| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 1 | # 2010 July 16 |
| 2 | # |
| 3 | # The author disclaims copyright to this source code. In place of |
| 4 | # a legal notice, here is a blessing: |
| 5 | # |
| 6 | # May you do good and not evil. |
| 7 | # May you find forgiveness for yourself and forgive others. |
| 8 | # May you share freely, never taking more than you give. |
| 9 | # |
| 10 | #*********************************************************************** |
| 11 | # |
| 12 | # This file implements tests to verify that the "testable statements" in |
| 13 | # the lang_expr.html document are correct. |
| 14 | # |
| 15 | |
| 16 | set testdir [file dirname $argv0] |
| 17 | source $testdir/tester.tcl |
| 18 | source $testdir/malloc_common.tcl |
| 19 | |
| dan | 4336cc4 | 2010-09-02 11:53:12 +0000 | [diff] [blame] | 20 | |
| 21 | proc do_expr_test {tn expr type value} { |
| 22 | uplevel do_execsql_test $tn [list "SELECT typeof($expr), $expr"] [ |
| 23 | list [list $type $value] |
| 24 | ] |
| 25 | } |
| 26 | |
| 27 | proc do_qexpr_test {tn expr value} { |
| 28 | uplevel do_execsql_test $tn [list "SELECT quote($expr)"] [list $value] |
| 29 | } |
| 30 | |
| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 31 | # Set up three global variables: |
| 32 | # |
| 33 | # ::opname An array mapping from SQL operator to an easy to parse |
| 34 | # name. The names are used as part of test case names. |
| 35 | # |
| 36 | # ::opprec An array mapping from SQL operator to a numeric |
| 37 | # precedence value. Operators that group more tightly |
| 38 | # have lower numeric precedences. |
| 39 | # |
| 40 | # ::oplist A list of all SQL operators supported by SQLite. |
| 41 | # |
| 42 | foreach {op opn} { |
| 43 | || cat * mul / div % mod + add |
| 44 | - sub << lshift >> rshift & bitand | bitor |
| 45 | < less <= lesseq > more >= moreeq = eq1 |
| 46 | == eq2 <> ne1 != ne2 IS is LIKE like |
| 47 | GLOB glob AND and OR or MATCH match REGEXP regexp |
| 48 | {IS NOT} isnt |
| 49 | } { |
| 50 | set ::opname($op) $opn |
| 51 | } |
| 52 | set oplist [list] |
| 53 | foreach {prec opl} { |
| 54 | 1 || |
| 55 | 2 {* / %} |
| 56 | 3 {+ -} |
| 57 | 4 {<< >> & |} |
| 58 | 5 {< <= > >=} |
| 59 | 6 {= == != <> IS {IS NOT} LIKE GLOB MATCH REGEXP} |
| 60 | 7 AND |
| 61 | 8 OR |
| 62 | } { |
| 63 | foreach op $opl { |
| 64 | set ::opprec($op) $prec |
| 65 | lappend oplist $op |
| 66 | } |
| 67 | } |
| 68 | |
| 69 | |
| 70 | # Hook in definitions of MATCH and REGEX. The following implementations |
| 71 | # cause MATCH and REGEX to behave similarly to the == operator. |
| 72 | # |
| 73 | proc matchfunc {a b} { return [expr {$a==$b}] } |
| 74 | proc regexfunc {a b} { return [expr {$a==$b}] } |
| 75 | db func match -argcount 2 matchfunc |
| 76 | db func regexp -argcount 2 regexfunc |
| 77 | |
| 78 | #------------------------------------------------------------------------- |
| 79 | # Test cases e_expr-1.* attempt to verify that all binary operators listed |
| 80 | # in the documentation exist and that the relative precedences of the |
| 81 | # operators are also as the documentation suggests. |
| 82 | # |
| 83 | # EVIDENCE-OF: R-15514-65163 SQLite understands the following binary |
| 84 | # operators, in order from highest to lowest precedence: || * / % + - |
| 85 | # << >> & | < <= > >= = == != <> IS IS |
| 86 | # NOT IN LIKE GLOB MATCH REGEXP AND OR |
| 87 | # |
| 88 | # EVIDENCE-OF: R-38759-38789 Operators IS and IS NOT have the same |
| 89 | # precedence as =. |
| 90 | # |
| 91 | |
| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 92 | unset -nocomplain untested |
| 93 | foreach op1 $oplist { |
| 94 | foreach op2 $oplist { |
| 95 | set untested($op1,$op2) 1 |
| 96 | foreach {tn A B C} { |
| 97 | 1 22 45 66 |
| 98 | 2 0 0 0 |
| 99 | 3 0 0 1 |
| 100 | 4 0 1 0 |
| 101 | 5 0 1 1 |
| 102 | 6 1 0 0 |
| 103 | 7 1 0 1 |
| 104 | 8 1 1 0 |
| 105 | 9 1 1 1 |
| 106 | 10 5 6 1 |
| 107 | 11 1 5 6 |
| 108 | 12 1 5 5 |
| 109 | 13 5 5 1 |
| 110 | |
| 111 | 14 5 2 1 |
| 112 | 15 1 4 1 |
| 113 | 16 -1 0 1 |
| 114 | 17 0 1 -1 |
| 115 | |
| 116 | } { |
| 117 | set testname "e_expr-1.$opname($op1).$opname($op2).$tn" |
| 118 | |
| 119 | # If $op2 groups more tightly than $op1, then the result |
| 120 | # of executing $sql1 whould be the same as executing $sql3. |
| 121 | # If $op1 groups more tightly, or if $op1 and $op2 have |
| 122 | # the same precedence, then executing $sql1 should return |
| 123 | # the same value as $sql2. |
| 124 | # |
| 125 | set sql1 "SELECT $A $op1 $B $op2 $C" |
| 126 | set sql2 "SELECT ($A $op1 $B) $op2 $C" |
| 127 | set sql3 "SELECT $A $op1 ($B $op2 $C)" |
| 128 | |
| 129 | set a2 [db one $sql2] |
| 130 | set a3 [db one $sql3] |
| 131 | |
| 132 | do_execsql_test $testname $sql1 [list [ |
| dan | bd0c001 | 2010-07-19 05:27:17 +0000 | [diff] [blame] | 133 | if {$opprec($op2) < $opprec($op1)} {set a3} {set a2} |
| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 134 | ]] |
| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 135 | if {$a2 != $a3} { unset -nocomplain untested($op1,$op2) } |
| 136 | } |
| 137 | } |
| 138 | } |
| 139 | |
| 140 | foreach op {* AND OR + || & |} { unset untested($op,$op) } |
| 141 | unset untested(+,-) ;# Since (a+b)-c == a+(b-c) |
| 142 | unset untested(*,<<) ;# Since (a*b)<<c == a*(b<<c) |
| 143 | |
| 144 | do_test e_expr-1.1 { array names untested } {} |
| 145 | |
| 146 | # At one point, test 1.2.2 was failing. Instead of the correct result, it |
| 147 | # was returning {1 1 0}. This would seem to indicate that LIKE has the |
| 148 | # same precedence as '<'. Which is incorrect. It has lower precedence. |
| 149 | # |
| 150 | do_execsql_test e_expr-1.2.1 { |
| 151 | SELECT 0 < 2 LIKE 1, (0 < 2) LIKE 1, 0 < (2 LIKE 1) |
| 152 | } {1 1 0} |
| 153 | do_execsql_test e_expr-1.2.2 { |
| 154 | SELECT 0 LIKE 0 < 2, (0 LIKE 0) < 2, 0 LIKE (0 < 2) |
| 155 | } {0 1 0} |
| 156 | |
| 157 | # Showing that LIKE and == have the same precedence |
| 158 | # |
| 159 | do_execsql_test e_expr-1.2.3 { |
| 160 | SELECT 2 LIKE 2 == 1, (2 LIKE 2) == 1, 2 LIKE (2 == 1) |
| 161 | } {1 1 0} |
| 162 | do_execsql_test e_expr-1.2.4 { |
| 163 | SELECT 2 == 2 LIKE 1, (2 == 2) LIKE 1, 2 == (2 LIKE 1) |
| 164 | } {1 1 0} |
| 165 | |
| 166 | # Showing that < groups more tightly than == (< has higher precedence). |
| 167 | # |
| 168 | do_execsql_test e_expr-1.2.5 { |
| 169 | SELECT 0 < 2 == 1, (0 < 2) == 1, 0 < (2 == 1) |
| 170 | } {1 1 0} |
| 171 | do_execsql_test e_expr-1.6 { |
| 172 | SELECT 0 == 0 < 2, (0 == 0) < 2, 0 == (0 < 2) |
| 173 | } {0 1 0} |
| 174 | |
| dan | 784141e | 2010-07-17 18:44:49 +0000 | [diff] [blame] | 175 | #------------------------------------------------------------------------- |
| 176 | # Check that the four unary prefix operators mentioned in the |
| 177 | # documentation exist. |
| 178 | # |
| 179 | # EVIDENCE-OF: R-13958-53419 Supported unary prefix operators are these: |
| 180 | # - + ~ NOT |
| 181 | # |
| 182 | do_execsql_test e_expr-2.1 { SELECT - 10 } {-10} |
| 183 | do_execsql_test e_expr-2.2 { SELECT + 10 } {10} |
| 184 | do_execsql_test e_expr-2.3 { SELECT ~ 10 } {-11} |
| 185 | do_execsql_test e_expr-2.4 { SELECT NOT 10 } {0} |
| 186 | |
| 187 | #------------------------------------------------------------------------- |
| 188 | # Tests for the two statements made regarding the unary + operator. |
| 189 | # |
| 190 | # EVIDENCE-OF: R-53670-03373 The unary operator + is a no-op. |
| 191 | # |
| 192 | # EVIDENCE-OF: R-19480-30968 It can be applied to strings, numbers, |
| 193 | # blobs or NULL and it always returns a result with the same value as |
| 194 | # the operand. |
| 195 | # |
| 196 | foreach {tn literal type} { |
| 197 | 1 'helloworld' text |
| 198 | 2 45 integer |
| 199 | 3 45.2 real |
| 200 | 4 45.0 real |
| 201 | 5 X'ABCDEF' blob |
| 202 | 6 NULL null |
| 203 | } { |
| 204 | set sql " SELECT quote( + $literal ), typeof( + $literal) " |
| 205 | do_execsql_test e_expr-3.$tn $sql [list $literal $type] |
| 206 | } |
| 207 | |
| 208 | #------------------------------------------------------------------------- |
| 209 | # Check that both = and == are both acceptable as the "equals" operator. |
| 210 | # Similarly, either != or <> work as the not-equals operator. |
| 211 | # |
| 212 | # EVIDENCE-OF: R-03679-60639 Equals can be either = or ==. |
| 213 | # |
| 214 | # EVIDENCE-OF: R-30082-38996 The non-equals operator can be either != or |
| 215 | # <>. |
| 216 | # |
| 217 | foreach {tn literal different} { |
| 218 | 1 'helloworld' '12345' |
| 219 | 2 22 23 |
| 220 | 3 'xyz' X'78797A' |
| 221 | 4 X'78797A00' 'xyz' |
| 222 | } { |
| 223 | do_execsql_test e_expr-4.$tn " |
| 224 | SELECT $literal = $literal, $literal == $literal, |
| 225 | $literal = $different, $literal == $different, |
| 226 | $literal = NULL, $literal == NULL, |
| 227 | $literal != $literal, $literal <> $literal, |
| 228 | $literal != $different, $literal <> $different, |
| 229 | $literal != NULL, $literal != NULL |
| 230 | |
| 231 | " {1 1 0 0 {} {} 0 0 1 1 {} {}} |
| 232 | } |
| 233 | |
| 234 | #------------------------------------------------------------------------- |
| 235 | # Test the || operator. |
| 236 | # |
| 237 | # EVIDENCE-OF: R-44409-62641 The || operator is "concatenate" - it joins |
| 238 | # together the two strings of its operands. |
| 239 | # |
| 240 | foreach {tn a b} { |
| 241 | 1 'helloworld' '12345' |
| 242 | 2 22 23 |
| 243 | } { |
| 244 | set as [db one "SELECT $a"] |
| 245 | set bs [db one "SELECT $b"] |
| 246 | |
| 247 | do_execsql_test e_expr-5.$tn "SELECT $a || $b" [list "${as}${bs}"] |
| 248 | } |
| 249 | |
| 250 | #------------------------------------------------------------------------- |
| 251 | # Test the % operator. |
| 252 | # |
| 253 | # EVIDENCE-OF: R-08914-63790 The operator % outputs the value of its |
| 254 | # left operand modulo its right operand. |
| 255 | # |
| 256 | do_execsql_test e_expr-6.1 {SELECT 72%5} {2} |
| 257 | do_execsql_test e_expr-6.2 {SELECT 72%-5} {2} |
| 258 | do_execsql_test e_expr-6.3 {SELECT -72%-5} {-2} |
| 259 | do_execsql_test e_expr-6.4 {SELECT -72%5} {-2} |
| 260 | |
| 261 | #------------------------------------------------------------------------- |
| 262 | # Test that the results of all binary operators are either numeric or |
| 263 | # NULL, except for the || operator, which may evaluate to either a text |
| 264 | # value or NULL. |
| 265 | # |
| 266 | # EVIDENCE-OF: R-20665-17792 The result of any binary operator is either |
| 267 | # a numeric value or NULL, except for the || concatenation operator |
