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Kirill Smelkov
mariadb
Commits
62c43ec6
Commit
62c43ec6
authored
Apr 17, 2013
by
John Esmet
Committed by
Yoni Fogel
Apr 17, 2013
Browse files
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Browse Files
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Plain Diff
back out change
git-svn-id:
file:///svn/toku/tokudb@51266
c7de825b-a66e-492c-adef-691d508d4ae1
parent
93515995
Changes
13
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13 changed files
with
512 additions
and
377 deletions
+512
-377
src/tests/perf_cursor_nop.cc
src/tests/perf_cursor_nop.cc
+1
-1
src/tests/perf_iibench.cc
src/tests/perf_iibench.cc
+6
-6
src/tests/perf_insert.cc
src/tests/perf_insert.cc
+1
-1
src/tests/perf_malloc_free.cc
src/tests/perf_malloc_free.cc
+2
-9
src/tests/perf_nop.cc
src/tests/perf_nop.cc
+1
-5
src/tests/perf_ptquery.cc
src/tests/perf_ptquery.cc
+1
-1
src/tests/perf_ptquery2.cc
src/tests/perf_ptquery2.cc
+1
-1
src/tests/perf_read_write.cc
src/tests/perf_read_write.cc
+1
-1
src/tests/perf_txn_single_thread.cc
src/tests/perf_txn_single_thread.cc
+1
-1
src/tests/perf_xmalloc_free.cc
src/tests/perf_xmalloc_free.cc
+39
-0
src/tests/test_stress0.cc
src/tests/test_stress0.cc
+7
-10
src/tests/test_stress_hot_indexing.cc
src/tests/test_stress_hot_indexing.cc
+7
-10
src/tests/threaded_stress_test_helpers.h
src/tests/threaded_stress_test_helpers.h
+444
-331
No files found.
src/tests/perf_cursor_nop.cc
View file @
62c43ec6
...
...
@@ -42,6 +42,6 @@ int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_iibench.cc
View file @
62c43ec6
...
...
@@ -42,17 +42,17 @@ static int UU() iibench_put_op(DB_TXN *txn, ARG arg, void *operation_extra, void
}
int
r
=
0
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
uint8_t
valbuf
[
arg
->
cli
->
val_size
];
dbt_init
(
&
mult_key_dbt
[
0
],
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
mult_val_dbt
[
0
],
valbuf
,
sizeof
valbuf
);
ZERO_ARRAY
(
valbuf
);
uint64_t
puts_to_increment
=
0
;
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
++
i
)
{
fill_zeroed_array
(
valbuf
,
arg
->
cli
->
val_size
,
arg
->
random_data
,
arg
->
cli
->
compressibility
);
struct
iibench_op_extra
*
CAST_FROM_VOIDP
(
info
,
operation_extra
);
uint64_t
pk
=
toku_sync_fetch_and_add
(
&
info
->
autoincrement
,
1
);
fill_key_buf
(
pk
,
keybuf
,
arg
->
cli
);
fill_val_buf_random
(
arg
->
random_data
,
valbuf
,
arg
->
cli
);
dbt_init
(
&
mult_key_dbt
[
0
],
&
pk
,
sizeof
pk
);
dbt_init
(
&
mult_val_dbt
[
0
],
valbuf
,
sizeof
valbuf
);
r
=
env
->
put_multiple
(
env
,
dbs
[
0
],
// source db.
...
...
@@ -128,6 +128,6 @@ test_main(int argc, char *const argv[]) {
args
.
crash_on_operation_failure
=
false
;
}
args
.
env_args
.
generate_put_callback
=
iibench_generate_row_for_put
;
perf_test_main
(
&
args
);
stress_test_main_with_cmp
(
&
args
,
stress_uint64_dbt_cmp
);
return
0
;
}
src/tests/perf_insert.cc
View file @
62c43ec6
...
...
@@ -51,6 +51,6 @@ test_main(int argc, char *const argv[]) {
if
(
args
.
num_put_threads
>
1
)
{
args
.
crash_on_operation_failure
=
false
;
}
perf_test_main
(
&
args
);
stress_test_main_with_cmp
(
&
args
,
stress_uint64_dbt_cmp
);
return
0
;
}
src/tests/perf_malloc_free.cc
View file @
62c43ec6
...
...
@@ -20,13 +20,6 @@
// The intent of this test is to measure the throughput of malloc and free
// with multiple threads.
static
int
xmalloc_free_op
(
DB_TXN
*
UU
(
txn
),
ARG
UU
(
arg
),
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
size_t
s
=
256
;
void
*
p
=
toku_xmalloc
(
s
);
toku_free
(
p
);
return
0
;
}
static
void
stress_table
(
DB_ENV
*
env
,
DB
**
dbp
,
struct
cli_args
*
cli_args
)
{
if
(
verbose
)
printf
(
"starting creation of pthreads
\n
"
);
...
...
@@ -34,7 +27,7 @@ stress_table(DB_ENV* env, DB** dbp, struct cli_args *cli_args) {
struct
arg
myargs
[
num_threads
];
for
(
int
i
=
0
;
i
<
num_threads
;
i
++
)
{
arg_init
(
&
myargs
[
i
],
dbp
,
env
,
cli_args
);
myargs
[
i
].
operation
=
x
malloc_free_op
;
myargs
[
i
].
operation
=
malloc_free_op
;
}
run_workers
(
myargs
,
num_threads
,
cli_args
->
num_seconds
,
false
,
cli_args
);
}
...
...
@@ -43,6 +36,6 @@ int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_nop.cc
View file @
62c43ec6
...
...
@@ -18,10 +18,6 @@
// The intent of this test is to measure the throughput of the test infrastructure executing a nop
// on multiple threads.
static
int
UU
()
nop
(
DB_TXN
*
UU
(
txn
),
ARG
UU
(
arg
),
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
return
0
;
}
static
void
stress_table
(
DB_ENV
*
env
,
DB
**
dbp
,
struct
cli_args
*
cli_args
)
{
if
(
verbose
)
printf
(
"starting creation of pthreads
\n
"
);
...
...
@@ -38,6 +34,6 @@ int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_ptquery.cc
View file @
62c43ec6
...
...
@@ -62,6 +62,6 @@ int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_ptquery2.cc
View file @
62c43ec6
...
...
@@ -75,6 +75,6 @@ int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_read_write.cc
View file @
62c43ec6
...
...
@@ -78,6 +78,6 @@ test_main(int argc, char *const argv[]) {
args
.
num_update_threads
=
1
;
args
.
crash_on_operation_failure
=
false
;
parse_stress_test_args
(
argc
,
argv
,
&
args
);
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_txn_single_thread.cc
View file @
62c43ec6
...
...
@@ -71,6 +71,6 @@ test_main(int argc, char *const argv[]) {
// this test is all about transactions, make the DB small
args
.
num_elements
=
1
;
args
.
num_DBs
=
1
;
perf
_test_main
(
&
args
);
stress
_test_main
(
&
args
);
return
0
;
}
src/tests/perf_xmalloc_free.cc
0 → 100644
View file @
62c43ec6
/* -*- mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- */
// vim: ft=cpp:expandtab:ts=8:sw=4:softtabstop=4:
#ident "Copyright (c) 2007 Tokutek Inc. All rights reserved."
#ident "$Id$"
#include "test.h"
#include <stdio.h>
#include <stdlib.h>
#include <toku_pthread.h>
#include <unistd.h>
#include <memory.h>
#include <sys/stat.h>
#include <db.h>
#include "threaded_stress_test_helpers.h"
// The intent of this test is to measure the throughput of toku_malloc and toku_free
// with multiple threads.
static
void
stress_table
(
DB_ENV
*
env
,
DB
**
dbp
,
struct
cli_args
*
cli_args
)
{
if
(
verbose
)
printf
(
"starting creation of pthreads
\n
"
);
const
int
num_threads
=
cli_args
->
num_ptquery_threads
;
struct
arg
myargs
[
num_threads
];
for
(
int
i
=
0
;
i
<
num_threads
;
i
++
)
{
arg_init
(
&
myargs
[
i
],
dbp
,
env
,
cli_args
);
myargs
[
i
].
operation
=
xmalloc_free_op
;
}
run_workers
(
myargs
,
num_threads
,
cli_args
->
num_seconds
,
false
,
cli_args
);
}
int
test_main
(
int
argc
,
char
*
const
argv
[])
{
struct
cli_args
args
=
get_default_args_for_perf
();
parse_stress_test_args
(
argc
,
argv
,
&
args
);
stress_test_main
(
&
args
);
return
0
;
}
src/tests/test_stress0.cc
View file @
62c43ec6
...
...
@@ -22,14 +22,6 @@
// This test is targetted at stressing the locktree, hence the small table and many update threads.
//
static
int
UU
()
lock_escalation_op
(
DB_TXN
*
UU
(
txn
),
ARG
arg
,
void
*
operation_extra
,
void
*
UU
(
stats_extra
))
{
invariant_null
(
operation_extra
);
if
(
!
arg
->
cli
->
nolocktree
)
{
toku_env_run_lock_escalation_for_test
(
arg
->
env
);
}
return
0
;
}
static
void
stress_table
(
DB_ENV
*
env
,
DB
**
dbp
,
struct
cli_args
*
cli_args
)
{
...
...
@@ -48,8 +40,13 @@ stress_table(DB_ENV *env, DB **dbp, struct cli_args *cli_args) {
myargs
[
0
].
operation_extra
=
&
soe
[
0
];
myargs
[
0
].
operation
=
scan_op
;
myargs
[
1
].
sleep_ms
=
15L
*
1000
;
myargs
[
1
].
operation_extra
=
nullptr
;
// make the lock escalation thread.
