mirror of
http://github.com/valkey-io/valkey
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2a7847a3b5
It was verified in practice that this test is able to stress much more the implementation by introducing errors that were only trivially to detect with different offsets but impossible to detect starting always at zero and counting bits the full length of the string.
195 lines
5.8 KiB
Tcl
195 lines
5.8 KiB
Tcl
# Compare Redis commadns against Tcl implementations of the same commands.
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proc count_bits s {
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binary scan $s b* bits
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string length [regsub -all {0} $bits {}]
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}
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proc simulate_bit_op {op args} {
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set maxlen 0
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set j 0
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set count [llength $args]
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foreach a $args {
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binary scan $a b* bits
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set b($j) $bits
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if {[string length $bits] > $maxlen} {
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set maxlen [string length $bits]
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}
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incr j
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}
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for {set j 0} {$j < $count} {incr j} {
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if {[string length $b($j)] < $maxlen} {
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append b($j) [string repeat 0 [expr $maxlen-[string length $b($j)]]]
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}
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}
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set out {}
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for {set x 0} {$x < $maxlen} {incr x} {
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set bit [string range $b(0) $x $x]
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if {$op eq {not}} {set bit [expr {!$bit}]}
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for {set j 1} {$j < $count} {incr j} {
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set bit2 [string range $b($j) $x $x]
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switch $op {
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and {set bit [expr {$bit & $bit2}]}
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or {set bit [expr {$bit | $bit2}]}
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xor {set bit [expr {$bit ^ $bit2}]}
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}
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}
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append out $bit
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}
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binary format b* $out
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}
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start_server {tags {"bitops"}} {
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test {BITCOUNT returns 0 against non existing key} {
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r bitcount no-key
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} 0
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catch {unset num}
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foreach vec [list "" "\xaa" "\x00\x00\xff" "foobar" "123"] {
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incr num
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test "BITCOUNT against test vector #$num" {
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r set str $vec
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assert {[r bitcount str] == [count_bits $vec]}
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}
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}
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test {BITCOUNT fuzzing without start/end} {
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for {set j 0} {$j < 100} {incr j} {
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set str [randstring 0 3000]
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r set str $str
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assert {[r bitcount str] == [count_bits $str]}
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}
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}
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test {BITCOUNT fuzzing with start/end} {
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for {set j 0} {$j < 100} {incr j} {
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set str [randstring 0 3000]
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r set str $str
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set l [string length $str]
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set start [randomInt $l]
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set end [randomInt $l]
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if {$start > $end} {
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lassign [list $end $start] start end
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}
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assert {[r bitcount str $start $end] == [count_bits [string range $str $start $end]]}
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}
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}
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test {BITCOUNT with start, end} {
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r set s "foobar"
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assert_equal [r bitcount s 0 -1] [count_bits "foobar"]
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assert_equal [r bitcount s 1 -2] [count_bits "ooba"]
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assert_equal [r bitcount s -2 1] [count_bits ""]
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assert_equal [r bitcount s 0 1000] [count_bits "foobar"]
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}
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test {BITCOUNT syntax error #1} {
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catch {r bitcount s 0} e
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set e
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} {ERR*syntax*}
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test {BITCOUNT regression test for github issue #582} {
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r del str
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r setbit foo 0 1
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if {[catch {r bitcount foo 0 4294967296} e]} {
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assert_match {*ERR*out of range*} $e
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set _ 1
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} else {
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set e
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}
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} {1}
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test {BITOP NOT (empty string)} {
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r set s ""
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r bitop not dest s
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r get dest
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} {}
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test {BITOP NOT (known string)} {
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r set s "\xaa\x00\xff\x55"
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r bitop not dest s
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r get dest
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} "\x55\xff\x00\xaa"
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test {BITOP where dest and target are the same key} {
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r set s "\xaa\x00\xff\x55"
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r bitop not s s
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r get s
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} "\x55\xff\x00\xaa"
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test {BITOP AND|OR|XOR don't change the string with single input key} {
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r set a "\x01\x02\xff"
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r bitop and res1 a
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r bitop or res2 a
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r bitop xor res3 a
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list [r get res1] [r get res2] [r get res3]
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} [list "\x01\x02\xff" "\x01\x02\xff" "\x01\x02\xff"]
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test {BITOP missing key is considered a stream of zero} {
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r set a "\x01\x02\xff"
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r bitop and res1 no-suck-key a
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r bitop or res2 no-suck-key a no-such-key
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r bitop xor res3 no-such-key a
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list [r get res1] [r get res2] [r get res3]
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} [list "\x00\x00\x00" "\x01\x02\xff" "\x01\x02\xff"]
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test {BITOP shorter keys are zero-padded to the key with max length} {
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r set a "\x01\x02\xff\xff"
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r set b "\x01\x02\xff"
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r bitop and res1 a b
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r bitop or res2 a b
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r bitop xor res3 a b
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list [r get res1] [r get res2] [r get res3]
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} [list "\x01\x02\xff\x00" "\x01\x02\xff\xff" "\x00\x00\x00\xff"]
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foreach op {and or xor} {
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test "BITOP $op fuzzing" {
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for {set i 0} {$i < 10} {incr i} {
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r flushall
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set vec {}
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set veckeys {}
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set numvec [expr {[randomInt 10]+1}]
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for {set j 0} {$j < $numvec} {incr j} {
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set str [randstring 0 1000]
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lappend vec $str
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lappend veckeys vector_$j
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r set vector_$j $str
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}
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r bitop $op target {*}$veckeys
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assert_equal [r get target] [simulate_bit_op $op {*}$vec]
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}
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}
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}
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test {BITOP NOT fuzzing} {
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for {set i 0} {$i < 10} {incr i} {
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r flushall
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set str [randstring 0 1000]
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r set str $str
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r bitop not target str
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assert_equal [r get target] [simulate_bit_op not $str]
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}
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}
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test {BITOP with integer encoded source objects} {
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r set a 1
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r set b 2
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r bitop xor dest a b a
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r get dest
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} {2}
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test {BITOP with non string source key} {
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r del c
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r set a 1
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r set b 2
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r lpush c foo
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catch {r bitop xor dest a b c d} e
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set e
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} {WRONGTYPE*}
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test {BITOP with empty string after non empty string (issue #529)} {
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r flushdb
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r set a "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
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r bitop or x a b
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} {32}
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}
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