| 268 | # which always evaluates to either NULL or a text value. |
| 269 | # |
| 270 | set literals { |
| 271 | 1 'abc' 2 'hexadecimal' 3 '' |
| 272 | 4 123 5 -123 6 0 |
| 273 | 7 123.4 8 0.0 9 -123.4 |
| 274 | 10 X'ABCDEF' 11 X'' 12 X'0000' |
| 275 | 13 NULL |
| 276 | } |
| 277 | foreach op $oplist { |
| 278 | foreach {n1 rhs} $literals { |
| 279 | foreach {n2 lhs} $literals { |
| 280 | |
| 281 | set t [db one " SELECT typeof($lhs $op $rhs) "] |
| 282 | do_test e_expr-7.$opname($op).$n1.$n2 { |
| 283 | expr { |
| 284 | ($op=="||" && ($t == "text" || $t == "null")) |
| 285 | || ($op!="||" && ($t == "integer" || $t == "real" || $t == "null")) |
| 286 | } |
| 287 | } 1 |
| 288 | |
| 289 | }} |
| 290 | } |
| 291 | |
| 292 | #------------------------------------------------------------------------- |
| 293 | # Test the IS and IS NOT operators. |
| 294 | # |
| 295 | # EVIDENCE-OF: R-24731-45773 The IS and IS NOT operators work like = and |
| 296 | # != except when one or both of the operands are NULL. |
| 297 | # |
| 298 | # EVIDENCE-OF: R-06325-15315 In this case, if both operands are NULL, |
| 299 | # then the IS operator evaluates to 1 (true) and the IS NOT operator |
| 300 | # evaluates to 0 (false). |
| 301 | # |
| 302 | # EVIDENCE-OF: R-19812-36779 If one operand is NULL and the other is |
| 303 | # not, then the IS operator evaluates to 0 (false) and the IS NOT |
| 304 | # operator is 1 (true). |
| 305 | # |
| 306 | # EVIDENCE-OF: R-61975-13410 It is not possible for an IS or IS NOT |
| 307 | # expression to evaluate to NULL. |
| 308 | # |
| 309 | do_execsql_test e_expr-8.1.1 { SELECT NULL IS NULL } {1} |
| 310 | do_execsql_test e_expr-8.1.2 { SELECT 'ab' IS NULL } {0} |
| 311 | do_execsql_test e_expr-8.1.3 { SELECT NULL IS 'ab' } {0} |
| 312 | do_execsql_test e_expr-8.1.4 { SELECT 'ab' IS 'ab' } {1} |
| 313 | do_execsql_test e_expr-8.1.5 { SELECT NULL == NULL } {{}} |
| 314 | do_execsql_test e_expr-8.1.6 { SELECT 'ab' == NULL } {{}} |
| 315 | do_execsql_test e_expr-8.1.7 { SELECT NULL == 'ab' } {{}} |
| 316 | do_execsql_test e_expr-8.1.8 { SELECT 'ab' == 'ab' } {1} |
| 317 | do_execsql_test e_expr-8.1.9 { SELECT NULL IS NOT NULL } {0} |
| 318 | do_execsql_test e_expr-8.1.10 { SELECT 'ab' IS NOT NULL } {1} |
| 319 | do_execsql_test e_expr-8.1.11 { SELECT NULL IS NOT 'ab' } {1} |
| 320 | do_execsql_test e_expr-8.1.12 { SELECT 'ab' IS NOT 'ab' } {0} |
| 321 | do_execsql_test e_expr-8.1.13 { SELECT NULL != NULL } {{}} |
| 322 | do_execsql_test e_expr-8.1.14 { SELECT 'ab' != NULL } {{}} |
| 323 | do_execsql_test e_expr-8.1.15 { SELECT NULL != 'ab' } {{}} |
| 324 | do_execsql_test e_expr-8.1.16 { SELECT 'ab' != 'ab' } {0} |
| 325 | |
| 326 | foreach {n1 rhs} $literals { |
| 327 | foreach {n2 lhs} $literals { |
| 328 | if {$rhs!="NULL" && $lhs!="NULL"} { |
| 329 | set eq [execsql "SELECT $lhs = $rhs, $lhs != $rhs"] |
| 330 | } else { |
| 331 | set eq [list [expr {$lhs=="NULL" && $rhs=="NULL"}] \ |
| 332 | [expr {$lhs!="NULL" || $rhs!="NULL"}] |
| 333 | ] |
| 334 | } |
| 335 | set test e_expr-8.2.$n1.$n2 |
| 336 | do_execsql_test $test.1 "SELECT $lhs IS $rhs, $lhs IS NOT $rhs" $eq |
| 337 | do_execsql_test $test.2 " |
| 338 | SELECT ($lhs IS $rhs) IS NULL, ($lhs IS NOT $rhs) IS NULL |
| 339 | " {0 0} |
| 340 | } |
| 341 | } |
| 342 | |
| dan | c29486a | 2010-08-13 18:41:09 +0000 | [diff] [blame] | 343 | #------------------------------------------------------------------------- |
| 344 | # Run some tests on the COLLATE "unary postfix operator". |
| 345 | # |
| 346 | # This collation sequence reverses both arguments before using |
| 347 | # [string compare] to compare them. For example, when comparing the |
| 348 | # strings 'one' and 'four', return the result of: |
| 349 | # |
| 350 | # string compare eno ruof |
| 351 | # |
| 352 | proc reverse_str {zStr} { |
| 353 | set out "" |
| 354 | foreach c [split $zStr {}] { set out "${c}${out}" } |
| 355 | set out |
| 356 | } |
| 357 | proc reverse_collate {zLeft zRight} { |
| 358 | string compare [reverse_str $zLeft] [reverse_str $zRight] |
| 359 | } |
| 360 | db collate reverse reverse_collate |
| 361 | |
| 362 | # EVIDENCE-OF: R-59577-33471 The COLLATE operator is a unary postfix |
| 363 | # operator that assigns a collating sequence to an expression. |
| 364 | # |
| 365 | # EVIDENCE-OF: R-23441-22541 The COLLATE operator has a higher |
| 366 | # precedence (binds more tightly) than any prefix unary operator or any |
| 367 | # binary operator. |
| 368 | # |
| 369 | do_execsql_test e_expr-9.1 { SELECT 'abcd' < 'bbbb' COLLATE reverse } 0 |
| 370 | do_execsql_test e_expr-9.2 { SELECT ('abcd' < 'bbbb') COLLATE reverse } 1 |
| 371 | do_execsql_test e_expr-9.3 { SELECT 'abcd' <= 'bbbb' COLLATE reverse } 0 |
| 372 | do_execsql_test e_expr-9.4 { SELECT ('abcd' <= 'bbbb') COLLATE reverse } 1 |
| 373 | |
| 374 | do_execsql_test e_expr-9.5 { SELECT 'abcd' > 'bbbb' COLLATE reverse } 1 |
| 375 | do_execsql_test e_expr-9.6 { SELECT ('abcd' > 'bbbb') COLLATE reverse } 0 |
| 376 | do_execsql_test e_expr-9.7 { SELECT 'abcd' >= 'bbbb' COLLATE reverse } 1 |
| 377 | do_execsql_test e_expr-9.8 { SELECT ('abcd' >= 'bbbb') COLLATE reverse } 0 |
| 378 | |
| 379 | do_execsql_test e_expr-9.10 { SELECT 'abcd' = 'ABCD' COLLATE nocase } 1 |
| 380 | do_execsql_test e_expr-9.11 { SELECT ('abcd' = 'ABCD') COLLATE nocase } 0 |
| 381 | do_execsql_test e_expr-9.12 { SELECT 'abcd' == 'ABCD' COLLATE nocase } 1 |
| 382 | do_execsql_test e_expr-9.13 { SELECT ('abcd' == 'ABCD') COLLATE nocase } 0 |
| 383 | do_execsql_test e_expr-9.14 { SELECT 'abcd' IS 'ABCD' COLLATE nocase } 1 |
| 384 | do_execsql_test e_expr-9.15 { SELECT ('abcd' IS 'ABCD') COLLATE nocase } 0 |
| 385 | |
| 386 | do_execsql_test e_expr-9.16 { SELECT 'abcd' != 'ABCD' COLLATE nocase } 0 |
| 387 | do_execsql_test e_expr-9.17 { SELECT ('abcd' != 'ABCD') COLLATE nocase } 1 |
| 388 | do_execsql_test e_expr-9.18 { SELECT 'abcd' <> 'ABCD' COLLATE nocase } 0 |
| 389 | do_execsql_test e_expr-9.19 { SELECT ('abcd' <> 'ABCD') COLLATE nocase } 1 |
| 390 | do_execsql_test e_expr-9.20 { SELECT 'abcd' IS NOT 'ABCD' COLLATE nocase } 0 |
| 391 | do_execsql_test e_expr-9.21 { SELECT ('abcd' IS NOT 'ABCD') COLLATE nocase } 1 |
| 392 | |
| 393 | do_execsql_test e_expr-9.22 { |
| 394 | SELECT 'bbb' BETWEEN 'AAA' AND 'CCC' COLLATE nocase |
| 395 | } 1 |
| 396 | do_execsql_test e_expr-9.23 { |
| 397 | SELECT ('bbb' BETWEEN 'AAA' AND 'CCC') COLLATE nocase |
| 398 | } 0 |
| 399 | |
| 400 | # EVIDENCE-OF: R-58731-25439 The collating sequence set by the COLLATE |
| 401 | # operator overrides the collating sequence determined by the COLLATE |
| 402 | # clause in a table column definition. |
| 403 | # |
| 404 | do_execsql_test e_expr-9.24 { |
| 405 | CREATE TABLE t24(a COLLATE NOCASE, b); |
| 406 | INSERT INTO t24 VALUES('aaa', 1); |
| 407 | INSERT INTO t24 VALUES('bbb', 2); |
| 408 | INSERT INTO t24 VALUES('ccc', 3); |
| 409 | } {} |
| 410 | do_execsql_test e_expr-9.25 { SELECT 'BBB' = a FROM t24 } {0 1 0} |
| 411 | do_execsql_test e_expr-9.25 { SELECT a = 'BBB' FROM t24 } {0 1 0} |
| 412 | do_execsql_test e_expr-9.25 { SELECT 'BBB' = a COLLATE binary FROM t24 } {0 0 0} |
| 413 | do_execsql_test e_expr-9.25 { SELECT a COLLATE binary = 'BBB' FROM t24 } {0 0 0} |
| 414 | |
| 415 | #------------------------------------------------------------------------- |
| 416 | # Test statements related to literal values. |
| 417 | # |
| 418 | # EVIDENCE-OF: R-31536-32008 Literal values may be integers, floating |
| 419 | # point numbers, strings, BLOBs, or NULLs. |
| 420 | # |
| 421 | do_execsql_test e_expr-10.1.1 { SELECT typeof(5) } {integer} |
| 422 | do_execsql_test e_expr-10.1.2 { SELECT typeof(5.1) } {real} |
| 423 | do_execsql_test e_expr-10.1.3 { SELECT typeof('5.1') } {text} |
| 424 | do_execsql_test e_expr-10.1.4 { SELECT typeof(X'ABCD') } {blob} |
| 425 | do_execsql_test e_expr-10.1.5 { SELECT typeof(NULL) } {null} |
| 426 | |
| 427 | # EVIDENCE-OF: R-26921-59298 Scientific notation is supported for |
| 428 | # floating point literal values. |
| 429 | # |
| 430 | do_execsql_test e_expr-10.2.1 { SELECT typeof(3.4e-02) } {real} |
| 431 | do_execsql_test e_expr-10.2.2 { SELECT typeof(3e+5) } {real} |
| 432 | do_execsql_test e_expr-10.2.3 { SELECT 3.4e-02 } {0.034} |
| 433 | do_execsql_test e_expr-10.2.4 { SELECT 3e+4 } {30000.0} |
| 434 | |
| 435 | # EVIDENCE-OF: R-35229-17830 A string constant is formed by enclosing |
| 436 | # the string in single quotes ('). |
| 437 | # |
| 438 | # EVIDENCE-OF: R-07100-06606 A single quote within the string can be |
| 439 | # encoded by putting two single quotes in a row - as in Pascal. |
| 440 | # |
| 441 | do_execsql_test e_expr-10.3.1 { SELECT 'is not' } {{is not}} |
| 442 | do_execsql_test e_expr-10.3.2 { SELECT typeof('is not') } {text} |
| 443 | do_execsql_test e_expr-10.3.3 { SELECT 'isn''t' } {isn't} |
| 444 | do_execsql_test e_expr-10.3.4 { SELECT typeof('isn''t') } {text} |
| 445 | |
| 446 | # EVIDENCE-OF: R-09593-03321 BLOB literals are string literals |
| 447 | # containing hexadecimal data and preceded by a single "x" or "X" |
| 448 | # character. |
| 449 | # |
| 450 | # EVIDENCE-OF: R-39344-59787 For example: X'53514C697465' |
| 451 | # |
| 452 | do_execsql_test e_expr-10.4.1 { SELECT typeof(X'0123456789ABCDEF') } blob |
| 453 | do_execsql_test e_expr-10.4.2 { SELECT typeof(x'0123456789ABCDEF') } blob |
| 454 | do_execsql_test e_expr-10.4.3 { SELECT typeof(X'0123456789abcdef') } blob |
| 455 | do_execsql_test e_expr-10.4.4 { SELECT typeof(x'0123456789abcdef') } blob |
| 456 | do_execsql_test e_expr-10.4.5 { SELECT typeof(X'53514C697465') } blob |
| 457 | |
| 458 | # EVIDENCE-OF: R-23914-51476 A literal value can also be the token |
| 459 | # "NULL". |
| dan | c7d6156 | 2010-08-14 12:25:18 +0000 | [diff] [blame] | 460 | # |
| dan | c29486a | 2010-08-13 18:41:09 +0000 | [diff] [blame] | 461 | do_execsql_test e_expr-10.5.1 { SELECT NULL } {{}} |
| 462 | do_execsql_test e_expr-10.5.2 { SELECT typeof(NULL) } {null} |
| 463 | |
| dan | c7d6156 | 2010-08-14 12:25:18 +0000 | [diff] [blame] | 464 | #------------------------------------------------------------------------- |
| 465 | # Test statements related to bound parameters |
| 466 | # |
| 467 | |
| 468 | proc parameter_test {tn sql params result} { |
| 469 | set stmt [sqlite3_prepare_v2 db $sql -1] |
| 470 | |
| 471 | foreach {number name} $params { |
| 472 | set nm [sqlite3_bind_parameter_name $stmt $number] |
| 473 | do_test $tn.name.$number [list set {} $nm] $name |
| 474 | sqlite3_bind_int $stmt $number [expr -1 * $number] |
