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btree.cc
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#include <unistd.h>
#include <iostream>
#include <map>
#include <set>
#include <stack>
#include <vector>
#include <sstream>
#include <atomic>
#include <memory>
#include "core.h"
#include "btree.h"
#include "btree_impl.h"
#include "thread.h"
#include "txn.h"
#include "util.h"
#include "scopedperf.hh"
#if defined(NDB_MASSTREE)
#include "masstree_btree.h"
struct testing_concurrent_btree_traits : public masstree_params {
static const bool RcuRespCaller = false;
};
typedef mbtree<testing_concurrent_btree_traits> testing_concurrent_btree;
#define HAVE_REVERSE_RANGE_SCANS
#else
struct testing_concurrent_btree_traits : public concurrent_btree_traits {
static const bool RcuRespCaller = false;
};
typedef btree<testing_concurrent_btree_traits> testing_concurrent_btree;
#endif
using namespace std;
using namespace util;
class scoped_rate_timer {
private:
util::timer t;
string region;
size_t n;
public:
scoped_rate_timer(const string ®ion, size_t n) : region(region), n(n)
{}
~scoped_rate_timer()
{
double x = t.lap() / 1000.0; // ms
double rate = double(n) / (x / 1000.0);
cerr << "timed region `" << region << "' took " << x
<< " ms (" << rate << " events/sec)" << endl;
}
};
class btree_worker : public ndb_thread {
public:
btree_worker(testing_concurrent_btree *btr) : btr(btr) {}
btree_worker(testing_concurrent_btree &btr) : btr(&btr) {}
protected:
testing_concurrent_btree *const btr;
};
static void
test1()
{
testing_concurrent_btree btr;
btr.invariant_checker();
// fill up root leaf node
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == testing_concurrent_btree::NKeysPerNode);
// induce a split
btr.insert(u64_varkey(testing_concurrent_btree::NKeysPerNode), (typename testing_concurrent_btree::value_type) (testing_concurrent_btree::NKeysPerNode));
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == testing_concurrent_btree::NKeysPerNode + 1);
// now make sure we can find everything post split
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode + 1; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
// now fill up the new root node
const size_t n = (testing_concurrent_btree::NKeysPerNode + testing_concurrent_btree::NKeysPerNode * (testing_concurrent_btree::NMinKeysPerNode));
for (size_t i = testing_concurrent_btree::NKeysPerNode + 1; i < n; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == n);
// cause the root node to split
btr.insert(u64_varkey(n), (typename testing_concurrent_btree::value_type) n);
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == n + 1);
// once again make sure we can find everything
for (size_t i = 0; i < n + 1; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
}
static void
test2()
{
testing_concurrent_btree btr;
const size_t n = 1000;
for (size_t i = 0; i < n; i += 2) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
for (size_t i = 1; i < n; i += 2) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == n);
}
static void
test3()
{
testing_concurrent_btree btr;
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode * 2; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == testing_concurrent_btree::NKeysPerNode * 2);
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode * 2; i++) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode * 2; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == testing_concurrent_btree::NKeysPerNode * 2);
for (ssize_t i = testing_concurrent_btree::NKeysPerNode * 2 - 1; i >= 0; i--) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
for (size_t i = 0; i < testing_concurrent_btree::NKeysPerNode * 2; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == testing_concurrent_btree::NKeysPerNode * 2);
for (ssize_t i = testing_concurrent_btree::NKeysPerNode; i >= 0; i--) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
