ω # Before ICU 55, the following reordered together with Gothic. <1 𐌈 # Old Italic <1 𐑐 # Shavian