| 475 | } |
| 476 | |
| 477 | sqlite3_step $stmt |
| 478 | |
| 479 | set res [list] |
| 480 | for {set i 0} {$i < [sqlite3_column_count $stmt]} {incr i} { |
| 481 | lappend res [sqlite3_column_text $stmt $i] |
| 482 | } |
| 483 | |
| 484 | set rc [sqlite3_finalize $stmt] |
| 485 | do_test $tn.rc [list set {} $rc] SQLITE_OK |
| 486 | do_test $tn.res [list set {} $res] $result |
| 487 | } |
| 488 | |
| 489 | # EVIDENCE-OF: R-33509-39458 A question mark followed by a number NNN |
| 490 | # holds a spot for the NNN-th parameter. NNN must be between 1 and |
| 491 | # SQLITE_MAX_VARIABLE_NUMBER. |
| 492 | # |
| 493 | set mvn $SQLITE_MAX_VARIABLE_NUMBER |
| 494 | parameter_test e_expr-11.1 " |
| 495 | SELECT ?1, ?123, ?$SQLITE_MAX_VARIABLE_NUMBER, ?123, ?4 |
| 496 | " "1 ?1 123 ?123 $mvn ?$mvn 4 ?4" "-1 -123 -$mvn -123 -4" |
| 497 | |
| 498 | set errmsg "variable number must be between ?1 and ?$SQLITE_MAX_VARIABLE_NUMBER" |
| 499 | foreach {tn param_number} [list \ |
| 500 | 2 0 \ |
| 501 | 3 [expr $SQLITE_MAX_VARIABLE_NUMBER+1] \ |
| 502 | 4 [expr $SQLITE_MAX_VARIABLE_NUMBER+2] \ |
| 503 | 5 12345678903456789034567890234567890 \ |
| 504 | 6 2147483648 \ |
| 505 | 7 2147483649 \ |
| 506 | 8 4294967296 \ |
| 507 | 9 4294967297 \ |
| 508 | 10 9223372036854775808 \ |
| 509 | 11 9223372036854775809 \ |
| 510 | 12 18446744073709551616 \ |
| 511 | 13 18446744073709551617 \ |
| 512 | ] { |
| 513 | do_catchsql_test e_expr-11.1.$tn "SELECT ?$param_number" [list 1 $errmsg] |
| 514 | } |
| 515 | |
| 516 | # EVIDENCE-OF: R-33670-36097 A question mark that is not followed by a |
| 517 | # number creates a parameter with a number one greater than the largest |
| 518 | # parameter number already assigned. |
| 519 | # |
| 520 | # EVIDENCE-OF: R-42938-07030 If this means the parameter number is |
| 521 | # greater than SQLITE_MAX_VARIABLE_NUMBER, it is an error. |
| 522 | # |
| 523 | parameter_test e_expr-11.2.1 "SELECT ?" {1 {}} -1 |
| 524 | parameter_test e_expr-11.2.2 "SELECT ?, ?" {1 {} 2 {}} {-1 -2} |
| 525 | parameter_test e_expr-11.2.3 "SELECT ?5, ?" {5 ?5 6 {}} {-5 -6} |
| 526 | parameter_test e_expr-11.2.4 "SELECT ?, ?5" {1 {} 5 ?5} {-1 -5} |
| 527 | parameter_test e_expr-11.2.5 "SELECT ?, ?456, ?" { |
| 528 | 1 {} 456 ?456 457 {} |
| 529 | } {-1 -456 -457} |
| 530 | parameter_test e_expr-11.2.5 "SELECT ?, ?456, ?4, ?" { |
| 531 | 1 {} 456 ?456 4 ?4 457 {} |
| 532 | } {-1 -456 -4 -457} |
| 533 | foreach {tn sql} [list \ |
| 534 | 1 "SELECT ?$mvn, ?" \ |
| 535 | 2 "SELECT ?[expr $mvn-5], ?, ?, ?, ?, ?, ?" \ |
| 536 | 3 "SELECT ?[expr $mvn], ?5, ?6, ?" \ |
| 537 | ] { |
| 538 | do_catchsql_test e_expr-11.3.$tn $sql [list 1 {too many SQL variables}] |
| 539 | } |
| 540 | |
| 541 | # EVIDENCE-OF: R-11620-22743 A colon followed by an identifier name |
| 542 | # holds a spot for a named parameter with the name :AAAA. |
| 543 | # |
| 544 | # Identifiers in SQLite consist of alphanumeric, '_' and '$' characters, |
| 545 | # and any UTF characters with codepoints larger than 127 (non-ASCII |
| 546 | # characters). |
| 547 | # |
| 548 | parameter_test e_expr-11.2.1 {SELECT :AAAA} {1 :AAAA} -1 |
| 549 | parameter_test e_expr-11.2.2 {SELECT :123} {1 :123} -1 |
| 550 | parameter_test e_expr-11.2.3 {SELECT :__} {1 :__} -1 |
| 551 | parameter_test e_expr-11.2.4 {SELECT :_$_} {1 :_$_} -1 |
| 552 | parameter_test e_expr-11.2.5 " |
| 553 | SELECT :\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25 |
| 554 | " "1 :\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25" -1 |
| 555 | parameter_test e_expr-11.2.6 "SELECT :\u0080" "1 :\u0080" -1 |
| 556 | |
| 557 | # EVIDENCE-OF: R-49783-61279 An "at" sign works exactly like a colon, |
| 558 | # except that the name of the parameter created is @AAAA. |
| 559 | # |
| 560 | parameter_test e_expr-11.3.1 {SELECT @AAAA} {1 @AAAA} -1 |
| 561 | parameter_test e_expr-11.3.2 {SELECT @123} {1 @123} -1 |
| 562 | parameter_test e_expr-11.3.3 {SELECT @__} {1 @__} -1 |
| 563 | parameter_test e_expr-11.3.4 {SELECT @_$_} {1 @_$_} -1 |
| 564 | parameter_test e_expr-11.3.5 " |
| 565 | SELECT @\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25 |
| 566 | " "1 @\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25" -1 |
| 567 | parameter_test e_expr-11.3.6 "SELECT @\u0080" "1 @\u0080" -1 |
| 568 | |
| 569 | # EVIDENCE-OF: R-62610-51329 A dollar-sign followed by an identifier |
| 570 | # name also holds a spot for a named parameter with the name $AAAA. |
| 571 | # |
| 572 | # EVIDENCE-OF: R-55025-21042 The identifier name in this case can |
| 573 | # include one or more occurrences of "::" and a suffix enclosed in |
| 574 | # "(...)" containing any text at all. |
| 575 | # |
| 576 | # Note: Looks like an identifier cannot consist entirely of "::" |
| 577 | # characters or just a suffix. Also, the other named variable characters |
| 578 | # (: and @) work the same way internally. Why not just document it that way? |
| 579 | # |
| 580 | parameter_test e_expr-11.4.1 {SELECT $AAAA} {1 $AAAA} -1 |
| 581 | parameter_test e_expr-11.4.2 {SELECT $123} {1 $123} -1 |
| 582 | parameter_test e_expr-11.4.3 {SELECT $__} {1 $__} -1 |
| 583 | parameter_test e_expr-11.4.4 {SELECT $_$_} {1 $_$_} -1 |
| 584 | parameter_test e_expr-11.4.5 " |
| 585 | SELECT \$\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25 |
| 586 | " "1 \$\u0e40\u0e2d\u0e28\u0e02\u0e39\u0e40\u0e2d\u0e25" -1 |
| 587 | parameter_test e_expr-11.4.6 "SELECT \$\u0080" "1 \$\u0080" -1 |
| 588 | |
| 589 | parameter_test e_expr-11.5.1 {SELECT $::::a(++--++)} {1 $::::a(++--++)} -1 |
| 590 | parameter_test e_expr-11.5.2 {SELECT $::a()} {1 $::a()} -1 |
| 591 | parameter_test e_expr-11.5.3 {SELECT $::1(::#$)} {1 $::1(::#$)} -1 |
| 592 | |
| 593 | # EVIDENCE-OF: R-11370-04520 Named parameters are also numbered. The |
| 594 | # number assigned is one greater than the largest parameter number |
| 595 | # already assigned. |
| 596 | # |
| 597 | # EVIDENCE-OF: R-42620-22184 If this means the parameter would be |
| 598 | # assigned a number greater than SQLITE_MAX_VARIABLE_NUMBER, it is an |
| 599 | # error. |
| 600 | # |
| 601 | parameter_test e_expr-11.6.1 "SELECT ?, @abc" {1 {} 2 @abc} {-1 -2} |
| 602 | parameter_test e_expr-11.6.2 "SELECT ?123, :a1" {123 ?123 124 :a1} {-123 -124} |
| 603 | parameter_test e_expr-11.6.3 {SELECT $a, ?8, ?, $b, ?2, $c} { |
| 604 | 1 $a 8 ?8 9 {} 10 $b 2 ?2 11 $c |
| 605 | } {-1 -8 -9 -10 -2 -11} |
| 606 | foreach {tn sql} [list \ |
| 607 | 1 "SELECT ?$mvn, \$::a" \ |
| 608 | 2 "SELECT ?$mvn, ?4, @a1" \ |
| 609 | 3 "SELECT ?[expr $mvn-2], :bag, @123, \$x" \ |
| 610 | ] { |
| 611 | do_catchsql_test e_expr-11.7.$tn $sql [list 1 {too many SQL variables}] |
| 612 | } |
| 613 | |
| dan | 1afca9b | 2010-08-14 18:32:23 +0000 | [diff] [blame] | 614 | # EVIDENCE-OF: R-14068-49671 Parameters that are not assigned values |
| 615 | # using sqlite3_bind() are treated as NULL. |
| 616 | # |
| 617 | do_test e_expr-11.7.1 { |
| 618 | set stmt [sqlite3_prepare_v2 db { SELECT ?, :a, @b, $d } -1] |
| 619 | sqlite3_step $stmt |
| 620 | |
| 621 | list [sqlite3_column_type $stmt 0] \ |
| 622 | [sqlite3_column_type $stmt 1] \ |
| 623 | [sqlite3_column_type $stmt 2] \ |
| 624 | [sqlite3_column_type $stmt 3] |
| 625 | } {NULL NULL NULL NULL} |
| 626 | do_test e_expr-11.7.1 { sqlite3_finalize $stmt } SQLITE_OK |
| 627 | |
| dan | 994e940 | 2010-08-16 18:26:30 +0000 | [diff] [blame] | 628 | #------------------------------------------------------------------------- |
| 629 | # "Test" the syntax diagrams in lang_expr.html. |
| 630 | # |
| 631 | # EVIDENCE-OF: R-04177-20688 -- syntax diagram signed-number |
| 632 | # |
| 633 | do_execsql_test e_expr-12.1.1 { SELECT 0, +0, -0 } {0 0 0} |
| 634 | do_execsql_test e_expr-12.1.2 { SELECT 1, +1, -1 } {1 1 -1} |
| 635 | do_execsql_test e_expr-12.1.3 { SELECT 2, +2, -2 } {2 2 -2} |
| 636 | do_execsql_test e_expr-12.1.4 { |
| 637 | SELECT 1.4, +1.4, -1.4 |
| 638 | } {1.4 1.4 -1.4} |
| 639 | do_execsql_test e_expr-12.1.5 { |
| 640 | SELECT 1.5e+5, +1.5e+5, -1.5e+5 |
| 641 | } {150000.0 150000.0 -150000.0} |
| 642 | do_execsql_test e_expr-12.1.6 { |
| 643 | SELECT 0.0001, +0.0001, -0.0001 |
| 644 | } {0.0001 0.0001 -0.0001} |
| 645 | |
| 646 | # EVIDENCE-OF: R-30740-26723 -- syntax diagram literal-value |
| 647 | # |
| 648 | set sqlite_current_time 1 |
| 649 | do_execsql_test e_expr-12.2.1 {SELECT 123} {123} |
| 650 | do_execsql_test e_expr-12.2.2 {SELECT 123.4e05} {12340000.0} |
| 651 | do_execsql_test e_expr-12.2.3 {SELECT 'abcde'} {abcde} |
| 652 | do_execsql_test e_expr-12.2.4 {SELECT X'414243'} {ABC} |
| 653 | do_execsql_test e_expr-12.2.5 {SELECT NULL} {{}} |
| 654 | do_execsql_test e_expr-12.2.6 {SELECT CURRENT_TIME} {00:00:01} |
| 655 | do_execsql_test e_expr-12.2.7 {SELECT CURRENT_DATE} {1970-01-01} |
| 656 | do_execsql_test e_expr-12.2.8 {SELECT CURRENT_TIMESTAMP} {{1970-01-01 00:00:01}} |
| 657 | set sqlite_current_time 0 |
| 658 | |
| 659 | # EVIDENCE-OF: R-57598-59332 -- syntax diagram expr |
| 660 | # |
| 661 | file delete -force test.db2 |
| 662 | execsql { |
| 663 | ATTACH 'test.db2' AS dbname; |
| 664 | CREATE TABLE dbname.tblname(cname); |
| 665 | } |
| 666 | |
| 667 | proc glob {args} {return 1} |
| 668 | db function glob glob |
| 669 | db function match glob |
| 670 | db function regexp glob |
| 671 | |
| 672 | foreach {tn expr} { |
| 673 | 1 123 |
| 674 | 2 123.4e05 |
| 675 | 3 'abcde' |
| 676 | 4 X'414243' |
| 677 | 5 NULL |
| 678 | 6 CURRENT_TIME |
| 679 | 7 CURRENT_DATE |
| 680 | 8 CURRENT_TIMESTAMP |
| 681 | |
| 682 | 9 ? |
| 683 | 10 ?123 |
| 684 | 11 @hello |
| 685 | 12 :world |
| 686 | 13 $tcl |
| 687 | 14 $tcl(array) |
| 688 | |
| 689 | 15 cname |
| 690 | 16 tblname.cname |
| 691 | 17 dbname.tblname.cname |
| 692 | |
| 693 | 18 "+ EXPR" |
| 694 | 19 "- EXPR" |
| 695 | 20 "NOT EXPR" |
| 696 | 21 "~ EXPR" |
| 697 | |
| 698 | 22 "EXPR1 || EXPR2" |
| 699 | 23 "EXPR1 * EXPR2" |
| 700 | 24 "EXPR1 / EXPR2" |
| 701 | 25 "EXPR1 % EXPR2" |
| 702 | 26 "EXPR1 + EXPR2" |
| 703 | 27 "EXPR1 - EXPR2" |
| 704 | 28 "EXPR1 << EXPR2" |
| 705 | 29 "EXPR1 >> EXPR2" |
| 706 | 30 "EXPR1 & EXPR2" |
| 707 | 31 "EXPR1 | EXPR2" |
| 708 | 32 "EXPR1 < EXPR2" |
| 709 | 33 "EXPR1 <= EXPR2" |
| 710 | 34 "EXPR1 > EXPR2" |
| 711 | 35 "EXPR1 >= EXPR2" |
| 712 | 36 "EXPR1 = EXPR2" |
| 713 | 37 "EXPR1 == EXPR2" |
| 714 | 38 "EXPR1 != EXPR2" |
| 715 | 39 "EXPR1 <> EXPR2" |
| 716 | 40 "EXPR1 IS EXPR2" |
| 717 | 41 "EXPR1 IS NOT EXPR2" |
| 718 | 42 "EXPR1 AND EXPR2" |
| 719 | 43 "EXPR1 OR EXPR2" |
| 720 | |
| 721 | 44 "count(*)" |
| 722 | 45 "count(DISTINCT EXPR)" |
