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Explicit RPOP/LPOP tests.
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1start_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 $i }
57 assert_encoding intset myset
58 assert_equal 1 [r sadd myset 512]
59 assert_encoding hashtable myset
60 }
61
62 test {Variadic SADD} {
63 r del myset
64 assert_equal 3 [r sadd myset a b c]
65 assert_equal 2 [r sadd myset A a b c B]
66 assert_equal [lsort {A a b c B}] [lsort [r smembers myset]]
67 }
68
69 test "Set encoding after DEBUG RELOAD" {
70 r del myintset myhashset mylargeintset
71 for {set i 0} {$i < 100} {incr i} { r sadd myintset $i }
72 for {set i 0} {$i < 1280} {incr i} { r sadd mylargeintset $i }
73 for {set i 0} {$i < 256} {incr i} { r sadd myhashset [format "i%03d" $i] }
74 assert_encoding intset myintset
75 assert_encoding hashtable mylargeintset
76 assert_encoding hashtable myhashset
77
78 r debug reload
79 assert_encoding intset myintset
80 assert_encoding hashtable mylargeintset
81 assert_encoding hashtable myhashset
82 }
83
84 test {SREM basics - regular set} {
85 create_set myset {foo bar ciao}
86 assert_encoding hashtable myset
87 assert_equal 0 [r srem myset qux]
88 assert_equal 1 [r srem myset foo]
89 assert_equal {bar ciao} [lsort [r smembers myset]]
90 }
91
92 test {SREM basics - intset} {
93 create_set myset {3 4 5}
94 assert_encoding intset myset
95 assert_equal 0 [r srem myset 6]
96 assert_equal 1 [r srem myset 4]
97 assert_equal {3 5} [lsort [r smembers myset]]
98 }
99
100 test {SREM with multiple arguments} {
101 r del myset
102 r sadd myset a b c d
103 assert_equal 0 [r srem myset k k k]
104 assert_equal 2 [r srem myset b d x y]
105 lsort [r smembers myset]
106 } {a c}
107
108 test {SREM variadic version with more args needed to destroy the key} {
109 r del myset
110 r sadd myset 1 2 3
111 r srem myset 1 2 3 4 5 6 7 8
112 } {3}
113
114 foreach {type} {hashtable intset} {
115 for {set i 1} {$i <= 5} {incr i} {
116 r del [format "set%d" $i]
117 }
118 for {set i 0} {$i < 200} {incr i} {
119 r sadd set1 $i
120 r sadd set2 [expr $i+195]
121 }
122 foreach i {199 195 1000 2000} {
123 r sadd set3 $i
124 }
125 for {set i 5} {$i < 200} {incr i} {
126 r sadd set4 $i
127 }
128 r sadd set5 0
129
130 # To make sure the sets are encoded as the type we are testing -- also
131 # when the VM is enabled and the values may be swapped in and out
132 # while the tests are running -- an extra element is added to every
133 # set that determines its encoding.
134 set large 200
135 if {$type eq "hashtable"} {
136 set large foo
137 }
138
139 for {set i 1} {$i <= 5} {incr i} {
140 r sadd [format "set%d" $i] $large
141 }
142
143 test "Generated sets must be encoded as $type" {
144 for {set i 1} {$i <= 5} {incr i} {
145 assert_encoding $type [format "set%d" $i]
146 }
147 }
148
149 test "SINTER with two sets - $type" {
150 assert_equal [list 195 196 197 198 199 $large] [lsort [r sinter set1 set2]]
151 }
152
153 test "SINTERSTORE with two sets - $type" {
154 r sinterstore setres set1 set2
155 assert_encoding $type setres
156 assert_equal [list 195 196 197 198 199 $large] [lsort [r smembers setres]]
157 }
158
159 test "SINTERSTORE with two sets, after a DEBUG RELOAD - $type" {
160 r debug reload
161 r sinterstore setres set1 set2
162 assert_encoding $type setres
163 assert_equal [list 195 196 197 198 199 $large] [lsort [r smembers setres]]
164 }
165
166 test "SUNION with two sets - $type" {
167 set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
168 assert_equal $expected [lsort [r sunion set1 set2]]
169 }
170
171 test "SUNIONSTORE with two sets - $type" {
172 r sunionstore setres set1 set2
173 assert_encoding $type setres
174 set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
175 assert_equal $expected [lsort [r smembers setres]]
176 }
177
178 test "SINTER against three sets - $type" {
179 assert_equal [list 195 199 $large] [lsort [r sinter set1 set2 set3]]
180 }
181
182 test "SINTERSTORE with three sets - $type" {
183 r sinterstore setres set1 set2 set3
184 assert_equal [list 195 199 $large] [lsort [r smembers setres]]
185 }
186
187 test "SUNION with non existing keys - $type" {
188 set expected [lsort -uniq "[r smembers set1] [r smembers set2]"]
189 assert_equal $expected [lsort [r sunion nokey1 set1 set2 nokey2]]
190 }
191
192 test "SDIFF with two sets - $type" {
193 assert_equal {0 1 2 3 4} [lsort [r sdiff set1 set4]]
194 }
195
196 test "SDIFF with three sets - $type" {
197 assert_equal {1 2 3 4} [lsort [r sdiff set1 set4 set5]]
198 }
199
200 test "SDIFFSTORE with three sets - $type" {
201 r sdiffstore setres set1 set4 set5
202 # The type is determined by type of the first key to diff against.
