tests/unit/type/set.tcl

   1 start_server {
   2     tags {"set"}
   3     overrides {
   4         "set-max-intset-entries" 512
   5     }
   6 } {
   7     proc create_set {key entries} {
   8         r del $key
   9         foreach entry $entries { r sadd $key $entry }
  10     }
  11
  12     test {SADD, SCARD, SISMEMBER, SMEMBERS basics - regular set} {
  13         create_set myset {foo}
  14         assert_encoding hashtable myset
  15         assert_equal 1 [r sadd myset bar]
  16         assert_equal 0 [r sadd myset bar]
  17         assert_equal 2 [r scard myset]
  18         assert_equal 1 [r sismember myset foo]
  19         assert_equal 1 [r sismember myset bar]
  20         assert_equal 0 [r sismember myset bla]
  21         assert_equal {bar foo} [lsort [r smembers myset]]
  22     }
  23
  24     test {SADD, SCARD, SISMEMBER, SMEMBERS basics - intset} {
  25         create_set myset {17}
  26         assert_encoding intset myset
  27         assert_equal 1 [r sadd myset 16]
  28         assert_equal 0 [r sadd myset 16]
  29         assert_equal 2 [r scard myset]
  30         assert_equal 1 [r sismember myset 16]
  31         assert_equal 1 [r sismember myset 17]
  32         assert_equal 0 [r sismember myset 18]
  33         assert_equal {16 17} [lsort [r smembers myset]]
  34     }
  35
  36     test {SADD against non set} {
  37         r lpush mylist foo
  38         assert_error ERR*kind* {r sadd mylist bar}
  39     }
  40
  41     test "SADD a non-integer against an intset" {
  42         create_set myset {1 2 3}
  43         assert_encoding intset myset
  44         assert_equal 1 [r sadd myset a]
  45         assert_encoding hashtable myset
  46     }
  47
  48     test "SADD an integer larger than 64 bits" {
  49         create_set myset {213244124402402314402033402}
  50         assert_encoding hashtable myset
  51         assert_equal 1 [r sismember myset 213244124402402314402033402]
  52     }
  53
  54     test "SADD overflows the maximum allowed integers in an intset" {
  55         r del myset
  56         for {set i 0} {$i < 512} {incr i} { r sadd myset $i }
  57         assert_encoding intset myset
  58         assert_equal 1 [r sadd myset 512]
  59         assert_encoding hashtable myset
  60     }
  61
  62     test "Set encoding after DEBUG RELOAD" {
  63         r del myintset myhashset mylargeintset
  64         for {set i 0} {$i <  100} {incr i} { r sadd myintset $i }
  65         for {set i 0} {$i < 1280} {incr i} { r sadd mylargeintset $i }
  66         for {set i 0} {$i <  256} {incr i} { r sadd myhashset [format "i%03d" $i] }
  67         assert_encoding intset myintset
  68         assert_encoding hashtable mylargeintset
  69         assert_encoding hashtable myhashset
  70
  71         r debug reload
  72         assert_encoding intset myintset
  73         assert_encoding hashtable mylargeintset
  74         assert_encoding hashtable myhashset
  75     }
  76
  77     test {SREM basics - regular set} {
  78         create_set myset {foo bar ciao}
  79         assert_encoding hashtable myset
  80         assert_equal 0 [r srem myset qux]
  81         assert_equal 1 [r srem myset foo]
  82         assert_equal {bar ciao} [lsort [r smembers myset]]
  83     }
  84
  85     test {SREM basics - intset} {
  86         create_set myset {3 4 5}
  87         assert_encoding intset myset
  88         assert_equal 0 [r srem myset 6]
  89         assert_equal 1 [r srem myset 4]
  90         assert_equal {3 5} [lsort [r smembers myset]]
  91     }
  92
  93     foreach {type} {hashtable intset} {
  94         for {set i 1} {$i <= 5} {incr i} {
  95             r del [format "set%d" $i]
  96         }
  97         for {set i 0} {$i < 200} {incr i} {
  98             r sadd set1 $i
  99             r sadd set2 [expr $i+195]
 100         }
 101         foreach i {199 195 1000 2000} {
 102             r sadd set3 $i
 103         }
 104         for {set i 5} {$i < 200} {incr i} {
 105             r sadd set4 $i
 106         }
 107         r sadd set5 0
 108
 109         # To make sure the sets are encoded as the type we are testing -- also
 110         # when the VM is enabled and the values may be swapped in and out
 111         # while the tests are running -- an extra element is added to every
 112         # set that determines its encoding.