| 723 | 46 "substr(EXPR, 10, 20)" |
| 724 | 47 "changes()" |
| 725 | |
| 726 | 48 "( EXPR )" |
| 727 | |
| 728 | 49 "CAST ( EXPR AS integer )" |
| 729 | 50 "CAST ( EXPR AS 'abcd' )" |
| 730 | 51 "CAST ( EXPR AS 'ab$ $cd' )" |
| 731 | |
| 732 | 52 "EXPR COLLATE nocase" |
| 733 | 53 "EXPR COLLATE binary" |
| 734 | |
| 735 | 54 "EXPR1 LIKE EXPR2" |
| 736 | 55 "EXPR1 LIKE EXPR2 ESCAPE EXPR" |
| 737 | 56 "EXPR1 GLOB EXPR2" |
| 738 | 57 "EXPR1 GLOB EXPR2 ESCAPE EXPR" |
| 739 | 58 "EXPR1 REGEXP EXPR2" |
| 740 | 59 "EXPR1 REGEXP EXPR2 ESCAPE EXPR" |
| 741 | 60 "EXPR1 MATCH EXPR2" |
| 742 | 61 "EXPR1 MATCH EXPR2 ESCAPE EXPR" |
| 743 | 62 "EXPR1 NOT LIKE EXPR2" |
| 744 | 63 "EXPR1 NOT LIKE EXPR2 ESCAPE EXPR" |
| 745 | 64 "EXPR1 NOT GLOB EXPR2" |
| 746 | 65 "EXPR1 NOT GLOB EXPR2 ESCAPE EXPR" |
| 747 | 66 "EXPR1 NOT REGEXP EXPR2" |
| 748 | 67 "EXPR1 NOT REGEXP EXPR2 ESCAPE EXPR" |
| 749 | 68 "EXPR1 NOT MATCH EXPR2" |
| 750 | 69 "EXPR1 NOT MATCH EXPR2 ESCAPE EXPR" |
| 751 | |
| 752 | 70 "EXPR ISNULL" |
| 753 | 71 "EXPR NOTNULL" |
| 754 | 72 "EXPR NOT NULL" |
| 755 | |
| 756 | 73 "EXPR1 IS EXPR2" |
| 757 | 74 "EXPR1 IS NOT EXPR2" |
| 758 | |
| 759 | 75 "EXPR NOT BETWEEN EXPR1 AND EXPR2" |
| 760 | 76 "EXPR BETWEEN EXPR1 AND EXPR2" |
| 761 | |
| 762 | 77 "EXPR NOT IN (SELECT cname FROM tblname)" |
| 763 | 78 "EXPR NOT IN (1)" |
| 764 | 79 "EXPR NOT IN (1, 2, 3)" |
| 765 | 80 "EXPR NOT IN tblname" |
| 766 | 81 "EXPR NOT IN dbname.tblname" |
| 767 | 82 "EXPR IN (SELECT cname FROM tblname)" |
| 768 | 83 "EXPR IN (1)" |
| 769 | 84 "EXPR IN (1, 2, 3)" |
| 770 | 85 "EXPR IN tblname" |
| 771 | 86 "EXPR IN dbname.tblname" |
| 772 | |
| 773 | 87 "EXISTS (SELECT cname FROM tblname)" |
| 774 | 88 "NOT EXISTS (SELECT cname FROM tblname)" |
| 775 | |
| 776 | 89 "CASE EXPR WHEN EXPR1 THEN EXPR2 ELSE EXPR END" |
| 777 | 90 "CASE EXPR WHEN EXPR1 THEN EXPR2 END" |
| 778 | 91 "CASE EXPR WHEN EXPR1 THEN EXPR2 WHEN EXPR THEN EXPR1 ELSE EXPR2 END" |
| 779 | 92 "CASE EXPR WHEN EXPR1 THEN EXPR2 WHEN EXPR THEN EXPR1 END" |
| 780 | 93 "CASE WHEN EXPR1 THEN EXPR2 ELSE EXPR END" |
| 781 | 94 "CASE WHEN EXPR1 THEN EXPR2 END" |
| 782 | 95 "CASE WHEN EXPR1 THEN EXPR2 WHEN EXPR THEN EXPR1 ELSE EXPR2 END" |
| 783 | 96 "CASE WHEN EXPR1 THEN EXPR2 WHEN EXPR THEN EXPR1 END" |
| 784 | } { |
| 785 | |
| 786 | # If the expression string being parsed contains "EXPR2", then replace |
| 787 | # string "EXPR1" and "EXPR2" with arbitrary SQL expressions. If it |
| 788 | # contains "EXPR", then replace EXPR with an arbitrary SQL expression. |
| 789 | # |
| 790 | set elist [list $expr] |
| 791 | if {[string match *EXPR2* $expr]} { |
| 792 | set elist [list] |
| 793 | foreach {e1 e2} { cname "34+22" } { |
| 794 | lappend elist [string map [list EXPR1 $e1 EXPR2 $e2] $expr] |
| 795 | } |
| 796 | } |
| 797 | if {[string match *EXPR* $expr]} { |
| 798 | set elist2 [list] |
| 799 | foreach el $elist { |
| 800 | foreach e { cname "34+22" } { |
| 801 | lappend elist2 [string map [list EXPR $e] $el] |
| 802 | } |
| 803 | } |
| 804 | set elist $elist2 |
| 805 | } |
| 806 | |
| 807 | set x 0 |
| 808 | foreach e $elist { |
| 809 | incr x |
| 810 | do_test e_expr-12.3.$tn.$x { |
| 811 | set rc [catch { execsql "SELECT $e FROM tblname" } msg] |
| 812 | } {0} |
| 813 | } |
| 814 | } |
| 815 | |
| 816 | # EVIDENCE-OF: R-49462-56079 -- syntax diagram raise-function |
| 817 | # |
| 818 | foreach {tn raiseexpr} { |
| 819 | 1 "RAISE(IGNORE)" |
| 820 | 2 "RAISE(ROLLBACK, 'error message')" |
| 821 | 3 "RAISE(ABORT, 'error message')" |
| 822 | 4 "RAISE(FAIL, 'error message')" |
| 823 | } { |
| 824 | do_execsql_test e_expr-12.4.$tn " |
| 825 | CREATE TRIGGER dbname.tr$tn BEFORE DELETE ON tblname BEGIN |
| 826 | SELECT $raiseexpr ; |
| 827 | END; |
| 828 | " {} |
| 829 | } |
| 830 | |
| dan | 73625ec | 2010-08-17 16:06:08 +0000 | [diff] [blame] | 831 | #------------------------------------------------------------------------- |
| 832 | # Test the statements related to the BETWEEN operator. |
| 833 | # |
| 834 | # EVIDENCE-OF: R-40079-54503 The BETWEEN operator is logically |
| 835 | # equivalent to a pair of comparisons. "x BETWEEN y AND z" is equivalent |
| 836 | # to "x>=y AND x<=z" except that with BETWEEN, the x expression is |
| 837 | # only evaluated once. |
| 838 | # |
| 839 | db func x x |
| 840 | proc x {} { incr ::xcount ; return [expr $::x] } |
| 841 | foreach {tn x expr res nEval} { |
| 842 | 1 10 "x() >= 5 AND x() <= 15" 1 2 |
| 843 | 2 10 "x() BETWEEN 5 AND 15" 1 1 |
| 844 | |
| 845 | 3 5 "x() >= 5 AND x() <= 5" 1 2 |
| 846 | 4 5 "x() BETWEEN 5 AND 5" 1 1 |
| 847 | } { |
| 848 | do_test e_expr-13.1.$tn { |
| 849 | set ::xcount 0 |
| 850 | set a [execsql "SELECT $expr"] |
| 851 | list $::xcount $a |
| 852 | } [list $nEval $res] |
| 853 | } |
| 854 | |
| 855 | # EVIDENCE-OF: R-05155-34454 The precedence of the BETWEEN operator is |
| 856 | # the same as the precedence as operators == and != and LIKE and groups |
| 857 | # left to right. |
| 858 | # |
| 859 | # Therefore, BETWEEN groups more tightly than operator "AND", but less |
| 860 | # so than "<". |
| 861 | # |
| 862 | do_execsql_test e_expr-13.2.1 { SELECT 1 == 10 BETWEEN 0 AND 2 } 1 |
| 863 | do_execsql_test e_expr-13.2.2 { SELECT (1 == 10) BETWEEN 0 AND 2 } 1 |
| 864 | do_execsql_test e_expr-13.2.3 { SELECT 1 == (10 BETWEEN 0 AND 2) } 0 |
| 865 | do_execsql_test e_expr-13.2.4 { SELECT 6 BETWEEN 4 AND 8 == 1 } 1 |
| 866 | do_execsql_test e_expr-13.2.5 { SELECT (6 BETWEEN 4 AND 8) == 1 } 1 |
| 867 | do_execsql_test e_expr-13.2.6 { SELECT 6 BETWEEN 4 AND (8 == 1) } 0 |
| 868 | |
| 869 | do_execsql_test e_expr-13.2.7 { SELECT 5 BETWEEN 0 AND 0 != 1 } 1 |
| 870 | do_execsql_test e_expr-13.2.8 { SELECT (5 BETWEEN 0 AND 0) != 1 } 1 |
| 871 | do_execsql_test e_expr-13.2.9 { SELECT 5 BETWEEN 0 AND (0 != 1) } 0 |
| 872 | do_execsql_test e_expr-13.2.10 { SELECT 1 != 0 BETWEEN 0 AND 2 } 1 |
| 873 | do_execsql_test e_expr-13.2.11 { SELECT (1 != 0) BETWEEN 0 AND 2 } 1 |
| 874 | do_execsql_test e_expr-13.2.12 { SELECT 1 != (0 BETWEEN 0 AND 2) } 0 |
| 875 | |
| dan | f5d3df4 | 2010-08-21 15:51:05 +0000 | [diff] [blame] | 876 | do_execsql_test e_expr-13.2.13 { SELECT 1 LIKE 10 BETWEEN 0 AND 2 } 1 |
| 877 | do_execsql_test e_expr-13.2.14 { SELECT (1 LIKE 10) BETWEEN 0 AND 2 } 1 |
| 878 | do_execsql_test e_expr-13.2.15 { SELECT 1 LIKE (10 BETWEEN 0 AND 2) } 0 |
| 879 | do_execsql_test e_expr-13.2.16 { SELECT 6 BETWEEN 4 AND 8 LIKE 1 } 1 |
| 880 | do_execsql_test e_expr-13.2.17 { SELECT (6 BETWEEN 4 AND 8) LIKE 1 } 1 |
| 881 | do_execsql_test e_expr-13.2.18 { SELECT 6 BETWEEN 4 AND (8 LIKE 1) } 0 |
| dan | 73625ec | 2010-08-17 16:06:08 +0000 | [diff] [blame] | 882 | |
| dan | f5d3df4 | 2010-08-21 15:51:05 +0000 | [diff] [blame] | 883 | do_execsql_test e_expr-13.2.19 { SELECT 0 AND 0 BETWEEN 0 AND 1 } 0 |
| 884 | do_execsql_test e_expr-13.2.20 { SELECT 0 AND (0 BETWEEN 0 AND 1) } 0 |
| 885 | do_execsql_test e_expr-13.2.21 { SELECT (0 AND 0) BETWEEN 0 AND 1 } 1 |
| 886 | do_execsql_test e_expr-13.2.22 { SELECT 0 BETWEEN -1 AND 1 AND 0 } 0 |
| 887 | do_execsql_test e_expr-13.2.23 { SELECT (0 BETWEEN -1 AND 1) AND 0 } 0 |
| 888 | do_execsql_test e_expr-13.2.24 { SELECT 0 BETWEEN -1 AND (1 AND 0) } 1 |
| dan | 73625ec | 2010-08-17 16:06:08 +0000 | [diff] [blame] | 889 | |
| dan | f5d3df4 | 2010-08-21 15:51:05 +0000 | [diff] [blame] | 890 | do_execsql_test e_expr-13.2.25 { SELECT 2 < 3 BETWEEN 0 AND 1 } 1 |
| 891 | do_execsql_test e_expr-13.2.26 { SELECT (2 < 3) BETWEEN 0 AND 1 } 1 |
| 892 | do_execsql_test e_expr-13.2.27 { SELECT 2 < (3 BETWEEN 0 AND 1) } 0 |
| 893 | do_execsql_test e_expr-13.2.28 { SELECT 2 BETWEEN 1 AND 2 < 3 } 0 |
| 894 | do_execsql_test e_expr-13.2.29 { SELECT 2 BETWEEN 1 AND (2 < 3) } 0 |
| 895 | do_execsql_test e_expr-13.2.30 { SELECT (2 BETWEEN 1 AND 2) < 3 } 1 |
| 896 | |
| 897 | #------------------------------------------------------------------------- |
| 898 | # Test the statements related to the LIKE and GLOB operators. |
| 899 | # |
| 900 | # EVIDENCE-OF: R-16584-60189 The LIKE operator does a pattern matching |
| 901 | # comparison. |
| 902 | # |
| 903 | # EVIDENCE-OF: R-11295-04657 The operand to the right of the LIKE |
| 904 | # operator contains the pattern and the left hand operand contains the |
| 905 | # string to match against the pattern. |
| 906 | # |
| 907 | do_execsql_test e_expr-14.1.1 { SELECT 'abc%' LIKE 'abcde' } 0 |
| 908 | do_execsql_test e_expr-14.1.2 { SELECT 'abcde' LIKE 'abc%' } 1 |
| 909 | |
| 910 | # EVIDENCE-OF: R-55406-38524 A percent symbol ("%") in the LIKE pattern |
| 911 | # matches any sequence of zero or more characters in the string. |
| 912 | # |
| 913 | do_execsql_test e_expr-14.2.1 { SELECT 'abde' LIKE 'ab%de' } 1 |
| 914 | do_execsql_test e_expr-14.2.2 { SELECT 'abXde' LIKE 'ab%de' } 1 |
| 915 | do_execsql_test e_expr-14.2.3 { SELECT 'abABCde' LIKE 'ab%de' } 1 |
| 916 | |
| 917 | # EVIDENCE-OF: R-30433-25443 An underscore ("_") in the LIKE pattern |
| 918 | # matches any single character in the string. |
| 919 | # |
| 920 | do_execsql_test e_expr-14.3.1 { SELECT 'abde' LIKE 'ab_de' } 0 |
| 921 | do_execsql_test e_expr-14.3.2 { SELECT 'abXde' LIKE 'ab_de' } 1 |
| 922 | do_execsql_test e_expr-14.3.3 { SELECT 'abABCde' LIKE 'ab_de' } 0 |
| 923 | |
| 924 | # EVIDENCE-OF: R-59007-20454 Any other character matches itself or its |
| 925 | # lower/upper case equivalent (i.e. case-insensitive matching). |
| 926 | # |
| 927 | do_execsql_test e_expr-14.4.1 { SELECT 'abc' LIKE 'aBc' } 1 |
| 928 | do_execsql_test e_expr-14.4.2 { SELECT 'aBc' LIKE 'aBc' } 1 |
| 929 | do_execsql_test e_expr-14.4.3 { SELECT 'ac' LIKE 'aBc' } 0 |
| 930 | |
| 931 | # EVIDENCE-OF: R-23648-58527 SQLite only understands upper/lower case |
| 932 | # for ASCII characters by default. |
| 933 | # |
| 934 | # EVIDENCE-OF: R-04532-11527 The LIKE operator is case sensitive by |
| 935 | # default for unicode characters that are beyond the ASCII range. |
| 936 | # |
| 937 | # EVIDENCE-OF: R-44381-11669 the expression |
| 938 | # 'a' LIKE 'A' is TRUE but |
| 939 | # 'æ' LIKE 'Æ' is FALSE. |
| 940 | # |
| 941 | do_execsql_test e_expr-14.5.1 { SELECT 'A' LIKE 'a' } 1 |
| 942 | do_execsql_test e_expr-14.5.2 "SELECT '\u00c6' LIKE '\u00e6'" 0 |
| 943 | |
| 944 | # EVIDENCE-OF: R-56683-13731 If the optional ESCAPE clause is present, |
| 945 | # then the expression following the ESCAPE keyword must evaluate to a |
| 946 | # string consisting of a single character. |
| 947 | # |
| 948 | do_catchsql_test e_expr-14.6.1 { |
| 949 | SELECT 'A' LIKE 'a' ESCAPE '12' |
| 950 | } {1 {ESCAPE expression must be a single character}} |