// it should sleep somewhere between 10 and 20
// seconds between each escalation.
struct
lock_escalation_op_extra
eoe
;
eoe
.
min_sleep_time_micros
=
10UL
*
(
1000
*
1000
);
eoe
.
max_sleep_time_micros
=
20UL
*
(
1000
*
1000
);
myargs
[
1
].
operation_extra
=
&
eoe
;
myargs
[
1
].
operation
=
lock_escalation_op
;
// make the threads that update the db
...
...
src/tests/test_stress_hot_indexing.cc
View file @
62c43ec6
...
...
@@ -69,15 +69,9 @@ static int hi_inserts(DB_TXN* UU(txn), ARG arg, void* UU(operation_extra), void
DBT
dest_vals
[
2
];
memset
(
dest_keys
,
0
,
sizeof
(
dest_keys
));
memset
(
dest_vals
,
0
,
sizeof
(
dest_vals
));
DBT
key
,
val
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
uint8_t
valbuf
[
arg
->
cli
->
val_size
];
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
),
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
),
r
=
env
->
txn_begin
(
env
,
NULL
,
&
hi_txn
,
0
);
CKERR
(
r
);
int
i
;
r
=
env
->
txn_begin
(
env
,
NULL
,
&
hi_txn
,
0
);
CKERR
(
r
);
for
(
i
=
0
;
i
<
1000
;
i
++
)
{
DB
*
dbs
[
2
];
toku_mutex_lock
(
&
hi_lock
);
...
...
@@ -85,8 +79,11 @@ static int hi_inserts(DB_TXN* UU(txn), ARG arg, void* UU(operation_extra), void
dbs
[
1
]
=
hot_db
;
int
num_dbs
=
hot_db
?
2
:
1
;
// do a random insertion
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
fill_val_buf_random
(
arg
->
random_data
,
valbuf
,
arg
->
cli
);
int
rand_key
=
random
()
%
arg
->
cli
->
num_elements
;
int
rand_val
=
random
();
DBT
key
,
val
;
dbt_init
(
&
key
,
&
rand_key
,
sizeof
(
rand_key
)),
dbt_init
(
&
val
,
&
rand_val
,
sizeof
(
rand_val
)),
r
=
env
->
put_multiple
(
env
,
db
,
...
...
src/tests/threaded_stress_test_helpers.h
View file @
62c43ec6
...
...
@@ -52,11 +52,6 @@ memalign(size_t UU(alignment), size_t size)
# endif
#endif
#define MIN_VAL_SIZE sizeof(int64_t)
#define MIN_KEY_SIZE sizeof(int64_t)
#define MIN_COMPRESSIBILITY (0.0)
#define MAX_COMPRESSIBILITY (1.0)
volatile
bool
run_test
;
// should be volatile since we are communicating through this variable.
typedef
struct
arg
*
ARG
;
...
...
@@ -92,6 +87,9 @@ enum perf_output_format {
HUMAN
=
0
,
CSV
,
TSV
,
#if 0
GNUPLOT,
#endif
NUM_OUTPUT_FORMATS
};
...
...
@@ -155,6 +153,8 @@ struct arg {
bool
prelock_updates
;
};
DB_TXN
*
const
null_txn
=
0
;
static
void
arg_init
(
struct
arg
*
arg
,
DB
**
dbp
,
DB_ENV
*
env
,
struct
cli_args
*
cli_args
)
{
arg
->
cli
=
cli_args
;
arg
->
dbp
=
dbp
;
...
...
@@ -163,7 +163,7 @@ static void arg_init(struct arg *arg, DB **dbp, DB_ENV *env, struct cli_args *cl
arg
->
sleep_ms
=
0
;
arg
->
lock_type
=
STRESS_LOCK_NONE
;
arg
->
txn_type
=
DB_TXN_SNAPSHOT
;
arg
->
operation_extra
=
nullptr
;
arg
->
operation_extra
=
NULL
;
arg
->
do_prepare
=
false
;
arg
->
prelock_updates
=
false
;
}
...
...
@@ -174,14 +174,12 @@ enum operation_type {
PTQUERIES
,
NUM_OPERATION_TYPES
};
const
char
*
operation_names
[]
=
{
"ops"
,
"puts"
,
"ptqueries"
,
nullptr
NULL
};
static
void
increment_counter
(
void
*
extra
,
enum
operation_type
type
,
uint64_t
inc
)
{
invariant
(
type
!=
OPERATION
);
int
t
=
(
int
)
type
;
...
...
@@ -401,6 +399,45 @@ tsv_print_perf_totals(const struct cli_args *cli_args, uint64_t *counters[], con
printf
(
"
\n
"
);
}
#if 0
static void
gnuplot_print_perf_header(const struct cli_args *cli_args, const int num_threads)
{
printf("set terminal postscript solid color\n");
printf("set output \"foo.eps\"\n");
printf("set xlabel \"seconds\"\n");
printf("set xrange [0:*]\n");
printf("set ylabel \"X/s\"\n");
printf("plot ");
if (cli_args->print_thread_performance) {
for (int t = 1; t <= num_threads; ++t) {
for (int op = 0; op < (int) NUM_OPERATION_TYPES; ++op) {
const int col = (2 * ((t - 1) * (int) NUM_OPERATION_TYPES + op)) + 2;
//printf("'-' u 1:%d w lines t \"Thread %d %s\", ", col, t, operation_names[op]);
printf("'-' u 1:%d w lines t \"Thread %d %s/s\", ", col + 1, t, operation_names[op]);
}
}
}
for (int op = 0; op < (int) NUM_OPERATION_TYPES; ++op) {
const int col = (2 * (num_threads * (int) NUM_OPERATION_TYPES + op)) + 2;
//printf("'-' u 1:%d w lines t \"Total %s\", ", col);
printf("'-' u 1:%d w lines t \"Total %s/s\"%s", col + 1, operation_names[op], op == ((int) NUM_OPERATION_TYPES - 1) ? "\n" : ", ");
}
}
static void
gnuplot_print_perf_iteration(const struct cli_args *cli_args, const int current_time, uint64_t last_counters[][(int) NUM_OPERATION_TYPES], uint64_t *counters[], const int num_threads)
{
tsv_print_perf_iteration(cli_args, current_time, last_counters, counters, num_threads);
}
static void
gnuplot_print_perf_totals(const struct cli_args *UU(cli_args), uint64_t *UU(counters[]), const int UU(num_threads))
{
printf("e\n");
}
#endif
const
struct
perf_formatter
perf_formatters
[]
=
{
[
HUMAN
]
=
{
.
header
=
human_print_perf_header
,
...
...
@@ -417,6 +454,13 @@ const struct perf_formatter perf_formatters[] = {
.
iteration
=
tsv_print_perf_iteration
,
.
totals
=
tsv_print_perf_totals
},
#if 0
[GNUPLOT] = {
.header = gnuplot_print_perf_header,
.iteration = gnuplot_print_perf_iteration,
.totals = gnuplot_print_perf_totals
}
#endif
};
static
int
get_env_open_flags
(
struct
cli_args
*
args
)
{
...
...
@@ -487,7 +531,7 @@ static void *worker(void *arg_v) {
assert_zero
(
r
);
arg
->
random_data
=
&
random_data
;
DB_ENV
*
env
=
arg
->
env
;
DB_TXN
*
txn
=
nullptr
;
DB_TXN
*
txn
=
NULL
;
if
(
verbose
)
{
toku_pthread_t
self
=
toku_pthread_self
();
uintptr_t
intself
=
(
uintptr_t
)
self
;
...
...
@@ -544,6 +588,7 @@ static void *worker(void *arg_v) {
return
arg
;
}
typedef
struct
scan_cb_extra
*
SCAN_CB_EXTRA
;
struct
scan_cb_extra
{
bool
fast
;
int64_t
curr_sum
;
...
...
@@ -557,13 +602,13 @@ struct scan_op_extra {
};
static
int
scan_cb
(
const
DBT
*
key
,
const
DBT
*
val
,
void
*
arg_v
)
{
struct
scan_cb_extra
*
CAST_FROM_VOIDP
(
cb_extra
,
arg_v
);
assert
(
key
);
assert
(
val
);
scan_cb
(
const
DBT
*
a
,
const
DBT
*
b
,
void
*
arg_v
)
{
SCAN_CB_EXTRA
CAST_FROM_VOIDP
(
cb_extra
,
arg_v
);
assert
(
a
);
assert
(
b
);
assert
(
cb_extra
);
assert
(
val
->
size
>=
sizeof
(
int64_
t
));
cb_extra
->
curr_sum
+=
*
(
int
64_t
*
)
val
->
data
;
assert
(
b
->
size
>=
sizeof
(
in
t
));
cb_extra
->
curr_sum
+=
*
(
int
*
)
b
->
data
;
cb_extra
->
num_elements
++
;
return
cb_extra
->
fast
?
TOKUDB_CURSOR_CONTINUE
:
0
;
}
...
...
@@ -576,13 +621,12 @@ static int scan_op_and_maybe_check_sum(
)
{
int
r
=
0
;
DBC
*
cursor
=
nullptr
;
DBC
*
cursor
=
NULL
;
struct
scan_cb_extra
e
=
{
e
.
fast
=
sce
->
fast
,
e
.
curr_sum
=
0
,
e
.
num_elements
=
0
,
};
struct
scan_cb_extra
e
;
e
.
fast
=
sce
->
fast
;
e
.
curr_sum
=
0
;
e
.
num_elements
=
0
;
{
int
chk_r
=
db
->
cursor
(
db
,
txn
,
&
cursor
,
0
);
CKERR
(
chk_r
);
}
if
(
sce
->
prefetch
)
{
...