 113         set large 200
 114         if {$type eq "hashtable"} {
 115             set large foo
 116         }
 117
 118         for {set i 1} {$i <= 5} {incr i} {
 119             r sadd [format "set%d" $i] $large
 120         }
 121
 122         test "Generated sets must be encoded as $type" {
 123             for {set i 1} {$i <= 5} {incr i} {
 124                 assert_encoding $type [format "set%d" $i]
 125             }
 126         }
 127
 128         test "SINTER with two sets - $type" {
 129             assert_equal [list 195 196 197 198 199 $large] [lsort [r sinter set1 set2]]
 130         }
 131
 132         test "SINTERSTORE with two sets - $type" {
 133             r sinterstore setres set1 set2
 134             assert_encoding $type setres
 135             assert_equal [list 195 196 197 198 199 $large] [lsort [r smembers setres]]
 136         }
 137
 138         test "SINTERSTORE with two sets, after a DEBUG RELOAD - $type" {
 139             r debug reload
 140             r sinterstore setres set1 set2
 141             assert_encoding $type setres
 142             assert_equal [list 195 196 197 198 199 $large] [lsort [r smembers setres]]
 143         }
 144
 145         test "SUNION with two sets - $type" {
 146             set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
 147             assert_equal $expected [lsort [r sunion set1 set2]]
 148         }
 149
 150         test "SUNIONSTORE with two sets - $type" {
 151             r sunionstore setres set1 set2
 152             assert_encoding $type setres
 153             set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
 154             assert_equal $expected [lsort [r smembers setres]]
 155         }
 156
 157         test "SINTER against three sets - $type" {
 158             assert_equal [list 195 199 $large] [lsort [r sinter set1 set2 set3]]
 159         }
 160
 161         test "SINTERSTORE with three sets - $type" {
 162             r sinterstore setres set1 set2 set3
 163             assert_equal [list 195 199 $large] [lsort [r smembers setres]]
 164         }
 165
 166         test "SUNION with non existing keys - $type" {
 167             set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
 168             assert_equal $expected [lsort [r sunion nokey1 set1 set2 nokey2]]
 169         }
 170
 171         test "SDIFF with two sets - $type" {
 172             assert_equal {0 1 2 3 4} [lsort [r sdiff set1 set4]]
 173         }
 174
 175         test "SDIFF with three sets - $type" {
 176             assert_equal {1 2 3 4} [lsort [r sdiff set1 set4 set5]]
 177         }
 178
 179         test "SDIFFSTORE with three sets - $type" {
 180             r sdiffstore setres set1 set4 set5
 181             # The type is determined by type of the first key to diff against.
 182             # See the implementation for more information.
 183             assert_encoding $type setres
 184             assert_equal {1 2 3 4} [lsort [r smembers setres]]
 185         }
 186     }
 187
 188     test "SINTER against non-set should throw error" {
 189         r set key1 x
 190         assert_error "ERR*wrong kind*" {r sinter key1 noset}
 191     }
 192
 193     test "SUNION against non-set should throw error" {
 194         r set key1 x
 195         assert_error "ERR*wrong kind*" {r sunion key1 noset}
 196     }
 197
 198     test "SINTERSTORE against non existing keys should delete dstkey" {
 199         r set setres xxx
 200         assert_equal 0 [r sinterstore setres foo111 bar222]
 201         assert_equal 0 [r exists setres]
 202     }
 203
 204     test "SUNIONSTORE against non existing keys should delete dstkey" {
 205         r set setres xxx
 206         assert_equal 0 [r sunionstore setres foo111 bar222]
 207         assert_equal 0 [r exists setres]
 208     }
 209
 210     foreach {type contents} {hashtable {a b c} intset {1 2 3}} {
 211         test "SPOP basics - $type" {
 212             create_set myset $contents
 213             assert_encoding $type myset
 214             assert_equal $contents [lsort [list [r spop myset] [r spop myset] [r spop myset]]]
 215             assert_equal 0 [r scard myset]
 216         }
 217
 218         test "SRANDMEMBER - $type" {
 219             create_set myset $contents
 220             unset -nocomplain myset
 221             array set myset {}
 222             for {set i 0} {$i < 100} {incr i} {