| 951 | do_catchsql_test e_expr-14.6.2 { |
| 952 | SELECT 'A' LIKE 'a' ESCAPE '' |
| 953 | } {1 {ESCAPE expression must be a single character}} |
| 954 | do_catchsql_test e_expr-14.6.3 { SELECT 'A' LIKE 'a' ESCAPE 'x' } {0 1} |
| 955 | do_catchsql_test e_expr-14.6.4 "SELECT 'A' LIKE 'a' ESCAPE '\u00e6'" {0 1} |
| 956 | |
| 957 | # EVIDENCE-OF: R-02045-23762 This character may be used in the LIKE |
| 958 | # pattern to include literal percent or underscore characters. |
| 959 | # |
| 960 | # EVIDENCE-OF: R-13345-31830 The escape character followed by a percent |
| 961 | # symbol (%), underscore (_), or a second instance of the escape |
| 962 | # character itself matches a literal percent symbol, underscore, or a |
| 963 | # single escape character, respectively. |
| 964 | # |
| 965 | do_execsql_test e_expr-14.7.1 { SELECT 'abc%' LIKE 'abcX%' ESCAPE 'X' } 1 |
| 966 | do_execsql_test e_expr-14.7.2 { SELECT 'abc5' LIKE 'abcX%' ESCAPE 'X' } 0 |
| 967 | do_execsql_test e_expr-14.7.3 { SELECT 'abc' LIKE 'abcX%' ESCAPE 'X' } 0 |
| 968 | do_execsql_test e_expr-14.7.4 { SELECT 'abcX%' LIKE 'abcX%' ESCAPE 'X' } 0 |
| 969 | do_execsql_test e_expr-14.7.5 { SELECT 'abc%%' LIKE 'abcX%' ESCAPE 'X' } 0 |
| 970 | |
| 971 | do_execsql_test e_expr-14.7.6 { SELECT 'abc_' LIKE 'abcX_' ESCAPE 'X' } 1 |
| 972 | do_execsql_test e_expr-14.7.7 { SELECT 'abc5' LIKE 'abcX_' ESCAPE 'X' } 0 |
| 973 | do_execsql_test e_expr-14.7.8 { SELECT 'abc' LIKE 'abcX_' ESCAPE 'X' } 0 |
| 974 | do_execsql_test e_expr-14.7.9 { SELECT 'abcX_' LIKE 'abcX_' ESCAPE 'X' } 0 |
| 975 | do_execsql_test e_expr-14.7.10 { SELECT 'abc__' LIKE 'abcX_' ESCAPE 'X' } 0 |
| 976 | |
| 977 | do_execsql_test e_expr-14.7.11 { SELECT 'abcX' LIKE 'abcXX' ESCAPE 'X' } 1 |
| 978 | do_execsql_test e_expr-14.7.12 { SELECT 'abc5' LIKE 'abcXX' ESCAPE 'X' } 0 |
| 979 | do_execsql_test e_expr-14.7.13 { SELECT 'abc' LIKE 'abcXX' ESCAPE 'X' } 0 |
| 980 | do_execsql_test e_expr-14.7.14 { SELECT 'abcXX' LIKE 'abcXX' ESCAPE 'X' } 0 |
| 981 | |
| 982 | # EVIDENCE-OF: R-51359-17496 The infix LIKE operator is implemented by |
| 983 | # calling the application-defined SQL functions like(Y,X) or like(Y,X,Z). |
| 984 | # |
| 985 | proc likefunc {args} { |
| 986 | eval lappend ::likeargs $args |
| 987 | return 1 |
| 988 | } |
| 989 | db func like likefunc |
| 990 | set ::likeargs [list] |
| 991 | do_execsql_test e_expr-15.1.1 { SELECT 'abc' LIKE 'def' } 1 |
| 992 | do_test e_expr-15.1.2 { set likeargs } {def abc} |
| 993 | set ::likeargs [list] |
| 994 | do_execsql_test e_expr-15.1.3 { SELECT 'abc' LIKE 'def' ESCAPE 'X' } 1 |
| 995 | do_test e_expr-15.1.4 { set likeargs } {def abc X} |
| 996 | db close |
| 997 | sqlite3 db test.db |
| 998 | |
| 999 | # EVIDENCE-OF: R-22868-25880 The LIKE operator can be made case |
| 1000 | # sensitive using the case_sensitive_like pragma. |
| 1001 | # |
| 1002 | do_execsql_test e_expr-16.1.1 { SELECT 'abcxyz' LIKE 'ABC%' } 1 |
| 1003 | do_execsql_test e_expr-16.1.2 { PRAGMA case_sensitive_like = 1 } {} |
| 1004 | do_execsql_test e_expr-16.1.3 { SELECT 'abcxyz' LIKE 'ABC%' } 0 |
| 1005 | do_execsql_test e_expr-16.1.4 { SELECT 'ABCxyz' LIKE 'ABC%' } 1 |
| 1006 | do_execsql_test e_expr-16.1.5 { PRAGMA case_sensitive_like = 0 } {} |
| 1007 | do_execsql_test e_expr-16.1.6 { SELECT 'abcxyz' LIKE 'ABC%' } 1 |
| 1008 | do_execsql_test e_expr-16.1.7 { SELECT 'ABCxyz' LIKE 'ABC%' } 1 |
| 1009 | |
| 1010 | # EVIDENCE-OF: R-52087-12043 The GLOB operator is similar to LIKE but |
| 1011 | # uses the Unix file globbing syntax for its wildcards. |
| 1012 | # |
| 1013 | # EVIDENCE-OF: R-09813-17279 Also, GLOB is case sensitive, unlike LIKE. |
| 1014 | # |
| 1015 | do_execsql_test e_expr-17.1.1 { SELECT 'abcxyz' GLOB 'abc%' } 0 |
| 1016 | do_execsql_test e_expr-17.1.2 { SELECT 'abcxyz' GLOB 'abc*' } 1 |
| 1017 | do_execsql_test e_expr-17.1.3 { SELECT 'abcxyz' GLOB 'abc___' } 0 |
| 1018 | do_execsql_test e_expr-17.1.4 { SELECT 'abcxyz' GLOB 'abc???' } 1 |
| 1019 | |
| 1020 | do_execsql_test e_expr-17.1.5 { SELECT 'abcxyz' GLOB 'abc*' } 1 |
| 1021 | do_execsql_test e_expr-17.1.6 { SELECT 'ABCxyz' GLOB 'abc*' } 0 |
| 1022 | do_execsql_test e_expr-17.1.7 { SELECT 'abcxyz' GLOB 'ABC*' } 0 |
| 1023 | |
| 1024 | # EVIDENCE-OF: R-39616-20555 Both GLOB and LIKE may be preceded by the |
| 1025 | # NOT keyword to invert the sense of the test. |
| 1026 | # |
| 1027 | do_execsql_test e_expr-17.2.1 { SELECT 'abcxyz' NOT GLOB 'ABC*' } 1 |
| 1028 | do_execsql_test e_expr-17.2.2 { SELECT 'abcxyz' NOT GLOB 'abc*' } 0 |
| 1029 | do_execsql_test e_expr-17.2.3 { SELECT 'abcxyz' NOT LIKE 'ABC%' } 0 |
| 1030 | do_execsql_test e_expr-17.2.4 { SELECT 'abcxyz' NOT LIKE 'abc%' } 0 |
| 1031 | do_execsql_test e_expr-17.2.5 { SELECT 'abdxyz' NOT LIKE 'abc%' } 1 |
| 1032 | |
| 1033 | db nullvalue null |
| 1034 | do_execsql_test e_expr-17.2.6 { SELECT 'abcxyz' NOT GLOB NULL } null |
| 1035 | do_execsql_test e_expr-17.2.7 { SELECT 'abcxyz' NOT LIKE NULL } null |
| 1036 | do_execsql_test e_expr-17.2.8 { SELECT NULL NOT GLOB 'abc*' } null |
| 1037 | do_execsql_test e_expr-17.2.9 { SELECT NULL NOT LIKE 'ABC%' } null |
| 1038 | db nullvalue {} |
| 1039 | |
| 1040 | # EVIDENCE-OF: R-39414-35489 The infix GLOB operator is implemented by |
| 1041 | # calling the function glob(Y,X) and can be modified by overriding that |
| 1042 | # function. |
| 1043 | proc globfunc {args} { |
| 1044 | eval lappend ::globargs $args |
| 1045 | return 1 |
| 1046 | } |
| 1047 | db func glob -argcount 2 globfunc |
| 1048 | set ::globargs [list] |
| 1049 | do_execsql_test e_expr-17.3.1 { SELECT 'abc' GLOB 'def' } 1 |
| 1050 | do_test e_expr-17.3.2 { set globargs } {def abc} |
| 1051 | set ::globargs [list] |
| 1052 | do_execsql_test e_expr-17.3.3 { SELECT 'X' NOT GLOB 'Y' } 0 |
| 1053 | do_test e_expr-17.3.4 { set globargs } {Y X} |
| 1054 | sqlite3 db test.db |
| 1055 | |
| 1056 | # EVIDENCE-OF: R-41650-20872 No regexp() user function is defined by |
| 1057 | # default and so use of the REGEXP operator will normally result in an |
| 1058 | # error message. |
| 1059 | # |
| 1060 | do_catchsql_test e_expr-18.1.1 { |
| 1061 | SELECT regexp('abc', 'def') |
| 1062 | } {1 {no such function: regexp}} |
| 1063 | do_catchsql_test e_expr-18.1.2 { |
| 1064 | SELECT 'abc' REGEXP 'def' |
| 1065 | } {1 {no such function: REGEXP}} |
| 1066 | |
| 1067 | # EVIDENCE-OF: R-33693-50180 The REGEXP operator is a special syntax for |
| 1068 | # the regexp() user function. |
| 1069 | # |
| 1070 | # EVIDENCE-OF: R-57289-13578 If a application-defined SQL function named |
| 1071 | # "regexp" is added at run-time, that function will be called in order |
| 1072 | # to implement the REGEXP operator. |
| 1073 | # |
| 1074 | proc regexpfunc {args} { |
| 1075 | eval lappend ::regexpargs $args |
| 1076 | return 1 |
| 1077 | } |
| 1078 | db func regexp -argcount 2 regexpfunc |
| 1079 | set ::regexpargs [list] |
| 1080 | do_execsql_test e_expr-18.2.1 { SELECT 'abc' REGEXP 'def' } 1 |
| 1081 | do_test e_expr-18.2.2 { set regexpargs } {def abc} |
| 1082 | set ::regexpargs [list] |
| 1083 | do_execsql_test e_expr-18.2.3 { SELECT 'X' NOT REGEXP 'Y' } 0 |
| 1084 | do_test e_expr-18.2.4 { set regexpargs } {Y X} |
| 1085 | sqlite3 db test.db |
| 1086 | |
| 1087 | # EVIDENCE-OF: R-42037-37826 The default match() function implementation |
| 1088 | # raises an exception and is not really useful for anything. |
| 1089 | # |
| 1090 | do_catchsql_test e_expr-19.1.1 { |
| 1091 | SELECT 'abc' MATCH 'def' |
| 1092 | } {1 {unable to use function MATCH in the requested context}} |
| 1093 | do_catchsql_test e_expr-19.1.2 { |
| 1094 | SELECT match('abc', 'def') |
| 1095 | } {1 {unable to use function MATCH in the requested context}} |
| 1096 | |
| 1097 | # EVIDENCE-OF: R-37916-47407 The MATCH operator is a special syntax for |
| 1098 | # the match() application-defined function. |
| 1099 | # |
| 1100 | # EVIDENCE-OF: R-06021-09373 But extensions can override the match() |
| 1101 | # function with more helpful logic. |
| 1102 | # |
| 1103 | proc matchfunc {args} { |
| 1104 | eval lappend ::matchargs $args |
| 1105 | return 1 |
| 1106 | } |
| 1107 | db func match -argcount 2 matchfunc |
| 1108 | set ::matchargs [list] |
| 1109 | do_execsql_test e_expr-19.2.1 { SELECT 'abc' MATCH 'def' } 1 |
| 1110 | do_test e_expr-19.2.2 { set matchargs } {def abc} |
| 1111 | set ::matchargs [list] |
| 1112 | do_execsql_test e_expr-19.2.3 { SELECT 'X' NOT MATCH 'Y' } 0 |
| 1113 | do_test e_expr-19.2.4 { set matchargs } {Y X} |
| 1114 | sqlite3 db test.db |
| 1115 | |
| dan | eb385b4 | 2010-08-24 13:11:52 +0000 | [diff] [blame] | 1116 | #------------------------------------------------------------------------- |
| 1117 | # Test cases for the testable statements related to the CASE expression. |
| 1118 | # |
| 1119 | # EVIDENCE-OF: R-15199-61389 There are two basic forms of the CASE |
| 1120 | # expression: those with a base expression and those without. |
| 1121 | # |
| 1122 | do_execsql_test e_expr-20.1 { |
| 1123 | SELECT CASE WHEN 1 THEN 'true' WHEN 0 THEN 'false' ELSE 'else' END; |
| 1124 | } {true} |
| 1125 | do_execsql_test e_expr-20.2 { |
| 1126 | SELECT CASE 0 WHEN 1 THEN 'true' WHEN 0 THEN 'false' ELSE 'else' END; |
| 1127 | } {false} |
| 1128 | |
| 1129 | proc var {nm} { |
| 1130 | lappend ::varlist $nm |
| 1131 | return [set "::$nm"] |
| 1132 | } |
| 1133 | db func var var |
| 1134 | |
| 1135 | # EVIDENCE-OF: R-30638-59954 In a CASE without a base expression, each |
| 1136 | # WHEN expression is evaluated and the result treated as a boolean, |
| 1137 | # starting with the leftmost and continuing to the right. |
| 1138 | # |
| 1139 | foreach {a b c} {0 0 0} break |
| 1140 | set varlist [list] |
| 1141 | do_execsql_test e_expr-21.1.1 { |
| 1142 | SELECT CASE WHEN var('a') THEN 'A' |
| 1143 | WHEN var('b') THEN 'B' |
| 1144 | WHEN var('c') THEN 'C' END |
| 1145 | } {{}} |
| 1146 | do_test e_expr-21.1.2 { set varlist } {a b c} |
| 1147 | set varlist [list] |
| 1148 | do_execsql_test e_expr-21.1.3 { |
| 1149 | SELECT CASE WHEN var('c') THEN 'C' |
| 1150 | WHEN var('b') THEN 'B' |
| 1151 | WHEN var('a') THEN 'A' |
| 1152 | ELSE 'no result' |
| 1153 | END |
| 1154 | } {{no result}} |
| 1155 | do_test e_expr-21.1.4 { set varlist } {c b a} |
| 1156 | |
| 1157 | # EVIDENCE-OF: R-39009-25596 The result of the CASE expression is the |
| 1158 | # evaluation of the THEN expression that corresponds to the first WHEN |
| 1159 | # expression that evaluates to true. |
| 1160 | # |
| 1161 | foreach {a b c} {0 1 0} break |
| 1162 | do_execsql_test e_expr-21.2.1 { |