for (size_t i = testing_concurrent_btree::NKeysPerNode + 1; i < testing_concurrent_btree::NKeysPerNode * 2; i++) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
}
static void
test4()
{
testing_concurrent_btree btr;
const size_t nkeys = 10000;
for (size_t i = 0; i < nkeys; i++) {
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == nkeys);
srand(12345);
for (size_t i = 0; i < nkeys; i++) {
size_t k = rand() % nkeys;
btr.remove(u64_varkey(k));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(k), v));
}
for (size_t i = 0; i < nkeys; i++) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
}
static void
test5()
{
// insert in random order, delete in random order
testing_concurrent_btree btr;
unsigned int seeds[] = {
54321, 2013883780, 3028985725, 3058602342, 256561598, 2895653051
};
for (size_t iter = 0; iter < ARRAY_NELEMS(seeds); iter++) {
srand(seeds[iter]);
const size_t nkeys = 20000;
set<size_t> s;
for (size_t i = 0; i < nkeys; i++) {
size_t k = rand() % nkeys;
s.insert(k);
btr.insert(u64_varkey(k), (typename testing_concurrent_btree::value_type) k);
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(k), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) k);
}
ALWAYS_ASSERT(btr.size() == s.size());
for (size_t i = 0; i < nkeys * 2; i++) {
size_t k = rand() % nkeys;
btr.remove(u64_varkey(k));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(k), v));
}
// clean it up
for (size_t i = 0; i < nkeys; i++) {
btr.remove(u64_varkey(i));
btr.invariant_checker();
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
}
}
namespace test6_ns {
struct scan_callback {
typedef vector<
pair< std::string, // we want to make copies of keys
typename testing_concurrent_btree::value_type > > kv_vec;
scan_callback(kv_vec *data, bool reverse = false)
: data(data), reverse_(reverse) {}
inline bool
operator()(const typename testing_concurrent_btree::string_type &k,
typename testing_concurrent_btree::value_type v) const
{
if (!data->empty()) {
const bool geq =
typename testing_concurrent_btree::string_type(data->back().first) >= k;
const bool leq =
typename testing_concurrent_btree::string_type(data->back().first) <= k;
if ((!reverse_ && geq) || (reverse_ && leq)) {
cerr << "data->size(): " << data->size() << endl;
cerr << "prev: " << varkey(data->back().first) << endl;
cerr << "cur : " << varkey(k) << endl;
ALWAYS_ASSERT(false);
}
}
data->push_back(make_pair(k, v));
return true;
}
kv_vec *data;
bool reverse_;
};
}
static void
test6()
{
testing_concurrent_btree btr;
const size_t nkeys = 1000;
for (size_t i = 0; i < nkeys; i++)
btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == nkeys);
using namespace test6_ns;
scan_callback::kv_vec data;
scan_callback cb(&data);
u64_varkey max_key(600);
btr.search_range(u64_varkey(500), &max_key, cb);
ALWAYS_ASSERT(data.size() == 100);
for (size_t i = 0; i < 100; i++) {
const varkey lhs(data[i].first), rhs(u64_varkey(500 + i));
ALWAYS_ASSERT(lhs == rhs);
ALWAYS_ASSERT(data[i].second == (typename testing_concurrent_btree::value_type) (500 + i));
}
data.clear();
btr.search_range(u64_varkey(500), NULL, cb);
ALWAYS_ASSERT(data.size() == 500);
for (size_t i = 0; i < 500; i++) {
ALWAYS_ASSERT(varkey(data[i].first) == u64_varkey(500 + i));
ALWAYS_ASSERT(data[i].second == (typename testing_concurrent_btree::value_type) (500 + i));
}
#ifdef HAVE_REVERSE_RANGE_SCANS
data.clear();
scan_callback cb_rev(&data, true);
btr.rsearch_range(u64_varkey(499), NULL, cb_rev);
ALWAYS_ASSERT(data.size() == 500);
for (ssize_t i = 499; i >= 0; i--) {
ALWAYS_ASSERT(varkey(data[499 - i].first) == u64_varkey(i));
ALWAYS_ASSERT(data[499 - i].second == (typename testing_concurrent_btree::value_type) (i));
}
data.clear();
u64_varkey min_key(499);
btr.rsearch_range(u64_varkey(999), &min_key, cb_rev);
ALWAYS_ASSERT(data.size() == 500);
for (ssize_t i = 999; i >= 500; i--) {
ALWAYS_ASSERT(varkey(data[999 - i].first) == u64_varkey(i));