...
@@ -633,68 +677,37 @@ static int generate_row_for_put(
return
0
;
}
static
uint64_t
breverse
(
uint64_t
v
)
// Effect: return the bits in i, reversed
// Notes: implementation taken from http://graphics.stanford.edu/~seander/bithacks.html#BitReverseObvious
// Rationale: just a hack to spread out the keys during loading, doesn't need to be fast but does need to be correct.
{
uint64_t
r
=
v
;
// r will be reversed bits of v; first get LSB of v
int
s
=
sizeof
(
v
)
*
CHAR_BIT
-
1
;
// extra shift needed at end
for
(
v
>>=
1
;
v
;
v
>>=
1
)
{
r
<<=
1
;
r
|=
v
&
1
;
s
--
;
}
r
<<=
s
;
// shift when v's highest bits are zero
return
r
;
}
static
void
fill_key_buf
(
uint64_t
key
,
uint8_t
*
data
,
struct
cli_args
*
args
)
{
invariant
(
args
->
key_size
>=
MIN_KEY_SIZE
);
uint64_t
*
k
=
reinterpret_cast
<
uint64_t
*>
(
data
);
if
(
args
->
disperse_keys
)
{
*
k
=
static_cast
<
uint64_t
>
(
breverse
(
key
));
}
else
{
*
k
=
key
;
}
if
(
args
->
key_size
>
sizeof
(
uint64_t
))
{
memset
(
data
+
sizeof
(
uint64_t
),
0
,
args
->
key_size
-
sizeof
(
uint64_t
));
}
static
int
UU
()
nop
(
DB_TXN
*
UU
(
txn
),
ARG
UU
(
arg
),
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
return
0
;
}
static
void
fill_key_buf_random
(
struct
random_data
*
random_data
,
uint8_t
*
data
,
ARG
arg
)
{
uint64_t
key
=
randu64
(
random_data
);
if
(
arg
->
bounded_element_range
&&
arg
->
cli
->
num_elements
>
0
)
{
key
=
key
%
arg
->
cli
->
num_elements
;
}
fill_key_buf
(
key
,
data
,
arg
->
cli
);
static
int
UU
()
xmalloc_free_op
(
DB_TXN
*
UU
(
txn
),
ARG
UU
(
arg
),
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
size_t
s
=
256
;
void
*
p
=
toku_xmalloc
(
s
);
toku_free
(
p
);
return
0
;
}
static
void
fill_val_buf
(
int64_t
val
,
uint8_t
*
data
,
uint32_t
val_size
)
{
invariant
(
val_size
>=
MIN_VAL_SIZE
);
int64_t
*
v
=
reinterpret_cast
<
int64_t
*>
(
data
);
*
v
=
val
;
if
(
val_size
>
sizeof
(
int64_t
))
{
memset
(
data
+
sizeof
(
int64_t
),
0
,
val_size
-
sizeof
(
int64_t
));
}
#if DONT_DEPRECATE_MALLOC
static
int
UU
()
malloc_free_op
(
DB_TXN
*
UU
(
txn
),
ARG
UU
(
arg
),
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
size_t
s
=
256
;
void
*
p
=
malloc
(
s
);
free
(
p
);
return
0
;
}
#endif
// Fill array with compressibility*size 0s.
// 0.0<=compressibility<=1.0
// Compressibility is the fraction of size that will be 0s (e.g. approximate fraction that will be compressed away).
// The rest will be random data.
static
void
fill_val_buf_random
(
struct
random_data
*
random_data
,
uint8_t
*
data
,
struct
cli_args
*
args
)
{
invariant
(
args
->
val_size
>=
MIN_VAL_SIZE
);
fill_zeroed_array
(
uint8_t
*
data
,
uint32_t
size
,
struct
random_data
*
random_data
,
double
compressibility
)
{
//Requires: The array was zeroed since the last time 'size' was changed.
//Requires: compressibility is in range [0,1] indicating fraction that should be zeros.
// Fill in the random bytes
uint32_t
num_random_bytes
=
(
1
-
args
->
compressibility
)
*
args
->
val_size
;
uint32_t
num_random_bytes
=
(
1
-
compressibility
)
*
size
;
if
(
num_random_bytes
>
0
)
{
uint32_t
filled
;
for
(
filled
=
0
;
filled
+
sizeof
(
uint64_t
)
<=
num_random_bytes
;
filled
+=
sizeof
(
uint64_t
))
{
...
...
@@ -705,28 +718,39 @@ fill_val_buf_random(struct random_data *random_data, uint8_t *data, struct cli_a
memcpy
(
&
data
[
filled
],
&
last8
,
num_random_bytes
-
filled
);
}
}
}
// Fill in the zero bytes
if
(
num_random_bytes
<
args
->
val_size
)
{
memset
(
data
+
num_random_bytes
,
0
,
args
->
val_size
-
num_random_bytes
);
}
static
inline
size_t
size_t_max
(
size_t
a
,
size_t
b
)
{
return
(
a
>
b
)
?
a
:
b
;
}
static
int
random_put_in_db
(
DB
*
db
,
DB_TXN
*
txn
,
ARG
arg
,
bool
ignore_errors
,
void
*
stats_extra
)
{
int
r
=
0
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
uint8_t
rand_key_b
[
size_t_max
(
arg
->
cli
->
key_size
,
sizeof
(
uint64_t
))];
uint64_t
*
rand_key_key
=
cast_to_typeof
(
rand_key_key
)
rand_key_b
;
uint16_t
*
rand_key_i
=
cast_to_typeof
(
rand_key_i
)
rand_key_b
;
ZERO_ARRAY
(
rand_key_b
);
uint8_t
valbuf
[
arg
->
cli
->
val_size
];
DBT
key
,
val
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
);
const
int
put_flags
=
get_put_flags
(
arg
->
cli
);
ZERO_ARRAY
(
valbuf
);
uint64_t
puts_to_increment
=
0
;
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
++
i
)
{
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
fill_val_buf_random
(
arg
->
random_data
,
valbuf
,
arg
->
cli
);
r
=
db
->
put
(
db
,
txn
,
&
key
,
&
val
,
put_flags
);
rand_key_key
[
0
]
=
randu64
(
arg
->
random_data
);
if
(
arg
->
cli
->
interleave
)
{
rand_key_i
[
3
]
=
arg
->
thread_idx
;
}
else
{
rand_key_i
[
0
]
=
arg
->
thread_idx
;
}
if
(
arg
->
cli
->
num_elements
>
0
&&
arg
->
bounded_element_range
)
{
rand_key_key
[
0
]
=
rand_key_key
[
0
]
%
arg
->
cli
->
num_elements
;
}
fill_zeroed_array
(
valbuf
,
arg
->
cli
->
val_size
,
arg
->
random_data
,
arg
->
cli
->
compressibility
);
DBT
key
,
val
;
dbt_init
(
&
key
,
&
rand_key_b
,
sizeof
rand_key_b
);
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
);
int
flags
=
get_put_flags
(
arg
->
cli
);
r
=
db
->
put
(
db
,
txn
,
&
key
,
&
val
,
flags
);
if
(
!
ignore_errors
&&
r
!=
0
)
{
goto
cleanup
;
}
...
...
@@ -736,7 +760,6 @@ static int random_put_in_db(DB *db, DB_TXN *txn, ARG arg, bool ignore_errors, vo
puts_to_increment
=
0
;
}
}
cleanup:
increment_counter
(
stats_extra
,
PUTS
,
puts_to_increment
);
return
r
;
...
...
@@ -765,19 +788,22 @@ static int UU() serial_put_op(DB_TXN *txn, ARG arg, void *operation_extra, void
DB
*
db
=
arg
->
dbp
[
db_index
];
int
r
=
0
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
uint8_t
rand_key_b
[
size_t_max
(
arg
->
cli
->
key_size
,
sizeof
(
uint64_t
))];
uint64_t
*
rand_key_key
=
cast_to_typeof
(
rand_key_key
)
rand_key_b
;
uint16_t
*
rand_key_i
=
cast_to_typeof
(
rand_key_i
)
rand_key_b
;
ZERO_ARRAY
(
rand_key_b
);
uint8_t
valbuf
[
arg
->
cli
->
val_size
];
DBT
key
,
val
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
);
const
int
put_flags
=
get_put_flags
(
arg
->
cli
);
ZERO_ARRAY
(
valbuf
);
uint64_t
puts_to_increment
=
0
;
for
(
uint64_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
++
i
)
{
fill_key_buf
(
i
,
keybuf
,
arg
->
cli
);
fill_val_buf_random
(
arg
->
random_data
,
valbuf
,
arg
->
cli
);
r
=
db
->
put
(
db
,
txn
,
&
key
,
&
val
,
put_flags
);
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
++
i
)
{
rand_key_key
[
0
]
=
extra
->
current
++
;
fill_zeroed_array
(
valbuf
,
arg
->
cli
->
val_size
,
arg
->
random_data
,
arg
->
cli
->
compressibility
);
DBT
key
,
val
;
dbt_init
(
&
key
,
&
rand_key_b
,
sizeof
rand_key_b
);
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
);
int
flags
=
get_put_flags
(
arg
->
cli
);
r
=
db
->
put
(
db
,
txn
,
&
key
,
&
val
,
flags
);
if
(
r
!=
0
)
{
goto
cleanup
;
}
...