| 1163 | SELECT CASE WHEN var('a') THEN 'A' |
| 1164 | WHEN var('b') THEN 'B' |
| 1165 | WHEN var('c') THEN 'C' |
| 1166 | ELSE 'no result' |
| 1167 | END |
| 1168 | } {B} |
| 1169 | foreach {a b c} {0 1 1} break |
| 1170 | do_execsql_test e_expr-21.2.2 { |
| 1171 | SELECT CASE WHEN var('a') THEN 'A' |
| 1172 | WHEN var('b') THEN 'B' |
| 1173 | WHEN var('c') THEN 'C' |
| 1174 | ELSE 'no result' |
| 1175 | END |
| 1176 | } {B} |
| 1177 | foreach {a b c} {0 0 1} break |
| 1178 | do_execsql_test e_expr-21.2.3 { |
| 1179 | SELECT CASE WHEN var('a') THEN 'A' |
| 1180 | WHEN var('b') THEN 'B' |
| 1181 | WHEN var('c') THEN 'C' |
| 1182 | ELSE 'no result' |
| 1183 | END |
| 1184 | } {C} |
| 1185 | |
| 1186 | # EVIDENCE-OF: R-24227-04807 Or, if none of the WHEN expressions |
| 1187 | # evaluate to true, the result of evaluating the ELSE expression, if |
| 1188 | # any. |
| 1189 | # |
| 1190 | foreach {a b c} {0 0 0} break |
| 1191 | do_execsql_test e_expr-21.3.1 { |
| 1192 | SELECT CASE WHEN var('a') THEN 'A' |
| 1193 | WHEN var('b') THEN 'B' |
| 1194 | WHEN var('c') THEN 'C' |
| 1195 | ELSE 'no result' |
| 1196 | END |
| 1197 | } {{no result}} |
| 1198 | |
| 1199 | # EVIDENCE-OF: R-14168-07579 If there is no ELSE expression and none of |
| 1200 | # the WHEN expressions are true, then the overall result is NULL. |
| 1201 | # |
| 1202 | db nullvalue null |
| 1203 | do_execsql_test e_expr-21.3.2 { |
| 1204 | SELECT CASE WHEN var('a') THEN 'A' |
| 1205 | WHEN var('b') THEN 'B' |
| 1206 | WHEN var('c') THEN 'C' |
| 1207 | END |
| 1208 | } {null} |
| 1209 | db nullvalue {} |
| 1210 | |
| 1211 | # EVIDENCE-OF: R-13943-13592 A NULL result is considered untrue when |
| 1212 | # evaluating WHEN terms. |
| 1213 | # |
| 1214 | do_execsql_test e_expr-21.4.1 { |
| 1215 | SELECT CASE WHEN NULL THEN 'A' WHEN 1 THEN 'B' END |
| 1216 | } {B} |
| 1217 | do_execsql_test e_expr-21.4.2 { |
| 1218 | SELECT CASE WHEN 0 THEN 'A' WHEN NULL THEN 'B' ELSE 'C' END |
| 1219 | } {C} |
| 1220 | |
| 1221 | # EVIDENCE-OF: R-38620-19499 In a CASE with a base expression, the base |
| 1222 | # expression is evaluated just once and the result is compared against |
| 1223 | # the evaluation of each WHEN expression from left to right. |
| 1224 | # |
| 1225 | # Note: This test case tests the "evaluated just once" part of the above |
| 1226 | # statement. Tests associated with the next two statements test that the |
| 1227 | # comparisons take place. |
| 1228 | # |
| 1229 | foreach {a b c} [list [expr 3] [expr 4] [expr 5]] break |
| 1230 | set ::varlist [list] |
| 1231 | do_execsql_test e_expr-22.1.1 { |
| 1232 | SELECT CASE var('a') WHEN 1 THEN 'A' WHEN 2 THEN 'B' WHEN 3 THEN 'C' END |
| 1233 | } {C} |
| 1234 | do_test e_expr-22.1.2 { set ::varlist } {a} |
| 1235 | |
| 1236 | # EVIDENCE-OF: R-07667-49537 The result of the CASE expression is the |
| 1237 | # evaluation of the THEN expression that corresponds to the first WHEN |
| 1238 | # expression for which the comparison is true. |
| 1239 | # |
| 1240 | do_execsql_test e_expr-22.2.1 { |
| 1241 | SELECT CASE 23 WHEN 1 THEN 'A' WHEN 23 THEN 'B' WHEN 23 THEN 'C' END |
| 1242 | } {B} |
| 1243 | do_execsql_test e_expr-22.2.2 { |
| 1244 | SELECT CASE 1 WHEN 1 THEN 'A' WHEN 23 THEN 'B' WHEN 23 THEN 'C' END |
| 1245 | } {A} |
| 1246 | |
| 1247 | # EVIDENCE-OF: R-47543-32145 Or, if none of the WHEN expressions |
| 1248 | # evaluate to a value equal to the base expression, the result of |
| 1249 | # evaluating the ELSE expression, if any. |
| 1250 | # |
| 1251 | do_execsql_test e_expr-22.3.1 { |
| 1252 | SELECT CASE 24 WHEN 1 THEN 'A' WHEN 23 THEN 'B' WHEN 23 THEN 'C' ELSE 'D' END |
| 1253 | } {D} |
| 1254 | |
| 1255 | # EVIDENCE-OF: R-54721-48557 If there is no ELSE expression and none of |
| 1256 | # the WHEN expressions produce a result equal to the base expression, |
| 1257 | # the overall result is NULL. |
| 1258 | # |
| 1259 | do_execsql_test e_expr-22.4.1 { |
| 1260 | SELECT CASE 24 WHEN 1 THEN 'A' WHEN 23 THEN 'B' WHEN 23 THEN 'C' END |
| 1261 | } {{}} |
| 1262 | db nullvalue null |
| 1263 | do_execsql_test e_expr-22.4.2 { |
| 1264 | SELECT CASE 24 WHEN 1 THEN 'A' WHEN 23 THEN 'B' WHEN 23 THEN 'C' END |
| 1265 | } {null} |
| 1266 | db nullvalue {} |
| 1267 | |
| 1268 | # EVIDENCE-OF: R-11479-62774 When comparing a base expression against a |
| 1269 | # WHEN expression, the same collating sequence, affinity, and |
| 1270 | # NULL-handling rules apply as if the base expression and WHEN |
| 1271 | # expression are respectively the left- and right-hand operands of an = |
| 1272 | # operator. |
| 1273 | # |
| 1274 | proc rev {str} { |
| 1275 | set ret "" |
| 1276 | set chars [split $str] |
| 1277 | for {set i [expr [llength $chars]-1]} {$i>=0} {incr i -1} { |
| 1278 | append ret [lindex $chars $i] |
| 1279 | } |
| 1280 | set ret |
| 1281 | } |
| 1282 | proc reverse {lhs rhs} { |
| 1283 | string compare [rev $lhs] [ref $rhs] |
| 1284 | } |
| 1285 | db collate reverse reverse |
| 1286 | do_execsql_test e_expr-23.1.1 { |
| 1287 | CREATE TABLE t1( |
| 1288 | a TEXT COLLATE NOCASE, |
| 1289 | b COLLATE REVERSE, |
| 1290 | c INTEGER, |
| 1291 | d BLOB |
| 1292 | ); |
| 1293 | INSERT INTO t1 VALUES('abc', 'cba', 55, 34.5); |
| 1294 | } {} |
| 1295 | do_execsql_test e_expr-23.1.2 { |
| 1296 | SELECT CASE a WHEN 'xyz' THEN 'A' WHEN 'AbC' THEN 'B' END FROM t1 |
| 1297 | } {B} |
| 1298 | do_execsql_test e_expr-23.1.3 { |
| 1299 | SELECT CASE 'AbC' WHEN 'abc' THEN 'A' WHEN a THEN 'B' END FROM t1 |
| 1300 | } {B} |
| 1301 | do_execsql_test e_expr-23.1.4 { |
| 1302 | SELECT CASE a WHEN b THEN 'A' ELSE 'B' END FROM t1 |
| 1303 | } {B} |
| 1304 | do_execsql_test e_expr-23.1.5 { |
| 1305 | SELECT CASE b WHEN a THEN 'A' ELSE 'B' END FROM t1 |
| 1306 | } {A} |
| 1307 | do_execsql_test e_expr-23.1.6 { |
| 1308 | SELECT CASE 55 WHEN '55' THEN 'A' ELSE 'B' END |
| 1309 | } {B} |
| 1310 | do_execsql_test e_expr-23.1.7 { |
| 1311 | SELECT CASE c WHEN '55' THEN 'A' ELSE 'B' END FROM t1 |
| 1312 | } {A} |
| 1313 | do_execsql_test e_expr-23.1.8 { |
| 1314 | SELECT CASE '34.5' WHEN d THEN 'A' ELSE 'B' END FROM t1 |
| 1315 | } {B} |
| 1316 | do_execsql_test e_expr-23.1.9 { |
| 1317 | SELECT CASE NULL WHEN NULL THEN 'A' ELSE 'B' END |
| 1318 | } {B} |
| 1319 | |
| 1320 | # EVIDENCE-OF: R-37304-39405 If the base expression is NULL then the |
| 1321 | # result of the CASE is always the result of evaluating the ELSE |
| 1322 | # expression if it exists, or NULL if it does not. |
| 1323 | # |
| 1324 | do_execsql_test e_expr-24.1.1 { |
| 1325 | SELECT CASE NULL WHEN 'abc' THEN 'A' WHEN 'def' THEN 'B' END; |
| 1326 | } {{}} |
| 1327 | do_execsql_test e_expr-24.1.2 { |
| 1328 | SELECT CASE NULL WHEN 'abc' THEN 'A' WHEN 'def' THEN 'B' ELSE 'C' END; |
| 1329 | } {C} |
| 1330 | |
| 1331 | # EVIDENCE-OF: R-56280-17369 Both forms of the CASE expression use lazy, |
| 1332 | # or short-circuit, evaluation. |
| 1333 | # |
| 1334 | set varlist [list] |
| 1335 | foreach {a b c} {0 1 0} break |
| 1336 | do_execsql_test e_expr-25.1.1 { |
| 1337 | SELECT CASE WHEN var('a') THEN 'A' |
| 1338 | WHEN var('b') THEN 'B' |
| 1339 | WHEN var('c') THEN 'C' |
| 1340 | END |
| 1341 | } {B} |
| 1342 | do_test e_expr-25.1.2 { set ::varlist } {a b} |
| 1343 | set varlist [list] |
| 1344 | do_execsql_test e_expr-25.1.3 { |
| 1345 | SELECT CASE '0' WHEN var('a') THEN 'A' |
| 1346 | WHEN var('b') THEN 'B' |
| 1347 | WHEN var('c') THEN 'C' |
| 1348 | END |
| 1349 | } {A} |
| 1350 | do_test e_expr-25.1.4 { set ::varlist } {a} |
| 1351 | |
| 1352 | # EVIDENCE-OF: R-34773-62253 The only difference between the following |
| 1353 | # two CASE expressions is that the x expression is evaluated exactly |
| 1354 | # once in the first example but might be evaluated multiple times in the |
| 1355 | # second: CASE x WHEN w1 THEN r1 WHEN w2 THEN r2 ELSE r3 END CASE WHEN |
| 1356 | # x=w1 THEN r1 WHEN x=w2 THEN r2 ELSE r3 END |
| 1357 | # |
| 1358 | proc ceval {x} { |
| 1359 | incr ::evalcount |
| 1360 | return $x |
| 1361 | } |
| 1362 | db func ceval ceval |
| 1363 | set ::evalcount 0 |
| 1364 | |
| 1365 | do_execsql_test e_expr-26.1.1 { |
| 1366 | CREATE TABLE t2(x, w1, r1, w2, r2, r3); |
| 1367 | INSERT INTO t2 VALUES(1, 1, 'R1', 2, 'R2', 'R3'); |
| 1368 | INSERT INTO t2 VALUES(2, 1, 'R1', 2, 'R2', 'R3'); |
| 1369 | INSERT INTO t2 VALUES(3, 1, 'R1', 2, 'R2', 'R3'); |
| 1370 | } {} |
| 1371 | do_execsql_test e_expr-26.1.2 { |
| 1372 | SELECT CASE x WHEN w1 THEN r1 WHEN w2 THEN r2 ELSE r3 END FROM t2 |
| 1373 | } {R1 R2 R3} |
| 1374 | do_execsql_test e_expr-26.1.3 { |
| 1375 | SELECT CASE WHEN x=w1 THEN r1 WHEN x=w2 THEN r2 ELSE r3 END FROM t2 |
| 1376 | } {R1 R2 R3} |
| 1377 | |
| 1378 | do_execsql_test e_expr-26.1.4 { |
| 1379 | SELECT CASE ceval(x) WHEN w1 THEN r1 WHEN w2 THEN r2 ELSE r3 END FROM t2 |
| 1380 | } {R1 R2 R3} |
| 1381 | do_test e_expr-26.1.5 { set ::evalcount } {3} |
| 1382 | set ::evalcount 0 |
| 1383 | do_execsql_test e_expr-26.1.6 { |
| 1384 | SELECT CASE |
| 1385 | WHEN ceval(x)=w1 THEN r1 |
| 1386 | WHEN ceval(x)=w2 THEN r2 |
| 1387 | ELSE r3 END |
| 1388 | FROM t2 |
| 1389 | } {R1 R2 R3} |
| 1390 | do_test e_expr-26.1.6 { set ::evalcount } {5} |
| dan | 994e940 | 2010-08-16 18:26:30 +0000 | [diff] [blame] | 1391 | |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1392 | |
| 1393 | #------------------------------------------------------------------------- |
| 1394 | # Test statements related to CAST expressions. |
| 1395 | # |
| 1396 | # EVIDENCE-OF: R-65079-31758 Application of a CAST expression is |
| 1397 | # different to application of a column affinity, as with a CAST |
| 1398 | # expression the storage class conversion is forced even if it is lossy |
| 1399 | # and irrreversible. |
| 1400 | # |
| 1401 | do_execsql_test e_expr-27.1.1 { |
| 1402 | CREATE TABLE t3(a TEXT, b REAL, c INTEGER); |
| 1403 | INSERT INTO t3 VALUES(X'555655', '1.23abc', 4.5); |
| 1404 | SELECT typeof(a), a, typeof(b), b, typeof(c), c FROM t3; |
| 1405 | } {blob UVU text 1.23abc real 4.5} |
| 1406 | do_execsql_test e_expr-27.1.2 { |
| 1407 | SELECT |
| 1408 | typeof(CAST(X'555655' as TEXT)), CAST(X'555655' as TEXT), |
| 1409 | typeof(CAST('1.23abc' as REAL)), CAST('1.23abc' as REAL), |
| 1410 | typeof(CAST(4.5 as INTEGER)), CAST(4.5 as INTEGER) |
| 1411 | } {text UVU real 1.23 integer 4} |
| 1412 | |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1413 | # EVIDENCE-OF: R-27225-65050 If the value of <expr> is NULL, then |
| 1414 | # the result of the CAST expression is also NULL. |
| 1415 | # |
