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// Copyright (c) 2015-2018 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <vector>
#include <prevector.h>
#include <reverse_iterator.h>
#include <serialize.h>
#include <streams.h>
#include <test/test_bitcoin.h>
#include <boost/test/unit_test.hpp>
BOOST_FIXTURE_TEST_SUITE(prevector_tests, TestingSetup)
template<unsigned int N, typename T>
class prevector_tester {
typedef std::vector<T> realtype;
realtype real_vector;
realtype real_vector_alt;
typedef prevector<N, T> pretype;
pretype pre_vector;
pretype pre_vector_alt;
typedef typename pretype::size_type Size;
bool passed = true;
FastRandomContext rand_cache;
uint256 rand_seed;
template <typename A, typename B>
void local_check_equal(A a, B b)
{
local_check(a == b);
}
void local_check(bool b)
{
passed &= b;
}
void test() {
const pretype& const_pre_vector = pre_vector;
local_check_equal(real_vector.size(), pre_vector.size());
local_check_equal(real_vector.empty(), pre_vector.empty());
for (Size s = 0; s < real_vector.size(); s++) {
local_check(real_vector[s] == pre_vector[s]);
local_check(&(pre_vector[s]) == &(pre_vector.begin()[s]));
local_check(&(pre_vector[s]) == &*(pre_vector.begin() + s));
local_check(&(pre_vector[s]) == &*((pre_vector.end() + s) - real_vector.size()));
}
// local_check(realtype(pre_vector) == real_vector);
local_check(pretype(real_vector.begin(), real_vector.end()) == pre_vector);
local_check(pretype(pre_vector.begin(), pre_vector.end()) == pre_vector);
size_t pos = 0;
for (const T& v : pre_vector) {
local_check(v == real_vector[pos++]);
}
for (const T& v : reverse_iterate(pre_vector)) {
local_check(v == real_vector[--pos]);
}
for (const T& v : const_pre_vector) {
local_check(v == real_vector[pos++]);
}
for (const T& v : reverse_iterate(const_pre_vector)) {
local_check(v == real_vector[--pos]);
}
CDataStream ss1(SER_DISK, 0);
CDataStream ss2(SER_DISK, 0);
ss1 << real_vector;
ss2 << pre_vector;
local_check_equal(ss1.size(), ss2.size());
for (Size s = 0; s < ss1.size(); s++) {
local_check_equal(ss1[s], ss2[s]);
}
}
public:
void resize(Size s) {
real_vector.resize(s);
local_check_equal(real_vector.size(), s);
pre_vector.resize(s);
local_check_equal(pre_vector.size(), s);
test();
}
void reserve(Size s) {
real_vector.reserve(s);
local_check(real_vector.capacity() >= s);
pre_vector.reserve(s);
local_check(pre_vector.capacity() >= s);
test();
}
void insert(Size position, const T& value) {
real_vector.insert(real_vector.begin() + position, value);
pre_vector.insert(pre_vector.begin() + position, value);
test();
}
void insert(Size position, Size count, const T& value) {
real_vector.insert(real_vector.begin() + position, count, value);
pre_vector.insert(pre_vector.begin() + position, count, value);
test();
}
template<typename I>
void insert_range(Size position, I first, I last) {
real_vector.insert(real_vector.begin() + position, first, last);
pre_vector.insert(pre_vector.begin() + position, first, last);
test();
}
void erase(Size position) {
real_vector.erase(real_vector.begin() + position);
pre_vector.erase(pre_vector.begin() + position);
test();
}
void erase(Size first, Size last) {
real_vector.erase(real_vector.begin() + first, real_vector.begin() + last);
pre_vector.erase(pre_vector.begin() + first, pre_vector.begin() + last);
test();
}
void update(Size pos, const T& value) {
real_vector[pos] = value;
pre_vector[pos] = value;
test();
}
void push_back(const T& value) {
real_vector.push_back(value);
pre_vector.push_back(value);
test();
}
void pop_back() {
real_vector.pop_back();
pre_vector.pop_back();
test();
}
void clear() {
real_vector.clear();
pre_vector.clear();
}
void assign(Size n, const T& value) {
real_vector.assign(n, value);
pre_vector.assign(n, value);
}
Size size() const {
return real_vector.size();
}
Size capacity() const {
return pre_vector.capacity();
}
void shrink_to_fit() {
pre_vector.shrink_to_fit();
test();
}
void swap() {
real_vector.swap(real_vector_alt);
pre_vector.swap(pre_vector_alt);
test();
}
void move() {
real_vector = std::move(real_vector_alt);
real_vector_alt.clear();
pre_vector = std::move(pre_vector_alt);
pre_vector_alt.clear();
}
void copy() {
real_vector = real_vector_alt;
pre_vector = pre_vector_alt;
}
~prevector_tester() {
BOOST_CHECK_MESSAGE(passed, "insecure_rand: " + rand_seed.ToString());
}
prevector_tester() {
SeedInsecureRand();
rand_seed = insecure_rand_seed;
rand_cache = insecure_rand_ctx;
}
};
BOOST_AUTO_TEST_CASE(PrevectorTestInt)
{
for (int j = 0; j < 64; j++) {
prevector_tester<8, int> test;
for (int i = 0; i < 2048; i++) {
if (InsecureRandBits(2) == 0) {
test.insert(InsecureRandRange(test.size() + 1), InsecureRand32());
}
if (test.size() > 0 && InsecureRandBits(2) == 1) {
test.erase(InsecureRandRange(test.size()));
}
if (InsecureRandBits(3) == 2) {
int new_size = std::max(0, std::min(30, (int)test.size() + (int)InsecureRandRange(5) - 2));
test.resize(new_size);
}
if (InsecureRandBits(3) == 3) {
test.insert(InsecureRandRange(test.size() + 1), 1 + InsecureRandBool(), InsecureRand32());
}
if (InsecureRandBits(3) == 4) {
int del = std::min<int>(test.size(), 1 + (InsecureRandBool()));
int beg = InsecureRandRange(test.size() + 1 - del);
test.erase(beg, beg + del);
}
if (InsecureRandBits(4) == 5) {
test.push_back(InsecureRand32());
}
if (test.size() > 0 && InsecureRandBits(4) == 6) {
test.pop_back();
}
if (InsecureRandBits(5) == 7) {
int values[4];
int num = 1 + (InsecureRandBits(2));
for (int k = 0; k < num; k++) {
values[k] = InsecureRand32();
}
test.insert_range(InsecureRandRange(test.size() + 1), values, values + num);
}
if (InsecureRandBits(5) == 8) {
int del = std::min<int>(test.size(), 1 + (InsecureRandBits(2)));
int beg = InsecureRandRange(test.size() + 1 - del);
test.erase(beg, beg + del);
}
if (InsecureRandBits(5) == 9) {
test.reserve(InsecureRandBits(5));
}
if (InsecureRandBits(6) == 10) {
test.shrink_to_fit();
}
if (test.size() > 0) {
test.update(InsecureRandRange(test.size()), InsecureRand32());
}
if (InsecureRandBits(10) == 11) {
test.clear();
}
if (InsecureRandBits(9) == 12) {
test.assign(InsecureRandBits(5), InsecureRand32());
}
if (InsecureRandBits(3) == 3) {
test.swap();
}
if (InsecureRandBits(4) == 8) {
test.copy();
}
if (InsecureRandBits(5) == 18) {
test.move();
}
}
}
}
BOOST_AUTO_TEST_SUITE_END()
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