203 # See the implementation for more information.
204 assert_encoding $type setres
205 assert_equal {1 2 3 4} [lsort [r smembers setres]]
206 }
207 }
208
209 test "SINTER against non-set should throw error" {
210 r set key1 x
211 assert_error "ERR*wrong kind*" {r sinter key1 noset}
212 }
213
214 test "SUNION against non-set should throw error" {
215 r set key1 x
216 assert_error "ERR*wrong kind*" {r sunion key1 noset}
217 }
218
219 test "SINTERSTORE against non existing keys should delete dstkey" {
220 r set setres xxx
221 assert_equal 0 [r sinterstore setres foo111 bar222]
222 assert_equal 0 [r exists setres]
223 }
224
225 test "SUNIONSTORE against non existing keys should delete dstkey" {
226 r set setres xxx
227 assert_equal 0 [r sunionstore setres foo111 bar222]
228 assert_equal 0 [r exists setres]
229 }
230
231 foreach {type contents} {hashtable {a b c} intset {1 2 3}} {
232 test "SPOP basics - $type" {
233 create_set myset $contents
234 assert_encoding $type myset
235 assert_equal $contents [lsort [list [r spop myset] [r spop myset] [r spop myset]]]
236 assert_equal 0 [r scard myset]
237 }
238
239 test "SRANDMEMBER - $type" {
240 create_set myset $contents
241 unset -nocomplain myset
242 array set myset {}
243 for {set i 0} {$i < 100} {incr i} {
244 set myset([r srandmember myset]) 1
245 }
246 assert_equal $contents [lsort [array names myset]]
247 }
248 }
249
250 proc setup_move {} {
251 r del myset3 myset4
252 create_set myset1 {1 a b}
253 create_set myset2 {2 3 4}
254 assert_encoding hashtable myset1
255 assert_encoding intset myset2
256 }
257
258 test "SMOVE basics - from regular set to intset" {
259 # move a non-integer element to an intset should convert encoding
260 setup_move
261 assert_equal 1 [r smove myset1 myset2 a]
262 assert_equal {1 b} [lsort [r smembers myset1]]
263 assert_equal {2 3 4 a} [lsort [r smembers myset2]]
264 assert_encoding hashtable myset2
265
266 # move an integer element should not convert the encoding
267 setup_move
268 assert_equal 1 [r smove myset1 myset2 1]
269 assert_equal {a b} [lsort [r smembers myset1]]
270 assert_equal {1 2 3 4} [lsort [r smembers myset2]]
271 assert_encoding intset myset2
272 }
273
274 test "SMOVE basics - from intset to regular set" {
275 setup_move
276 assert_equal 1 [r smove myset2 myset1 2]
277 assert_equal {1 2 a b} [lsort [r smembers myset1]]
278 assert_equal {3 4} [lsort [r smembers myset2]]
279 }
280
281 test "SMOVE non existing key" {
282 setup_move
283 assert_equal 0 [r smove myset1 myset2 foo]
284 assert_equal {1 a b} [lsort [r smembers myset1]]
285 assert_equal {2 3 4} [lsort [r smembers myset2]]
286 }
287
288 test "SMOVE non existing src set" {
289 setup_move
290 assert_equal 0 [r smove noset myset2 foo]
291 assert_equal {2 3 4} [lsort [r smembers myset2]]
292 }
293
294 test "SMOVE from regular set to non existing destination set" {
295 setup_move
296 assert_equal 1 [r smove myset1 myset3 a]
297 assert_equal {1 b} [lsort [r smembers myset1]]
298 assert_equal {a} [lsort [r smembers myset3]]
299 assert_encoding hashtable myset3
300 }
301
302 test "SMOVE from intset to non existing destination set" {
303 setup_move
304 assert_equal 1 [r smove myset2 myset3 2]
305 assert_equal {3 4} [lsort [r smembers myset2]]
306 assert_equal {2} [lsort [r smembers myset3]]
307 assert_encoding intset myset3
308 }
309
310 test "SMOVE wrong src key type" {
311 r set x 10
312 assert_error "ERR*wrong kind*" {r smove x myset2 foo}
313 }
314
315 test "SMOVE wrong dst key type" {
316 r set x 10
317 assert_error "ERR*wrong kind*" {r smove myset2 x foo}
318 }
319
320 tags {slow} {
321 test {intsets implementation stress testing} {
322 for {set j 0} {$j < 20} {incr j} {
323 unset -nocomplain s
324 array set s {}
325 r del s
326 set len [randomInt 1024]
327 for {set i 0} {$i < $len} {incr i} {
328 randpath {
329 set data [randomInt 65536]
330 } {
331 set data [randomInt 4294967296]
332 } {
333 set data [randomInt 18446744073709551616]
334 }
335 set s($data) {}
336 r sadd s $data
337 }
338 assert_equal [lsort [r smembers s]] [lsort [array names s]]
339 set len [array size s]
340 for {set i 0} {$i < $len} {incr i} {
341 set e [r spop s]
342 if {![info exists s($e)]} {
343 puts "Can't find '$e' on local array"
344 puts "Local array: [lsort [r smembers s]]"
345 puts "Remote array: [lsort [array names s]]"
346 error "exception"
347 }
348 array unset s $e
349 }
350 assert_equal [r scard s] 0
351 assert_equal [array size s] 0
352 }
353 }
354 }
355}