| 1416 | do_expr_test e_expr-27.2.1 { CAST(NULL AS integer) } null {} |
| 1417 | do_expr_test e_expr-27.2.2 { CAST(NULL AS text) } null {} |
| 1418 | do_expr_test e_expr-27.2.3 { CAST(NULL AS blob) } null {} |
| 1419 | do_expr_test e_expr-27.2.4 { CAST(NULL AS number) } null {} |
| 1420 | |
| 1421 | # EVIDENCE-OF: R-31076-23575 Casting a value to a <type-name> with |
| 1422 | # no affinity causes the value to be converted into a BLOB. |
| 1423 | # |
| 1424 | do_expr_test e_expr-27.3.1 { CAST('abc' AS blob) } blob abc |
| 1425 | do_expr_test e_expr-27.3.2 { CAST('def' AS shobblob_x) } blob def |
| 1426 | do_expr_test e_expr-27.3.3 { CAST('ghi' AS abbLOb10) } blob ghi |
| 1427 | |
| 1428 | # EVIDENCE-OF: R-22956-37754 Casting to a BLOB consists of first casting |
| 1429 | # the value to TEXT in the encoding of the database connection, then |
| 1430 | # interpreting the resulting byte sequence as a BLOB instead of as TEXT. |
| 1431 | # |
| 1432 | do_qexpr_test e_expr-27.4.1 { CAST('ghi' AS blob) } X'676869' |
| 1433 | do_qexpr_test e_expr-27.4.2 { CAST(456 AS blob) } X'343536' |
| 1434 | do_qexpr_test e_expr-27.4.3 { CAST(1.78 AS blob) } X'312E3738' |
| 1435 | rename db db2 |
| 1436 | sqlite3 db :memory: |
| 1437 | db eval { PRAGMA encoding = 'utf-16le' } |
| 1438 | do_qexpr_test e_expr-27.4.4 { CAST('ghi' AS blob) } X'670068006900' |
| 1439 | do_qexpr_test e_expr-27.4.5 { CAST(456 AS blob) } X'340035003600' |
| 1440 | do_qexpr_test e_expr-27.4.6 { CAST(1.78 AS blob) } X'31002E0037003800' |
| 1441 | db close |
| 1442 | sqlite3 db :memory: |
| 1443 | db eval { PRAGMA encoding = 'utf-16be' } |
| 1444 | do_qexpr_test e_expr-27.4.7 { CAST('ghi' AS blob) } X'006700680069' |
| 1445 | do_qexpr_test e_expr-27.4.8 { CAST(456 AS blob) } X'003400350036' |
| 1446 | do_qexpr_test e_expr-27.4.9 { CAST(1.78 AS blob) } X'0031002E00370038' |
| 1447 | db close |
| 1448 | rename db2 db |
| 1449 | |
| 1450 | # EVIDENCE-OF: R-04207-37981 To cast a BLOB value to TEXT, the sequence |
| 1451 | # of bytes that make up the BLOB is interpreted as text encoded using |
| 1452 | # the database encoding. |
| 1453 | # |
| 1454 | do_expr_test e_expr-28.1.1 { CAST (X'676869' AS text) } text ghi |
| 1455 | do_expr_test e_expr-28.1.2 { CAST (X'670068006900' AS text) } text g |
| 1456 | rename db db2 |
| 1457 | sqlite3 db :memory: |
| 1458 | db eval { PRAGMA encoding = 'utf-16le' } |
| 1459 | do_expr_test e_expr-28.1.3 { CAST (X'676869' AS text) == 'ghi' } integer 0 |
| 1460 | do_expr_test e_expr-28.1.4 { CAST (X'670068006900' AS text) } text ghi |
| 1461 | db close |
| 1462 | rename db2 db |
| 1463 | |
| 1464 | # EVIDENCE-OF: R-22235-47006 Casting an INTEGER or REAL value into TEXT |
| 1465 | # renders the value as if via sqlite3_snprintf() except that the |
| 1466 | # resulting TEXT uses the encoding of the database connection. |
| 1467 | # |
| 1468 | do_expr_test e_expr-28.2.1 { CAST (1 AS text) } text 1 |
| 1469 | do_expr_test e_expr-28.2.2 { CAST (45 AS text) } text 45 |
| 1470 | do_expr_test e_expr-28.2.3 { CAST (-45 AS text) } text -45 |
| 1471 | do_expr_test e_expr-28.2.4 { CAST (8.8 AS text) } text 8.8 |
| 1472 | do_expr_test e_expr-28.2.5 { CAST (2.3e+5 AS text) } text 230000.0 |
| 1473 | do_expr_test e_expr-28.2.6 { CAST (-2.3e-5 AS text) } text -2.3e-05 |
| 1474 | do_expr_test e_expr-28.2.7 { CAST (0.0 AS text) } text 0.0 |
| 1475 | do_expr_test e_expr-28.2.7 { CAST (0 AS text) } text 0 |
| 1476 | |
| 1477 | # EVIDENCE-OF: R-26346-36443 When casting a BLOB value to a REAL, the |
| 1478 | # value is first converted to TEXT. |
| 1479 | # |
| 1480 | do_expr_test e_expr-29.1.1 { CAST (X'312E3233' AS REAL) } real 1.23 |
| 1481 | do_expr_test e_expr-29.1.2 { CAST (X'3233302E30' AS REAL) } real 230.0 |
| 1482 | do_expr_test e_expr-29.1.3 { CAST (X'2D392E3837' AS REAL) } real -9.87 |
| 1483 | do_expr_test e_expr-29.1.4 { CAST (X'302E30303031' AS REAL) } real 0.0001 |
| 1484 | rename db db2 |
| 1485 | sqlite3 db :memory: |
| 1486 | db eval { PRAGMA encoding = 'utf-16le' } |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1487 | do_expr_test e_expr-29.1.5 { |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1488 | CAST (X'31002E0032003300' AS REAL) } real 1.23 |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1489 | do_expr_test e_expr-29.1.6 { |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1490 | CAST (X'3200330030002E003000' AS REAL) } real 230.0 |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1491 | do_expr_test e_expr-29.1.7 { |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1492 | CAST (X'2D0039002E0038003700' AS REAL) } real -9.87 |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1493 | do_expr_test e_expr-29.1.8 { |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1494 | CAST (X'30002E003000300030003100' AS REAL) } real 0.0001 |
| 1495 | db close |
| 1496 | rename db2 db |
| 1497 | |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1498 | # EVIDENCE-OF: R-54898-34554 When casting a TEXT value to REAL, the |
| 1499 | # longest possible prefix of the value that can be interpreted as a real |
| 1500 | # number is extracted from the TEXT value and the remainder ignored. |
| 1501 | # |
| 1502 | do_expr_test e_expr-29.2.1 { CAST('1.23abcd' AS REAL) } real 1.23 |
| 1503 | do_expr_test e_expr-29.2.2 { CAST('1.45.23abcd' AS REAL) } real 1.45 |
| 1504 | do_expr_test e_expr-29.2.3 { CAST('-2.12e-01ABC' AS REAL) } real -0.212 |
| 1505 | do_expr_test e_expr-29.2.4 { CAST('1 2 3 4' AS REAL) } real 1.0 |
| dan | 51f3a50 | 2010-08-26 19:05:23 +0000 | [diff] [blame] | 1506 | |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1507 | # EVIDENCE-OF: R-11321-47427 Any leading spaces in the TEXT value are |
| 1508 | # ignored when converging from TEXT to REAL. |
| 1509 | # |
| 1510 | do_expr_test e_expr-29.3.1 { CAST(' 1.23abcd' AS REAL) } real 1.23 |
| 1511 | do_expr_test e_expr-29.3.2 { CAST(' 1.45.23abcd' AS REAL) } real 1.45 |
| 1512 | do_expr_test e_expr-29.3.3 { CAST(' -2.12e-01ABC' AS REAL) } real -0.212 |
| 1513 | do_expr_test e_expr-29.3.4 { CAST(' 1 2 3 4' AS REAL) } real 1.0 |
| 1514 | |
| 1515 | # EVIDENCE-OF: R-22662-28218 If there is no prefix that can be |
| 1516 | # interpreted as a real number, the result of the conversion is 0.0. |
| 1517 | # |
| 1518 | do_expr_test e_expr-29.4.1 { CAST('' AS REAL) } real 0.0 |
| 1519 | do_expr_test e_expr-29.4.2 { CAST('not a number' AS REAL) } real 0.0 |
| 1520 | do_expr_test e_expr-29.4.3 { CAST('XXI' AS REAL) } real 0.0 |
| 1521 | |
| 1522 | # EVIDENCE-OF: R-21829-14563 When casting a BLOB value to INTEGER, the |
| 1523 | # value is first converted to TEXT. |
| 1524 | # |
| 1525 | do_expr_test e_expr-30.1.1 { CAST(X'313233' AS INTEGER) } integer 123 |
| 1526 | do_expr_test e_expr-30.1.2 { CAST(X'2D363738' AS INTEGER) } integer -678 |
| 1527 | do_expr_test e_expr-30.1.3 { |
| 1528 | CAST(X'31303030303030' AS INTEGER) |
| 1529 | } integer 1000000 |
| 1530 | do_expr_test e_expr-30.1.4 { |
| 1531 | CAST(X'2D31313235383939393036383432363234' AS INTEGER) |
| 1532 | } integer -1125899906842624 |
| 1533 | |
| 1534 | rename db db2 |
| 1535 | sqlite3 db :memory: |
| 1536 | execsql { PRAGMA encoding = 'utf-16be' } |
| 1537 | do_expr_test e_expr-30.1.5 { CAST(X'003100320033' AS INTEGER) } integer 123 |
| 1538 | do_expr_test e_expr-30.1.6 { CAST(X'002D003600370038' AS INTEGER) } integer -678 |
| 1539 | do_expr_test e_expr-30.1.7 { |
| 1540 | CAST(X'0031003000300030003000300030' AS INTEGER) |
| 1541 | } integer 1000000 |
| 1542 | do_expr_test e_expr-30.1.8 { |
| 1543 | CAST(X'002D0031003100320035003800390039003900300036003800340032003600320034' AS INTEGER) |
| 1544 | } integer -1125899906842624 |
| 1545 | db close |
| 1546 | rename db2 db |
| 1547 | |
| 1548 | # EVIDENCE-OF: R-47612-45842 When casting a TEXT value to INTEGER, the |
| 1549 | # longest possible prefix of the value that can be interpreted as an |
| 1550 | # integer number is extracted from the TEXT value and the remainder |
| 1551 | # ignored. |
| 1552 | # |
| 1553 | do_expr_test e_expr-30.2.1 { CAST('123abcd' AS INT) } integer 123 |
| 1554 | do_expr_test e_expr-30.2.2 { CAST('14523abcd' AS INT) } integer 14523 |
| 1555 | do_expr_test e_expr-30.2.3 { CAST('-2.12e-01ABC' AS INT) } integer -2 |
| 1556 | do_expr_test e_expr-30.2.4 { CAST('1 2 3 4' AS INT) } integer 1 |
| 1557 | |
| 1558 | # EVIDENCE-OF: R-34400-33772 Any leading spaces in the TEXT value when |
| 1559 | # converting from TEXT to INTEGER are ignored. |
| 1560 | # |
| 1561 | do_expr_test e_expr-30.3.1 { CAST(' 123abcd' AS INT) } integer 123 |
| 1562 | do_expr_test e_expr-30.3.2 { CAST(' 14523abcd' AS INT) } integer 14523 |
| 1563 | do_expr_test e_expr-30.3.3 { CAST(' -2.12e-01ABC' AS INT) } integer -2 |
| 1564 | do_expr_test e_expr-30.3.4 { CAST(' 1 2 3 4' AS INT) } integer 1 |
| 1565 | |
| 1566 | # EVIDENCE-OF: R-43164-44276 If there is no prefix that can be |
| 1567 | # interpreted as an integer number, the result of the conversion is 0. |
| 1568 | # |
| 1569 | do_expr_test e_expr-30.4.1 { CAST('' AS INTEGER) } integer 0 |
| 1570 | do_expr_test e_expr-30.4.2 { CAST('not a number' AS INTEGER) } integer 0 |
| 1571 | do_expr_test e_expr-30.4.3 { CAST('XXI' AS INTEGER) } integer 0 |
| 1572 | |
| 1573 | # EVIDENCE-OF: R-00741-38776 A cast of a REAL value into an INTEGER will |
| 1574 | # truncate the fractional part of the REAL. |
| 1575 | # |
| 1576 | do_expr_test e_expr-31.1.1 { CAST(3.14159 AS INTEGER) } integer 3 |
| 1577 | do_expr_test e_expr-31.1.2 { CAST(1.99999 AS INTEGER) } integer 1 |
| 1578 | do_expr_test e_expr-31.1.3 { CAST(-1.99999 AS INTEGER) } integer -1 |
| 1579 | do_expr_test e_expr-31.1.4 { CAST(-0.99999 AS INTEGER) } integer 0 |
| 1580 | |
| 1581 | # EVIDENCE-OF: R-06126-36021 If an REAL is too large to be represented |
| 1582 | # as an INTEGER then the result of the cast is the largest negative |
| 1583 | # integer: -9223372036854775808. |
| 1584 | # |
| 1585 | do_expr_test e_expr-31.2.1 { CAST(2e+50 AS INT) } integer -9223372036854775808 |
| 1586 | do_expr_test e_expr-31.2.2 { CAST(-2e+50 AS INT) } integer -9223372036854775808 |
| 1587 | do_expr_test e_expr-31.2.3 { |
| 1588 | CAST(-9223372036854775809.0 AS INT) |
| 1589 | } integer -9223372036854775808 |
| 1590 | do_expr_test e_expr-31.2.4 { |
| 1591 | CAST(9223372036854775809.0 AS INT) |
| 1592 | } integer -9223372036854775808 |
| 1593 | |
| 1594 | |
| 1595 | # EVIDENCE-OF: R-09295-61337 Casting a TEXT or BLOB value into NUMERIC |
| 1596 | # first does a forced conversion into REAL but then further converts the |
| 1597 | # result into INTEGER if and only if the conversion from REAL to INTEGER |