...
@@ -787,7 +813,6 @@ static int UU() serial_put_op(DB_TXN *txn, ARG arg, void *operation_extra, void
puts_to_increment
=
0
;
}
}
cleanup:
increment_counter
(
stats_extra
,
PUTS
,
puts_to_increment
);
return
r
;
...
...
@@ -802,44 +827,42 @@ static int UU() loader_op(DB_TXN* txn, ARG UU(arg), void* UU(operation_extra), v
uint32_t
dbt_flags
=
0
;
r
=
db_create
(
&
db_load
,
env
,
0
);
assert
(
r
==
0
);
r
=
db_load
->
open
(
db_load
,
txn
,
"loader-db"
,
nullptr
,
DB_BTREE
,
DB_CREATE
,
0666
);
r
=
db_load
->
open
(
db_load
,
txn
,
"loader-db"
,
NULL
,
DB_BTREE
,
DB_CREATE
,
0666
);
assert
(
r
==
0
);
DB_LOADER
*
loader
;
uint32_t
loader_flags
=
(
num
==
0
)
?
0
:
LOADER_COMPRESS_INTERMEDIATES
;
r
=
env
->
create_loader
(
env
,
txn
,
&
loader
,
db_load
,
1
,
&
db_load
,
&
db_flags
,
&
dbt_flags
,
loader_flags
);
CKERR
(
r
);
DBT
key
,
val
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
uint8_t
valbuf
[
arg
->
cli
->
val_size
];
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
valbuf
,
sizeof
valbuf
);
for
(
int
i
=
0
;
i
<
1000
;
i
++
)
{
fill_key_buf
(
i
,
keybuf
,
arg
->
cli
);
fill_val_buf_random
(
arg
->
random_data
,
valbuf
,
arg
->
cli
);
DBT
key
,
val
;
int
rand_key
=
i
;
int
rand_val
=
myrandom_r
(
arg
->
random_data
);
dbt_init
(
&
key
,
&
rand_key
,
sizeof
(
rand_key
));
dbt_init
(
&
val
,
&
rand_val
,
sizeof
(
rand_val
));
r
=
loader
->
put
(
loader
,
&
key
,
&
val
);
CKERR
(
r
);
}
r
=
loader
->
close
(
loader
);
CKERR
(
r
);
r
=
db_load
->
close
(
db_load
,
0
);
CKERR
(
r
);
r
=
env
->
dbremove
(
env
,
txn
,
"loader-db"
,
nullptr
,
0
);
CKERR
(
r
);
r
=
env
->
dbremove
(
env
,
txn
,
"loader-db"
,
NULL
,
0
);
CKERR
(
r
);
}
return
0
;
}
static
int
UU
()
keyrange_op
(
DB_TXN
*
txn
,
ARG
arg
,
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
// Pick a random DB, do a keyrange operation.
int
r
;
// callback is designed to run on tests with one DB
// no particular reason why, just the way it was
// originally done
int
db_index
=
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_DBs
;
DB
*
db
=
arg
->
dbp
[
db_index
];
i
nt
r
=
0
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
]
;
int
rand_key
=
myrandom_r
(
arg
->
random_data
);
i
f
(
arg
->
bounded_element_range
)
{
rand_key
=
rand_key
%
arg
->
cli
->
num_elements
;
}
DBT
key
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
dbt_init
(
&
key
,
&
rand_key
,
sizeof
rand_key
);
uint64_t
less
,
equal
,
greater
;
int
is_exact
;
r
=
db
->
key_range64
(
db
,
txn
,
&
key
,
&
less
,
&
equal
,
&
greater
,
&
is_exact
);
...
...
@@ -867,6 +890,27 @@ static int UU() verify_op(DB_TXN* UU(txn), ARG UU(arg), void* UU(operation_extra
return
r
;
}
struct
lock_escalation_op_extra
{
// sleep somewhere between these times before running escalation.
// this will add some chaos into the mix.
uint64_t
min_sleep_time_micros
;
uint64_t
max_sleep_time_micros
;
};
static
int
UU
()
lock_escalation_op
(
DB_TXN
*
UU
(
txn
),
ARG
arg
,
void
*
operation_extra
,
void
*
UU
(
stats_extra
))
{
struct
lock_escalation_op_extra
*
CAST_FROM_VOIDP
(
extra
,
operation_extra
);
if
(
extra
->
max_sleep_time_micros
>
0
)
{
invariant
(
extra
->
max_sleep_time_micros
>=
extra
->
min_sleep_time_micros
);
uint64_t
extra_sleep_time
=
(
extra
->
max_sleep_time_micros
-
extra
->
min_sleep_time_micros
)
+
1
;
uint64_t
sleep_time
=
extra
->
min_sleep_time_micros
+
(
myrandom_r
(
arg
->
random_data
)
%
extra_sleep_time
);
usleep
(
sleep_time
);
}
if
(
!
arg
->
cli
->
nolocktree
)
{
toku_env_run_lock_escalation_for_test
(
arg
->
env
);
}
return
0
;
}
static
int
UU
()
scan_op
(
DB_TXN
*
txn
,
ARG
UU
(
arg
),
void
*
operation_extra
,
void
*
UU
(
stats_extra
))
{
struct
scan_op_extra
*
CAST_FROM_VOIDP
(
extra
,
operation_extra
);
for
(
int
i
=
0
;
run_test
&&
i
<
arg
->
cli
->
num_DBs
;
i
++
)
{
...
...
@@ -923,24 +967,23 @@ static int dbt_do_nothing (DBT const *UU(key), DBT const *UU(row), void *UU(con
}
static
int
UU
()
ptquery_and_maybe_check_op
(
DB
*
db
,
DB_TXN
*
txn
,
ARG
arg
,
bool
check
)
{
int
r
=
0
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
int
r
;
int
rand_key
=
myrandom_r
(
arg
->
random_data
);
if
(
arg
->
bounded_element_range
)
{
rand_key
=
rand_key
%
arg
->
cli
->
num_elements
;
}
DBT
key
,
val
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
nullptr
,
0
);
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
dbt_init
(
&
key
,
&
rand_key
,
sizeof
rand_key
);
dbt_init
(
&
val
,
NULL
,
0
);
r
=
db
->
getf_set
(
db
,
txn
,
0
,
&
key
,
dbt_do_nothing
,
nullptr
NULL
);
if
(
check
)
{
assert
(
r
!=
DB_NOTFOUND
);
}
if
(
check
)
assert
(
r
!=
DB_NOTFOUND
);
r
=
0
;
return
r
;
}
...
...
@@ -968,7 +1011,7 @@ static int UU() ptquery_op_no_check(DB_TXN *txn, ARG arg, void* UU(operation_ext
static
int
UU
()
cursor_create_close_op
(
DB_TXN
*
txn
,
ARG
arg
,
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
int
db_index
=
arg
->
cli
->
num_DBs
>
1
?
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_DBs
:
0
;
DB
*
db
=
arg
->
dbp
[
db_index
];
DBC
*
cursor
=
nullptr
;
DBC
*
cursor
=
NULL
;
int
r
=
db
->
cursor
(
db
,
txn
,
&
cursor
,
0
);
assert
(
r
==
0
);
r
=
cursor
->
c_close
(
cursor
);
assert
(
r
==
0
);
return
0
;
...
...
@@ -1017,14 +1060,14 @@ static int update_op_callback(DB *UU(db), const DBT *UU(key),
void
*
set_extra
),
void
*
set_extra
)
{
int
64_t
old_int_val
=
0
;
int
old_int_val
=
0
;
if
(
old_val
)
{
old_int_val
=
*
(
int
64_t
*
)
old_val
->
data
;
old_int_val
=
*
(
int
*
)
old_val
->
data
;
}
assert
(
extra
->
size
==
sizeof
(
struct
update_op_extra
));
struct
update_op_extra
*
CAST_FROM_VOIDP
(
e
,
extra
->
data
);
int
64_t
new_int_val
;
int
new_int_val
;
switch
(
e
->
type
)
{
case
UPDATE_ADD_DIFF
:
new_int_val
=
old_int_val
+
e
->
u
.
d
.
diff
;
...
...