ALWAYS_ASSERT(data[999 - i].second == (typename testing_concurrent_btree::value_type) (i));
}
#endif
}
static void
test7()
{
testing_concurrent_btree btr;
ALWAYS_ASSERT(!btr.remove(u64_varkey(0)));
ALWAYS_ASSERT(btr.insert(u64_varkey(0), (typename testing_concurrent_btree::value_type) 0));
ALWAYS_ASSERT(!btr.insert(u64_varkey(0), (typename testing_concurrent_btree::value_type) 1));
typename testing_concurrent_btree::value_type v;
ALWAYS_ASSERT(btr.search(u64_varkey(0), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) 1);
ALWAYS_ASSERT(!btr.insert_if_absent(u64_varkey(0), (typename testing_concurrent_btree::value_type) 2));
ALWAYS_ASSERT(btr.search(u64_varkey(0), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) 1);
ALWAYS_ASSERT(btr.remove(u64_varkey(0)));
ALWAYS_ASSERT(btr.insert_if_absent(u64_varkey(0), (typename testing_concurrent_btree::value_type) 2));
ALWAYS_ASSERT(btr.search(u64_varkey(0), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) 2);
}
static void
test_varlen_single_layer()
{
testing_concurrent_btree btr;
const char *k0 = "a";
const char *k1 = "aa";
const char *k2 = "aaa";
const char *k3 = "aaaa";
const char *k4 = "aaaaa";
const char *keys[] = {k0, k1, k2, k3, k4};
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.insert(varkey(keys[i]), (typename testing_concurrent_btree::value_type) keys[i]));
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == ARRAY_NELEMS(keys));
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(keys[i]), v));
ALWAYS_ASSERT(strcmp((const char *) v, keys[i]) == 0);
}
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.remove(varkey(keys[i])));
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == 0);
}
static void
test_varlen_multi_layer()
{
testing_concurrent_btree btr;
const char *k0 = "aaaaaaa";
const char *k1 = "aaaaaaaa";
const char *k2 = "aaaaaaaaa";
const char *k3 = "aaaaaaaaaa";
const char *k4 = "aaaaaaaaaaa";
const char *k5 = "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa";
const char *keys[] = {k0, k1, k2, k3, k4, k5};
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.insert(varkey(keys[i]), (typename testing_concurrent_btree::value_type) keys[i]));
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == ARRAY_NELEMS(keys));
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(keys[i]), v));
ALWAYS_ASSERT(strcmp((const char *) v, keys[i]) == 0);
}
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.remove(varkey(keys[i])));
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == 0);
}
static void
test_two_layer()
{
const char *k0 = "aaaaaaaaa";
const char *k1 = "aaaaaaaaaa";
testing_concurrent_btree btr;
ALWAYS_ASSERT(btr.insert(varkey(k0), (typename testing_concurrent_btree::value_type) k0));
ALWAYS_ASSERT(btr.insert(varkey(k1), (typename testing_concurrent_btree::value_type) k1));
ALWAYS_ASSERT(btr.size() == 2);
}
static __attribute__((used)) void test_ensure_printable() {
testing_concurrent_btree btr;
btr.print();
}
class test_range_scan_helper : public testing_concurrent_btree::search_range_callback {
public:
struct expect {
expect() : tag(), expected_size() {}
expect(size_t expected_size)
: tag(0), expected_size(expected_size) {}
expect(const set<string> &expected_keys)
: tag(1), expected_keys(expected_keys) {}
uint8_t tag;
size_t expected_size;
set<string> expected_keys;
};
enum ExpectType {
EXPECT_EXACT,
EXPECT_ATLEAST,
};
test_range_scan_helper(
testing_concurrent_btree &btr,
const testing_concurrent_btree::key_type &begin,
const testing_concurrent_btree::key_type *end,
bool reverse,
const expect &expectation,
ExpectType ex_type = EXPECT_EXACT)
: btr(&btr),
begin(begin),
end(end ? new testing_concurrent_btree::key_type(*end) : NULL),
reverse_(reverse),
expectation(expectation),
ex_type(ex_type)
{
}
~test_range_scan_helper()
{
if (end)
delete end;
}
virtual bool
invoke(const typename testing_concurrent_btree::string_type &k,
typename testing_concurrent_btree::value_type v)
{