| 1598 | # is lossless and reversible. |
| 1599 | # |
| 1600 | do_expr_test e_expr-32.1.1 { CAST('45' AS NUMERIC) } integer 45 |
| 1601 | do_expr_test e_expr-32.1.2 { CAST('45.0' AS NUMERIC) } integer 45 |
| 1602 | do_expr_test e_expr-32.1.3 { CAST('45.2' AS NUMERIC) } real 45.2 |
| 1603 | do_expr_test e_expr-32.1.4 { CAST('11abc' AS NUMERIC) } integer 11 |
| 1604 | do_expr_test e_expr-32.1.5 { CAST('11.1abc' AS NUMERIC) } real 11.1 |
| 1605 | |
| 1606 | # EVIDENCE-OF: R-30347-18702 Casting a REAL or INTEGER value to NUMERIC |
| 1607 | # is a no-op, even if a real value could be losslessly converted to an |
| 1608 | # integer. |
| 1609 | # |
| 1610 | do_expr_test e_expr-32.2.1 { CAST(13.0 AS NUMERIC) } real 13.0 |
| 1611 | do_expr_test e_expr-32.2.2 { CAST(13.5 AS NUMERIC) } real 13.5 |
| 1612 | |
| 1613 | do_expr_test e_expr-32.2.3 { |
| 1614 | CAST(-9223372036854775808 AS NUMERIC) |
| 1615 | } integer -9223372036854775808 |
| 1616 | do_expr_test e_expr-32.2.4 { |
| 1617 | CAST(9223372036854775807 AS NUMERIC) |
| 1618 | } integer 9223372036854775807 |
| 1619 | |
| 1620 | # EVIDENCE-OF: R-64550-29191 Note that the result from casting any |
| 1621 | # non-BLOB value into a BLOB and the result from casting any BLOB value |
| 1622 | # into a non-BLOB value may be different depending on whether the |
| 1623 | # database encoding is UTF-8, UTF-16be, or UTF-16le. |
| 1624 | # |
| 1625 | sqlite3 db1 :memory: ; db1 eval { PRAGMA encoding = 'utf-8' } |
| 1626 | sqlite3 db2 :memory: ; db2 eval { PRAGMA encoding = 'utf-16le' } |
| 1627 | sqlite3 db3 :memory: ; db3 eval { PRAGMA encoding = 'utf-16be' } |
| 1628 | foreach {tn castexpr differs} { |
| 1629 | 1 { CAST(123 AS BLOB) } 1 |
| 1630 | 2 { CAST('' AS BLOB) } 0 |
| 1631 | 3 { CAST('abcd' AS BLOB) } 1 |
| 1632 | |
| 1633 | 4 { CAST(X'abcd' AS TEXT) } 1 |
| 1634 | 5 { CAST(X'' AS TEXT) } 0 |
| 1635 | } { |
| 1636 | set r1 [db1 eval "SELECT typeof($castexpr), quote($castexpr)"] |
| 1637 | set r2 [db2 eval "SELECT typeof($castexpr), quote($castexpr)"] |
| 1638 | set r3 [db3 eval "SELECT typeof($castexpr), quote($castexpr)"] |
| 1639 | |
| 1640 | if {$differs} { |
| 1641 | set res [expr {$r1!=$r2 && $r2!=$r3}] |
| 1642 | } else { |
| 1643 | set res [expr {$r1==$r2 && $r2==$r3}] |
| 1644 | } |
| 1645 | |
| 1646 | do_test e_expr-33.1.$tn {set res} 1 |
| 1647 | } |
| 1648 | db1 close |
| 1649 | db2 close |
| 1650 | db3 close |
| 1651 | |
| dan | 4336cc4 | 2010-09-02 11:53:12 +0000 | [diff] [blame] | 1652 | #------------------------------------------------------------------------- |
| 1653 | # Test statements related to the EXISTS and NOT EXISTS operators. |
| 1654 | # |
| 1655 | catch { db close } |
| 1656 | file delete -force test.db |
| 1657 | sqlite3 db test.db |
| 1658 | |
| 1659 | do_execsql_test e_expr-34.1 { |
| 1660 | CREATE TABLE t1(a, b); |
| 1661 | INSERT INTO t1 VALUES(1, 2); |
| 1662 | INSERT INTO t1 VALUES(NULL, 2); |
| 1663 | INSERT INTO t1 VALUES(1, NULL); |
| 1664 | INSERT INTO t1 VALUES(NULL, NULL); |
| 1665 | } {} |
| 1666 | |
| 1667 | # EVIDENCE-OF: R-25588-27181 The EXISTS operator always evaluates to one |
| 1668 | # of the integer values 0 and 1. |
| 1669 | # |
| 1670 | # This statement is not tested by itself. Instead, all e_expr-34.* tests |
| 1671 | # following this point explicitly test that specific invocations of EXISTS |
| 1672 | # return either integer 0 or integer 1. |
| 1673 | # |
| 1674 | |
| 1675 | # EVIDENCE-OF: R-58553-63740 If executing the SELECT statement specified |
| 1676 | # as the right-hand operand of the EXISTS operator would return one or |
| 1677 | # more rows, then the EXISTS operator evaluates to 1. |
| 1678 | # |
| 1679 | foreach {tn expr} { |
| 1680 | 1 { EXISTS ( SELECT a FROM t1 ) } |
| 1681 | 2 { EXISTS ( SELECT b FROM t1 ) } |
| 1682 | 3 { EXISTS ( SELECT 24 ) } |
| 1683 | 4 { EXISTS ( SELECT NULL ) } |
| 1684 | 5 { EXISTS ( SELECT a FROM t1 WHERE a IS NULL ) } |
| 1685 | } { |
| 1686 | do_expr_test e_expr-34.2.$tn $expr integer 1 |
| 1687 | } |
| 1688 | |
| 1689 | # EVIDENCE-OF: R-19673-40972 If executing the SELECT would return no |
| 1690 | # rows at all, then the EXISTS operator evaluates to 0. |
| 1691 | # |
| 1692 | foreach {tn expr} { |
| 1693 | 1 { EXISTS ( SELECT a FROM t1 WHERE 0) } |
| 1694 | 2 { EXISTS ( SELECT b FROM t1 WHERE a = 5) } |
| 1695 | 3 { EXISTS ( SELECT 24 WHERE 0) } |
| 1696 | 4 { EXISTS ( SELECT NULL WHERE 1=2) } |
| 1697 | } { |
| 1698 | do_expr_test e_expr-34.3.$tn $expr integer 0 |
| 1699 | } |
| 1700 | |
| 1701 | # EVIDENCE-OF: R-35109-49139 The number of columns in each row returned |
| 1702 | # by the SELECT statement (if any) and the specific values returned have |
| 1703 | # no effect on the results of the EXISTS operator. |
| 1704 | # |
| 1705 | foreach {tn expr res} { |
| 1706 | 1 { EXISTS ( SELECT * FROM t1 ) } 1 |
| 1707 | 2 { EXISTS ( SELECT *, *, * FROM t1 ) } 1 |
| 1708 | 3 { EXISTS ( SELECT 24, 25 ) } 1 |
| 1709 | 4 { EXISTS ( SELECT NULL, NULL, NULL ) } 1 |
| 1710 | 5 { EXISTS ( SELECT a,b,a||b FROM t1 WHERE a IS NULL ) } 1 |
| 1711 | |
| 1712 | 6 { EXISTS ( SELECT a, a FROM t1 WHERE 0) } 0 |
| 1713 | 7 { EXISTS ( SELECT b, b, a FROM t1 WHERE a = 5) } 0 |
| 1714 | 8 { EXISTS ( SELECT 24, 46, 89 WHERE 0) } 0 |
| 1715 | 9 { EXISTS ( SELECT NULL, NULL WHERE 1=2) } 0 |
| 1716 | } { |
| 1717 | do_expr_test e_expr-34.4.$tn $expr integer $res |
| 1718 | } |
| 1719 | |
| 1720 | # EVIDENCE-OF: R-10645-12439 In particular, rows containing NULL values |
| 1721 | # are not handled any differently from rows without NULL values. |
| 1722 | # |
| 1723 | foreach {tn e1 e2} { |
| 1724 | 1 { EXISTS (SELECT 'not null') } { EXISTS (SELECT NULL) } |
| 1725 | 2 { EXISTS (SELECT NULL FROM t1) } { EXISTS (SELECT 'bread' FROM t1) } |
| 1726 | } { |
| 1727 | set res [db one "SELECT $e1"] |
| 1728 | do_expr_test e_expr-34.5.${tn}a $e1 integer $res |
| 1729 | do_expr_test e_expr-34.5.${tn}b $e2 integer $res |
| 1730 | } |
| 1731 | |
| dan | 4336cc4 | 2010-09-02 11:53:12 +0000 | [diff] [blame] | 1732 | #------------------------------------------------------------------------- |
| dan | 74b617b | 2010-09-02 19:01:16 +0000 | [diff] [blame] | 1733 | # Test statements related to scalar sub-queries. |
| dan | 4336cc4 | 2010-09-02 11:53:12 +0000 | [diff] [blame] | 1734 | # |
| 1735 | |
| dan | 74b617b | 2010-09-02 19:01:16 +0000 | [diff] [blame] | 1736 | catch { db close } |
| 1737 | file delete -force test.db |
| 1738 | sqlite3 db test.db |
| 1739 | do_test e_expr-35.0 { |
| 1740 | execsql { |
| 1741 | CREATE TABLE t2(a, b); |
| 1742 | INSERT INTO t2 VALUES('one', 'two'); |
| 1743 | INSERT INTO t2 VALUES('three', NULL); |
| 1744 | INSERT INTO t2 VALUES(4, 5.0); |
| 1745 | } |
| 1746 | } {} |
| 1747 | |
| 1748 | # EVIDENCE-OF: R-00980-39256 A SELECT statement enclosed in parentheses |
| 1749 | # may appear as a scalar quantity. |
| 1750 | # |
| 1751 | # EVIDENCE-OF: R-56294-03966 All types of SELECT statement, including |
| 1752 | # aggregate and compound SELECT queries (queries with keywords like |
| 1753 | # UNION or EXCEPT) are allowed as scalar subqueries. |
| 1754 | # |
| 1755 | do_expr_test e_expr-35.1.1 { (SELECT 35) } integer 35 |
| 1756 | do_expr_test e_expr-35.1.2 { (SELECT NULL) } null {} |
| 1757 | |
| 1758 | do_expr_test e_expr-35.1.3 { (SELECT count(*) FROM t2) } integer 3 |
| 1759 | do_expr_test e_expr-35.1.4 { (SELECT 4 FROM t2) } integer 4 |
| 1760 | |
| 1761 | do_expr_test e_expr-35.1.5 { |
| 1762 | (SELECT b FROM t2 UNION SELECT a+1 FROM t2) |
| 1763 | } null {} |
| 1764 | do_expr_test e_expr-35.1.6 { |
| 1765 | (SELECT a FROM t2 UNION SELECT COALESCE(b, 55) FROM t2 ORDER BY 1) |
| 1766 | } integer 4 |
| 1767 | |
| 1768 | # EVIDENCE-OF: R-46899-53765 A SELECT used as a scalar quantity must |
| 1769 | # return a result set with a single column. |
| 1770 | # |
| dan | 06ce413 | 2010-09-03 10:58:47 +0000 | [diff] [blame] | 1771 | # The following block tests that errors are returned in a bunch of cases |
| 1772 | # where a subquery returns more than one column. |
| 1773 | # |
| dan | 74b617b | 2010-09-02 19:01:16 +0000 | [diff] [blame] | 1774 | set M {only a single result allowed for a SELECT that is part of an expression} |
| 1775 | foreach {tn sql} { |
| 1776 | 1 { SELECT (SELECT * FROM t2 UNION SELECT a+1, b+1 FROM t2) } |
| 1777 | 2 { SELECT (SELECT * FROM t2 UNION SELECT a+1, b+1 FROM t2 ORDER BY 1) } |
| 1778 | 3 { SELECT (SELECT 1, 2) } |
| 1779 | 4 { SELECT (SELECT NULL, NULL, NULL) } |
| 1780 | 5 { SELECT (SELECT * FROM t2) } |
| 1781 | 6 { SELECT (SELECT * FROM (SELECT 1, 2, 3)) } |
| 1782 | } { |
| 1783 | do_catchsql_test e_expr-35.2.$tn $sql [list 1 $M] |
| 1784 | } |
| 1785 | |
| dan | 06ce413 | 2010-09-03 10:58:47 +0000 | [diff] [blame] | 1786 | # EVIDENCE-OF: R-35764-28041 The result of the expression is the value |
| 1787 | # of the only column in the first row returned by the SELECT statement. |
| 1788 | # |
| 1789 | # EVIDENCE-OF: R-41898-06686 If the SELECT yields more than one result |
| 1790 | # row, all rows after the first are ignored. |
| 1791 | # |
| 1792 | do_execsql_test e_expr-36.3.1 { |
| 1793 | CREATE TABLE t4(x, y); |
| 1794 | INSERT INTO t4 VALUES(1, 'one'); |
| 1795 | INSERT INTO t4 VALUES(2, 'two'); |
| 1796 | INSERT INTO t4 VALUES(3, 'three'); |
| 1797 | } {} |
| 1798 | |
| 1799 | foreach {tn expr restype resval} { |
| 1800 | 2 { ( SELECT x FROM t4 ORDER BY x ) } integer 1 |
| 1801 | 3 { ( SELECT x FROM t4 ORDER BY y ) } integer 1 |
| 1802 | 4 { ( SELECT x FROM t4 ORDER BY x DESC ) } integer 3 |
| 1803 | 5 { ( SELECT x FROM t4 ORDER BY y DESC ) } integer 2 |
| 1804 | 6 { ( SELECT y FROM t4 ORDER BY y DESC ) } text two |
| 1805 | |
| 1806 | 7 { ( SELECT sum(x) FROM t4 ) } integer 6 |
| 1807 | 8 { ( SELECT group_concat(y,'') FROM t4 ) } text onetwothree |
| 1808 | 9 { ( SELECT max(x) FROM t4 WHERE y LIKE '___') } integer 2 |
| 1809 | |
| 1810 | } { |
| 1811 | do_expr_test e_expr-36.3.$tn $expr $restype $resval |
| 1812 | } |
| 1813 | |
| 1814 | # EVIDENCE-OF: R-25492-41572 If the SELECT yields no rows, then the |
| 1815 | # value of the expression is NULL. |
| 1816 | # |
| 1817 | foreach {tn expr} { |
| 1818 | 1 { ( SELECT x FROM t4 WHERE x>3 ORDER BY x ) } |
| 1819 | 2 { ( SELECT x FROM t4 WHERE y<'one' ORDER BY y ) } |
| 1820 | } { |
| 1821 | do_expr_test e_expr-36.4.$tn $expr null {} |
| 1822 | } |
| 1823 | |
| 1824 | |
| dan | 48d9e01 | 2010-08-27 11:19:55 +0000 | [diff] [blame] | 1825 | finish_test |
| dan | 4336cc4 | 2010-09-02 11:53:12 +0000 | [diff] [blame] | 1826 | |