@@ -1040,59 +1083,53 @@ static int update_op_callback(DB *UU(db), const DBT *UU(key),
assert
(
false
);
}
uint32_t
val_size
=
sizeof
(
int64_t
)
+
e
->
pad_bytes
;
uint8_t
valbuf
[
val_size
];
fill_val_buf
(
new_int_val
,
valbuf
,
val_size
);
DBT
new_val
;
dbt_init
(
&
new_val
,
valbuf
,
val_size
);
set_val
(
&
new_val
,
set_extra
);
uint32_t
data_size
=
sizeof
(
int
)
+
e
->
pad_bytes
;
char
*
data
[
data_size
];
ZERO_ARRAY
(
data
);
memcpy
(
data
,
&
new_int_val
,
sizeof
(
new_int_val
));
set_val
(
dbt_init
(
&
new_val
,
data
,
data_size
),
set_extra
);
return
0
;
}
static
int
UU
()
update_op2
(
DB_TXN
*
txn
,
ARG
arg
,
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
static
int
UU
()
update_op2
(
DB_TXN
*
txn
,
ARG
arg
,
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
int
r
;
int
db_index
=
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_DBs
;
DB
*
db
=
arg
->
dbp
[
db_index
];
int
r
=
0
;
int
curr_val_sum
=
0
;
DBT
key
,
val
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
]
;
int
rand_key
;
int
rand_key2
;
toku_sync_fetch_and_add
(
&
update_count
,
1
);
struct
update_op_extra
extra
;
ZERO_STRUCT
(
extra
);
extra
.
type
=
UPDATE_ADD_DIFF
;
extra
.
pad_bytes
=
0
;
int64_t
curr_val_sum
=
0
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
);
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
i
++
)
{
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
rand_key
=
myrandom_r
(
arg
->
random_data
);
if
(
arg
->
bounded_element_range
)
{
rand_key
=
rand_key
%
(
arg
->
cli
->
num_elements
/
2
);
}
rand_key2
=
arg
->
cli
->
num_elements
-
rand_key
;
assert
(
rand_key
!=
rand_key2
);
extra
.
u
.
d
.
diff
=
1
;
curr_val_sum
+=
extra
.
u
.
d
.
diff
;
r
=
db
->
update
(
db
,
txn
,
&
key
,
&
val
,
dbt_init
(
&
key
,
&
rand_key
,
sizeof
rand_key
)
,
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
)
,
0
);
if
(
r
!=
0
)
{
return
r
;
}
int64_t
*
rkp
=
(
int64_t
*
)
keybuf
;
int64_t
rand_key
=
*
rkp
;
invariant
(
rand_key
!=
(
arg
->
cli
->
num_elements
-
rand_key
));
rand_key
-=
arg
->
cli
->
num_elements
;
fill_key_buf
(
rand_key
,
keybuf
,
arg
->
cli
);
extra
.
u
.
d
.
diff
=
-
1
;
r
=
db
->
update
(
db
,
txn
,
&
key
,
&
val
,
dbt_init
(
&
key
,
&
rand_key2
,
sizeof
rand_key
)
,
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
)
,
0
);
if
(
r
!=
0
)
{
...
...
@@ -1119,6 +1156,10 @@ static int pre_acquire_write_lock(DB *db, DB_TXN *txn,
// take the given db and do an update on it
static
int
UU
()
update_op_db
(
DB
*
db
,
DB_TXN
*
txn
,
ARG
arg
,
void
*
operation_extra
,
void
*
UU
(
stats_extra
))
{
int
r
=
0
;
int
curr_val_sum
=
0
;
DBT
key
,
val
;
int
update_key
;
uint64_t
old_update_count
=
toku_sync_fetch_and_add
(
&
update_count
,
1
);
struct
update_op_args
*
CAST_FROM_VOIDP
(
op_args
,
operation_extra
);
struct
update_op_extra
extra
;
...
...
@@ -1130,14 +1171,7 @@ UU() update_op_db(DB *db, DB_TXN *txn, ARG arg, void* operation_extra, void *UU(
extra
.
pad_bytes
=
100
;
}
}
int
r
=
0
;
DBT
key
,
val
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
int64_t
update_key
;
int64_t
curr_val_sum
=
0
;
const
int
update_flags
=
arg
->
cli
->
prelock_updates
?
DB_PRELOCKED_WRITE
:
0
;
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
i
++
)
{
if
(
arg
->
prelock_updates
)
{
if
(
i
==
0
)
{
...
...
@@ -1146,9 +1180,9 @@ UU() update_op_db(DB *db, DB_TXN *txn, ARG arg, void* operation_extra, void *UU(
update_key
=
update_key
%
arg
->
cli
->
num_elements
;
}
const
int64
_t
max_key_in_table
=
arg
->
cli
->
num_elements
-
1
;
const
uint32
_t
max_key_in_table
=
arg
->
cli
->
num_elements
-
1
;
const
bool
range_wraps
=
(
update_key
+
arg
->
cli
->
txn_size
-
1
)
>
max_key_in_table
;
int
64_t
left_key
,
right_key
;
int
left_key
,
right_key
;
DBT
left_key_dbt
,
right_key_dbt
;
// acquire the range starting at the random key, plus txn_size - 1
...
...
@@ -1184,16 +1218,15 @@ UU() update_op_db(DB *db, DB_TXN *txn, ARG arg, void* operation_extra, void *UU(
}
}
else
{
update_key
++
;
if
(
arg
->
bounded_element_range
)
{
update_key
=
update_key
%
arg
->
cli
->
num_elements
;
}
}
fill_key_buf
(
update_key
,
keybuf
,
arg
->
cli
);
}
else
{
// just do a usual, random point update without locking first
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
update_key
=
myrandom_r
(
arg
->
random_data
);
}
if
(
arg
->
bounded_element_range
)
{
update_key
=
update_key
%
arg
->
cli
->
num_elements
;
}
// the last update keeps the table's sum as zero
// every other update except the last applies a random delta
...
...
@@ -1208,15 +1241,12 @@ UU() update_op_db(DB *db, DB_TXN *txn, ARG arg, void* operation_extra, void *UU(
curr_val_sum
+=
extra
.
u
.
d
.
diff
;
}
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
);
// do the update
r
=
db
->
update
(
db
,
txn
,
&
key
,
&
val
,
dbt_init
(
&
key
,
&
update_key
,
sizeof
update_key
)
,
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
)
,
update_flags
);
if
(
r
!=
0
)
{
...
...
@@ -1239,11 +1269,12 @@ static int UU() update_with_history_op(DB_TXN *txn, ARG arg, void* operation_ext
struct
update_op_args
*
CAST_FROM_VOIDP
(
op_args
,
operation_extra
);
assert
(
arg
->
bounded_element_range
);
assert
(
op_args
->
update_history_buffer
);
int
r
=
0
;
int
r
;
int
db_index
=
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_DBs
;
DB
*
db
=
arg
->
dbp
[
db_index
];
int
curr_val_sum
=
0
;
DBT
key
,
val
;
int
rand_key
;
struct
update_op_extra
extra
;
ZERO_STRUCT
(
extra
);
extra
.
type
=
UPDATE_WITH_HISTORY
;
...
...
@@ -1254,44 +1285,47 @@ static int UU() update_with_history_op(DB_TXN *txn, ARG arg, void* operation_ext
extra
.
pad_bytes
=
500
;
}
}
DBT
key
,
val
;
uint8_t
keybuf
[
arg
->
cli
->
key_size
];
int64_t
rand_key
;
int64_t
curr_val_sum
=
0
;
dbt_init
(
&
key
,
keybuf
,
sizeof
keybuf
);
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
);
for
(
uint32_t
i
=
0
;
i
<
arg
->
cli
->
txn_size
;
i
++
)
{
fill_key_buf_random
(
arg
->
random_data
,
keybuf
,
arg
);
int64_t
*
rkp
=
(
int64_t
*
)
keybuf
;
rand_key
=
*
rkp
;
invariant
(
rand_key
<
arg
->
cli
->
num_elements
);
if
(
i
<
arg
->
cli
->
txn_size
-
1
)
{
extra
.
u
.
h
.
new_val
=
myrandom_r
(
arg
->
random_data
)
%
MAX_RANDOM_VAL
;
// just make every other value random
if
(
i
%
2
==
0
)
{
extra
.
u
.
h
.
new_val
=
-
extra
.
u
.
h
.
new_val
;
}
curr_val_sum
+=
extra
.
u
.
h
.
new_val
;
}
else
{
// the last update should ensure the sum stays zero
extra
.
u
.
h
.
new_val
=
-
curr_val_sum
;
rand_key
=
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_elements
;
extra
.
u
.
h
.
new_val
=
myrandom_r
(
arg
->
random_data
)
%
MAX_RANDOM_VAL
;
// just make every other value random
if
(
i
%
2
==
0
)
{
extra
.
u
.
h
.
new_val
=
-
extra
.
u
.
h
.
new_val
;
}
curr_val_sum
+=
extra
.
u
.
h
.
new_val
;
extra
.
u
.
h
.
expected
=
op_args
->
update_history_buffer
[
rand_key
];
op_args
->
update_history_buffer
[
rand_key
]
=
extra
.
u
.
h
.
new_val
;
r
=
db
->
update
(
db
,
txn
,
&
key
,
&
val
,
dbt_init
(
&
key
,
&
rand_key
,
sizeof
rand_key
)
,
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
)
,
0
);
if
(
r
!=
0
)
{
return
r
;
}
}
//
// now put in one more to ensure that the sum stays 0
//
extra
.
u
.
h
.
new_val
=
-
curr_val_sum
;
rand_key
=
myrandom_r
(
arg
->
random_data
);
if
(
arg
->
bounded_element_range
)
{
rand_key
=
rand_key
%
arg
->
cli
->
num_elements
;
}
extra
.
u
.
h
.
expected
=
op_args
->
update_history_buffer
[
rand_key
];
op_args
->
update_history_buffer
[
rand_key
]
=
extra
.
u
.
h
.
new_val
;
r
=
db
->
update
(
db
,
txn
,
dbt_init
(
&
key
,
&
rand_key
,
sizeof
rand_key
),
dbt_init
(
&
val
,
&
extra
,
sizeof
extra
),
0
);
if
(
r
!=
0
)
{
return
r
;
}
return
r
;
}
...
...
@@ -1317,7 +1351,7 @@ static int UU() hot_op(DB_TXN *UU(txn), ARG UU(arg), void* UU(operation_extra),
int
r
;
for
(
int
i
=
0
;
run_test
&&
i
<
arg
->
cli
->
num_DBs
;
i
++
)
{
DB
*
db
=
arg
->
dbp
[
i
];
r
=
db
->
hot_optimize
(
db
,
hot_progress_callback
,
nullptr
);
r
=
db
->
hot_optimize
(
db
,
hot_progress_callback
,
NULL
);
if
(
run_test
)
{
CKERR
(
r
);
}
...