VERBOSE(cerr << "test_range_scan_helper::invoke(): received key(size="
<< k.size() << "): " << hexify(k) << endl);
if (!keys.empty()) {
if (!reverse_)
ALWAYS_ASSERT(typename testing_concurrent_btree::string_type(keys.back()) < k);
else
ALWAYS_ASSERT(typename testing_concurrent_btree::string_type(keys.back()) > k);
}
keys.push_back(k);
return true;
}
void test()
{
keys.clear();
if (!reverse_)
btr->search_range_call(begin, end, *this);
else
btr->rsearch_range_call(begin, end, *this);
if (expectation.tag == 0) {
switch (ex_type) {
case EXPECT_EXACT:
ALWAYS_ASSERT(keys.size() == expectation.expected_size);
break;
case EXPECT_ATLEAST:
ALWAYS_ASSERT(keys.size() >= expectation.expected_size);
break;
}
} else {
switch (ex_type) {
case EXPECT_EXACT: {
ALWAYS_ASSERT(keys.size() == expectation.expected_keys.size());
vector<string> cmp;
if (!reverse_)
cmp.assign(expectation.expected_keys.begin(), expectation.expected_keys.end());
else
cmp.assign(expectation.expected_keys.rbegin(), expectation.expected_keys.rend());
for (size_t i = 0; i < keys.size(); i++) {
if (keys[i] != cmp[i]) {
cerr << "A: " << hexify(keys[i]) << endl;
cerr << "B: " << hexify(cmp[i]) << endl;
ALWAYS_ASSERT(false);
}
}
break;
}
case EXPECT_ATLEAST: {
ALWAYS_ASSERT(keys.size() >= expectation.expected_keys.size());
// every key in the expected set must be present
set<string> keyset(keys.begin(), keys.end());
for (auto it = expectation.expected_keys.begin();
it != expectation.expected_keys.end(); ++it)
ALWAYS_ASSERT(keyset.count(*it) == 1);
break;
}
}
}
}
private:
testing_concurrent_btree *const btr;
testing_concurrent_btree::key_type begin;
testing_concurrent_btree::key_type *end;
bool reverse_;
expect expectation;
ExpectType ex_type;
vector<string> keys;
};
static void
test_two_layer_range_scan()
{
const char *keys[] = {
"a",
"aaaaaaaa",
"aaaaaaaaa",
"aaaaaaaaaa",
"aaaaaaaaaaa",
"b", "c", "d", "e", "f", "g", "h", "i", "j", "k",
"l", "m", "n", "o", "p", "q", "r", "s",
};
testing_concurrent_btree btr;
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.insert(varkey(keys[i]), (typename testing_concurrent_btree::value_type) keys[i]));
btr.invariant_checker();
}
test_range_scan_helper::expect ex(set<string>(keys, keys + ARRAY_NELEMS(keys)));
test_range_scan_helper tester(btr, varkey(""), NULL, false, ex);
tester.test();
#ifdef HAVE_REVERSE_RANGE_SCANS
test_range_scan_helper tester_rev(btr, varkey("zzzzzzzzzzzzzzzzzzzzzz"), NULL, true, ex);
tester_rev.test();
#endif
}
static void
test_multi_layer_scan()
{
const uint8_t lokey_cstr[] = {
0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x02, 0x45, 0x49, 0x4E, 0x47,
0x41, 0x54, 0x49, 0x4F, 0x4E, 0x45, 0x49, 0x4E, 0x47, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00
};
const uint8_t hikey_cstr[] = {
0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x02, 0x45, 0x49, 0x4E, 0x47,
0x41, 0x54, 0x49, 0x4F, 0x4E, 0x45, 0x49, 0x4E, 0x47, 0x00, 0x00, 0x00,
0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
0xFF, 0xFF, 0xFF, 0xFF
};
const string lokey_s((const char *) &lokey_cstr[0], ARRAY_NELEMS(lokey_cstr));
const string hikey_s((const char *) &hikey_cstr[0], ARRAY_NELEMS(hikey_cstr));
string lokey_s_next(lokey_s);
lokey_s_next.resize(lokey_s_next.size() + 1);
const varkey hikey(hikey_s);
testing_concurrent_btree btr;
ALWAYS_ASSERT(btr.insert(varkey(lokey_s), (typename testing_concurrent_btree::value_type) 0x123));
test_range_scan_helper::expect ex(0);
test_range_scan_helper tester(btr, varkey(lokey_s_next), &hikey, false, ex);
tester.test();
#ifdef HAVE_REVERSE_RANGE_SCANS
const varkey lokey(lokey_s);
test_range_scan_helper tester_rev(btr, varkey(hikey_s), &lokey, true, ex);
tester_rev.test();
#endif
}
static void
test_null_keys()
{
const uint8_t k0[] = {};
const uint8_t k1[] = {'\0'};
const uint8_t k2[] = {'\0', '\0'};
const uint8_t k3[] = {'\0', '\0', '\0'};
const uint8_t k4[] = {'\0', '\0', '\0', '\0'};
const uint8_t k5[] = {'\0', '\0', '\0', '\0', '\0'};