 223                 set myset([r srandmember myset]) 1
 224             }
 225             assert_equal $contents [lsort [array names myset]]
 226         }
 227     }
 228
 229     proc setup_move {} {
 230         r del myset3 myset4
 231         create_set myset1 {1 a b}
 232         create_set myset2 {2 3 4}
 233         assert_encoding hashtable myset1
 234         assert_encoding intset myset2
 235     }
 236
 237     test "SMOVE basics - from regular set to intset" {
 238         # move a non-integer element to an intset should convert encoding
 239         setup_move
 240         assert_equal 1 [r smove myset1 myset2 a]
 241         assert_equal {1 b} [lsort [r smembers myset1]]
 242         assert_equal {2 3 4 a} [lsort [r smembers myset2]]
 243         assert_encoding hashtable myset2
 244
 245         # move an integer element should not convert the encoding
 246         setup_move
 247         assert_equal 1 [r smove myset1 myset2 1]
 248         assert_equal {a b} [lsort [r smembers myset1]]
 249         assert_equal {1 2 3 4} [lsort [r smembers myset2]]
 250         assert_encoding intset myset2
 251     }
 252
 253     test "SMOVE basics - from intset to regular set" {
 254         setup_move
 255         assert_equal 1 [r smove myset2 myset1 2]
 256         assert_equal {1 2 a b} [lsort [r smembers myset1]]
 257         assert_equal {3 4} [lsort [r smembers myset2]]
 258     }
 259
 260     test "SMOVE non existing key" {
 261         setup_move
 262         assert_equal 0 [r smove myset1 myset2 foo]
 263         assert_equal {1 a b} [lsort [r smembers myset1]]
 264         assert_equal {2 3 4} [lsort [r smembers myset2]]
 265     }
 266
 267     test "SMOVE non existing src set" {
 268         setup_move
 269         assert_equal 0 [r smove noset myset2 foo]
 270         assert_equal {2 3 4} [lsort [r smembers myset2]]
 271     }
 272
 273     test "SMOVE from regular set to non existing destination set" {
 274         setup_move
 275         assert_equal 1 [r smove myset1 myset3 a]
 276         assert_equal {1 b} [lsort [r smembers myset1]]
 277         assert_equal {a} [lsort [r smembers myset3]]
 278         assert_encoding hashtable myset3
 279     }
 280
 281     test "SMOVE from intset to non existing destination set" {
 282         setup_move
 283         assert_equal 1 [r smove myset2 myset3 2]
 284         assert_equal {3 4} [lsort [r smembers myset2]]
 285         assert_equal {2} [lsort [r smembers myset3]]
 286         assert_encoding intset myset3
 287     }
 288
 289     test "SMOVE wrong src key type" {
 290         r set x 10
 291         assert_error "ERR*wrong kind*" {r smove x myset2 foo}
 292     }
 293
 294     test "SMOVE wrong dst key type" {
 295         r set x 10
 296         assert_error "ERR*wrong kind*" {r smove myset2 x foo}
 297     }
 298
 299     tags {slow} {
 300         test {intsets implementation stress testing} {
 301             for {set j 0} {$j < 20} {incr j} {
 302                 unset -nocomplain s
 303                 array set s {}
 304                 r del s
 305                 set len [randomInt 1024]
 306                 for {set i 0} {$i < $len} {incr i} {
 307                     randpath {
 308                         set data [randomInt 65536]
 309                     } {
 310                         set data [randomInt 4294967296]
 311                     } {
 312                         set data [randomInt 18446744073709551616]
 313                     }
 314                     set s($data) {}
 315                     r sadd s $data
 316                 }
 317                 assert_equal [lsort [r smembers s]] [lsort [array names s]]
 318                 set len [array size s]
 319                 for {set i 0} {$i < $len} {incr i} {
 320                     set e [r spop s]
 321                     if {![info exists s($e)]} {
 322                         puts "Can't find '$e' on local array"
 323                         puts "Local array: [lsort [r smembers s]]"
 324                         puts "Remote array: [lsort [array names s]]"
 325                         error "exception"
 326                     }
 327                     array unset s $e
 328                 }
 329                 assert_equal [r scard s] 0
 330                 assert_equal [array size s] 0
 331             }
 332         }
 333     }
 334 }