...
@@ -1330,8 +1364,6 @@ get_ith_table_name(char *buf, size_t len, int i) {
snprintf
(
buf
,
len
,
"main%d"
,
i
);
}
DB_TXN
*
const
null_txn
=
0
;
static
int
UU
()
remove_and_recreate_me
(
DB_TXN
*
UU
(
txn
),
ARG
arg
,
void
*
UU
(
operation_extra
),
void
*
UU
(
stats_extra
))
{
int
r
;
int
db_index
=
myrandom_r
(
arg
->
random_data
)
%
arg
->
cli
->
num_DBs
;
...
...
@@ -1342,12 +1374,12 @@ static int UU() remove_and_recreate_me(DB_TXN *UU(txn), ARG arg, void* UU(operat
ZERO_ARRAY
(
name
);
get_ith_table_name
(
name
,
sizeof
(
name
),
db_index
);
r
=
arg
->
env
->
dbremove
(
arg
->
env
,
null_txn
,
name
,
nullptr
,
0
);
r
=
arg
->
env
->
dbremove
(
arg
->
env
,
null_txn
,
name
,
NULL
,
0
);
CKERR
(
r
);
r
=
db_create
(
&
(
arg
->
dbp
[
db_index
]),
arg
->
env
,
0
);
assert
(
r
==
0
);
r
=
arg
->
dbp
[
db_index
]
->
open
(
arg
->
dbp
[
db_index
],
null_txn
,
name
,
nullptr
,
DB_BTREE
,
DB_CREATE
,
0666
);
r
=
arg
->
dbp
[
db_index
]
->
open
(
arg
->
dbp
[
db_index
],
null_txn
,
name
,
NULL
,
DB_BTREE
,
DB_CREATE
,
0666
);
assert
(
r
==
0
);
return
0
;
}
...
...
@@ -1432,7 +1464,6 @@ struct sleep_and_crash_extra {
bool
is_setup
;
bool
threads_have_joined
;
};
static
void
*
sleep_and_crash
(
void
*
extra
)
{
sleep_and_crash_extra
*
e
=
static_cast
<
sleep_and_crash_extra
*>
(
extra
);
toku_mutex_lock
(
&
e
->
mutex
);
...
...
@@ -1477,7 +1508,7 @@ static int run_workers(
int
r
;
const
struct
perf_formatter
*
perf_formatter
=
&
perf_formatters
[
cli_args
->
perf_output_format
];
toku_mutex_t
mutex
=
ZERO_MUTEX_INITIALIZER
;
toku_mutex_init
(
&
mutex
,
nullptr
);
toku_mutex_init
(
&
mutex
,
NULL
);
struct
rwlock
rwlock
;
rwlock_init
(
&
rwlock
);
toku_pthread_t
tids
[
num_threads
];
...
...
@@ -1502,11 +1533,11 @@ static int run_workers(
worker_extra
[
i
].
operation_lock_mutex
=
&
mutex
;
XCALLOC_N
((
int
)
NUM_OPERATION_TYPES
,
worker_extra
[
i
].
counters
);
TOKU_DRD_IGNORE_VAR
(
worker_extra
[
i
].
counters
);
{
int
chk_r
=
toku_pthread_create
(
&
tids
[
i
],
nullptr
,
worker
,
&
worker_extra
[
i
]);
CKERR
(
chk_r
);
}
{
int
chk_r
=
toku_pthread_create
(
&
tids
[
i
],
NULL
,
worker
,
&
worker_extra
[
i
]);
CKERR
(
chk_r
);
}
if
(
verbose
)
printf
(
"%lu created
\n
"
,
(
unsigned
long
)
tids
[
i
]);
}
{
int
chk_r
=
toku_pthread_create
(
&
time_tid
,
nullptr
,
test_time
,
&
tte
);
CKERR
(
chk_r
);
}
{
int
chk_r
=
toku_pthread_create
(
&
time_tid
,
NULL
,
test_time
,
&
tte
);
CKERR
(
chk_r
);
}
if
(
verbose
)
printf
(
"%lu created
\n
"
,
(
unsigned
long
)
time_tid
);
...
...
@@ -1629,22 +1660,131 @@ static int create_tables(DB_ENV **env_res, DB **db_res, int num_DBs,
r
=
db
->
set_readpagesize
(
db
,
env_args
.
basement_node_size
);
CKERR
(
r
);
const
int
flags
=
DB_CREATE
|
(
cli_args
->
blackhole
?
DB_BLACKHOLE
:
0
);
r
=
db
->
open
(
db
,
null_txn
,
name
,
nullptr
,
DB_BTREE
,
flags
,
0666
);
r
=
db
->
open
(
db
,
null_txn
,
name
,
NULL
,
DB_BTREE
,
flags
,
0666
);
CKERR
(
r
);
db_res
[
i
]
=
db
;
}
return
r
;
}
static
void
report_overall_fill_table_progress
(
struct
cli_args
*
args
,
int
num_rows
)
{
static
int
fill_table_from_fun
(
DB_ENV
*
env
,
DB
*
db
,
int
num_elements
,
int
key_bufsz
,
int
val_bufsz
,
void
(
*
callback
)(
int
idx
,
void
*
extra
,
void
*
key
,
int
*
keysz
,
void
*
val
,
int
*
valsz
),
void
*
extra
,
void
(
*
progress_cb
)(
int
num_rows
))
{
DB_TXN
*
txn
=
nullptr
;
const
int
puts_per_txn
=
100000
;
int
r
=
0
;
for
(
long
i
=
0
;
i
<
num_elements
;
++
i
)
{
if
(
txn
==
nullptr
)
{
r
=
env
->
txn_begin
(
env
,
0
,
&
txn
,
0
);
CKERR
(
r
);
}
char
keybuf
[
key_bufsz
],
valbuf
[
val_bufsz
];
memset
(
keybuf
,
0
,
sizeof
(
keybuf
));
memset
(
valbuf
,
0
,
sizeof
(
valbuf
));
int
keysz
,
valsz
;
callback
(
i
,
extra
,
keybuf
,
&
keysz
,
valbuf
,
&
valsz
);
// let's make sure the data stored fits in the buffers we passed in
assert
(
keysz
<=
key_bufsz
);
assert
(
valsz
<=
val_bufsz
);
DBT
key
,
val
;
// make size of data what is specified w/input parameters
// note that key and val have sizes of
// key_bufsz and val_bufsz, which were passed into this
// function, not what was stored by the callback
r
=
db
->
put
(
db
,
txn
,
dbt_init
(
&
key
,
keybuf
,
key_bufsz
),
dbt_init
(
&
val
,
valbuf
,
val_bufsz
),
// don't bother taking locks in the locktree
DB_PRELOCKED_WRITE
);
assert
(
r
==
0
);
if
(
i
>
0
&&
i
%
puts_per_txn
==
0
)
{
// don't bother fsyncing to disk.
// the caller can checkpoint if they want.
r
=
txn
->
commit
(
txn
,
DB_TXN_NOSYNC
);
CKERR
(
r
);
txn
=
nullptr
;
if
(
verbose
)
{
progress_cb
(
puts_per_txn
);
}
}
}
if
(
txn
)
{
r
=
txn
->
commit
(
txn
,
DB_TXN_NOSYNC
);
invariant_zero
(
r
);
}
return
r
;
}
static
uint32_t
breverse
(
uint32_t
v
)
// Effect: return the bits in i, reversed
// Notes: implementation taken from http://graphics.stanford.edu/~seander/bithacks.html#BitReverseObvious
// Rationale: just a hack to spread out the keys during loading, doesn't need to be fast but does need to be correct.
{
uint32_t
r
=
v
;
// r will be reversed bits of v; first get LSB of v
int
s
=
sizeof
(
v
)
*
CHAR_BIT
-
1
;
// extra shift needed at end
for
(
v
>>=
1
;
v
;
v
>>=
1
)
{
r
<<=
1
;
r
|=
v
&
1
;
s
--
;
}
r
<<=
s
;
// shift when v's highest bits are zero
return
r
;
}
static
void
zero_element_callback
(
int
idx
,
void
*
extra
,
void
*
keyv
,
int
*
keysz
,
void
*
valv
,
int
*
valsz
)
{
const
bool
*
disperse_keys
=
static_cast
<
bool
*>
(
extra
);
int
*
CAST_FROM_VOIDP
(
key
,
keyv
);
int
*
CAST_FROM_VOIDP
(
val
,
valv
);
if
(
*
disperse_keys
)
{
*
key
=
static_cast
<
int
>
(
breverse
(
idx
));
}
else
{
*
key
=
idx
;
}
*
val
=
0
;
*
keysz
=
sizeof
(
int
);
*
valsz
=
sizeof
(
int
);
}
struct
fill_table_worker_info
{
DB_ENV
*
env
;
DB
*
db
;
int
num_elements
;
uint32_t
key_size
;
uint32_t
val_size
;
bool
disperse_keys
;
void
(
*
progress_cb
)(
int
num_rows
);
};
static
void
fill_table_worker
(
void
*
arg
)
{
struct
fill_table_worker_info
*
CAST_FROM_VOIDP
(
info
,
arg
);
int
r
=
fill_table_from_fun
(
info
->
env
,
info
->
db
,
info
->
num_elements
,
info
->
key_size
,
info
->
val_size
,
zero_element_callback
,
&
info
->
disperse_keys
,
info
->
progress_cb
);
invariant_zero
(
r
);
toku_free
(
info
);
}
static
int
num_tables_to_fill
=
1
;
static
int
rows_per_table
=
1
;
static
void
report_overall_fill_table_progress
(
int
num_rows
)
{
// for sanitary reasons we'd like to prevent two threads
// from printing the same performance report twice.
static
bool
reporting
;
// when was the first time measurement taken?
static
uint64_t
t0
;
static
int
rows_inserted
;
// when was the last report? what was its progress?
static
uint64_t
last_report
;
static
double
last_progress
;
...