const uint8_t k6[] = {'\0', '\0', '\0', '\0', '\0', '\0'};
const uint8_t k7[] = {'\0', '\0', '\0', '\0', '\0', '\0', '\0'};
const uint8_t k8[] = {'\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0'};
const uint8_t k9[] = {'\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0'};
const uint8_t k10[] = {'\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0', '\0'};
const uint8_t *keys[] = {k0, k1, k2, k3, k4, k5, k6, k7, k8, k9, k10};
testing_concurrent_btree btr;
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
ALWAYS_ASSERT(btr.insert(varkey(keys[i], i), (typename testing_concurrent_btree::value_type) i));
btr.invariant_checker();
}
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(keys[i], i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
for (size_t i = 1; i <= 20; i++) {
ALWAYS_ASSERT(btr.insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i));
btr.invariant_checker();
}
for (size_t i = 0; i < ARRAY_NELEMS(keys); i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(keys[i], i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
for (size_t i = 1; i <= 20; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
}
static void
test_null_keys_2()
{
const size_t nprefixes = 200;
testing_concurrent_btree btr;
fast_random r(9084398309893);
set<string> prefixes;
for (size_t i = 0; i < nprefixes; i++) {
retry:
const string k(r.next_string(r.next() % 30));
if (prefixes.count(k) == 1)
goto retry;
prefixes.insert(k);
}
set<string> keys;
for (auto &prefix : prefixes) {
for (size_t i = 1; i <= 12; i++) {
std::string x(prefix);
x.resize(x.size() + i);
keys.insert(x);
}
}
size_t ctr = 1;
for (auto it = keys.begin(); it != keys.end(); ++it, ++ctr) {
ALWAYS_ASSERT(btr.insert(varkey(*it), (typename testing_concurrent_btree::value_type) it->data()));
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == ctr);
}
ALWAYS_ASSERT(btr.size() == keys.size());
for (auto it = keys.begin(); it != keys.end(); ++it) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(*it), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) it->data());
}
test_range_scan_helper::expect ex(keys);
test_range_scan_helper tester(btr, varkey(*keys.begin()), NULL, false, ex);
tester.test();
#ifdef HAVE_REVERSE_RANGE_SCANS
test_range_scan_helper tester_rev(btr, varkey(*keys.rbegin()), NULL, true, ex);
tester_rev.test();
#endif
ctr = keys.size() - 1;
for (auto it = keys.begin(); it != keys.end(); ++it, --ctr) {
ALWAYS_ASSERT(btr.remove(varkey(*it)));
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == ctr);
}
ALWAYS_ASSERT(btr.size() == 0);
}
static inline string
maxkey(unsigned size)
{
return string(size, 255);
}
static void
test_random_keys()
{
testing_concurrent_btree btr;
fast_random r(43698);
const size_t nkeys = 10000;
const unsigned int maxkeylen = 1000;
set<string> keyset;
vector<string> keys;
keys.resize(nkeys);
for (size_t i = 0; i < nkeys; i++) {
retry:
string k = r.next_readable_string(r.next() % (maxkeylen + 1));
if (keyset.count(k) == 1)
goto retry;
keyset.insert(k);
swap(keys[i], k);
btr.insert(varkey(keys[i]), (typename testing_concurrent_btree::value_type) keys[i].data());
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == keyset.size());
for (size_t i = 0; i < nkeys; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(varkey(keys[i]), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) keys[i].data());
}
test_range_scan_helper::expect ex(keyset);
test_range_scan_helper tester(btr, varkey(""), NULL, false, ex);
tester.test();
#ifdef HAVE_REVERSE_RANGE_SCANS
const string mkey = maxkey(maxkeylen);
test_range_scan_helper tester_rev(btr, varkey(mkey), NULL, true, ex);
tester_rev.test();
#endif
for (size_t i = 0; i < nkeys; i++) {
btr.remove(varkey(keys[i]));
btr.invariant_checker();
}
ALWAYS_ASSERT(btr.size() == 0);
}
static void
test_insert_remove_mix()
{
testing_concurrent_btree btr;
fast_random r(38953623328597);