...
@@ -1654,9 +1794,12 @@ static void report_overall_fill_table_progress(struct cli_args *args, int num_ro
}
uint64_t
rows_so_far
=
toku_sync_add_and_fetch
(
&
rows_inserted
,
num_rows
);
double
progress
=
rows_so_far
/
(
args
->
num_elements
*
args
->
num_DBs
*
1.0
);
double
progress
=
rows_so_far
/
(
rows_per_table
*
num_tables_to_fill
*
1.0
);
if
(
progress
>
(
last_progress
+
.01
))
{
uint64_t
t1
=
toku_current_time_microsec
();
// report no more often than once every 5 seconds, for less output.
// there is a race condition. it is probably harmless.
const
uint64_t
minimum_report_period
=
5
*
1000000
;
if
(
t1
>
last_report
+
minimum_report_period
&&
toku_sync_bool_compare_and_swap
(
&
reporting
,
0
,
1
)
==
0
)
{
...
...
@@ -1670,68 +1813,24 @@ static void report_overall_fill_table_progress(struct cli_args *args, int num_ro
}
}
static
void
fill_single_table
(
DB_ENV
*
env
,
DB
*
db
,
struct
cli_args
*
args
,
bool
fill_with_zeroes
)
{
const
int
puts_per_txn
=
100000
;
int
r
=
0
;
DB_TXN
*
txn
=
nullptr
;
struct
random_data
random_data
;
char
random_buf
[
8
];
r
=
myinitstate_r
(
random
(),
random_buf
,
8
,
&
random_data
);
CKERR
(
r
);
uint8_t
keybuf
[
args
->
key_size
],
valbuf
[
args
->
val_size
];
memset
(
keybuf
,
0
,
sizeof
keybuf
);
memset
(
valbuf
,
0
,
sizeof
valbuf
);
DBT
key
,
val
;
dbt_init
(
&
key
,
keybuf
,
args
->
key_size
);
dbt_init
(
&
val
,
valbuf
,
args
->
val_size
);
static
int
fill_tables_with_zeroes
(
DB_ENV
*
env
,
DB
**
dbs
,
int
num_DBs
,
int
num_elements
,
uint32_t
key_size
,
uint32_t
val_size
,
bool
disperse_keys
)
{
// set the static globals that the progress reporter uses
num_tables_to_fill
=
num_DBs
;
rows_per_table
=
num_elements
;
for
(
int
i
=
0
;
i
<
args
->
num_elements
;
i
++
)
{
if
(
txn
==
nullptr
)
{
r
=
env
->
txn_begin
(
env
,
0
,
&
txn
,
0
);
CKERR
(
r
);
}
fill_key_buf
(
i
,
keybuf
,
args
);
if
(
!
fill_with_zeroes
)
{
fill_val_buf_random
(
&
random_data
,
valbuf
,
args
);
}
r
=
db
->
put
(
db
,
txn
,
&
key
,
&
val
,
DB_PRELOCKED_WRITE
);
CKERR
(
r
);
if
(
i
>
0
&&
i
%
puts_per_txn
==
0
)
{
// don't bother fsyncing to disk.
// the caller can checkpoint if they want.
r
=
txn
->
commit
(
txn
,
DB_TXN_NOSYNC
);
CKERR
(
r
);
txn
=
nullptr
;
if
(
verbose
)
{
report_overall_fill_table_progress
(
args
,
puts_per_txn
);
}
}
}
if
(
txn
)
{
r
=
txn
->
commit
(
txn
,
DB_TXN_NOSYNC
);
CKERR
(
r
);
}
}
struct
fill_table_worker_info
{
struct
cli_args
*
args
;
DB_ENV
*
env
;
DB
*
db
;
bool
fill_with_zeroes
;
};
static
void
fill_table_worker
(
void
*
arg
)
{
struct
fill_table_worker_info
*
CAST_FROM_VOIDP
(
info
,
arg
);
fill_single_table
(
info
->
env
,
info
->
db
,
info
->
args
,
info
->
fill_with_zeroes
);
toku_free
(
info
);
}
static
int
fill_tables
(
DB_ENV
*
env
,
DB
**
dbs
,
struct
cli_args
*
args
,
bool
fill_with_zeroes
)
{
const
int
num_cores
=
toku_os_get_number_processors
();
KIBBUTZ
kibbutz
=
toku_kibbutz_create
(
num_cores
);
for
(
int
i
=
0
;
i
<
args
->
num_DBs
;
i
++
)
{
for
(
int
i
=
0
;
i
<
num_DBs
;
i
++
)
{
assert
(
key_size
>=
sizeof
(
int
));
assert
(
val_size
>=
sizeof
(
int
));
struct
fill_table_worker_info
*
XCALLOC
(
info
);
info
->
env
=
env
;
info
->
db
=
dbs
[
i
];
info
->
args
=
args
;
info
->
fill_with_zeroes
=
fill_with_zeroes
;
info
->
num_elements
=
num_elements
;
info
->
key_size
=
key_size
;
info
->
val_size
=
val_size
;
info
->
disperse_keys
=
disperse_keys
;
info
->
progress_cb
=
report_overall_fill_table_progress
;
toku_kibbutz_enq
(
kibbutz
,
fill_table_worker
,
info
);
}
toku_kibbutz_destroy
(
kibbutz
);
...
...
@@ -1766,6 +1865,7 @@ static int open_tables(DB_ENV **env_res, DB **db_res, int num_DBs,
int
r
;
struct
env_args
env_args
=
cli_args
->
env_args
;
/* create the dup database file */
DB_ENV
*
env
;
db_env_set_num_bucket_mutexes
(
env_args
.
num_bucket_mutexes
);
r
=
db_env_create
(
&
env
,
0
);
assert
(
r
==
0
);
...
...
@@ -1773,6 +1873,7 @@ static int open_tables(DB_ENV **env_res, DB **db_res, int num_DBs,
r
=
env
->
set_default_bt_compare
(
env
,
bt_compare
);
CKERR
(
r
);
r
=
env
->
set_lk_max_memory
(
env
,
env_args
.
lk_max_memory
);
CKERR
(
r
);
env
->
set_update
(
env
,
env_args
.
update_function
);
// set the cache size to 10MB
r
=
env
->
set_cachesize
(
env
,
env_args
.
cachetable_size
/
(
1
<<
30
),
env_args
.
cachetable_size
%
(
1
<<
30
),
1
);
CKERR
(
r
);
r
=
env
->
set_lg_bsize
(
env
,
env_args
.
rollback_node_size
);
CKERR
(
r
);
if
(
env_args
.
generate_put_callback
)
{
...
...
@@ -1803,7 +1904,7 @@ static int open_tables(DB_ENV **env_res, DB **db_res, int num_DBs,
r
=
db_create
(
&
db
,
env
,
0
);
CKERR
(
r
);
const
int
flags
=
cli_args
->
blackhole
?
DB_BLACKHOLE
:
0
;
r
=
db
->
open
(
db
,
null_txn
,
name
,
nullptr
,
DB_BTREE
,
flags
,
0666
);
r
=
db
->
open
(
db
,
null_txn
,
name
,
NULL
,
DB_BTREE
,
flags
,
0666
);
CKERR
(
r
);
db_res
[
i
]
=
db
;
}
...
...
@@ -1831,8 +1932,8 @@ static const struct env_args DEFAULT_ENV_ARGS = {
.
num_bucket_mutexes
=
1024
,
.
envdir
=
ENVDIR
,
.
update_function
=
update_op_callback
,
.
generate_put_callback
=
nullptr
,
.
generate_del_callback
=
nullptr
,
.
generate_put_callback
=
NULL
,
.
generate_del_callback
=
NULL
,
};
static
const
struct
env_args
DEFAULT_PERF_ENV_ARGS
=
{
...
...
@@ -1846,11 +1947,15 @@ static const struct env_args DEFAULT_PERF_ENV_ARGS = {
.
cachetable_size
=
1
<<
30
,
.
num_bucket_mutexes
=
1024
*
1024
,
.
envdir
=
ENVDIR
,
.
update_function
=
nullptr
,
.
generate_put_callback
=
nullptr
,
.
generate_del_callback
=
nullptr
,
.
update_function
=
NULL
,
.
generate_put_callback
=
NULL
,
.
generate_del_callback
=
NULL
,
};
#define MIN_VAL_SIZE sizeof(int)
#define MIN_KEY_SIZE sizeof(int)
#define MIN_COMPRESSIBILITY (0.0)
#define MAX_COMPRESSIBILITY (1.0)
static
struct
cli_args
UU
()
get_default_args
(
void
)
{
struct
cli_args
DEFAULT_ARGS
=
{
.
num_elements
=
150000
,
...
...
@@ -2222,7 +2327,7 @@ static inline void parse_stress_test_args (int argc, char *const argv[], struct
#define LOCAL_STRING_ARG(name_string, variable, default) \
MAKE_LOCAL_ARG(name_string, type_string, s, default, variable, "", "", "")
const
char
*
perf_format_s
=
nullptr
;
const
char
*
perf_format_s
=
NULL
;
struct
arg_type
arg_types
[]
=
{
INT32_ARG_NONNEG
(
"--num_elements"
,
num_elements
,
""
),
INT32_ARG_NONNEG
(
"--num_DBs"
,
num_DBs
,
""
),
...
...
@@ -2334,15 +2439,20 @@ static inline void parse_stress_test_args (int argc, char *const argv[], struct
}
}
}
if
(
perf_format_s
!=
nullptr
)
{
if
(
perf_format_s
!=
NULL
)
{
if
(
!
strcmp
(
perf_format_s
,
"human"
))
{
args
->
perf_output_format
=
HUMAN
;
}
else
if
(
!
strcmp
(
perf_format_s
,
"csv"
))
{
args
->
perf_output_format
=
CSV
;
}
else
if
(
!
strcmp
(
perf_format_s
,
"tsv"
))
{
args
->
perf_output_format
=
TSV
;
#if 0
} else if (!strcmp(perf_format_s, "gnuplot")) {
args->perf_output_format = GNUPLOT;
#endif
}
else
{
fprintf
(
stderr
,
"valid values for --perf_format are
\"
human
\"
,
\"
csv
\"
, and
\"
tsv
\"\n
"
);
//fprintf(stderr, "valid values for --perf_format are \"human\", \"csv\", \"tsv\", and \"gnuplot\"\n");
do_usage
(
argv0
,
num_arg_types
,
arg_types
);
exit
(
EINVAL
);
}
...
...
@@ -2358,24 +2468,35 @@ static void
stress_table
(
DB_ENV
*
,
DB
**
,
struct
cli_args
*
);
static
int
stress_dbt_cmp
(
DB
*
db
,
const
DBT
*
a
,
const
DBT
*
b
)
{
UU
()
stress_int_dbt_cmp
(
DB
*
db
,
const
DBT
*
a
,
const
DBT
*
b
)
{
assert
(
db
&&
a
&&
b
);
assert
(
a
->
size
>=
sizeof
(
int
));
assert
(
b
->
size
>=
sizeof
(
int
));
int
x
=
*
(
int
*
)
a
->
data
;
int
y
=
*
(
int
*
)
b
->
data
;
if
(
x
<
y
)
return
-
1
;
if
(
x
>
y
)
return
1
;
return
0
;
}
// Keys are only compared by their first 8 bytes,
// interpreted as a little endian 64 bit integer..
assert
(
a
->
size
>=
sizeof
(
int64_t
));
assert
(
b
->
size
>=
sizeof
(
int64_t
));
static
int
UU
()
stress_uint64_dbt_cmp
(
DB
*
db
,
const
DBT
*
a
,
const
DBT
*
b
)
{
assert
(
db
&&
a
&&
b
);
assert
(
a
->
size
>=
sizeof
(
uint64_t
));
assert
(
b
->
size
>=
sizeof
(
uint64_t
));
int64_t
x
=
*
(
int64_t
*
)
a
->
data
;
int64_t
y
=
*
(
int64_t
*
)
b
->
data
;
uint64_t
x
=
*
(
u
int64_t
*
)
a
->
data
;
uint64_t
y
=
*
(
u
int64_t
*
)
b
->
data
;
if
(
x
<
y
)
{
return
-
1
;
}
else
if
(
x
>
y
)
{
}
if
(
x
>
y
)
{
return
+
1
;
}
else
{
return
0
;
}
return
0
;
}
...
...
@@ -2391,49 +2512,21 @@ do_warm_cache(DB_ENV *env, DB **dbs, struct cli_args *args)
scan_arg
.
operation_extra
=
&
soe
;
scan_arg
.
operation
=
scan_op_no_check
;
scan_arg
.
lock_type
=
STRESS_LOCK_NONE
;
DB_TXN
*
txn
=
nullptr
;
DB_TXN
*
txn
=
NULL
;
// don't take serializable read locks when scanning.
int
r
=
env
->
txn_begin
(
env
,
0
,
&
txn
,
DB_TXN_SNAPSHOT
);
CKERR
(
r
);
// make sure the scan doesn't terminate early
run_test
=
true
;
// warm up each DB in parallel
scan_op_no_check_parallel
(
txn
,
&
scan_arg
,
&
soe
,
nullptr
);
scan_op_no_check_parallel
(
txn
,
&
scan_arg
,
&
soe
,
NULL
);
r
=
txn
->
commit
(
txn
,
0
);
CKERR
(
r
);
}
static
void
UU
()
stress_recover
(
struct
cli_args
*
args
)
{
DB_ENV
*
env
=
nullptr
;
DB
*
dbs
[
args
->
num_DBs
];
memset
(
dbs
,
0
,
sizeof
(
dbs
));
{
int
chk_r
=
open_tables
(
&
env
,
dbs
,
args
->
num_DBs
,
stress_dbt_cmp
,
args
);
CKERR
(
chk_r
);
}
DB_TXN
*
txn
=
nullptr
;
struct
arg
recover_args
;
arg_init
(
&
recover_args
,
dbs
,
env
,
args
);
int
r
=
env
->
txn_begin
(
env
,
0
,
&
txn
,
recover_args
.
txn_type
);
CKERR
(
r
);
struct
scan_op_extra
soe
;
soe
.
fast
=
true
;
soe
.
fwd
=
true
;
soe
.
prefetch
=
false
;
// make sure the scan doesn't terminate early
run_test
=
true
;
r
=
scan_op
(
txn
,
&
recover_args
,
&
soe
,
nullptr
);
CKERR
(
r
);
{
int
chk_r
=
txn
->
commit
(
txn
,
0
);
CKERR
(
chk_r
);
}
{
int
chk_r
=
close_tables
(
env
,
dbs
,
args
->
num_DBs
);
CKERR
(
chk_r
);
}
}
static
void
test_main
(
struct
cli_args
*
args
,
bool
fill_with_zeroes
)
UU
()
stress_test_main_with_cmp
(
struct
cli_args
*
args
,
int
(
*
bt_compare
)(
DB
*
,
const
DBT
*
,
const
DBT
*
))
{
{
char
*
loc
=
setlocale
(
LC_NUMERIC
,
"en_US.UTF-8"
);
assert
(
loc
);
}
DB_ENV
*
env
=
nullptr
;
DB_ENV
*
env
=
NULL
;
DB
*
dbs
[
args
->
num_DBs
];
memset
(
dbs
,
0
,
sizeof
(
dbs
));
db_env_enable_engine_status
(
args
->
nocrashstatus
?
false
:
true
);
...
...
@@ -2442,17 +2535,17 @@ test_main(struct cli_args *args, bool fill_with_zeroes)
&
env
,
dbs
,
args
->
num_DBs
,
stress_dbt_cmp
,
bt_compare
,
args
);
{
int
chk_r
=
fill_tables
(
env
,
dbs
,
args
,
fill_with_zeroe
s
);
CKERR
(
chk_r
);
}
{
int
chk_r
=
fill_tables
_with_zeroes
(
env
,
dbs
,
args
->
num_DBs
,
args
->
num_elements
,
args
->
key_size
,
args
->
val_size
,
args
->
disperse_key
s
);
CKERR
(
chk_r
);
}
{
int
chk_r
=
close_tables
(
env
,
dbs
,
args
->
num_DBs
);
CKERR
(
chk_r
);
}
}
if
(
!
args
->
only_create
)
{
{
int
chk_r
=
open_tables
(
&
env
,
dbs
,
args
->
num_DBs
,
stress_dbt_cmp
,
bt_compare
,
args
);
CKERR
(
chk_r
);
}
if
(
args
->
warm_cache
)
{
do_warm_cache
(
env
,
dbs
,
args
);
...
...
@@ -2463,17 +2556,37 @@ test_main(struct cli_args *args, bool fill_with_zeroes)
}
static
void
UU
()
stress_test_main
(
struct
cli_args
*
args
)
{
// Begin the test with fixed size values equal to zero.
// This is important for correctness testing.
test_main
(
args
,
true
);
UU
()
stress_test_main
(
struct
cli_args
*
args
)
{
stress_test_main_with_cmp
(
args
,
stress_int_dbt_cmp
);
}
static
void
UU
()
perf_test_main
(
struct
cli_args
*
args
)
{
// Do not begin the test by creating a table of all zeroes.
// We want to control the row size and its compressibility.
test_main
(
args
,
false
);
UU
()
stress_recover
(
struct
cli_args
*
args
)
{
DB_ENV
*
env
=
NULL
;
DB
*
dbs
[
args
->
num_DBs
];
memset
(
dbs
,
0
,
sizeof
(
dbs
));
{
int
chk_r
=
open_tables
(
&
env
,
dbs
,
args
->
num_DBs
,
stress_int_dbt_cmp
,
args
);
CKERR
(
chk_r
);
}
DB_TXN
*
txn
=
NULL
;
struct
arg
recover_args
;
arg_init
(
&
recover_args
,
dbs
,
env
,
args
);
int
r
=
env
->
txn_begin
(
env
,
0
,
&
txn
,
recover_args
.
txn_type
);
CKERR
(
r
);
struct
scan_op_extra
soe
;
soe
.
fast
=
true
;
soe
.
fwd
=
true
;
soe
.
prefetch
=
false
;
// make sure the scan doesn't terminate early
run_test
=
true
;
r
=
scan_op
(
txn
,
&
recover_args
,
&
soe
,
NULL
);
CKERR
(
r
);
{
int
chk_r
=
txn
->
commit
(
txn
,
0
);
CKERR
(
chk_r
);
}
{
int
chk_r
=
close_tables
(
env
,
dbs
,
args
->
num_DBs
);
CKERR
(
chk_r
);
}
}
#endif
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