// bootstrap with keys, then alternate insert/remove
const size_t nkeys_start = 100000;
vector<string> start_keys_v;
set<string> start_keys;
for (size_t i = 0; i < nkeys_start; i++) {
retry:
string k = r.next_readable_string(r.next() % 200);
if (start_keys.count(k) == 1)
goto retry;
start_keys_v.push_back(k);
start_keys.insert(k);
ALWAYS_ASSERT(btr.insert(varkey(k), (typename testing_concurrent_btree::value_type) k.data()));
}
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == start_keys.size());
vector<string> insert_keys_v;
set<string> insert_keys;
for (size_t i = 0; i < nkeys_start; i++) {
retry1:
string k = r.next_readable_string(r.next() % 200);
if (start_keys.count(k) == 1 || insert_keys.count(k) == 1)
goto retry1;
insert_keys_v.push_back(k);
insert_keys.insert(k);
}
for (size_t i = 0; i < nkeys_start; i++) {
ALWAYS_ASSERT(btr.remove(varkey(start_keys_v[i])));
ALWAYS_ASSERT(btr.insert(varkey(insert_keys_v[i]), (typename testing_concurrent_btree::value_type) insert_keys_v[i].data()));
}
btr.invariant_checker();
ALWAYS_ASSERT(btr.size() == insert_keys.size());
}
namespace mp_test1_ns {
static const size_t nkeys = 20000;
class ins0_worker : public btree_worker {
public:
ins0_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
for (size_t i = 0; i < nkeys / 2; i++)
btr->insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
}
};
class ins1_worker : public btree_worker {
public:
ins1_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
for (size_t i = nkeys / 2; i < nkeys; i++)
btr->insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
}
};
}
static void
mp_test1()
{
using namespace mp_test1_ns;
// test a bunch of concurrent inserts
testing_concurrent_btree btr;
ins0_worker w0(btr);
ins1_worker w1(btr);
w0.start(); w1.start();
w0.join(); w1.join();
btr.invariant_checker();
for (size_t i = 0; i < nkeys; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(btr.search(u64_varkey(i), v));
ALWAYS_ASSERT(v == (typename testing_concurrent_btree::value_type) i);
}
ALWAYS_ASSERT(btr.size() == nkeys);
}
namespace mp_test2_ns {
static const size_t nkeys = 20000;
class rm0_worker : public btree_worker {
public:
rm0_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
for (size_t i = 0; i < nkeys / 2; i++)
btr->remove(u64_varkey(i));
}
};
class rm1_worker : public btree_worker {
public:
rm1_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
for (size_t i = nkeys / 2; i < nkeys; i++)
btr->remove(u64_varkey(i));
}
};
}
static void
mp_test2()
{
using namespace mp_test2_ns;
// test a bunch of concurrent removes
testing_concurrent_btree btr;
for (size_t i = 0; i < nkeys; i++)
btr.insert(u64_varkey(u64_varkey(i)), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
rm0_worker w0(btr);
rm1_worker w1(btr);
w0.start(); w1.start();
w0.join(); w1.join();
btr.invariant_checker();
for (size_t i = 0; i < nkeys; i++) {
typename testing_concurrent_btree::value_type v = 0;
ALWAYS_ASSERT(!btr.search(u64_varkey(i), v));
}
ALWAYS_ASSERT(btr.size() == 0);
}
namespace mp_test3_ns {
static const size_t nkeys = 20000;
class rm0_worker : public btree_worker {
public:
rm0_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
// remove the even keys
for (size_t i = 0; i < nkeys; i += 2)
btr->remove(u64_varkey(i));
}
};
class ins0_worker : public btree_worker {
public:
ins0_worker(testing_concurrent_btree &btr) : btree_worker(btr) {}
virtual void run()
{
// insert the odd keys
for (size_t i = 1; i < nkeys; i += 2)
btr->insert(u64_varkey(i), (typename testing_concurrent_btree::value_type) i);
}
};
}
static void
mp_test3()
{
using namespace mp_test3_ns;
// test a bunch of concurrent inserts and removes
testing_concurrent_btree btr;
// insert the even keys
for (size_t i = 0; i < nkeys; i += 2)
btr.insert(u64_varkey(u64_varkey(i)), (typename testing_concurrent_btree::value_type) i);
btr.invariant_checker();
rm0_worker w0(btr);
ins0_worker w1(btr);
w0.start(); w1.start();